So, I’ve decided to try a slightly different approach for the next while—one that has these sorts of folks in mind. From time to time, you can still expect those more in-depth, technical articles, or perhaps a discussion of some new research that makes the popular press, or even an analysis of some new argument from the IDM or RTB. These will be breaks from the new routine, however. For the most part, we’re going to stick to the basics, much like you would if you took an introductory evolution course at a university. Don’t worry, though: this course doesn’t have any prerequisites! All that’s needed is a willingness to learn.

What you can expect

The goal of this course is straightforward: to provide evangelical Christians with a step-by-step introduction to the science of evolutionary biology.  This will provide benefits beyond just the joy of learning more about God’s wonderful creation. An understanding of the basic science of evolution is of great benefit for reflecting on its theological implications, since this reflection can then be done from a scientifically-informed perspective. From time to time we might comment briefly on some issues of theological interest (and suggest resources for those looking to explore those issues further), but for the most part, we’re going to focus on the science. For folks interested in the interaction between science and Christianity, I heartily recommend Ted Davis’ recent series as a fabulous introduction to the topic.

You can also expect a slow, patient pace. Since this course is intended for folks with little or no background in biology, we’re going to take our time to make sure no one gets left behind. This might be frustrating to folks who already know a fair bit about evolution. Hopefully even more knowledgeable readers will learn some new and interesting details along the way—but the goal will primarily be to help folks who are less well versed in evolution increase their understanding.

You can also expect a survey of many different areas that have some bearing on evolution. We’ll examine geology, paleontology, biogeography, genetics, and a host of other topics in order to provide a “big picture” overview. This broad-brush approach means that any given individual post will not necessarily be “convincing” to folks who have doubts about evolution. Think about assembling a large jigsaw puzzle: placing any individual piece, on its own, doesn’t convincingly demonstrate what the overall picture will show. This course will be like that. Each topic we cover will put a few pieces in place here and there, slowly building towards the final overall picture.

Since evolution is an active science, this process will also highlight where there are “missing pieces” that are still being sought by scientists. All of this is well and good, since the purpose of this course is not so much to convince anyone of the validity of evolutionary theory, but rather to inform readers about the nature and scope of evolution as a scientific theory in the present day. My goal is to provide readers with a basic understanding of what evolution is and how it works. Given that as the primary goal, if one finds the scope of the evidence ultimately convincing (or not) is somewhat beside the point. The intent here is to provide readers with information they can use to make their own, informed decision.

How you can help

First and foremost, you can help by spreading the word about this series to folks you think would be interested in learning more about evolution in a non-threatening environment. Secondly, you can help me by asking questions in the comments. One of the challenges of being a specialist is having the ability to put oneself in the shoes of someone just starting out. What might seem obvious to me may not seem obvious to you, and I hope you’ll feel that no question is too basic or too simplistic. If you’re wondering about something, it’s almost guaranteed that other folks are, too! So, please don’t be shy. I’ll do my best to answer questions in the comments, though I hope that some of our more skilled commenters will (respectfully!) help out here, as well. Finally, you can help by letting me know what broader areas of evolution you find confusing. I have my own ideas about what areas of evolution are commonly misunderstood, but I’d love to hear from readers about what areas they find difficult to understand. I’ll use this input to shape the topics I will cover as we go forward.

Getting started

In the next post in this course, we’ll dive into the course content by introducing two key areas: how scientific theories work in general, and how evolution in particular works as the current organizing theory of modern biology. 

Good science has an addiction to theories,¹ and for science to be good science, it must deal with good scientific theories.  What constitutes a good scientific theory?  That is a very involved question, but a user’s view of good scientific theories looks something like this:

1.  A scientific theory is not a guess or suspicion.  For example, “I have a theory about who shot President Kennedy,” reflects the colloquial meaning of the word “theory,” and not the meaning conveyed by scientists when they use the word “theory.”  
2. Scientific theories are convincing explanatory frameworks that efficiently integrate a large body of evidence about the world.  Good scientific theories have the capacity to make sense of a wide range of data that made less sense before the introduction of the theory. 
3. In order to be called a scientific theory, it must have been successfully tested and re-tested many times.²
4. A scientific theory must be falsifiable in order to be truly scientific.  The theory has to live constantly at risk from new data.³ 
5. A theory must have predictive power.⁴  Good theories allow scientists to make predictions based on the theory that, when tested, turn out to be at least roughly correct. 

These are not the only characteristics of a scientific theory, but they probably represent the most important features for practitioners of science. 

If we hold contemporary evolutionary theory to these standards, how well does it do?  Since the inception of evolutionary theory by Charles Darwin in 1859 with the publication of On the Origin of Species, there are four characteristics of evolutionary theory that have endured 150 years of further research:

1. Living species are descendants of other species that lived in the past.
2. These past species lived in populations that underwent gradual transformation so that the individuals in these populations changed their appearance, behaviors, metabolisms, and life histories over long spans of time.⁵
3. New forms of life arose by means of a process called speciation in which one lineage splits into two distinct lineages.  This continual splitting of organismal lineages leads to a nested genealogy of species.  This nested genealogy forms a veritable tree of life, whose root represents the first species to arise and whose twigs represent the millions of species living today.  If you trace back any pair of twigs from the modern species you will find that their histories merge at some node on the tree where the two species share a common ancestor.⁶ 
4. This process of biological change that takes place throughout the advance of geologic time, or evolution, occurs by means of variation in organisms (which we know today is due to genetic mutations) that is acted on by either random genetic drift or natural selection. Those individuals with variations better suited to the current environment leave more offspring, thus changing the average appearance of the population over time and making it a better fit to the environment. This improving fit between organisms and their environment gives the appearance of organisms having been well designed for their milieu.⁷ 

What is the evidence for these aspects of evolutionary theory?  The evidence is actually immense, but I will restrict this discussion to just a few items. 

First there is the fossil record. If life results from a natural process such as biological evolution, then we should observe a progression of fossil organisms that proceed from relatively simple, single-celled organisms in the oldest rocks to more complex, multicellular organisms in younger rocks. When paleontologists examine the geologic column, they perceive that some of the oldest and deepest layers of the geologic column contain fossils of microorganisms, and then marine invertebrates in younger layers above those,⁸ and then much later and higher up in the geologic column fish appear, followed later and higher still by amphibians, and then by reptiles, mammals, and birds.⁹  Thus, the general presentation of the fossil record in the rock record comports exactly with what the theory of evolution predicts. 

However, the fossil story gets even better, because scientists can trace evolutionary trends throughout the fossil record.  For example, horses get bigger, fuse their leg bones and toes into a single bone with a thick hoof and grow the thickness of their tooth enamel;¹⁰ Cenozoic brachiopod shells get narrower, decrease their rib numbers and beak angle;¹¹ diatoms get bigger;¹² and primate fossils reduce the size of their teeth and expand the size of their brains.¹³ 

Additionally, Darwin predicted that there should be organisms preserved in the fossil record that possess features found in two different types of creatures. Such organisms are “transitional forms” that bridge the gap between different types of organisms.¹⁴ However, the fossil record of Darwin’s time provided little evidence of such transitional forms.¹⁵ Therefore, Darwin gambled that future paleontological research would provide sufficient evidence to corroborate his theory. How did this gamble turn out? Since Darwin’s time, paleontologists have discovered transitional fossils that are part fish and tetrapod,¹⁶ part amphibian and part reptile,¹⁷ part dinosaur and part bird,¹⁸ and part reptile and part mammal.¹⁹ Once again, we would predict such paleontological trends and the existence of such transitional fossils if life came about through a process of organic evolution. Clearly paleontological research since Darwin’s time has powerfully vindicated his theory. 

Please join us for part two of this post tomorrow, where we will discuss how signs of evolution can be detected in organisms living today, and how evidence from multifarious scientific fields—not just biology and paleontology—have bolstered the theory of evolution and added to our understanding of how natural selection works.

Notes

1. Ratzsch, Del. The Battle of Beginnings: Why Neither Side Is Winning the Creation-Evolution Debate. Downer’s Grove, WI: Intervarsity Press, 1996. pp. 104–119. 
2. Kitcher, Philip. Abusing Science: The Case Against Creationism. Cambridge, MA: MIT Press, 1983. pp. 45–54.
3. Ibid, 42–48.  .
4. Ratzsch, Del. Science and Its Limits: The Natural Sciences in Christian Perspective. Downer’s Grove, WI: Intervarsity Press, 2000. pp. 21–24. 
5. Hall, Brian K., and Benedikt Hallgrimsson. Strickberger’s Evolution. 5th ed. Burlington, MA: Jones and Bartlett, 2013. pp. 19–68. 
6. Kitcher, Philip. Living With Darwin: Evolution, Design, and the Future of Faith. New York: Oxford University Press, 2009. pp. 43–71. 
7. Futuyma, Douglas J. Evolution. 3rd ed. Sundbury, MA: Sinauer Associates, 2013. pp. 281–343. 
8. Valentine, James W. On the Origin of Phyla. Chicago: University of Chicago Press, 2006. pp. 429–464. 
9. Carroll, Robert L. Vertebrate Paleontology and Evolution. New York: W. H. Freeman and Company, 1990. 
10. MacFadden, “Horses, the Fossil Record, and Evolution,” 131–158; McFadden, Bruce J. “Fossil Horses from "Eohippus" (Hyracotherium) to Equus: Scaling, Cope's Law, and the Evolution of Body Size.” Paleobiology 12, no. 4 (1986): 355–69.; Prothero, Donald R., and R.M. Schoch, eds. The Evolution of Perissodactyls. New York: Clarendon Press, 1989. ; McFadden, Bruce J. Fossil Horses. Systematics, Paleobiology, and Evolution of the Family Equidae. Cambridge, Cambridge University Press, 1993. 
11. McNamara, Kenneth J. “Evolutionary Trends.” In Encyclopedia of Life Sciences (New York: Macmillan Publishers Ltd, 2001), pp. 1–7. 
12. Litchman, E., C. A. Klausmeier, and K. Yoshiyama. “Contrasting Size Evolution in Marine and Freshwater Diatoms.” Proceedings of the National Academy of Sciences USA 106, no. 8 (2009): 2665–2670.
13. Tattersall, Ian. The Fossil Trail: How We Know What We Think We Know About Human Evolution. New York: Oxford University Press, 2008. pp. 89–198. 
14. Darwin, Charles. On the Origin of Species by Means of Natural Selection or the Preservation of Favoured Races in the Struggle for Life. London: Penguin Books, 1985. p. 292.
15. Hunt, Gene. “Evolution in Fossil Lineages: Paleontology and The Origin of Species.” Supplement American Naturalist 176 (2010): S61–S76. 
16. Clack, Jennifer A. Gaining Ground: The Origin and Evolution of Tetrapods. Bloomington, IN: Indiana University Press, 2002; Daeschler, Edward B., Neil H. Shubin, and Farish A. Jenkins, Jr. “A Devonian Tetrapod-Like Fish and the Evolution of the Tetrapod Body Plan,” Nature 440, no. 7085 (2006): 757–63; Shubin, Neil H., Edward B. Daeschler, and Farish A. Jenkins, Jr. “The Pectoral Fin of Tiktaalik roasae and the Origin of the Tetrapod Limb.” Nature 440, no. 7085 (2006).): 764–71; Downs, Jason P., Edward B. Daeschler, Farish A. Jenkins, and Neil H. Shubin. "The Cranial Endoskeleton of Tiktaalik roseae." Nature 455, no. 7215 (2008): 925–9. 
17. Carroll, Robert L. Vertebrate Paleontology and Evolution. New York: W. H. Freeman and Company, 1990. pp. 156–216. 
18. Shipman, Pat. Taking Wing: Archaeopteryx and the Evolution of Bird Flight. New York: Touchstone, 1998. pp. 169–244.  
19. Prothero, Donald R. Evolution: What the Fossils Say and Why It Matters. New York: Columbia University Press, 2007. pp. 271–297. 

In concordist interpretations, God made the earth using the sequence of events described in Genesis 1. In non-concordist interpretations, God created the earth using a different timing and order of events than those described Genesis 1.

How should Christians go about choosing among all of these interpretations? Such a decision should be based on consistent principles and prayerful reflection, not just on “what sounds good.” Here are our own conclusions.

Weaknesses in Concordist and Non-Concordist Interpretations

Both concordist and non-concordist interpretations of Genesis 1 arise from good motives, a desire to show that the Bible does not conflict with nature’s testimony.  But both types of interpretations have their pitfalls.

For concordists, the temptation is to interpret every Bible verse to match the current scientific picture. The meanings of particular phrases can be bent out of shape to match a particular scientific finding. For example, Hebrew words that literally meant birds or plants to the original audience are redefined to meet some modern scientific category such as insects or single-celled organisms, just to make the order of events line up. By focusing on trying to match the details of the ancient text to twenty-first century knowledge, the concordist may miss meanings in the passage that were clear in the original cultural context, including important spiritual insights. Moreover, concordists can be forced to regularly change and update their interpretations as modern scientific knowledge grows and changes. For instance, the Gap Interpretation twisted the meaning of Genesis 1:2 outside its original intent; later it failed to match new scientific evidence.

For non-concordists the temptation is to interpret every Bible verse that appears to disagree with science as figurative without first studying the text. By interpreting a text that was intended tobe understood literally as metaphoric, they may bend the meanings of particular phrases to refer to purely spiritual ideas and ignore the historical meanings they had in the original cultural context. At one extreme non-concordists can apply the same strategy to all Bible passages and even interpret Jesus’ miracles and resurrection as spiritual symbols simply because they think that miracles are scientifically impossible.

For both concordists and non-concordists the temptation is to let science drive the interpretation of Scripture more than it should. When an apparent conflict arises between science and a biblical text, it can and should motivate us to consider a biblical passage more closely. The scientifically discerned testimony from God’s book of nature can even be a useful tool for deciding between two or more biblical interpretations that are otherwise equally valid. But the interpretations themselves are not determined by science; they must be driven by theological considerationsand be consistent with the rest of Scripture.

To avoid these risks we need to look at what the best biblical scholarship has to say about the passage rather than at how it fitswith science. Finally, we must take care that the desire to resolve conflicts does not distract us from the main message God has forus in the text. Our primary calling as Christians is to live our lives according to the clear messages of God’s Word; it is a lesser calling to debate the subtleties of interpretation of less clear passages.

Genesis 1 in Its Original Context

To choose among the various interpretations, we recommend using a consistent approach based on the principles of biblical interpretation discussed in chapter 4.  The first principle, that each passage should be interpreted in light of the rest of the Bible, provides some guidance. For instance, the Bible’s teaching on God’s truthfulness and his glory displayed in creation might lead us away from the Appearance of Age Interpretation.  The differences between the Genesis 1 and Genesis 2 accounts might point toward a non-concordist interpretation.

The second principle of interpretation gives more direction. It reminds us first to work out what the passage meant in its original literary, cultural, and historical context, and then figure out what meaning it has for us today. How do the various interpretations fit this principle? Of the four concordist interpretations discussed in chapter 5, the Young Earth Interpretation seems to come closest to what ancient peoples would have heard in the text. The Gap and Day-Age concordist views would have baffled the original audience, since these ancients would have had no concept of geological ages; if they could not fathom time periods of millions or billions of years, the text must have meant something different to them.

Of the four non-concordist interpretations of Genesis discussed in this chapter, the Proclamation Day Interpretation, while it has some basis in the text, seems least likely to be the meaning heard by the original audience. The proclamations are implemented as soon as God says them, and there is no reference to a different timing or sequence of events in terrestrial time. In our view a combination of the Ancient Near East Cosmology, Kingdom and Covenant, and Creation Poem Interpretations come closest to what the original audience would have heard. The differences between the Genesis text and the pagan stories highlight the sovereignty of God and the goodness of creation. The elegant poetic structure and inspired phrases reinforce the theological messages of the Kingdom and Temple interpretations.

Genesis 1 for Modern Readers

With a better understanding of what the original audience heard,we have insight into God’s message for them and thus for us. If God’s purposes in Genesis 1 did not include teaching scientific facts to the Israelites, then we should not look here for scientific information about the age or development of the world. For modern readers, as for the original audience, the message of Genesis 1 is its powerful theological truths. God does not use theBible to teach us the physical processes he uses to make the rainfall or the earth orbit the sun or to form the mountains. Instead, in a beautifully crafted and impressively short text, God teaches us all about

• his sovereignty.
• the goodness of creation.
• the honored status of humankind as his image bearers.

God has given us a text that speaks of the physical world in simple terms, based on how it appears, in order that all peoplemight understand it.  The common language of this text has made it accessible to people of many times and cultures, aiding the communication ofthe gospel around the world.

Does a non-concordist interpretation of Genesis 1 mean that we have sacrificed a literal understanding of the gospel? No. TheGospels were surely heard by their first audience as historical eyewitness accounts by the disciples, and everything about the emphasis and tone in those books indicates that Jesus’ resurrection and miracles are essential events in the story. That is how we should read the Gospel stories still today. In Genesis 1, on theother hand, the first listeners heard nothing new about the physical universe; all the emphasis was on who created the world and humanity and why they were created.

What does this mean for science? It means that Genesis 1 is not a science textbook. The text was never intended to teach scientificinformation about the structure, age, or natural history of the world. Thus, comparing Genesis 1 to modern science is likecomparing apples to oranges. Or perhaps more accurately, comparing Genesis 1 to modern science is like comparing Psalm 93:1 (“The world is firmly established; it cannot be moved”) to modern astronomy. Genesis is neither in agreement nor in conflict with the sequence of events found by astronomy and geology.

As scientific knowledge increases and changes over the centuries, its understanding of the physical structure and historyof the earth will change. But through all of those centuries the theological truths of Genesis 1 remain the same: there is one sovereign God who makes light from darkness, creates an ordered world from chaos, and fills an empty world with good creatures. Humans need not fear the capricious whims of a pantheon ofgods but can instead trust in the one true God who made us in his image and declares us “very good.”

For more discussion of Biblical interpretation, see chapters 4, 5, and 6 of Origins. Next week, we'll look at an excerpt on astronomy and the age of the universe.

Excerpt from Chapters 5 and 6 of Origins: Christian Perspectives on Creation, Evolution, and Intelligent Design (Grand Rapids, MI: Faith Alive Christian Resources), 2011. Reprinted with permission. To order purchase a copy of the book or e-book, please call 1-800-333-8300 or visit our website www.faithaliveresources.org.

Want a free copy of Origins?  For a limited time, donations of $50 or more will receive a  copy of the book! Plus, from now through April, your gift will be doubled thanks to a matching grant from a generous donor. You can learn more here.

I was raised in a Christian home, where the Bible was a part of daily life. My family was very committed (probably overcommitted) to our local church, my father read the Bible aloud every night, and in a given year I probably went to half a dozen Bible-centered events. The only test I ever failed was in 7th grade.Every question on the test was about evolution, and every answer I gave was from the Bible. I wasn't a scientist but knew what Scripture said was sufficient for me.

By the time I graduated high school, I had memorized more Scripture than most people do in a lifetime, and along the way I had read dozens, probably hundreds, of books about spiritual warfare, the end times, and the mountains of evidence which proved the Genesis creation account was absolute fact. And in my sophomore year of college, I had made the ultimate sacrifice: I had given up on my intended lucrative career in psychiatry to pursue the thankless, penniless life of a minister, because I was certain that's what God was calling me to do.

So there I sat in a class on the prophets, giving a brilliant (in my estimation) explanation of how Daniel's 70th week and Revelation fit together, when my professor leveled that unforgivable charge, "You don't take Scripture seriously." Perhaps you can understand now why the very thought offended me. He asked me to turn to 2 Timothy 3 and read verses 16 and 17. I did him one better and quoted them without hesitation.

"All Scripture is God-breathed and is useful for teaching, rebuking, correcting and training in righteousness, so that the man of God may be thoroughly equipped for every good work."

He was not impressed by my instant recall, and pressed on making his point.

"Can you tell me where in the Bible it says Scripture is useful for telling the future?"

I could not.

"Where does it say Scripture is a primer on the end times?"

It doesn't.

"How about Math, or history, or geography, or science?"

No, I didn't know those passages either. He continued.

"The problem, Shea, is that you are asking Scripture questions it's not meant to answer, and not bothering with the questions it does. How does your analysis of these prophecies equip people to do good works? How does it teach, rebuke, correct, or train them in such a way that they can be righteous? If your interpretations can't do any of these things, then what's the point in having them?"

I couldn't bring myself to say it at the time, but my professor was completely right. I had spent so much time using the Bible as evidence to prove my point that I hadn't bothered to consider its intended purpose. It was as if I had been given a nice new pair of shoes, but instead of wearing them and letting them take me where I needed to go, I had been using them to kill bugs, prop open doors, and fix wobbly table legs. Shoes can be made to do all of those things, but that's not their purpose. There are other items out there that do those jobs a whole lot better. I hated to admit it, but I knew that I had to reconsider everything I thought I knew about Scripture.

So I began studying in earnest once more, but this time instead of trying to gather facts and evidence, I would ask myself "what is there about this passage that helps me to be prepared for good works?" Sometimes it changed my understanding a little, sometimes a lot, and sometimes not at all. But when I finally decided to tackle Genesis, everything changed. I half-read, half-remembered the seven day creation account. As I read, asking how this passage fulfilled the purpose of Scripture, I was amazed. This was the story about a God who cared about everything in the universe. It was a story about a God who looks at the world, at living things, and even at humans, and calls them "good." But they weren't just good. Those humans were a reflection of who God was. They bore in themselves an image of the Divine. It was a beautiful, intimate story about God's special love for and relationship with humans, which included me. It was then that I realized I could no longer read this, one of the greatest love poems ever written, as though it were a list of facts whose only use was to prove others wrong.

I am still not a scientist. I have read a lot on the subject, but I can't really tell you with absolute certainty the age of the earth or the timeline of how humans came into being. What I can tell you is what I learned the hard way: to really take Scripture seriously, we have to let Scripture do what it was meant to do. Scientists may find indisputable evidence tomorrow that this or that story in the Bible didn't happen exactly as written, but that won't matter one bit for those who take Scripture seriously. We need not plug our ears or drown out the voice of the scientists because we know the right question to ask of Scripture, and it is not, "Is that exactly the way it happened?" Scientists will do what they do best, proving and disproving this or that theory. We will be able to accept that with ease because we take Scripture, and its purpose, seriously.

Grantees will benefit from in-person interaction through a series of summer workshops in 2013, 2014, and 2015. These meetings will not only foster a broader knowledge base, but will build a sustained network of scholars and church leaders, both young and seasoned, who are serious about addressing the concerns of the church about evolution. Also in 2015, in connection with the third summer workshop, BioLogos will host a large conference open to scientists, scholars, and church leaders from around the world.

ECF History

In January 2012, BioLogos was awarded a multi-million dollar grant from the John Templeton Foundation to fund the work of scholars and church leaders on evolution and Christian faith. In spring 2012 we worked hard to get the word out. You may have seen announcements on the BioLogos website, in our newsletters, on the Books & Culture, Leadership Journal, or First Things websites, on your professional society’s listserv, or perhaps on your friend’s blog.

The response was overwhelming: we received 225 letters of intent for a total request of $21 million—about seven times the amount we had to offer. We needed to invite the most promising applicants to submit a full proposal, but recognizing the projects with highest potential would require broad expertise. From the beginning, we envisioned that a panel of scientists, pastors, and scholars would oversee the application and review process as well as play key advisory roles throughout the project. A team of eight highly qualified individuals came on board in the early months of the project. They reviewed each proposal and together recommended that BioLogos invite 86 applicants to submit full applications.

The deadline for submissions was October 1, 2012. As in the previous round, the ECF panel evaluated each proposal. In addition, we asked 55 other experts to participate, so that each proposal received 3-4 scores. Criteria for the decision included significance of topic, project design, creativity and innovation, long-term impact potential, feasibility, and budget.

The panel then met together November 29-30, 2012, to make the final funding decisions. In the end, they recommended that BioLogos give 37 awards, ranging from $23,000 to $300,000. BioLogos staff notified applicants of their awards on December 14, 2013.

The Grantees

As part of our objective to create a network of scholars and leaders, we awarded grants to organizations across the U.S. and the world. Thirty of the 37 grantees are domestic; seven are international, hailing from Canada, France, Great Britain, Netherlands, and Spain.

Two-thirds of the accepted projects will be led by teams—some with three or more Project Leaders. We expect that the teamwork and time spent together at our summer workshops will be the start of a long-lasting network of people dedicated to helping the church think carefully about origins.

Applicants chose to apply under one of three program tracks: interdisciplinary scholarship (Track 1), intra-disciplinary scholarship (Track 2), and translational projects (Track 3). Track 1 projects focus on both the collaboration between individuals in different disciplines and the development of projects at the interface of different content areas. Track 2 projects focus on work done within a specific discipline. Track 3 focuses on projects that encourage Christians, especially those within more conservative traditions, to engage in meaningful and productive dialogue to reduce tensions between mainstream science and the Christian faith. The numbers of grantees in Tracks 1, 2, and 3 are 6, 8, and 23, respectively.

Many of the scholarly projects tackle questions about Adam and Eve, the Fall, human identity, and Original Sin—some of the most critical interpretive issues for evangelical theology.  Some examples: 

• Theologian Oliver Crisp of Fuller Seminary will take an analytic theology approach to ask to what extent a theological account of the origin of human sin depends upon the evolution of modern humans from one and only one ancestral pair—especially if that pair does not appear to correspond to what we would think of as modern human beings. 

• Pastor Michael Gulker and philosopher James Smith, leading a large team from The Colossian Forum, ask a related question: if humanity emerged from non-human primates—as genetic, biological, and archaeological evidence seems to suggest—then what are the implications for Christian theology’s traditional account of origins, including both the origin of humanity and the origin of sin? 

• Biologist Dennis Venema of Trinity Western University and New Testament scholar Scot McKnight of Northern Seminary will write a book on the evidence for evolution and population genetics, with informed theological reflection on how these issues interact with orthodox Christianity.

• Biologist David Wilcox of Eastern University will develop an updated model of human identity which reflects the complex recent scientific advances in genetics and paleoanthropology and yet is sensitive to theological concerns.  

These are just a few of the scholarly awards; check out the Grantees page for full descriptions of all Track 1 and Track 2 projects.

All projects have translational potential, but Track 3 projects are designed to meet the needs of a particular constituency within the evangelical church. These projects run the gamut from ethics to education to media production to ministry resources.  Some examples include:

• Theologian Lee Camp of Lipscomb University will produce “The Questions in Monkey Town,” an episode of Tokens, a live variety show that features musical performances, comedic sketches, brief interpretive monologues, and dialog with authors and scholars. The episode will be performed and filmed on the site of the famous Scopes Trial in Dayton, Tennessee.

• Chaplain Joshua Hayashi and Educator Diane Sweeney of the Punahou School in Hawaii will lead a team to produce multimedia curricula aimed at helping high school students connect with their biology curricula and, at the same time, deepen their Christian faith.

• Physics teacher and pastor Benoît Hébert of Science et Foi Chrétienne in France will lead an international, multi-denominational team of French speaking Evangelical scientists, pastors and church leaders to produce a large number of resources on evolutionary creation.

• Pastor Seung-Hwan Kim of Grace Truth Community Church, a Southern Baptist church in Cambridge, Massachusetts, will produce teaching and preaching materials about evolution for church leaders.

• President Gregory Wolfe and Director of Resource Development for IMAGE will gather artists and writers of faith whose work explores the dialogue between evolutionary science and faith practice, convening a conversation between them and scientists, theologians, and church leaders in private and public conferences.

Again, this is just a taste of the diversity of Track 3 projects. Read more about each project on the Grantees page. You can look forward to an incredible variety of resources coming out of the ECF program, many of which will be featured right here on the BioLogos Forum.

A common argument leveled against the theory of evolution is that scientists have not been able to produce the expected transitional fossils that show the change of one species into another. If evolution were true, wouldn’t there be instances of clear intermediary species, like, for example, a species that was half whale and half hippo to show the transition between those two? In this BioLogos podcast, Kelsey Luoma addresses this misconception about what a transitional fossil actually is. Rather than a mix between two related species, transitional fossils point back to the common ancestors that modern species share. The fact is that the number of transitional species is massive and it grows with each passing year. Given the rarity with which organisms are actually fossilized, the amazing thing is actually the completeness of the fossil record, not its incompleteness. The transitional species story strongly supports, and certainly does not disprove, evolutionary theory. ¹

1. To hear the full audio clips which have been referenced go to:

• Rational Response Debate with Kirk Cameron (from Way of the Masters)
• Behind the Scenes with Dr. Neil Shubin (from Cincinnati Museum Center)
• Mark Norell Publishes New Archaeopteryx Findings (from American Museum of Natural Sciences)
• Texas A&M Professor Discusses Findings of Autralopithecus Sediba and its Relationship to Humans (from Texas A&M University)
• Intro/outro music composed by Martin Minor (Minor2Go).

An audio only version of the podcast can be downloaded here.

With his compelling personal story of becoming England’s “most reluctant convert,” his towering intellect, and his inimitable eloquence, American evangelicals’ lionization of Lewis is certainly understandable.² But when we attempt to lionize people we often ironically end up taming them, paring their claws so that our heroes and our preconceptions can safely cohabitate in our imaginations. But Lewis is no safer a lion than Aslan, and he will not go quietly into our tidy evangelical boxes. To be frank, American Evangelicalism’s infatuation with Lewis is in many respects somewhat odd. For here is a pathologically populist movement with a penchant for Big Tent Revivalism, an obsession with liturgical innovation, a deep-seated suspicion of ecclesiastical tradition, and a raw nerve about the doctrine of justification, falling head-over-heels for a tweed-jacketed, Anglo-Catholic Oxford don—a curmudgeonly liturgical traditionalist who was fuzzy on the atonement, a believer in purgatory, and, as we shall see, whose views on Scripture, Genesis, and evolution position him well outside of American Evangelicalism’s standard theological paradigms. All of that is to say that Lewis was not “just like us”—any of us—and if we would do him justice, we must be prepared to be surprised by Jack.

In what follows, I would like to look at three areas relevant to faith and science discussions where Lewis’s stated views might be surprising for his American Evangelical admirers—namely, his views on Scripture generally and Genesis in particular, his views on Adam and the doctrine of the Fall, and his views on evolutionary science and the myth of ‘Evolutionism.’

Reflections on the Scriptures: Lewis on the Bible, Myth, & Fact

Lewis derived his theological understanding of the Bible from his reading of Scripture, his intimate knowledge of the Church Fathers and the Medieval Doctors, and also from his awareness of modern biblical scholarship. While Lewis was regularly critical of Modernist biblical scholarship’s naturalistic dismissal of the miraculous, its pedantry, literary tin-ear, and over-eagerness to conflate Jesus’ story with the stories of pagan mythologies (he had precious little patience for Rudolf Bultmann, for instance ), he was not at all given to the knee-jerk reactionary Fundamentalism which has held so much sway in American Evangelical culture. In fact, Lewis incorporated many of the more well-supported conclusions of modern biblical criticism into his theology of Scripture, not least critical opinions about the historicity of much of the Old Testament. In good Anglican fashion, Lewis creatively drew upon the deep resources of the Church’s grand Tradition in order to think through the contemporary problems posed by modern critical scholarship. Here I wish to focus on three features of Lewis’s theological conception of Scripture—his understanding of the Bible as being incarnational and sacramental in character, and Christotelic in focus—before turning to his theological reading of Genesis 1-3.⁴

Inspiration and Incarnation

According to Lewis, the Bible is both a vessel of the divine Word and also a profoundly human collection of documents. In his longest, most substantive piece on Scripture, chapter XI of Reflections on the Psalms, Lewis frames a thoroughly incarnational understanding of the Bible:

The human qualities of the raw materials show through. Naïvety, error, contradiction, even (as in the cursing Psalms) wickedness are not removed. The total result is not “the Word of God” in the sense that every passage, in itself, gives impeccable science or history. It carries the Word of God; and we (under grace, with attention to tradition and to interpreters wiser than ourselves, and with the use of such intelligence and learning as we may have) receive that word from it not by using it as an encyclopedia or an encyclical but by steeping ourselves in its tone or temper and so learning its overall message.⁵

Lewis’s reference to “[the] human qualities” of the Bible’s “raw materials” is suggestive. As Peter Enns puts it in his book Inspiration & Incarnation: Evangelicals and the Problem of the Old Testament, the Incarnation of the Son and the inspiration of Scripture are “analogous.”⁶ Lewis clearly agrees. He goes on in the chapter to articulate a theology of Scripture precisely in incarnational terms:

For we are taught that the Incarnation itself proceeded “not by the conversion of the godhead into flesh, but by taking of (the) manhood into God”; in it human life becomes the vehicle of Divine life. If the Scriptures proceed not by conversion of God’s word into literature but by taking up of a literature to be the vehicle of God’s word, this is not anomalous.⁷

According to Lewis, the means whereby God gives us Scripture is not by faxing us transcripts of inner-Trinitarian dialogue direct from Heaven, but rather, on analogy with the Incarnation, by taking up very human literature and utilizing it to communicate His Divine life to us.

“We might have expected, we may think we should have preferred, an unrefracted light giving us ultimate truth in systematic form—something we could have tabulated and memorised and relied on like the multiplication table.”⁸ But God has instead deigned to give us a very human book, just as He deigned to send us a fully human Savior. Lewis makes this point most poignantly in his Introduction to J.B. Phillips’s Letters to Young Churches where he writes:

The same divine humility which decreed that God should become a baby at a peasant-woman’s breast, and later an arrested field-preacher in the hands of the Roman police, decreed also that He should be preached in a vulgar, prosaic and unliterary language. If you can stomach the one, you can stomach the other. The Incarnation is in that sense an irreverent doctrine: Christianity, in that sense, an incurably irreverent religion. When we expect that it should have come before the World in all the beauty that we now feel in the Authorised Version we are as wide of the mark as the Jews were in expecting that the Messiah would come as a great earthly King.⁹

For Lewis, God’s work in the inspiration of Scripture not only communicates but also emulates God’s humble, self-effacing work in the Incarnation. If the heart of Christianity, “an incurably irreverent religion,” should be the Incarnation, “an irreverent doctrine,” then it ought to come as no surprise that that doctrine should be most fundamentally communicated via an irreverent book.

A corollary of Lewis’ incarnational and sacramental view of Scripture is that when it comes to studying the Scriptures we must be prepared to be surprised. Lewis warns against “the Fundamentalist’s” procedure of attempting to frame our ideas of Scripture a priori, deducing parameters for what the Scriptures can and cannot be from our preconceptions about God. Lewis thinks such an approach to be a nonstarter:

[There] is one argument which we should beware of using…: God must have done what is best, this is best, therefore God has done this. For we are mortals and do not know what is best for us, and it is dangerous to prescribe what God must have done–especially when we cannot, for the life of us, see that He has after all done it.¹⁰

Instead, says Lewis, we should take a humble, a posteriori approach, looking and seeing just what kind of book it is that God has actually given us before making grand doctrinal declarations. “To a human mind,” Lewis recognizes, an incarnational Bible “seems, no doubt, an untidy and leaky vehicle.”¹¹ But it appears that this is what God has given us, and we must trust that God knows what He is doing. As Lewis says, “Since this is what God has done, this, we must conclude, was best.”¹²

Myth Became Fact

For Lewis, the Word is also like the sacrament. Just as ordinary water, bread, and wine are taken up into and become conduits for and communicators of the Divine life that we so desperately need, so, also, all-too-ordinary human writings are taken up into and become conduits for and communicators of the Divine life and word. In Lewis’s view, we must receive the Divine word by approaching Scripture in a sacramental manner. We “receive that word,” as Lewis says, again, “not by using [Scripture] as an encyclopedia or an encyclical but by steeping ourselves in its tone or temper and so learning its overall message.”¹³ For Lewis, at least when it comes to the Old Testament, receiving the Word means more than simply paying critical attention to the surface meaning of the text, the sensus literalis. Instead, we must press beyond the surface to the sensus plenior, to the “second sense” of the Old Testament, namely, Christ Himself. “It is Christ Himself, not the Bible, who is the true word of God,” Lewis once wrote in a private letter. “The Bible, read in the right spirit and with the guidance of good teachers, will bring us to Him.”¹⁴ While such Christological sensus plenior interpretation may have fallen out of favor with many Protestants (to say nothing of thoroughgoing Modernist historical-critics), Lewis believes that “[we] are committed to it in principle by Our Lord Himself.”¹⁵ Citing Jesus’ words to His disciples on the road to Emmaus, Lewis argues that Christ “accepted—indeed He claimed to be—the second meaning of Scripture.” Citing a litany of Dominical sayings and New Testament texts, Lewis is clear that Christ is mysteriously the true spiritual center, climax, coherence, sum, and substance of the Old Testament Scriptures.¹⁶

Lewis stands in good company in thinking along these lines. The “good teachers” from which Lewis learned this hermeneutic are undoubtedly Aquinas, Bernard of Clairveaux, Augustine, Origen, and Irenaeus, not to mention the Apostles and Christ Himself. In short, Lewis is standing within the mainstream tradition of pre-Reformation theological interpretation. But Lewis is not simply striking a traditionalist posture. Like a scribe trained for the Kingdom, he is prepared to bring forth treasures new and old. By positioning himself within the grand tradition of pre-modern theological interpretation, Lewis frees himself to follow his highly-attuned modern literary-critical instincts regarding the historicity of much of the Old Testament while simultaneously upholding both a robust belief in the historicity of the Incarnation and a vital theological hermeneutic. He writes:

The earliest stratum of the Old Testament contains many truths in a form which I take to be legendary, or even mythical—hanging in the clouds, but gradually the truth condenses, becomes more and more historical. From things like Noah’s Ark or the sun standing still upon Ajalon, you come down to the court memoirs of King David. Finally you reach the New Testament and history reigns supreme, and the Truth is incarnate. And “incarnate” here is more than a metaphor. It is not an accidental resemblance that what, from the point of view of being, is stated in the form “God became Man,” should involve, from the point of view of human knowledge, the statement “Myth became Fact.”¹⁷

He sets up the above paragraph by saying, “[The Christian story] is like watching something come gradually into focus; first it hangs in the clouds of myth and ritual, vast and vague, then it condenses, grows hard and in a sense small, as a historical event in first century Palestine.”¹⁸ Apart from the Incarnation, then, much of the Old Testament would be but “myth,” “ritual,” and “legend.” These elements of the Old Testament only become tangible historical “Fact,” for Lewis, in the person and work of Christ.

Next time, Williams looks at how this understanding of Scripture framed Lewis' reading of Genesis 1-3.

Note

1. C.S. Lewis, A Grief Observed, (San Francisco: Harper Collins, 2001), 66
2. See Smietana, Bob, “C.S. Lewis Superstar: How a reserved British intellectual with a checkered pedigree became a rockstar for evangelicals,” http://www.christianitytoday.com/ct/2005/december/9.28.html
3. “Through what strange process has this learned German gone in order to make himself blind to what all men except him see?,” wrote Lewis in “Modern Theology and Biblical Criticism,” in Walter Hooper, ed., Christian Reflections (Grand Rapids: Eerdmans, 1995), 156
4. I owe the word “christotelic” to my teachers at Westminster. See especially the discussion in Peter Enns’ Inspiration and Incarnation: Evangelicals and the Problem of the Old Testament, (Grand Rapids: Baker Academic, 2005)
5. Lewis, Reflections on the Psalms, (San Diego: Harcourt Inc., 1986), 111-12
6. See note xii above.
7. Lewis, Reflections on the Psalms, 116
8. Ibid, 112
9. Lewis, “Modern Translations,” in God in the Dock, (Grand Rapids: Eerdmans, 1970), 230
10. Lewis, Reflections on the Psalms, 112
11. Ibid
12. Ibid, 113
13. Ibid, 112
14. Lewis in a letter, 8 November, 1952, in W.H. Lewis, ed., Letters of C.S. Lewis, (New York: Harcourt Brace Jovanovich, 1966), 247 cited in Martindale and Root, The Quotable Lewis, 72
15. Lewis, Reflections on the Psalms, 117
16. Ibid, 117-19
17. Lewis, “Is Theology Poetry?,” in The Weight of Glory and Other Essays, (New York: Harper Collins, 2001), 129
18. Ibid

In 1774, the French chemist Antoine Lavoisier replicated the relevant experiments in more controlled ways to demonstrate that mass was conserved during combustion. He also renamed the part of the air that burned 'oxygène.' English scientists resisted the French scientist's new name, not least because the English Priestly had already published his discovery of the gas. 'Oxygen' nonetheless entered the common English vocabulary in part due to one of the first popular science books, The Botanic Garden (1791), which included a poem praising the gas using the preferred French name. By coincidence, this book also promoted some early ideas about biological evolution (specifically, it suggested that sexual reproduction might be important to evolution, which might help to explain the popularity of a book of poems about science). It was written by Erasmus Darwin, the grandfather of Charles Darwin, who first proposed the modern form of the theory of biological evolution in his 1859 book, On the Origin of Species.

150 years later, we are discovering that the lines connecting evolution and oxygen run deeper than the Darwin family tree. We now know, for instance, that for roughly half of the Earth's 4.6-billion-years of history, there was little to no oxygen in the atmosphere. Instead, oxygen entered the atmosphere in two major pulses, with one between 2.4 and 2.2 billion years ago, and another between 0.8 and 0.54 billion years ago. Recent evidence suggests that the first pulse may have actually been the largest event in a series of fits and starts beginning at around 2.7 billion years ago that finally produced a stable low oxygen atmosphere by around 1.8 billion years ago.

Remarkably, both episodes of atmospheric oxygenation happened just before explosions in biological diversity. We have spotty evidence of unicellular eukaryotes (cells with nuclei) before 2.4 billion years ago, but the first fossil evidence for large, diverse eukaryotic communities comes at 1.5 billion years ago. If you are a human, this is part of your history; humans are multicellular eukaryotes descended from one of these early unicellular pioneers. Multicellular animal life is an innovation that seems to have required more oxygen: animals don't appear in the fossil record until about 0.61 billion years ago, toward the end of the second pulse of oxygen.

It is, perhaps, not surprising that major evolutionary events in the eukaryotic family tree, including the origin and diversification of the animals, would be tied to or even driven by major changes in atmospheric oxygen abundance. Eukaryotes generally, and animals specifically, are oxygen lovers. As the subjects of Mayow and Priestly died to prove, we require oxygen for respiration. In general, the larger and more organizationally complex we are (for instance, a human versus a slime mold), the more oxygen we require.

But where did all the oxygen come from? Ultimately, it was produced by the bacterial equivalents of the plants in Joseph Priestley's experiment, a group of photosynthetic microbes called the cyanobacteria. These bacteria are the first and only organisms to have evolved the ability to produce oxygen by photosynthesis. In fact, plants are able to photosynthesize only because their cells harbor descendants of one of the early cyanobacteria. We call them chloroplasts and think of them as little cellular organs, but they are actually the great-great-great... granddaughters of a cyanobacterium that long ago gave up its independence in exchange for the stable environment inside a eukaryotic cell. In any case, photosynthesis is the only known geological process capable of producing oxygen at the rates required for the two pulses of atmospheric oxygenation. The first pulse was probably largely accomplished by cyanobacteria, while the second pulse was probably mostly associated with the cyanobacterial denizens of eukaryotic algae.

What is remarkable about all of this is the extent to which modern life and the atmosphere are products of each other's evolution. The tiniest of photosynthetic organisms played one of the most important roles in shaping the sky, and the sky helped to usher in the age of animals! As a Christian and a geobiologist, I do not believe that this relationship is anticipated or predicted by the Biblical creation accounts.

But then again, why should it have been? The original audience for these accounts would have found concepts like bacteria or even oxygen incomprehensible. The people for whom the Bible was originally addressed thought about origins primarily in terms of ongoing national conflicts and the current human condition. Faced with a variety of violent creation myths that reinforced national conflicts, Genesis said that the universe was created to be good, peaceful, and orderly by one god. It specifically listed things worshipped by other nations as creatures of that god, and in the climax of the creation account, Abraham was called by the same god to be a blessing to all the nations through Israel.

I am not claiming that the Bible cannot be read in a way that can shape us in real and meaningful ways today. In fact, for those who believe that the Bible is inspired, part of the meaning of inspiration has to be that the Bible is God's powerful word to both those with no concept of modern science (most of the world's population, both today and in the past) and to those deeply engaged in its practice. But, and this is a big but, we contemporary Americans read the Bible best when we are sensitive to the assumptions of the original audience, carefully observe how the Bible transformed those assumptions, and look for opportunities to do the same thing with our thinking.

I think that it is important for Christians to reflect on the view of origins that science has given us in light of the thinking evident in the Biblical creation accounts. We have to do this because science gives us a story that is inherently without philosophical or theological meaning; it is up to us to give it meaning by understanding it in relationship with our beliefs. For instance, some see the evolutionary history of life and the Earth and give that history meaning by elevating chance and necessity to the level of prime actors in their own modern creation account. This meaning is not inherent to the theory of evolution; it is supplied by an atheistic belief system external to the theory. I suggest that this view mistakes created things (chance and necessity) for the Creator.

Others have preferred to see the regularity of the universe as the action of an orderly God. This is an old approach to natural theology that was popular among many early scientists, and saw God as responsible for doing such things as maintaining the planets in consistent paths around the sun. Still others look for God in the unexplained. This is a newer approach that sees God as acting primarily in short bursts not explainable by the regular, orderly function of the universe. Looking for God in these ways is a little like trying to capture him in a bell jar, an approach that worked perfectly well with oxygen for Mayow, Priestley, and Lavoisier, but one that is unlikely to impress the Creator described in the Bible.

I prefer to see the same history in the light of a God who desires to share aspects of his nature with his creation, notably including his creativity. Just as he has made humans to be creators (with a little 'c'), he has given the rest of our world the gift of being instrumental in its own creation through the process of evolution. This surely must have been part of what God saw when he described his creation as good! It is my hope that the modern American church can learn to see the goodness of creation in things like the evolutionary history of life and the atmosphere, as well.

This post first appeared in October 2009

To say, “I believe in the Church” is to embrace and live into a reality that precedes us, encompasses us, and continues beyond us. Indeed, if we are to truly be the Church in the present, I believe that it is incumbent on us to listen to those who have gone before us, and recognize that our own “here and now” is not the whole of the Christian story. Moreover, paying attention to the voices in the history of the Church can reveal to us our own contemporary blindfolds and assumptions, and might even enable us to approach Scripture with fresh eyes.

As a case in point, over the next three posts I’d like to walk us through a number of what I call “pre-modern” church fathers’ readings of Genesis 1 so that we might hear how Christians have read this text across the last 1600 years. For, while exploring the history of interpretation of any biblical text can teach us several important things, the biblical account of creation in Genesis 1 is a particularly instructive case.

Many, many Christian readers interpreted Genesis 1 during the early, medieval and Reformation eras of the church, but my survey focuses on the accounts given by Origen, Augustine, Aquinas, Luther, and Calvin. Every one of these church fathers held to at least two strong, shared assumptions: first and foremost, they all believed Scripture is the inspired Word of God—an infallible revelation given by God to reveal God and God’s truths for the church. I will return to this point later to show that what these readers meant by “infallible” is not necessarily the same as what many modern readers mean today, but the fathers’ firm conviction in the absolute trustworthiness of the biblical text is something contemporary evangelicals have in common with our predecessors in the faith. Secondly, they all asserted that any good reading of Scripture has the ultimate goal of edifying the Church. A faithful reading is performed in, with and for the Church, for the Church’s strengthening and/or repentance.

Beyond these two essential points about the text itself, all five of these church fathers focused upon several shared theological teachings in their readings of Genesis 1:

• First, the world is created. In other words, the world is not eternal; it has a beginning and an end.
• Second, God created the world.
• Third, God created the world from nothing. This is the Christian doctrine of creation ex nihilo.
• Fourth, the Creator is also Trinity: Father, Son, and Holy Spirit.

The first three of these beliefs—the world is created, God created the world, and God created the world from nothing—set up a clear distinction between God the Creator and created creatures who depend upon God for their creation—that is, the supreme distinction between Creator and creature. This distinction is necessary to demonstrate that only God is God; there is no other God. There is no room for the world or anything else to claim existence outside of or beyond God. God is the beginning of all existence.

Finally, the church fathers’ agreement that Genesis 1 teaches us about God’s Trinitarian nature of Father, Son, and Holy Spirit gives us a sense of the complete and self-sufficient yet still relational quality of the Creator. In sum, Origen, Augustine, Aquinas, Luther, and Calvin agreed that the account of creation in Genesis 1 tells us in some kind of literal way how the world came to exist, but equally that Gen 1 is intended to teach us these key theological truths.

An infinite source of wisdom

One of the key issues debated amongst these early readers of Genesis 1 was a question of methodology: how should one read the text? The pre-modern Church held firmly to the belief of both the divine inspiration of Scripture and Scripture as an infinite source of God’s wisdom, revelation and teaching. This meant that the pre-modern Church believed that there was not just one singular correct meaning of a biblical text, but that there were many possible faithful readings of any given text.

Such an assertion involved the belief that since God is infinite, so also is God’s Word infinite. To assume that there is only one singular correct meaning of Scripture is in essence to “box God in” or offend the absolute sovereignty of God—namely, limiting what God may teach or say through God’s own very Word. Hence, from very early on in the Church’s history, the church held that Scripture has literal and spiritual meanings. The late-2nd / early 3rd-century church father Origen, for one, was a keen proponent of the spiritual reading of Scripture. He maintained that Genesis 1 has both a literal meaning and a spiritual or allegorical meaning. He wrote, “There is certainly no question about the literal meaning, for these things are clearly said to have been created by God,” but then he continued, “but it is also profitable to relate this text in a spiritual sense.”¹

The spiritual meaning of the text, according to Origen, is that the creation account is not simply about how the world was created, but it also sets forth the Christian’s journey in faith from infancy to maturity. Or, put another way, the days of creation are an illustration of the ethical journey of Christians toward righteousness. Thus according to Origen, for example, the separation of waters from the dry land (in verse 9) points to the call for the Christian to seek heavenly things rather than earthly things.² Though they may be literally the creation of the sun, moon and stars, the lights in verse 14’s “Let there be lights” spiritually signify Christ and his Church—Christ who is the “light of the world” and the church who has been called to reflect this light into the world (John 8:12).³ Hence, though Origen affirmed the literal reading of this text as teaching that God created the world, the weight of his focus fell upon reading Genesis 1 as a road map for the Christian’s journey in righteousness towards becoming more Christ-like.

The renowned late 4th/early 5th-century church father Augustine also believed in reading Genesis both literally and spiritually, though he placed more emphasis on the literal reading than did Origen. Augustine commented on Genesis 1 several times, including Against the Manichees and A Literal Interpretation of Genesis. In the both of these accounts, his primary intention was to set forth that the world is created by God out of nothing—hence light vs. dark or good vs. evil cannot be rightly believed to be dualistic entities. In fact, God is the only Supreme Being, and God created everything else out of nothing—not out of God’s self (which leads to pantheism or pan-entheism), nor out of something else existing alongside God (which would lead to dualism or the belief that there are two or more equal entities that can claim to be gods). All of these theological teachings were set forth to deliberately counter the heretical teachings of the Manicheans in Augustine’s day. Hence, one might argue that Augustine’s “literal” reading of Genesis was very much focused upon certain theological teachings of Genesis 1.⁴

But Augustine did not stop there. He also provided a number of ways in which the literal words of Genesis 1 may point to a spiritual meaning. For example, Augustine writes that the 7 days of creation represent the 7 ages of the world. Moreover, Augustine—much like Origen—also read the 7 days of creation in terms of the Christian’s spiritual journey in faith. Thus, Day 1 is the light of faith, day 2 is a time of learning and discernment; day 3 is the separation of heavenly and earthly things; day 4 is development in spiritual knowledge; day 5 involves good works; day 6 is being made in the image of God to gain mastery over carnal desires, and day 7 is a day of perpetual rest.⁵

Key theologians of the early church (such as Origen and Augustine, as we’ve discussed) read Scripture with multiple senses and meanings—with a literal sense and multiple spiritual senses. However, not all fully agreed with this methodology. Though most all would certainly hold to multiple senses of Scripture, some readers insisted upon a more profound attention to the literal sense, and the use of the literal sense to help restrain or hold in check the possible spiritual readings. Such 3rd- and 4th-century Church fathers, as St. Basil the Great, John Chrysostom, St. Ambrose, and Theodore of Mopsuestia insisted upon a much more restrained literal reading of Genesis 1.⁶

Yet even those who insist upon a more literal—or more historical—interpretation of Genesis 1 still contended that the primary purpose of any reading was to edify the Church, which entails setting forth the key theological teachings of Genesis 1, rather than focus on the material specifics. Again, such teachings include that the world is created, that God create the world out of nothing, and that the creation account demonstrates the great order and harmony of creation as a testimony of the God’s glory, beauty, and goodness.⁷

More than one thousand years later, 16th-century Protestant Reformers Martin Luther and John Calvin strongly argued for a literal reading of Genesis 1 over and against an allegorical one. Luther wrote, “God’s purpose is to teach us not about allegorical creatures and an allegorical world, but about real creatures and a visible world apprehended by the senses.”⁸ Calvin maintained, “For to my mind this is a certain principle, that what is here treated is the visible form of the world.”⁹

Yet Luther and Calvin also insisted that the central purpose of Genesis 1 is to set forth the theological teachings that the world is created, that God created the world out of nothing, and that creation demonstrates God’s providence, divine purpose, goodness and benevolence.¹⁰ While these historical readers do not all agree on whether Genesis 1 should be read allegorically, what becomes crystal clear is that for all of these interpreters, in one way or another, a “literal” reading of Genesis 1 retains as its focus the theological teachings of the text. In our next installment, we’ll look briefly at some of the difficulties our expositors perceived in Genesis 1 when they did attempt to read it literally.

Notes

1. Origen, Homilies on Genesis, 60.
2. Origen, 49, 50.
3. Origen, 53-55.
4. Augustine, Against the Manichees, 57, 58 and Genesi ad litteram, 145-46.
5. Augustine, Against the Manichees, 83-88, 89-90. The seven ages are the following: Day 1 = the infancy of the world that stretched from Adam to Noah; Day 2 = childhood, stretching from Noah to Abraham; Day 3 = adolescence, encompassing the biblical history from Abraham to David; Day 4 = the age of youth, from David to the Babylonian captivity; Day 5 = youth to old age, stretching from the Babylonian Exile to the first advent of Christ; Day 6 = old age, the coming of Christ until the 2nd coming; and Day 7 = on the even and including the 2nd coming of Christ.
6. St. Basil the Great, Hexameron 9.1.
7. Ibid, 7.6, 1.7-9, 1.2-4.
8. LW 1:5.
9. John Calvin, Commentary on Genesis, 79.
10. LW 1:3, 4, 10, 18, 36, 39, 47, 49. Calvin, Commentary on Genesis, 70, 89, 80-82, 88.

With the complete genome sequence in hand, we knew the sequence and location of our genes, but what we didn’t know was how all those genes are regulated: how do the trillions of cells in our bodies know when to turn on or off all those genes? How do the hundreds of distinct cell types develop and function together, when they are all running on the same DNA “operating system?”

That’s where the ENCODE (short for Encyclopedia of DNA Elements) project comes in. Launched in September 2003, shortly after the announced completion of the Human Genome Project, the goal of the ENCODE project is “to build a comprehensive parts list of functional elements in the human genome, including elements that act at the protein and RNA levels, and regulatory elements that control cells and circumstances in which a gene is active.” In other words, the project seeks to understand how the genome “works.”

Early this month, researchers from ENCODE released more than thirty papers presenting their findings. During a Science magazine online chat, the project’s data coordinator, Ewan Birney, explained the outcome:

The ENCODE project aimed to start our understanding of how the human genome works. We know that (nearly) all the information that determines a human is in the genome, as we all start off as single cell with this DNA. However, we had a patchy understanding of how it works, in particular away from protein coding genes.

To work out how the genome works, we used the fact there are many tiny machines (proteins and RNA - RNA is very like DNA) in each of our cells which know how to "read" parts of the genome. By monitoring where these little molecular machines are on the genome, or how parts of the DNA are copied into RNA (there are quite a few different types of RNA as well), we start to gain some insight into the genome.

We did many such experiments, across different cell types (eg, one cell type was very similar to a liver cell type; another was very similar to a white blood cell). This way not only can we see what is similar, we can also see differences between these cell types.

There is a lot more to get to know and understand here - this is definitely closer to the start than the end. But it is a substantial amount of data, and analysis, to start on this journey.

According to the abstract of one of the lead papers from Nature, this extraordinary glut of data “enabled us to assign biochemical functions for 80% of the genome, in particular outside of the well-studied protein-coding regions.” Only 2% of the genome codes for proteins, but 80% or more has some biochemical function. As a Science news article put it, these 30 papers “sound the death knell for the idea that our DNA is mostly littered with useless bases.”

The pro-Intelligent Design organization The Discovery Institute has heralded the discovery as the “demise of junk DNA.” Casey Luskin writes for their blog Evolution News:

Let's simply observe that it provides a stunning vindication of the prediction of intelligent design that the genome will turn out to have mass functionality for so-called "junk" DNA. ENCODE researchers use words like "surprising" or "unprecedented." They talk about of how "human DNA is a lot more active than we expected." But under an intelligent design paradigm, none of this is surprising. In fact, it is exactly what ID predicted.

The extent to which the ENCODE project been able to identify function has been surprising—even exhilarating—though scientists have for some time been getting glimpses of the many ways in which segments of DNA can be “active.” Even in 1970 biologists knew that some non-coding DNA had function, and by 2003 there was a large body of work demonstrating that many non-coding elements acted as promoters, enhancers, insulators, and so on. Indeed, in recent years many have come to appreciate the fact that “junk” was never really an appropriate metaphor in the first place. Still, because sequencing of multiple genomes has shed such extraordinary light on key evolutionary mechanisms, many geneticists have focused on function primarily in terms of which regions do or do not contribute to the evolutionary fitness of their host, rather than whether they were merely "doing something" biochemically. What the impressive ENCODE project has done is open a treasure trove of new information that can only accelerate the pace at which researchers are able to explore the incredible subtlety and complexity of DNA, and refine the very concept of “functionality.”

So with all this in mind, is ENCODE a stunning victory for ID, as Luskin believes? Bryan College biologist Todd Wood thinks not. He writes, “I don't think that function equates to design, nor do I think that design requires or predicts function. They're not the same thing… my understanding of function does not require me to hypothesize God (or an anonymous designer, if you must) as the proximal cause.”

We agree. Indeed we would go on to say that evolution and design are not mutually exclusive. So while finding function is not sufficient to prove design, recognizing that function has arisen by way of evolution does not indicate that God was not at work. We at BioLogos believe God providentially works out his purposes—his designs—through the elegant processes of evolution, not in opposition to them.

Amazing as the new data are, it only strengthens and enhances our evidence for evolution. While much of the genome is “doing something” biochemically, it is still likely that the majority of the sequence is evolutionarily neutral (Senior Fellow Dennis Venema discusses the evidence for this “neutrality” in a post on our site, including a striking comparison between 29 different mammal genomes and the human genome). In fact, another ENCODE researcher participating in the Science magazine chat, John A. Stamatoyannopoulos of the University of Washington School of Medicine, thinks the findings align beautifully with evolutionary theory:

ENCODE's data provide a unique and powerful window through which to view evolutionary change. We can see those changes directly by lining up the genome sequences of many different organisms -- these line-ups have revealed millions of regions where all the genomes agree, indicating sequences that have been specially preserved by evolution while others have decayed away (ie freely changed their letter codes). We now see that a large proportion of these 'conserved' regions are lighted up by ENCODE annotations, indicating that they are marking spots in the genome that contain important instructions for cell function.

We’ve discussed “junk” DNA previously, including a multi-part series by Dennis Venema, and we’ve received many emails over the past few days asking for our comments on the ENCODE findings. On Monday and Tuesday, Dr. Venema will begin to offer his own thoughts on ENCODE.

A special thanks goes to Darrel Falk, Mark Sprinkle, Kathryn Applegate, Dennis Venema, and Tom Burnett for their contributions to this post.

The Denisovans, an extinct hominid group that interbred with modern humans, made the news again lately with the publication of a more detailed study of their genome. One of the many interesting findings was that the Denisovans share the same chromosome 2 fusion that modern humans have. In this post, I review what we know about the origins of human chromosome 2, and then discuss the new Denisovan findings and their implications.

The origins of human chromosome 2: a brief review

Though I have discussed the evidence for a fusion event leading to human chromosome 2 before, perhaps a brief review of the evidence is in order. The human genome is made up of 23 pairs of chromosomes (for a total of 46 chromosomes). This makes us something of an oddity among living great apes, all the rest of whom have 24 pairs of chromosomes (for a total of 48). Given that there are many independent lines of evidence that support the conclusion that we share a common ancestor with other great apes, this poses something of a conundrum: how is it that our species arrived at this specific chromosome number? If we were to represent this “problem” on a phylogeny, or tree of relatedness, it would look something like this (not to scale):

Our closest living relatives, chimpanzees and bonobos, both have 48 chromosomes, as do all other great apes such as gorillas and orangutans. This pattern has one of two explanations, one of which is much more likely than the other. Either the common ancestor to these species had 48 chromosomes, and there was an event that reduced that number to 46 specifically on the lineage leading to humans (option A), or the common ancestor species had 46 chromosomes, and there were independent, repeated events that increased chromosome number in all other great ape species (option B). We can compare these options by placing the required event(s) on the phylogeny (again, not to scale):

It should be obvious that the option that requires the fewest events is the more likely one – in this case option A with an event that reduces chromosome number in the lineage leading to humans. The other option, that of repeated, independent events to increase chromosome number, remains a formal, but unlikely, possibility. Events that reduce chromosome number are not frequent occurrences, so Option A is more likely than Option B.

We can also find further support for Option A, because it predicts a specific type of event, namely one that reduces chromosome number. Since loss of a large amount of chromosomal material is almost always detrimental, we need an event that reduces chromosome number without losing information. One way for this to happen is for two chromosomes to fuse together and become one. Initially, this event would produce an individual with 47 chromosomes, where two different chromosomes get stuck together. Contrary to what is often assumed, this individual would be fertile and able to interbreed with the others in his or her population (who continue to have 48 chromosomes). In a small population, over time, two relatives who both have one copy of the fusion chromosome may mate and produce some progeny with two copies of the fused chromosome, or the first individuals with 46 chromosomes. Since either a 48-pair set or a 46-pair set is preferable for ease of cell division, this population will either eventually get rid of the fusion variant (the most likely outcome), or by chance will switch over completely to the “new” form, with everyone bearing 46 chromosome pairs. While not overly likely, this type of event is not especially rare in mammals, and we have observed this sort of thing happening within recorded human history in other species. Some mammalian species even maintain distinct populations in the wild with differing chromosome numbers due to fusions, and these populations retain the ability to interbreed.

Further evidence for a fusion event in the lineage leading to modern humans comes from comparing synteny, or gene locations and orders on chromosomes within modern great apes – an issue we have discussed here before. In brief, what we see in human chromosome 2 is exactly what we would predict for a fusion event. When compared to other great apes, we see the genes on human chromosome 2 match up, in order, with two smaller ape chromosomes. We also see that sequences used at the tips of chromosomes are present at the proposed fusion site, and that human chromosome 2 has not one but two sites for the cell cytoskeleton to attach to for cell division – but that one of the sites is mutated and not functional, though it lines up precisely with the location of this site on the appropriate ape chromosome. Together, this evidence consistently supports both common ancestry for humans and great apes, and specifically that the difference we see in our chromosome numbers arose due to a single fusion event. I briefly discussed this evidence in my last post where I describe how I teach some of this material and the compelling impact it has on students exploring the evolution question for the first time.

Enter the Denisovans

With that as background, we are now prepared to appreciate a new finding that comes from genomics work done on the Denisovan hominids, an archaic species that is more closely related to Neanderthals than to us, but that nonetheless interbred with some anatomically modern humans as they migrated out of Africa and populated the globe. (For those not familiar with the Denisovans, or the evidence for our interbreeding with them, both Darrel Falk and I have written on this previously, here and here). Recently, a more detailed understanding of the Denisovan genome was published, and nested in the new information is the discovery that the Denisovans share the 46 chromosome set with the same fusion that we have. This strongly supports the hypothesis that the fusion event predates the separation of our species. If we were to represent this on a phylogeny, we can now place this event with more accuracy than before (as before, the phylogeny is not to scale):

Despite this new information, one obvious question remains. Did the Neanderthals also have the 46-pair set? From looking at the phylogeny above, we can see that the most likely answer is that they did, since the fact that the Denisovans had it strongly implies that the last common ancestor of humans and Neanderthals / Denisovans had it as well, and the Neanderthal-Denisovan split comes later. While the Denisovan DNA samples are of high enough quality to make this assessment, we do not yet have Neanderthal DNA of high enough quality to do the same analysis with current methods (though one additional feature of the new work on the Denisovan genome is developing more sensitive DNA sequencing techniques that may resolve this question in the future).

In other words, this fusion seems to be an ancient one, predating our species by several hundred thousand years. Present estimates of the last common ancestor between humans and Neanderthals / Denisovans range at about 800,000 years ago.

Implications for understanding our “becoming human”

The main implication from this work is that it places the fusion event well before the advent of our species. I’ve often chatted informally with Christians about evolution, and at times some have thought that this fusion event was what “started” our species, or made our species unable to interbreed with other groups. Some have even suggested that perhaps the fusion event was what produced the first human (i.e. Adam).

Note that thinking this way suggests a misunderstanding of how chromosome fusions occur and what effect they have on their hosts. A fusion does not precipitate a speciation event, but rather the individual with the fusion remains a part of his or her population, and able to interbreed, even if with reduced fertility. Also, there is no necessary biological effect or change that the fusion produces on the appearance of the organism. These misunderstandings aside, however,what this new evidence shows is that this fusion event took place long before modern humans arose at around 200,000 years ago. Indeed, the 800,000 years ago date for the last human - Denisovan common ancestor means that this is the most recent date possible for the fusion. While it is an interesting piece of our evolutionary history, it doesn’t seem to have much to do with how we came to acquire the traits that set us apart from, and ultimately outcompete, other similar species.

In his essay for that series, Jeff Schloss addressed the question of whether animal death is a natural evil, but also noted that such theological considerations aside, death does not actually “drive evolution” in the way most people imagine—especially when they think of violence in the natural world. This more complicated sense of death’s role is partially the result of modern evolutionary science recognizing the importance of cooperation and inter-relation among species, rather than just direct competition. But just as important is the knowledge that evolution is significantly shaped not by the deaths of individual creatures, but by extinction, the loss of species over time. In this post, we explore some aspects of how extinction acts as both a destructive and creative force in evolutionary history, including the evolutionary history of mammals.

Sporadic extinction

Extinction is actually a common feature of life on earth when viewed over long (e.g. geological) timescales. By some estimates, over 99% of the species that have ever lived have gone extinct. One factor that promotes extinction is the fact that evolution does not produce species that are optimally adapted to their environment, but only better adapted than their local competitors. Invasive species testify to this fact: local (endemic) species are not always the best-adapted species for their own environment. Examples abound where species from other environments are actually better-suited to out-compete endemic species. Here in my own province, the invasive Himilayan blackberry (Rubis discolor) easily outcompetes many endemic species. If endemic species were optimally adapted to their environment, this would not be possible, as they would outcompete all exotic species. Instead, exotic species, by chance, might be better adapted to an ecosystem they did not evolve in. These exotics may be capable of eliminating endemic species altogether.

Such an extinction event (of a single species, or perhaps a handful of species) alters the environment of other remaining species in an ecosystem. This, in turn, may influence the ability of some of these remaining species to reproduce compared to other species. For example, the extinction of a competitor might allow a species to increase in population size. Conversely, the extinction of a species that provides a benefit (such as a pollinator) may reduce a species in number. As the ecosystem landscape shifts due to loss of species, new biological opportunities, or niches, might arise. These new niches are then available to support new species to fill them.

Extinction, en masse

One way to appreciate how extinction opens up new niches is to examine mass extinction events – geologically brief periods where large numbers of species go extinct at the same time. Over the history of life on our planet there have been several mass extinction events. The largest such event, at the end of the Permian (~250 million years ago) appears to have been caused, at least in part, by intense volcanic activity over several hundred thousand years. This activity likely shifted CO2 levels and eventually led to a “runaway” greenhouse effect that dramatically raised global temperatures and led to anoxic (i.e. oxygen-depleted) oceans, though the exact contributions of these varied factors remains an area of scientific debate. What appears certain is that during this period environmental changes were too rapid for most species to keep evolutionary pace with, and as a result over 90% of the world’s species alive at that time went extinct. Obviously this represents destruction of biodiversity on an unimaginable scale, and the destructive effects of this event are with us to this day.

Speciation, en masse

This destruction, however, is not the whole story. Following on from the Permian mass extinction, we observe a steady increase in new species. These are species previously unknown in the fossil record. In fact, this pattern (a “radiation” of new species following an extinction event) is the rule, not an exception – we see the same effect after every mass extinction in the fossil record. Extinction is a driving force for novelty.

Perhaps the most famous mass extinction event is the Cretaceous – Paleogene (KPg) extinction, and it too follows this standard pattern. This mass extinction took place 65 million years ago when an asteroid ~10 kilometers in diameter struck the Yucatan peninsula. (Note: this event was formerly known as the Cretaceous – Tertiary (K-T) extinction, but that terminology is in decline within the scientific community). This extinction event is famous since it is the one that eliminated the dinosaurs (with the exception of the ancestors of modern birds). As with the Permian extinction, the elimination of so many species shifted the evolutionary landscape for the remaining species, and the result was a burst of speciation that appears rapid when viewed in geological time. Significantly for our own species, following the KPg extinction event is a burst in mammalian speciation, as small mammals that survived the event diverge and fill niches left empty by the dinosaurs. Without this event, the trajectory of mammalian evolution would certainly look very different.

Clearing the deck, and re-filling the niches

One interesting fact to note is that biological features that make a species resistant to usual, sporadic extinction are not necessarily the same features that will be useful during a mass extinction event. While species are continually under selection at the local level, there is no mechanism for (pre) selection to survive a mass extinction. As such, only species that happen to have the right combination of traits will survive, and often spread widely after a mass extinction. These so-called “disaster species” are usually generalists, and will later be displaced by more specialized species as they arise. As such, where sporadic extinction allows for more gradual turnover in species, mass extinction events are major “resets” of evolution that can radically shift what constitutes “well adapted” in a geological eyeblink. For mammals at the KPg boundary, small body size and an omnivorous diet (including the ability to scavenge detritus) were the “winning” combination of traits that allowed them to survive where larger, more specialized animals (think Tyrannosaurus rex) could not. From this rather humble station, mammals would come to dominate the world’s ecosystems over the coming eons – including a lineage that would someday lead to our own species. Far from only a destructive force, extinction is a powerful mechanism to allow evolutionary innovation, and one that was of significant importance to us.

For further reading:

Meredith, R.W. et al (2011). Impacts of the Cretaceous Terrestrial Revolution and KPg Extinction on Mammal Diversification. Science 334; 521-524.

Fastovsky, D.E. (2005). The Extinction of the Dinosaurs in North America. GSA Today (15); 1052-5173.

Benton, M.J. and Twitchett, R.J. (2003). How to kill (almost) all life: the end-Permian extinction event. TRENDS in Ecology and Evolution (18); 358-365.

Darwin’s finches are some of the most visible and recognizable symbols of evolution in the world today. Biology textbooks feature them prominently, and the National Academy of Sciences has enshrined them in the entrance of their headquarters in Washington, DC. Surely the finches that Darwin collected on the Galápagos islands were a central feature of his evolutionary theory, right?

Lobby of The National Academies Building. Courtesy of CPNAS. Photo by Robert Lautman

Actually, the Galápagos finches are never even mentioned in Darwin’s famous work On the Origin of Species. Nor do they appear in Darwin’s famous notebooks on “Transmutation of Species”, in which he formulated the idea of evolution by natural selection.¹ Even Darwin’s private diary of his voyage on the HMS Beagle only mentions the Galápagos finches briefly in passing.²

It was only in 1845, in the second edition of The Voyage of the Beagle, that Darwin included a tantalizing sentence about the Galápagos finches:

Seeing this gradation and diversity of structure in one small, intimately related group of birds, one might really fancy that from an original paucity of birds in this archipelago, one species had been taken and modified for different ends.³

However insightful this statement may have been, Darwin never published anything else about the Galápagos finches for the rest of his life. Nor did he publically present these birds as direct evidence for this theory of evolution.⁴

If these finches were so important to Darwin’s evolutionary theory, why did he remain silent about them? One of his comments in The Voyage of the Beagle provides us with a clue:

Unfortunately most of the specimens of the finch tribe were mingled together; but I have strong reasons to suspect that some of the species of the subgroup Geospiza are confined to separate islands.⁵

When Darwin was exploring the Galápagos himself in 1835, he had not formulated his theory of evolution yet, and thus he did know what data would be necessary to make definitive conclusions about finch evolution. In particular, he did not keep careful track of which of his specimens came from which islands. Moreover, as was customary among naturalists at that time, Darwin only collected a small number specimens—he brought home only 31 finches and 64 total birds from the Galápagos.⁶

Though Darwin sensed that these birds were truly special, he lacked sufficient evidence to reach any specific conclusions about their evolutionary origins. It would be up to the rest of the scientific community to carry out the necessary empirical research. Subsequent expeditions in 1868, 1891, 1897, and 1905 brought back thousands of Galápagos finch specimens, but instead of unlocking the mysteries of evolutionary theory, the Galápagos finches became a great enigma.⁷

A century after Darwin's voyage, scientists still struggled to explain the staggering variety of finches on this tiny, remote archipelago. By the mid-1930’s, British Museum ornithologist Percy Lowe argued that the finches presented a "biological problem of first class importance", and he told the British Association for the Advancement of Science that the finches displayed a "bewildering diversity, intergradation, and distribution".⁸ Who would be up to the challenge of making sense of such tremendous biological complexity? It was David Lack.

David Lack

Ornithologist David Lack

David Lack had an exceptionally keen eye for bird-watching, and he possessed a passion to match it. By age 15, he had already observed 100 distinct species of birds, and before entering college, authored his first scientific paper. At Cambridge University in the early 1930’s, Lack was disappointed to find that his zoology professors taught “nothing about evolution, ecology, behavior or genetics, and of course nothing about birds.”⁹ In fact, at that time, there were only two professional ornithologists in all of Britain!

Thus David Lack took it upon himself to create his own learning opportunities. As an undergraduate, he became the president of the Cambridge Ornithological Club, traveled to Greenland for a bird-watching expedition, and cultivated a relationship with the prominent biologist Julian Huxley (grandson of Thomas Henry Huxley). Huxley was an inspiring mentor and encouraged Lack to expand his research further by studying tropical birds.¹⁰ Following this advice, Lack embarked on a research trip to Tanzania in the summer of 1934, but his greatest adventure was yet to come.

In 1937, Lack became fascinated by the scientific mysteries surrounding the Galápagos finches. But in order to study their behavior, Lack would need to travel to remote islands halfway around the world. How could he possibly get there? Once again, Julian Huxley was tremendously supportive and raised funds from two prominent scientific societies to pay for his expedition. After a long delay, David Lack and five companions finally set off on their journey.

Instead of residing in comfortable quarters aboard a royal naval ship, Lack’s group subsisted on a shoestring budget, traveled on commercial steamers, and stayed with local settlers. Their experience was definitely not a romantic tale of imperial expedition:

The Galápagos are interesting, but scarcely a residential paradise. The biological peculiarities are offset by an enervating climate, monotonous scenery, dense thorn scrub, cactus spines, loose sharp lava, food deficiencies, water shortage, black rats, fleas, jiggers, ants, mosquitoes, scorpions, Ecuadorian Indians of doubtful honesty, and dejected, disillusioned European settlers.¹¹

Whereas Charles Darwin spent only nineteen days on the shores of the Galápagos, Lack and his crew conducted more than five months of meticulous and exhausting study in the harsh climate. At that time, even the finches themselves provided little solace. Lack wrote,

Darwin’s finches are dull to look at, not only in their orderly ranks in museum trays, but also when they hop about the ground or perch in the trees of the Galápagos, making dull unmusical noises. Only the variety of their beaks and the number of their species excite attention.¹²

Large Cactus Finch on Española Island in the Galápagos Islands

The repetitive tedium requisite for important scientific discoveries is rarely discussed in public, and even today many bright-eyed science students become disillusioned by the painstaking work demanded by their Ph.D. programs. But one of the things that distinguishes great scientists is their unwavering commitment and tenacity in completing major projects. David Lack's efforts were not in vain:

"Despite his personal discomforts (or perhaps because of them), Lack did see something on the Galápagos that no one had ever seen before—natural selection at work among its finches through interspecies competition." ¹³

When the birds’ breeding season ended in 1939, Lack was ready to return to his home in England. But the captive finches that he had brought with him fared so badly on the voyage home that he detoured to San Francisco and put them in the care of the California Academy of Sciences. Turning this mishap into an opportunity, Lack stayed there for five additional months to study the Academy’s enormous collection of Galápagos finch specimens.¹⁴

To complete his systematic research, Lack then travelled across the United States to study the Galápagos finch collection housed at the American Museum in New York.¹⁵ Altogether, Lack examined more than 8000 specimens and specifically measured the length, width, and depth of all their beaks.¹⁶

Lack’s final obstacle was in getting his research published. Though he completed his academic manuscript “The Galápagos Finches—A Study in Variation” in 1940, paper shortages during World War II delayed its publication by the California Academy of Sciences until 1945. Were he only interested in making an original contribution to science, Lack could have stopped here and congratulated himself on a job well-done. However, his motivation sprung from a deeper source:

David Lack's drawing of 14 species of Galápagos finches, p. 19 of Darwin’s Finches

"I did not watch birds primarily for scientific reasons but for sheer enjoyment, and from the age of 15 onward returned day after day in a glow of excitement after seeing a new bird or a new habit." ¹⁷

Lack’s joyful fascination with the Galápagos finches inspired him to continue developing his conclusions long after returning from his expedition. While waiting for his academic paper to be published, he began writing a book that would enable students and the general public to share his excitement about these remarkable birds and the evolutionary processes that shaped them.

First published in 1947, Lack’s book became tremendously influential. Before this time, biology textbooks had never even mentioned the Galápagos finches. But after David Lack’s study, the finches became a primary example of evolution by natural selection, specifically adaptive radiation. Not only did textbooks fully rely on Lack’s findings, they also followed his lead in calling them “Darwin’s finches”, the title of Lack’s famous book.¹⁸

Iconic Finches

What was it about these birds that made them such a prominent symbol of evolution? As Darwin himself pointed out, the numerous Galápagos finch populations each have distinctive beaks, and he speculated that they could have evolved from an ancestral species that came to the islands. But a complete picture of finch evolution would have to wait another hundred years, when David Lack arrived.

During his five months on the Galápagos, including both the rainy and dry seasons, Lack observed that these beak differences enable the finches to subsist on different kinds of food:

The beak differences between most of the genera and subgenera of Darwin's finches are clearly correlated with differences in feeding methods. This is well borne out by the heavy, finch-like beak of the seed-eating Geospiza, the long beak of the flower-probing Cactornis, the somewhat parrot-like beak of the leaf, bud, and fruit-eating Platyspiza, the woodpecker-like beak of the woodboring Catcospiza, and the warbler-like beaks of the insect-eating certhidea and Pinaroloxias.¹⁹

Lack's image of beak adaptations from Darwin’s Finches

Specializing in such different sources of food enables these finches to live in close proximity without directly competing with each other or driving populations to extinction. The fact that so many of these closely related finches are able to co-exist is a remarkable fact in itself. As Lack himself put it, “It is not only the origin, but also the persistence, of new species which require explanation.”²⁰

But it is also fascinating to consider how these birds got to be so different in the first place. How did a finch come to have a beak like a “parrot”, “woodpecker”, or “warbler”? The answer lies in the distinct characteristics of the Galápagos. Because the islands are so remote, no actual parrots, woodpeckers, or warblers ever settled on it. In the absence of these species, the Galápagos finches were able to adopt feeding habits and forms that they would never have taken on a large continent full of other birds competing for food. The isolation of these islands offered just the right conditions for us to see living examples of adaptive radiation.²¹

Conclusion

Considering the immense popularity of the Galápagos finches, it is quite surprising to learn that Charles Darwin himself had so little to say about them. In fact, it was actually David Lack, one century later, who conducted the critical research that immortalized the finches in biology textbooks and popular lore. By naming his landmark book Darwin’s Finches,²² Lack paid homage to the man whose voyage on the HMS Beagle helped transform the study of natural history. But at the same time, Lack also obscured the fact that evolutionary biology is an enterprise conducted by a large community of brilliant scholars, not just the product of one man’s efforts.

This tendency to immortalize “great men of science” has also led many people to refer to modern evolutionary theory as Darwinism, despite the fact that it has substantially changed and developed over the past 150 years. It is important to give credit where credit is due, and if that’s the case, we should seriously reconsider how we refer to the Galapagos finches. Evolutionary biologist Dolph Schluter, who studied the finches several decades after David Lack, had this to say:

I find Lack's intuition really stunning given how little information he had. He's my hero actually… They should be called Lack's finches.²³

In the second part of this series, we’ll explore the fact that David Lack, in addition to being a world-renowned evolutionary biologist, was also a devout Christian. His study of evolutionary theory did not cause him to lose his faith; in fact, he actually converted to Christianity after completing his Galápagos finch research.

For Discussion

Further Reading

• Grant, Peter R.; Grant, B. Rosemary. How and Why Species Multiply: The Radiation of Darwin's Finches, Princeton University Press, 2008.
• Sulloway, Frank J. (Spring 1982), "Darwin and His Finches: The Evolution of a Legend" (PDF), Journal of the History of Biology 15 (1): 1–53.
• Weiner, Jonathon. The Beak of the Finch: A Story of Evolution in Our Time. Vintage Books, 1995.

Notes

1. Sulloway, F. (1983). "Darwin and his finches: The evolution of a legend." Journal of the history of biology 15(1): 32. Darwin’s notebooks on transmutation mentioned Galapagos tortoises and mockingbirds, not finches.
2. Lack, David. Darwin’s Finches. Cambridge University Press, 1947: 9. Confirmed by Sulloway (1983), p5.
3. Darwin, Charles. Journal of researches into the natural history and geology of the countries visited during the voyage of H.M.S. Beagle round the world. London: John Murray. 2d ed. 1845: 379-80. This edition of the book also contained the drawings of four different finches that have become enshrined in biology textbooks and on the walls of the National Academy of Sciences in Washington, DC.
4. Sulloway, p35. Sulloway points out that the first published evolutionary account of the Galapagos finches was not until 1876, by Osbert Salvin: "On the Avifauna of the Galapagos Archipelago." Trans. Zool. Soc. London, 9:447-51.
5. Darwin (1845), p395.
6. Sulloway, p40.
7. Sulloway, p40.
8. Larson, E. J. Evolution's Workshop: God and Science on the Galapagos Islands. New York, Basic Books, 2001: 166-67.
9. Lack, David. (1973) “My life as an amateur ornithologist.” Ibis: 424.
10. Lack (1973), 425-27.
11. Lack (1947), p1.
12. Lack (1947), p11.
13. Larson, 167-68.
14. The California Academy of Sciences sponsored an expedition to the Galapagos in 1905-06 and collected nearly 9000 Galapagos finch specimens (Sulloway, p40).
15. In New York, Lack roomed with the curator of the finch collection—German émigré zoologist Ernst Mayr. By developing this relationship, Lack had close ties with two of the biggest figures in the neo-Darwinian synthesis, Julian Huxley and Ernst Mayr (Larson, 168).
16. Larson, p168.
17. Lack (1973), p424.
18. Larson, p198.
19. Lack (1947), p60.
20. Lack (1947), p158.
21. See Lack’s concluding chapter on “Adaptive Radiation”, pp146-159 of Darwin’s Finches (1947).
22. British ornithologist Percy Lowe originally proposed the name “Darwin’s finches” in 1935, but the name did not catch on until Lack used it in his book. See P.R. Lowe, (1936) "The Finches of the Galapagos in Relation to Darwin's Conception of Species." Ibis, 13th ser., 6:310-321. (Cited in Larson, p287)
23. Schluter, in an interview with Edward Larson, 16 March 2000.

Eugene Dubois

13 years before, in 1877, Dubois had arrived in Amsterdam to study medicine, but always harboring a desire to study the ancestry of modern humans. So, after four years at the University there, he accepted an invitation to go to the University of Utrecht to study comparative anatomy and devote himself to the latest thinking about the origins of the human species. It was during his time at Utrecht (from 1881 to 1887) that Dubois became enamored of Haeckel’s views on human origins, which differed from those of Darwin. While Darwin argued that humans had evolved in Africa, the region in which our closest living relatives—the chimpanzees and gorillas—still live, Haeckel believed that the origins of humanity lay in East Asia. This was so, he believed, because of his own observations of gibbons that walk bipedally when on the ground.

Haeckel also believed that there had once been a large landmass called Lemuria between the continents of Africa and Asia. In his view, Lemuria had since become submerged, leaving the modern islands of Madagascar and the East Indies as its only remains. The idea of submerged continents was not unusual for the late 19th-century, as people struggled to understand the character of biological diversity present in the world and why there were such striking similarities between animals that were geographically dispersed. The geographical distribution of marsupial fossils in South America and Australia is an example of this sort of problem, and one that was not solved until the second half of the 20th century when continental drift reconstructions suggested that ancient marsupials had used Antarctica as a conduit between the other two continents. Not only did such theories make sense of modern distributions, they were confirmed with later discoveries of marsupial fossils in Antarctica.

In any case, in 1888 Dubois joined the army and set out for the Dutch East Indies to pursue his ideas. For the next two years, he would comb Sumatra attempting to locate the hominin remains that Haeckel promised would be there. In hindsight, what Dubois was attempting was something that had never been done before: discovery of hominin material through the tools of archaeological excavation. Up to this point, all of the human fossils had been found on the surface, eroding out of the side of a bank, or as a result of farming. It had not occurred to anyone to go looking for human ancestors.

Now, with his supply of prison workers dwindling due to desertion and fever, he had almost run out of options and was on the verge of failure. Using almost all of his remaining resources, he decided to abandon his excavations on Sumatra and turn to the nearby island of Java. Emboldened by the fact that early modern human fossils had been discovered there (at Wadjak), he arrived and settled in at Trinil, on the banks of the Solo River, in 1890.

Figure 1: Dubois' Pithecanthropus erectus

The very next year, Dubois’ long-standing efforts were finally rewarded, first with the discovery of a skullcap (calvaria) of a hominin cranium, and then with an intact femur (Figure 1). Judging by what he knew of cranial anatomy, Dubois estimated that the skull would have been approximately 900 cubic centimeters (cc) in volume, placing it below even the lowest threshold of modern humans. Further, he noticed that it was not like modern humans in shape, being too long and low. He concluded that it showed “evidence of a form intermediate between man and the anthropoid apes” (Dubois, 1896). Dubois envisioned a sequence of forms in which the gibbon gave rise to a form of chimpanzee called Anthropopithecus sivalensis, which then gave rise to the form represented by the Trinil remains, after which Homo sapiens arose (Turner, 1895).

Dubois spent the next twenty years on the road with his find, trying to drum up support for its place in human prehistory. As with Raymond Dart’s discovery of the first australopithecine thirty-three years later, Dubois did not receive a warm reception. Most critics simply said that he had gotten it wrong and that the femur did not belong to the same individual as the obviously-primitive skull cap. Some of the criticism Dubois suffered could have been mitigated had he been more open to sharing the Trinil materials; but, instead, he allowed very little access to the bones, so that very few people knew exactly what they looked like. Adding to Dubois’s credibility problems was the 1911 “discovery” of Piltdown. This intentional hoax turned the paleoanthropology world on its head for forty years, sending researchers down innumerable rabbit holes. As I noted in a previous post, the Piltdown remains made all of the other hominin finds appear too “ape-like” to be on the road to humanity and informed many opinions about finds such as those from Trinil.

On the other hand, some critics of Dubois’ new hominin claim were vicious, and questioned both his academic abilities and his judgment (Shipman & Storm, 2002)—in addition to the interpretation of the find itself. It was in reference to Dubois’ work that the term “Missing Link” was first used with reference to a particular human fossil, originating with Charles Lyell (1863) and describing palaeontological gaps. And ironically, it was in one of the most stinging criticisms of Dubois’ work that the name that would eventually stick was first used: “Homo erectus.” Eventually, many other finds in the same general area and across Southeast Asia demonstrated that what Dubois had found was a real, previously-unknown hominin form, and the first to colonize the Asian continent and the islands leading off towards Oceania.

Homo erectus across South East Asia:

Figure 2: Sangiran 17

Sangiran

The earliest point at which Homo erectus appears to have begun to colonize the greater East Asian region is around 1.8 million years ago, represented first by the partial child’s skull found at the site of Modjokerto, and then, at around 1.66 million years ago, at the site of Sangiran, in Trinil, where Dubois had made his landmark discovery. This site was rich, yielding the remains of many crania, perhaps best represented by Sangiran 17 (Figure 2), an almost complete skull.

The material from the Sangiran site is very diverse morphologically, with some crania having capacities of as little as 700 to 800 cc, and other, larger heads with volumes in the range of 1000 cc. As with the late Homo ergaster finds from Africa, the remains from Sangiran yielded crania that were still widest at their bases, possessing large brow ridges. Some have thick cranial bones and are very robust (Sangiran 4), while others are very gracile (Sangiran 31). What this variation means is not clear, but most workers believe it represents a very diverse diachronic population (that is, one group living and moving around over a long period) rather than separate species inhabiting the area. The Sangiran site yielded fossil material in an almost continuous succession from approximately 1.66 million years ago to less than 800,000 years ago.

Because the area of the excavations—the Sangiran Dome—is a volcanic deposit, the layers have been securely dated by the ⁴⁰Ar/³⁹Ar method, although questions remain about the historical sequence and distribution of other animals that lived there through the ages (its faunal succession). The problem is that many of the fossils were not found in context, and relating them directly to the stratigraphy is tenuous. Despite this, most workers are comfortable with the earliest hominins in the region being at least 1.5 million years old.

One of the things hampering workers in this region is the comparative paucity of recovered stone tools. Those that have been found suggest a technological stage similar to the late Oldowan design, equivalent to that being created by the Homo ergaster populations inhabiting the area of Dmanisi and East Africa. Unfortunately, none of the tools have been associated with the hominins directly so it is not exactly clear who made them.

Figure 3: Sambungmacan 3

Sambungmacan

Another major find from the area where Dubois brought Homo erectus to light is the cranium from the site of Sambungmachan. This skull was reportedly found in 1977 but was then illegally sold to the antiquities market, where is spent considerable time in different collections before being “rediscovered” in 1998—in a New York nature curio shop called Maxilla and Mandible, Inc. (Delson et al., 2001). This was an almost-complete calvaria (Figure 3), with only part of the base missing. It is equivalent in size to the fossils from Sangiran, with a cranial capacity of around 1000 cc. It has a large brow ridge extending all of the way across the top of the eyes, a long, low cranium with a sloping forehead and a maximum width near the cranial base—all features that are also characteristic of the late African H. ergaster and Sangiran crania. Although we will never know exactly how old this cranium is, its morphology is consistent with that of the material from Sangiran.

Figure 4: Ngandong 6

Ngandong

Later in time, but also located on the Solo River, is the site of Ngandong, excavated by Oppenoorth in the early 1930s. At this site, fourteen calvaria have been discovered, all of which show advanced Homo erectus characteristics: long and low in shape, with thick-bones and a distinctive brow-ridge. (Figure 4). As with the other Indonesian finds, dating the Ngandong material has been problematic. The deposits at the site were originally thought to be around 100,000 years old, but this interpretation was turned on its head in 1996, when Swisher and colleagues claimed that the deposits were no older than between 27,000 and 53,000 years old (Swisher et al., 1996). These age estimations were made on the associated fauna, however, and as Rainer Grün and the late Alan Thorne pointed out, the faunal material does not match the skulls either in color or in texture and is likely not from the same time. Recently, Swisher and colleagues revisited the dating of the site and derived internally-consistent dates of at least 143,000 years before the present (Indriati et al., 2011). As with the Trinil remains, however, there are no associated stone tools.

Homo erectus in China

The Chinese Homo erectus material is very widely scattered and working in the region has presented many difficulties for researchers in terms of transport, language barriers and funding. Consequently, we know less about this region and its previous inhabitants than we do about most other areas of the Old World. Although there are between ten and fifteen sites that have yielded Homo erectus material, I will only touch on the most important ones.

Lantian:

Figure 5: Lantian

In the early 1960s, a cranium and mandible were found in the cave of Lantian, Shaanxi province, whose characteristics matched other remains from China designated as Homo erectus. Paleomagnetic dating has yielded a date no earlier than 1.15 million years ago for the skull, with the consensus being that it is around 800,000 years old. A date of approximately 650,000 years before the present was derived for the mandible. The cranium is heavily encrusted and suffered from postmortem deformation (Figure 5). When reconstituted, it was found to have a capacity of around 780 cc (low for Homo erectus) and the bones on the sides of the head are the thickest yet recorded. At this site some flake tools, mammal remains, and an ash deposit were all recovered, suggesting hunting and control of fire.

Figure 5: Hexian

Hexian

Another almost-complete calvaria was found at Longtandong cave in the province of Hé Xiàn, dated to between 400,000 and 500,000 years ago. This find exemplifies typical Homo erectus in many ways in that it is long and low, with heavy muscle markings toward the base and the rear of the skull (Figure 6). The cranial capacity is around 1000 cc, a third-again greater than that of the Lantian calvaria. Its cranial shape is very similar to those found in Southeast Asia, suggesting that it straddles the Southeast Asian and Chinese boundary.

While both Lantian and Hexian were significant finds, another site in China boasted the single largest collection of Homo erectus fossils ever found at one site, as well as presenting one of the greatest mysteries in paleoanthropology. Tomorrow, in the conclusion of our look at Homo erectus in Asia, we’ll peer into the Zhoukoudian caves and consider how this species fits into the lineage of man.

This essay considers the meaning of another small word, but not one in Latin or Greek. This word appears in the Hebrew language in which the Old Testament was written. It is the word pronounced, mîn, that can be rhymed with “green.” In Modern Israeli Hebrew the word has taken on the meaning of “species.” This is also the traditional way in which is it translated in the Old Testament of Genesis 1. It appears in Genesis 1:11, 12, 21, 24, and 25. A survey of a variety of English translations (King James Version, New American Bible, New Revised Standard Version, English Standard Version, and New International Version) reveal that the translation “kind” or “kinds” is used.

Can we be more specific? Does the word imply a zoological classification such as the term “species” would in scientific discussions of the animal and vegetable kingdoms? It is always dangerous to apply modern concepts to ancient literature. The use of classificatory schemes provides a good example. The application of categories of knowledge in pre-Aristotelian writings invites misunderstanding as the means of viewing the world and its elements differed from the way we look at things today. This does not mean that communication is impossible; only that we need to remain especially cautious not to import our understanding of matters onto the ancient worldview of writers without approaching these questions carefully and critically.

In terms of ancient (or modern) literature, a word is best understood according to its usage in the writings in which it occurs. This suggests that context determines meaning. This is especially true where it appears multiple times in the same type of literature written from the same culture and general time period. The study of context is the primary determinant for understanding the definition of a word.

Secondarily, one may consider related words in the same literature. Because a Semitic language such as Hebrew is based on roots (usually of three consonants) that each generate verbs, nouns, and other particles of speech, words formed from the same root may provide additional understanding of the term we are considering.

The third area for study is where the same word occurs in comparative literature coming from similar, though not identical (which we consider in the first category), cultures and times. The Old Testament was written in Hebrew but we do not have much additional Hebrew writing preserved for us from the time when this part of the Bible was written. However, there are closely related Semitic languages that possess a wealth of literature and may contain our word in their writings. If so, it would be good to check this and see if there is a relationship there. At the same time, later Hebrew, written by Jewish scholars, may also use this word. It is of value to compare the usage here. This part of the study can confirm and refine our understanding of mîn, but it should not overturn clear contextual indications from the Old Testament usage itself.

Finally, we should note that, in the Old Testament, mîn does not appear by itself. Every one of its occurrences forms part of the same prepositional phrase. Thus our work is not complete when we have identified the contextual and comparative meaning of the word. Instead, we need to examine the usage of the term within this prepositional phrase. Such expressions can sometimes alter the meaning of the term. This is especially true in idioms, but also occurs in other common expressions.

Old Testament Context of mîn

The Hebrew term, mîn, occurs 31 times in the Old Testament. These occurrences are found in four contexts: the creation story of Genesis 1 (vv. 11, 12, 21, 24, and 25), the flood story (Genesis 6:20; 7:14), the lists of clean and unclean animals in Leviticus 11 (vv. 14, 15, 16, 19, 22, and 29) and Deuteronomy 14 (vv. 13, 14, 15, and 18), and the single occurrence in the prophet Ezekiel’s vision of the future river that will flow from the Jerusalem temple to the Dead Sea (Ezekiel 47:10).

The usage in Genesis 1:11 and 12 associates mîn with vegetation, especially those plants and trees that have seeds and bear fruit. These will form the basis for the food to be eaten by people, birds, and land animals in Genesis 1:29-30. There is no specification of mîn in terms of species or any more specific category than edible plants and fruit trees.

The same seems to be true in Genesis 1:21, where mîn appears alongside large and small sea creatures and birds with wings. The second and third days of creation in Genesis 1 describe God’s demarcation of three domains of the physical world: the sky, the seas, and the dry ground. On days five and six God fills these areas with life, with living creatures. For the sky and sea, the creatures are defined according to their general means of locomotion and not in any other way. Modern zoological classifications use criteria in addition to locomotion. Thus there are few clues that would connect mîn with any modern classification system.

The appearance of our term in Genesis 1:24 and 25 brings us to the fifth day when God fills the dry land with life. Here God creates three categories: livestock, wild animals, and creatures that crawl along the ground. In v. 24 the general category of all living animals on the ground is described with mîn; whereas in v. 25 each of these three categories receives this term. Thus the term can be used of more general and more specific “kinds” of animals within the same grouping.

The term recurs in Genesis 6:20 and 7:14, where it modifies individually the bird, the wild animal of the land, and the creature that crawls along the ground. In Genesis 7:14 livestock is added to those in the ark. It also is modified by mîn. Here the categories of animals resemble those in Genesis 1. From these “kinds” would come all the species that are found in nature. This confirms the broad usage of mîn but does not add new information.

The usage of mîn also occurs in the listing of unclean animals. It occurs in a list in Leviticus 11:14, 15, 16, 19, and 22; which closely follows the list in Deuteronomy 14:13, 14, 15, and 18. Only Leviticus 11:22 is separate. This list includes specific names of small wild animals, various birds, and insects (Leviticus 11:22). Although there is discussion and dispute regarding the specific identification of various of these animals, it is clear that they form subcategories of those types to whom the term mîn was applied in Genesis 1, 6, and 7. The resulting picture is thus that mîn applies to a variety of animal categories, both those more general and those more specific. While particular species may be described in Leviticus and Deuteronomy, that is certainly not the case in Genesis, where the categories of living creatures are much broader.

The remaining text with mîn is Ezekiel 47:10. Here the fresh water that will pour from the temple into the Dead Sea forms a natural habitat for fish that are mîn and are compared with those fish found in the Mediterranean Sea. As in Genesis 1:21, the picture is one of general creatures of the sea, rather than what anyone might identify as a particular species. Indeed, if the translation of the phrase in which mîn occurs is understood (following the New International Version) as, “The fish will be of many kinds,” then this could envision various species. However, such an interpretation is not explicit from the text itself.

Our survey of the usage of the term in biblical Hebrew suggests that it may describe all types of plants and animals, and this may include mîn in the broadest categories of living creatures: green plants with seed, fruit trees, birds, sea creatures, fish, wild land animals, domestic animals, and creatures that creep along the ground. It may also include specific categories as enumerated in Leviticus 11 and Deuteronomy 14. Thus mîn does refer to various kinds of living creatures without a predisposition as to how large a category is intended. Only context can tell us that. The term is applied only to living creatures as described in the Bible. It is never applied to people, abstract concepts, or nonliving objects.

In Part 2, Dr. Hess expands his analysis in by exploring closely related words in the Old Testament and by comparing how mîn is used in literature coming from similar cultures and times.

I am using the term in the same sense. Like Ramm, I don’t regard theistic evolution as a concordist view, even though some TE proponents like to say that evolution can be “harmonized” with Genesis. At the same time, Ramm completely rejected Price’s recent creation and Flood Geology, and he obviously did not consider that view to be a type of concordism either. Why not? On first glance, the YEC view might seem to fall within Ramm’s definition of concordism, and the authors of one of the books recommended in the first column in this series classify it as a type of concordism. However, the harmony sought by YEC proponents comes at the cost of entirely rejecting the standard geologic record, which they replace with Flood Geology. That isn’t what Ramm had in mind by seeking a “harmony.”

Often the concordist view is called “progressive creation,” another term that Ramm used with much approval: “We believe that the fundamental pattern of creation is progressive creation,” he wrote prominently in italics. Indeed, it is sometimes assumed that Ramm invented both terms, “concordism” and “progressive creation,” when in fact he did no such thing. If anything, the latter term is even older than the former, having been used to refer to an OEC interpretation of natural history for about two centuries. The first American author to use it may have been Benjamin Silliman, an evangelical who was appointed the first professor of natural history at Yale by another evangelical, Yale’s president Timothy Dwight. Silliman was the single most influential figure in American science during the nineteenth century. In his Outline of the Course of Geological Lectures Given in Yale College (1829), Silliman spoke of “the progressive creation, life, death and sepulture [fossilization], of animals and plants.” On another occasion he noted how the Bible describes “a successive creation of plants and animals, ending with man,” and that geology “proves this history to be true.”

Clearly, then, the concordist or progressive creationist view has been around for a long time. Let’s examine its main components.

Core Tenets or Assumptions of Concordism

(1) The Bible and science (mainly geology and astronomy) are BOTH reliable sources of knowledge about the origin of the earth and the universe. God has written two “books” for our instruction, the book of nature and the book of scripture. Since God is the author of both “books,” they must agree when properly interpreted.

If this strikes you as worded deliberately to sound like Galileo, you’re right—but only because so many proponents of the concordist view also have Galileo very much in their minds. The basic scheme is neatly depicted in this diagram:

Recall Galileo’s belief that the book of nature, written in the divine and unambiguous language of mathematics, should be used to help interpret the book of scripture, written in the richer but more ambiguous language spoken by the ordinary persons for whom its vital message of salvation was intended. When they accept the evidence for an ancient earth, Silliman and many other evangelical scholars right down to our own day believe they have merely applied Galileo’s logic to a different set of biblical texts.

(2) Scientific evidence, when properly interpreted, is consistent with the Bible, when properly interpreted.

Galileo again: because both “books” are written by the same Author, they must agree. As he said in his Letter to Christina, “the holy Bible can never speak untruth—whenever its true meaning is understood. But I believe nobody will deny that it is often very abstruse, and may say things which are quite different from what its bare words signify. Hence in expounding the Bible if one were always to confine oneself to the unadorned grammatical meaning, one might fall into error.”

What about those who interpret the book of nature? Can they ever be mistaken? Should they ever yield to those who interpret the book of scripture? Evolution was not the source of Galileo’s concerns, but concordists today would give the nod to scripture mainly when it comes to evolution—especially human evolution. Regardless of how much evolution they accept for other organisms, concordists hold strongly to the separate creation of Adam and Eve as the first human beings. They believe that Genesis 1 was intended to be at least broadly historical, even though it does not provide detailed scientific information.

Mainstream conclusions in geology and cosmology, however, are almost always accepted; indeed, Hugh Ross and some other OECs not only accept the “big bang” theory of the universe, they actively promote it as central to Christian apologetics, because it presents us with a universe that is not eternal and that appears to be exquisitely designed as a home for living creatures, including ourselves.

(3) The Bible does NOT tell us the age of the earth.

Two main concordist approaches to resolving the tension between Genesis and scientific dating of the earth have been popular since the mid-nineteenth century: the “day-age theory,” which still has numerous advocates (including Ross), and the “gap theory,” which is now nearly extinct. One hundred years ago, however, the gap theory was probably the more popular option among conservative Protestants, and it remained so until the 1960s and 1970s, when the rapid spread of Scientific Creationism all but relegated the gap view to the dust bin.

The Gap Theory

The gap theory posits a “gap” of untold length between “the beginning” of Genesis 1:1 and the first “day” of creation, starting with Genesis 1:3; the formless void of Gen 1:2 corresponds to this “gap.” Verse 1 refers to the original creation of the earth and the universe “in the beginning,” not to world as we now find it. The fossils represent creatures that populated the original creation. Current living creatures come from a second creation, after the “gap,” when God made them in six literal days, culminating in the creation of Adam and Eve just a few thousand years ago.

Although the creation of humanity matches the traditional biblical chronology—a major reason for the popularity of the gap theory in its heyday—the original creation cannot be dated from the Bible. Whether it happened 100 million years ago (as scientists thought around 1900) or billions of years ago (as scientists thought for much of the twentieth century), does not matter one bit to the Bible. Geologists can say whatever they wish about the age of the earth. The Scofield Reference Bible, originally published by Oxford University Press in 1909, taught the gap theory to generations of conservative Protestants in the English speaking world. The headings alone indicate Scofield’s endorsement of the gap theory, and he waited no longer than the second footnote to spell it out: “The first creative act refers to the dateless past, and gives scope for all the geologic ages.” (NOTE: the date “B.C. 4004" in the middle column refers to the start of the six days, not to “the beginning.” I’ll elaborate on that date in part two of this column.)

As Scofield’s third note shows, the gap theory was usually placed within an elaborate theological structure about the fall of Satan and the angels, based on certain prophetic texts (see below). A full discussion would take us far afield, but something should be said about how gap theorists interpret Genesis 1:2, the crucial verse for their model. Scofield sticks with the King James Version, “the earth was without form, and void,” doing the exegetical work in his notes, but others like to render it as, “the earth became a waste place,”, drawing out the implication (in their view) that God destroyed the original creation, laying waste to it in an act of judgment, leaving us with fossils of the pre-Adamic world.

In some versions of the gap view, the original creation included pre-Adamite people—that is, humans who were not descended from Adam and Eve. This idea that took many forms, some with racist overtones. Perhaps this strikes you as a bit surprising, but in the mid-nineteenth century it was a commonplace conception among Protestants, and not unknown to Catholics either. A prominent example would be The Pre-Adamite Earth: A Contribution to Theological Science (1846), a very popular book by the English Congregational minister John Harris. Historian David Livingstone has written the definitive history of this fascinating idea. For more, see this interview, but there is no substitute for reading the book itself! Let me make an invitation: who wants to borrow a copy and provide their own commentary here?

In all versions of the gap theory, however, fossils are vestiges of the pre-Adamic world, produced when it was destroyed; they are not a record of evolutionary history. All modern animals and many plants were created recently, in six literal days. Despite what YECs often say, there is just no way to see the gap theory as an “evolutionist” interpretation of Genesis!

The "Day-Age" Theory

The day-age theory takes the “days” in Genesis 1 as periods of indefinite length, such that neither the age of the earth nor the duration of any particular period in creation history can be determined from the Bible. The basis for this view is that the Hebrew word “yom” (day) can also mean an indefinite period of time. According to Hugh Ross, the leading advocate of progressive creation today, if the Hebrews had wanted to refer to a long period of indefinite length, they would have used the word “yom.” Thus, he claims to be giving a literal interpretation when he upholds the day-age view.

Numerous varieties of the day-age view have been proposed since the eighteenth century, too many to review here. They all teach that the major kinds of plants and animals were created separately, over the eons of earth history; the fossil record shows reliably which came earlier and which came later. Thus, the creation was accomplished “progressively,” as Silliman held in 1829 and Ross holds today. Ross thinks God performed millions of acts of special creation, but concordists differ substantially among themselves on the magnitude of the number for this.

Concordists mostly agree, however, that the first true humans were Adam and Eve, and that they were created ex nihilo—but, how recently were they created? Can the biblical 6,000 years be stretched far enough to encompass fossils of modern humans (homo sapiens sapiens) dating back perhaps to nearly 200,000 years? Can the biblical picture of Adam’s children living amidst cities and agriculture be reconciled with extensive evidence of humans who lived long before either existed? I’m no anthropologist, but anyone can see the relevance of such questions for this position.

(4) The Flood was a real historical event, but it was not responsible for producing the fossils; rather, fossils are relics of organisms that were mainly here before humans.

The last of the four basic assumptions shared by concordists is that they reject Flood Geology and accept the standard geologic column. Hugh Ross and some others believe that the flood was geographically localized, covering part of the ancient Near East but not the whole globe. This is called the “local flood” view. Biblical scholar Paul Seely briefly assesses this view in light of current knowledge here, but a full discussion of the issues goes well beyond of the scope of this online course. Anyone with appropriate expertise is invited to place comments below. The main point is that the flood has no geological significance for concordists, whether or not it was geographically “local.”

Looking Ahead

Our look at concordism concludes on July 3 with some conclusions about the OEC view and further historical comments. I’ll pay attention to your comments in the meantime.

There are two opposite errors which need to be countered about the fossil record: 1) that it is so incomplete as to be of no value in interpreting patterns and trends in the history of life, and 2) that it is so good that we should expect a relatively complete record of the details of evolutionary transitions within all or most lineages.

What then is the quality of the fossil record? It can be confidently stated that only a very small fraction of the species that once lived on Earth have been preserved in the rock record and subsequently discovered and described by science.

There is an entire field of scientific research referred to as "taphonomy" -- literally, "the study of death." Taphonomic research includes investigating those processes active from the time of death of an organism until its final burial by sediment. These processes include decomposition, scavenging, mechanical destruction, transportation, and chemical dissolution and alteration. The ways in which the remains of organisms are subsequently mechanically and chemically altered after burial are also examined -- including the various processes of fossilization. Burial and "fossilization" of an organism's remains in no way guarantees its ultimate preservation as a fossil. Processes such as dissolution and recrystallization can remove all record of fossils from the rock. What we collect as fossils are thus the "lucky" organisms that have avoided the wide spectrum of destructive pre- and post-depositional processes arrayed against them.

Soft-bodied organisms, and organisms with non-mineralized skeletons have very little chance of preservation under most environmental conditions. Until the Cambrian nearly all organisms were soft-bodied, and even today the majority of species in marine communities are soft-bodied. The discovery of new soft-bodied fossil localities is always met with great enthusiasm. These localities typically turn up new species with unusual morphologies, and new higher taxa can be erected on the basis of a few specimens! Such localities are also erratically and widely spaced geographically and in geologic time.

Even those organisms with preservable hard parts are unlikely to be preserved under "normal" conditions. Studies of the fate of clam shells in shallow coastal waters reveal that shells are rapidly destroyed by scavenging, boring, chemical dissolution and breakage. Occasional burial during major storm events is one process that favors the incorporation of shells into the sedimentary record, and their ultimate preservation as fossils. Getting terrestrial vertebrate material into the fossil record is even more difficult. The terrestrial environment is a very destructive one: with decomposition and scavenging together with physical and chemical destruction by weathering.

The potential for fossil preservation varies dramatically from environment to environment. Preservation is enhanced under conditions that limit destructive physical and biological processes. Thus marine and fresh water environments with low oxygen levels, high salinities, or relatively high rates of sediment deposition favor preservation. Similarly, in some environments biochemical conditions can favor the early mineralization of skeletons and even soft tissues by a variety of compounds (eg. carbonate, silica, pyrite, and phosphate). The likelihood of preservation is thus highly variable. As a result, the fossil record is biased toward sampling the biota of certain types of environments, and against sampling the biota of others.

In addition to these preservational biases, the erosion, deformation and metamorphism of originally fossiliferous sedimentary rock have eliminated significant portions of the fossil record over geologic time. Furthermore, much of the fossil-bearing sedimentary record is hidden in the subsurface, or located in poorly accessible or little studied geographic areas. For these reasons, of those once-living species actually preserved in the fossil record, only a small portion have been discovered and described by science. However, there is also the promise of continued new and important discovery.

The forces arrayed against fossil preservation also guarantee that the earliest fossils known for a given animal group will always date to some time after that group first evolved. The fossil record always provides only minimum ages for the first appearance of organisms.

Because of the biases of the fossil record, the most abundant and geographically widespread species of hardpart-bearing organisms would tend to be best represented. Also, short-lived species that belonged to rapidly evolving lines of descent are less likely to be preserved than long-lived stable species. Because evolutionary change is probably most rapid within small isolated populations, a detailed species-by-species record of such evolutionary transitions is unlikely to be preserved. Furthermore, capturing such evolutionary events in the fossil record requires the fortuitous sampling of the particular geographic locality where the changes occurred.

Using the model of a branching tree of life, the expectation is for the preservation of isolated branches on an originally very bushy evolutionary tree. A few of these branches (lines of descent) would be fairly complete, while most are reconstructed with only very fragmentary evidence. As a result, the large-scale patterns of evolutionary history can generally be better discerned than the population-by-population or species-by-species transitions. Evolutionary trends over longer periods of time and across greater anatomical transitions can be followed by reconstructing the sequences in which anatomical features were acquired within an evolving branch of the tree of life.

The issue at stake in the Galileo controversy is, of course, how the Bible should be interpreted. So let us think about some general principles of interpretation before we apply them to the moving-earth controversy.

The first obvious, yet important thing to say about the Bible is that it is literature. In fact, it is a whole library of books: some of them history, some poetry, some in the form of letters, and so on, very different in content and style. In approaching literature in general, the first question to ask is, how does the author who wrote it wish it to be understood? For instance, the author of a mathematics textbook does not intend it to be understood as poetry; Shakespeare does not intend us to understand his plays as exact history, and so on.

Next, one should in the first instance be guided by the natural understanding of a passage, sentence, word, or phrase in its context, historically, culturally, and linguistically. The Reformers emphasized this in their reaction against the kind of interpretation that (to cite an ancient example) took the four rivers mentioned in Genesis 2—the Pishon, Gihon, Tigris, and Euphrates—to represent the body, soul, spirit, and mind, respectively. By contrast with this “allegorical” method of interpretation, the Reformers adopted an approach described by the Oxford English Dictionary in its definition of literal: “that sense or interpretation (of a text) which is obtained by taking its words in their natural or customary meaning, and applying the ordinary rules of grammar; opposed to mystical, allegorical, etc.,” and “hence, by extension, … the primary sense of a word, or … the sense expressed by the actual wording of a passage, as distinguished from any metaphorical or merely suggested meaning.”¹ Of course, there is nothing new in this way of understanding literature: it is what all of us use every day in our reading and conversation, without even thinking about it.

The importance of considering the natural understanding of a passage is clear, when it comes to the basic teaching of the Christian faith. The crucial thing about Christianity’s fundamental doctrines is that they are first and foremost to be understood in their natural, primary sense. The cross of Christ is not a metaphor. It involved an actual death. The resurrection is not an allegory. It was a physical event: a “standing up again”² of a body that had died.

But this basic principle needs to be qualified. For instance, when we are dealing with a text that was produced in a culture distant from our own both in time and in geography, what we think the natural meaning is may not have been the natural meaning for those to whom the text was originally addressed. We shall consider this issue in due course.

At this stage we make a few general remarks about the way in which we use language. Some of us will be familiar with what I am about to say, but many of us may not have thought much about how we use language—we are too busy using it to bother. However, it will help us greatly if we spend just a little time thinking about this matter.

Firstly, there can be more than one natural reading of a word or phrase. For example, in Genesis 1 there are several instances of this. The word “earth” is first used for the planet, and then a little later for the dry land as distinct from the sea. Both times the word earth is clearly meant literally, but the two meanings are different, as is clear from their context.

Next, in many places a literal understanding will not work. Let’s take first an example from everyday speech. We all understand what a person means when they say, “The car was flying down the road.” The car and the road are very literal, but “flying” is a metaphor. However, we also are well aware that the metaphor “flying” stands for something very real that could be expressed more literally as “driving fast.” Just because a sentence contains a metaphor, it doesn’t mean that it is not referring to something real.

For a biblical example, take Jesus’ statement, “I am the door” (John 10:9). It is clearly not meant to be understood in the primary, literal sense of a door made of wood. It is meant metaphorically. But notice again that the metaphor stands for something real: Jesus is a real doorway into an actual, and therefore very literal, experience of salvation and eternal life. We should also note that the reason why we do not take this statement literally has to do with our experience of the world. We know about doors, and our experience of them helps us decide that Jesus is using a metaphor. We shall return to this point later.

Furthermore, it is impossible, as C. S. Lewis pointed out, to speak of things beyond our immediate senses without using metaphor. Scientists, therefore, use metaphor all the time. They talk about light particles and wave packets of energy; but they don’t intend you to imagine light as literal tiny balls, or energy as literal waves on the sea. Yet in each case the metaphor is describing something real—literal, if you like—at a higher level.

To make things more complicated, but also more interesting, sometimes both a primary and a metaphorical sense can occur together. Take the ascension of Christ, for example. In its primary sense it refers to the literal, vertical ascent of Jesus into the sky that was physically observed by the disciples.³ However, there is more to it than that. The literal upward movement carries a deeper meaning—he ascended to the throne of God. For instance, when we say that Queen Elizabeth II ascended the throne of England in 1952, we do not simply mean that she got up onto an ornate chair in Westminster Abbey. She did that, of course; but that (literal) getting up on the chair was at the same time a metaphor for her (literal) assumption of real power over her people. Similarly, the (literal) ascension of Christ is a metaphor of his (literal) assumption of universal authority.

In each of these examples we see how the word literal can turn out to be inadequate and even misleading, since there can be different levels of literality. It is therefore common nowadays to reserve the word literalistic for an adherence to the basic, primary meaning of a word or expression, and literal for the natural reading as intended by the author or speaker. Thus, reading the phrase “the car was flying down the road” in a literalistic way would mean understanding the car to be actually flying. Reading it literally—that is, in the natural sense—would mean that the car was going very fast. However, this usage of literal is not agreed by all, which often leads to confusion. We must, therefore, be careful with our use of literal.

I recall once talking about the Genesis creation narrative with a well-known astrophysicist, who suggested to me that it was primitive to believe the Bible. To illustrate a point, I wrote on his blackboard: “And God said, let there be light. And there was light.” He said: “That sounds really primitive. You don’t really believe it, do you? It suggests that God has a physical voice box and speaks like we do.” In other words, my colleague was taking the word “said” in its primary, natural, human sense—he was taking it literalistically. I laughed, and told him that it was now he who was being primitive. Of course God, who is spirit, doesn’t have a physical voice box, but he can communicate. In other words, the expression “And God said” denotes real, literal communication, but we do not have the slightest idea as to how it is done.

The word said means something different for God than it does for us,⁴ but the two usages are sufficiently related for one word to do both jobs effectively. The reason I was amused when my astrophysicist friend made his remarks is that, as I reminded him, scientists use metaphors all the time without batting an eyelid. They, of all people, should not complain when the Bible uses them.

As a general point, it is worth recalling a perceptive remark made by Henri Blocher: “Human speech rarely remains at the zero-point of plain prose, which communicates in the simplest and most direct manner, using words in their ordinary sense.”⁵ What Blocher means is that we all use metaphors in our ordinary conversation. How colourless life would be without them.

There is more that could be said about the use of language, but perhaps we now have enough to grasp the basic idea. And I am sure the last thing the reader wants is for this book to turn into a lengthy lesson in English grammar!

It would be a pity if, in a desire (rightly) to treat the Bible as more than a book, we ended up treating it as less than a book by not permitting it the range and use of language, order, and figures of speech that are (or ought to be) familiar to us from our ordinary experience of conversation and reading.

If we take this into account, the answer to the question, “At what level should a text be read?” is often obvious. We take the natural, primary meaning; and if that doesn’t make sense, we go for the next level. For example, Jesus’ statements “I am the door” (John 10:9) and “I am the bread of life” (John 6:48). But there are instances where the answer does not seem to be so obvious, in the sense that believers in all ages who are fully convinced of the authority of Scripture come to different interpretations. What should we do in such a situation? That was the hot-button question in the time of Galileo.

In part 2, Dr. Lennox applies these lessons to the historical controversy about whether the earth moves and what the Bible has to say (or not say) about it.

Notes

1. This is often called “the literal method.” We shall discuss the use of the word literal below.
2. This is the meaning of the Greek word anastasis, used in the New Testament for “resurrection.”
3. See Acts 1, written, it should be observed, by the historian Luke, who, as a doctor, had the nearest approximation to a scientific education of any of the New Testament writers. For Luke’s appreciation of the questions arising in connection with science and miracle, see David W. Gooding, According to Luke (Leicester, UK: Inter-Varsity, 1987), 37ff. For a scientific viewpoint see John C. Lennox, God’s Undertaker: Has Science Buried God? (Oxford: Lion Hudson, 2009), chap. 12.
4. Indeed, when God speaks to certain people in the Bible, he uses human language, though how he does so is, of course, unknown to us. One might go further and say that God’s speech is the primary kind and that human speech is derivative—in the sense that we are made in God’s image.
5. Henri Blocher, In the Beginning (Leicester, UK: Inter-Varsity, 1984), 18.