Macroevolution

(This is a copy of an essay that I published in 2006. I made some minor revisions to remove outdated context.)

Overheard at breakfast on the final day of a recent scientific meeting: "Do you believe in macroevolution?" Came the rely: "Well, it depends on how you define it."
                                                                         Roger Lewin (1980)

There is no difference between micro- and macroevolution except that genes between species usually diverge, while genes within species usually combine. The same processes that cause within-species evolution are responsible for above-species evolution.
                                                                         John Wilkins

The minimalist definition of evolution is a change in the hereditary characteristics of a population over the course of many generations. This is a definition that helps us distinguish between changes that are not evolution and changes that meet the minimum criteria. The definition comes from the field of population genetics developed in the early part of the last century. The modern theory of evolution owes much to population genetics and our understanding of how genes work. But is that all there is to evolution?

The central question of the Chicago conference was whether the mechanisms underlying microevolution can be extrapolated to explain the phenomena of macroevolution. At the risk of doing violence to the positions of some of the people at the meeting, the answer can be given as a clear, No.
               Roger Lewin (1980)

No. There's also common descent—the idea that all life has evolved from primitive species over billions of years. Common descent is about the history of life. In this essay I'll describe the main features of how life evolved but keep in mind that this history is a unique event that is accidental, contingent, quirky, and unpredictable. I'll try and point out the most important controversies about common descent.

The complete modern theory of evolution encompasses much more than changes in the genetics of a population. It includes ideas about the causes of speciation, long-term trends, and mass extinctions. This is the domain of macroevolution—loosely defined as evolution above the species level. The kind of evolution that focuses on genes in a population is usually called microevolution.

As a biochemist and a molecular biologist, I tend to view evolution from a molecular perspective. My main interest is molecular evolution and the analysis of sequences of proteins and nucleic acids. One of the goals in writing this essay is to explain this aspect of evolution to the best of my limited ability. However, another important goal is to show how molecular evolution integrates into the bigger picture of evolution as described by all other evolutionary biologists, including paleontologists. When dealing with macroevolution this is very much a learning experience for me since I'm not an expert. Please bear with me while we explore these ideas.

It's difficult to define macroevolution because it's a field of study and not a process. Mark Ridley has one of the best definitions I've seen ...

Macroevolution means evolution on the grand scale, and it is mainly studied in the fossil record. It is contrasted with microevolution, the study of evolution over short time periods., such as that of a human lifetime or less. Microevolution therefore refers to changes in gene frequency within a population .... Macroevolutionary events are more likely to take millions, probably tens of millions of years. Macroevolution refers to things like the trends in horse evolution described by Simpson, and occurring over tens of millions of years, or the origin of major groups, or mass extinctions, or the Cambrian explosion described by Conway Morris. Speciation is the traditional dividing line between micro- and macroevolution.
                                                                         Mark Ridley (1997) p. 227

When we talk about macroevolution we're talking about studies of the history of life on Earth. This takes in all the events that affect the actual historical lineages leading up to today's species. Jeffrey S. Levinton makes this point in his description of the field of macroevolution and it's worth quoting what he says in his book Genetics, Paleontology, and Macroevolution.

Macroevolution must be a field that embraces the ecological theater, including the range of time scales of the ecologist, to the sweeping historical changes available only to paleontological study. It must include the peculiarities of history, which must have had singular effects on the directions that the composition of the world's biota took (e.g., the splitting of continents, the establishment of land and oceanic isthmuses). It must take the entire network of phylogenetic relationships and impose a framework of genetic relationships and appearances of character changes. Then the nature of evolutionary directions and the qualitative transformation of ancestor to descendant over major taxonomic distances must be explained.
                                                                     Jeffrey S. Levinton (2001) p.6

Levinton then goes on to draw a parallel between microevolution and macroevolution on the one hand, and physics and astronomy on the other. He points out that the structure and history of the known universe has to be consistent with modern physics, but that's not sufficient. He gives the big bang as an example of a cosmological hypothesis that doesn't derive directly from fundamental physics. I think this analogy is insightful. Astronomers study the life and death of stars and the interactions of galaxies. Some of them are interested in the formation of planetary systems, especially the unique origin of our own solar system. Explanations of these "macro" phenomena depend on the correctness of the underlying "micro" physics phenomena (e.g., gravity, relativity) but there's more to the field of astronomy than that.

Levinton continues ....

Does the evolutionary biologist differ very much from this scheme of inference? A set of organisms exists today in a partially measurable state of spatial, morphological, and chemical relationships. We have a set of physical and biological laws that might be used to construct predictions about the outcome of the evolutionary process. But, as we all know, we are not very successful, except at solving problems at small scales. We have plausible explanations for the reason why moths living in industrialized areas are rich in dark pigment, but we don't know whether or why life arose more than once or why some groups became extinct (e.g., the dinosaurs) whereas others managed to survive (e.g., horseshoe crabs). Either our laws are inadequate and we have not described the available evidence properly or no such laws can be devised to predict uniquely what should have happened in the history of life. For better or worse, macroevolutionary biology is as much historical as is astronomy, perhaps with looser laws and more diverse objectives....

Indeed, the most profound problem in the study of evolution is to understand how poorly repeatable historical events (e.g., the trapping of an endemic radiation in a lake that dries up) can be distinguished from lawlike repeatable processes. A law that states 'an endemic radiation will become extinct if its structural habitat disappears' has no force because it maps to the singularity of a historical event.
                                                                 Jeffrey S. Levinton (2001) p.6-7

In conclusion, then, macroevolutionary processes are underlain by microevolutionary phenomena and are compatible with microevolutionary theories, but macroevolutionary studies require the formulation of autonomous hypotheses and models (which must be tested using macroevolutionary evidence). In this (epistemologically) very important sense, macroevolution is decoupled from microevolution: macroevolution is an autonomous field of evolutionary study.
     Francisco J. Ayala (1983)

I think it's important to appreciate what macroevolutionary biologists are saying. Most of these scientists are paleontologists and they think of their area of study as an interdisciplinary field that combines geology and biology. According to them, there's an important difference between evolutionary theory and the real history of life. The actual history has to be consistent with modern evolutionary theory (it is) but the unique sequence of historical events doesn't follow directly from application of evolutionary theory. Biological mechanisms such as natural selection and random genetic drift are part of a much larger picture that includes moving continents, asteroid impacts, ice ages, contingency, etc. The field of macroevolution addresses these big picture issues.

Clearly, there are some evolutionary biologists who are only interested in macroevolution. They don't care about microevolution. This is perfectly understandable since they are usually looking at events that take place on a scale of millions of years. They want to understand why some species survive while others perish and why there are some long-term trends in the history of life. (Examples of such trends are the loss of toes during the evolution of horses, the development of elaborate flowers during the evolution of vascular plants, and the tendency of diverse species, such as the marsupial Tasmanian wolf and the common placental wolf, to converge on a similar body plan.)

Nobody denies that macroevolutionary processes involve the fundamental mechanisms of natural selection and random genetic drift, but these microevolutionary processes are not sufficient, by themselves, to explain the history of life. That's why, in the domain of macroevolution, we encounter theories about species sorting and tracking, species selection, and punctuated equilibria.

Micro- and macroevolution are thus different levels of analysis of the same phenomenon: evolution. Macroevolution cannot solely be reduced to microevolution because it encompasses so many other phenomena: adaptive radiation, for example, cannot be reduced only to natural selection, though natural selection helps bring it about.
     Eugenie C. Scott (2004)

As I mentioned earlier, most of macroevolutionary theory is intimately connected with the observed fossil record and, in this sense, it is much more historical than population genetics and evolution within a species. Macroevolution, as a field of study, is the turf of paleontologists and much of the debate about a higher level of evolution (above species and populations) is motivated by the desire of paleontologists to be accepted at the high table of evolutionary theory. It's worth recalling that during the last part of the twentieth century evolutionary theorizing was dominated by population geneticists. Their perspective was described by John Maynard Smith, "... the attitude of population geneticists to any paleontologist rash enough to offer a contribution to evolutionary theory has been to tell him to go away and find another fossil, and not to bother the grownups." (Maynard Smith, 1984)

The distinction between microevolution and macroevolution is often exaggerated, especially by the anti-science crowd. Creationists have gleefully exploited the distinction in order to legitimate their position in the light of clear and obvious examples of evolution that they can't ignore. They claim they can accept microevolution, but they reject macroevolution.

In the real world—the one inhabited by rational human beings—the difference between macroevolution and microevolution is basically a difference in emphasis and level. Some evolutionary biologists are interested in species, trends, and the big picture of evolution, while others are more interested in the mechanics of the underlying mechanisms.

Speciation is critical to conserving the results of both natural selection and genetic drift. Speciation is obviously central to the fate of genetic variation, and a major shaper of patterns of evolutionary change through evolutionary time. It is as if Darwinians—neo- and ulra- most certainly included—care only for the process generating change, and not about its ultimate fate in geological time.
     Niles Eldredge (1995)

The Creationists would have us believe there is some magical barrier separating selection and drift within a species from the evolution of new species and new characteristics. Not only is this imagined barrier invisible to most scientists but, in addition, there is abundant evidence that no such barrier exists. We have numerous examples that show how diverse species are connected by a long series of genetic changes. This is why many scientists claim that macroevoluton is just lots of microevolution over a long period of time.

But wait a minute. I just said that many scientists think of macroevolution as simply a scaled-up version of microevolution, but a few paragraphs ago I said there's more to the theory of evolution than just changes in the frequency of alleles within a population. Don't these statements conflict? Yes, they do ... and therein lies a problem.

When the principle tenets of the Modern Synthesis were being worked out in the 1940's, one of the fundamental conclusions was that macroevolution could be explained by changes in the frequency of alleles within a population due, mostly, to natural selection. This gave rise to the commonly accepted notion that macroevolution is just a lot of microevolution. Let's refer to this as the sufficiency of microevolution argument.

At the time of the synthesis, there were several other explanations that attempted to decouple macroevolution from microevolution. One of these was saltation, or the idea that macroevolution was driven by large-scale mutations (macromutations) leading to the formation of new species. This is the famous "hopeful monster" theory of Goldschmidt. Another decoupling hypothesis was called orthogenesis, or the idea that there is some intrinsic driving force that directs evolution along certain pathways. Some macroevolutionary trends, such as the increase in the size of horses, were thought to be the result of this intrinsic force.

Both of these ideas about macroevolutionary change (saltation and orthogensis) had support from a number of evolutionary biologists. Both were strongly opposed by the group of scientists that produced the Modern Synthesis. One of the key players was the paleontologist George Gaylord Simpson whose books Tempo and Mode in Evolution (1944) and The Major Features of Evolution (1953) attempted to combine paleontology and population genetics. "Tempo" is often praised by evolutionary biologists and many of our classic examples of evolution, such as the bushiness of the horse tree, come from that book. It's influence on paleontologists was profound because it upset the traditional view that macroevolution and the newfangled genetics had nothing in common.

Just as mutation and drift introduce a strong random component into the process of adaptation, mass extinctions introduce chance into the process of diversification. This is because mass extinctions are a sampling process analogous to genetic drift. Instead of sampling allele frequencies, mass extinctions samples species and lineages. ... The punchline? Chance plays a large role in the processes responsible for adaptation and diversity.
        Freeman and Herron (1998)

We see, in context, that the blurring of the distinction between macroevolution and microevolution was part of a counter-attack on the now discredited ideas of saltation and orthogenesis. As usual, when pressing the attack against objectionable ideas, there's a tendency to overrun the objective and inflict collateral damage. In this case, the attack on orthogenesis and the old version of saltation was justified since neither of these ideas offer viable alternatives to natural selection and drift as mechanisms of evolution. Unfortunately, Simpson's attack was so successful that a generation of scientists grew up thinking that macroevolution could be entirely explained by microevolutionary processes. That's why we still see this position being advocated today and that's why many biology textbooks promote the sufficiency of microevolution argument. Gould argues—successfully, in my opinion—that the sufficiency of microevolution became dogma during the hardening of the synthesis in the 1950-'s and 1960's. It was part of an emphasis on the individual as the only real unit of selection.

However, from the beginning of the Modern Synthesis there were other evolutionary biologists who wanted to decouple macroevolution and microevolution—not because they believed in the false doctrines of saltation and orthogenesis, but because they knew of higher level processes that went beyond microevolution. One of these was Ernst Mayr. In his essay "Does Microevolution Explain Macroevolution," Mayr says ...

Among all the claims made during the evolutionary synthesis, perhaps the one that found least acceptance was the assertion that all phenomena of macroevolution can be ‘reduced to,' that is, explained by, microevolutionary genetic processes. Not surprisingly, this claim was usually supported by geneticists but was widely rejected by the very biologists who dealt with macroevolution, the morphologists and paleontologists. Many of them insisted that there is more or less complete discontinuity between the processes at the two levels—that what happens at the species level is entirely different from what happens at the level of the higher categories. Now, 50 years later the controversy remains undecided.
                                                                         Ernst Mayr (1988) p.402

Mayr goes on to make several points about the difference between macroevolution and microevolution. In particular, he emphasizes that macroevolution is concerned with phenotypes and not genotypes, "In this respect, indeed, macroevolution as a field of study is completely decoupled from microevolution." (ibid p. 403). This statement reiterates an important point, namely that macroevolution is a "field of study" and, as such, its focus differs from that of other fields of study such as molecular evolution.

If you think of macroevolution as a field of study rather than a process, then it doesn't make much sense to say that macroevolution can be explained by the process of changing alleles within a population. This would be like saying the entire field of paleontology can be explained by microevolution. This is the point about the meaning of the term "macroevolution" that is so often missed by those who dismiss it as just a bunch of microevolution.

The orthodox believers in the hardened synthesis feel threatened by macroevolution since it implies a kind of evolution that goes beyond the natural selection of individuals within a population. The extreme version of this view is called adaptationism and the believers are called Ultra-Darwinians by their critics. This isn't the place to debate adaptationism: for now, let's just assume that the sufficiency of microevolution argument is related to the pluralist-adaptationist controversy and see how our concept of macroevolution as a field of study relates to the issue. Niles Eldredge describes it like this ...

The very term macroevolution is enough to make an ultra-Darwinian snarl. Macroevolution is counterpoised with microevolution—generation by generation selection- mediated change in gene frequencies within populations. The debate is over the question, Are conventional Darwinian microevolutionary processes sufficient to explain the entire history of life? To ultra-Darwinians, the very term macroevolution suggests that the answer is automatically no. To them, macroevolution implies the action of processes—even genetic processes—that are as yet unknown but must be imagined to yield a satisfactory explanation of the history of life.

But macroevolution need not carry such heavy conceptual baggage. In its most basic usage, it simply means evolution on a large-scale. In particular, to some biologists, it suggests the origin of major groups - such as the origin and radiation of mammals, or the derivation of whales and bats from terrestrial mammalian ancestors. Such sorts of events may or may not demand additional theory for their explanation. Traditional Darwinian explanation, of course, insists not.
                                                              Niles Eldredge (1995) p. 126-127

Eldredge sees macroevolution as a field of study that's mostly concerned with evolution on a large scale. Since he's a paleontologist, it's likely that, for him, macroevolution is the study of evolution based on the fossil record. Eldredge is quite comfortable with the idea that one of the underlying causes of evolution can be natural selection—this includes many changes seen over the course of millions of years. In other words, there is no conflict between microevolution and macroevolution in the sense that microevolution stops and is replaced by macroevolution above the level of species. But there is a conflict in the sense that Eldredge, and many other evolutionary biologists, do not buy the sufficiency of microevolution argument. They believe there are additional theories, and mechanisms, needed to explain macroevolution. Gould says it best ....

We do not advance some special theory for long times and large transitions, fundamentally opposed to the processes of microevolution. Rather, we maintain that nature is organized hierarchically and that no smooth continuum leads across levels. We may attain a unified theory of process, but the processes work differently at different levels and we cannot extrapolate from one level to encompass all events at the next. I believe, in fact, that ... speciation by splitting guarantees that macroevolution must be studied at its own level. ... [S]election among species—not an extrapolation of changes in gene frequencies within populations—may be the motor of macroevolutionary trends. If macroevolution is, as I believe, mainly a story of the differential success of certain kinds of species and, if most species change little in the phyletic mode during the course of their existence, then microevolutionary change within populations is not the stuff (by extrapolation) of major transformations.
                                                         Stephen Jay Gould (1980b) p. 170

Naturalists such as Ernst Mayr and paleontologists such as Gould and Eldredge have all argued convincingly that speciation is an important part of evolution. Since speciation is not a direct consequence of changes in the frequencies of alleles in a population, it follows that microevolution is not sufficient to explain all of evolution. Gould and Eldredge (and others) go even further to argue that there are processes such as species sorting that can only take place above the species level. This means there are evolutionary theories that only apply in the domain of macroevolution.

The idea that there's much more to evolution than genes and population genetics was a favorite theme of Stephen Jay Gould. He advocated a pluralist, hierarchical approach to evolution and his last book The Structure of Evolutionary Theory emphasized macroevolutionary theory—although he often avoided using this term. The Structure of Evolutionary Theory is a huge book that has become required reading for anyone interested in evolution. Remarkably, there's hardly anything in the book about population genetics, molecular evolution, and microevolution as popularly defined. What better way of illustrating that macroevolution must be taken seriously!

Macroevolutionary theory tries to identify patterns and trends that help us understand the big picture. In some cases, the macroevolution biologists have recognized generalities (theories & hypotheses) that only apply to higher level processes. Punctuated equilibria and species sorting are examples of such higher level phenomena. The possible repeatedness of mass extinctions might be another.

Remember that macroevolution should not be contrasted with microevolution because macroevolution deals with history. Microevolution and macroevolution are not competing explanations of the history of life any more than astronomy and physics compete for the correct explanation of the history of the known universe. Both types of explanation are required.

I think species sorting is the easiest higher level phenomena to describe. It illustrates a mechanism that is clearly distinct from changes in the frequencies of alleles within a population. In this sense, it will help explain why microevolution isn't a sufficient explanation for the evolution of life. Of course, one needs to emphasize that macroevolution must be consistent with microevolution.

I have championed contingency, and will continue to do so, because its large realm and legitimate claims have been so poorly attended by evolutionary scientists who cannot discern the beat of this different drummer while their brains and ears remain tuned to only the sounds of general theory.
        Stephen Jay Gould (2002)

If we could track a single lineage through time, say from a single-cell protist to Homo sapiens, then we would see a long series of mutations and fixations as each ancestral population evolved. It might look as though the entire history could be accounted for by microevolutionary processes. This is an illusion because the track of the single lineage ignores all of the branching and all of the other species that lived and died along the way. That track would not explain why Neanderthals became extinct and Cro-Magnon survived. It would not explain why modern humans arose in Africa. It would not tell us why placental mammals became more successful than the dinosaurs. It would not explain why humans don't have wings and can't breathe underwater. It doesn't tell us whether replaying the tape of life will automatically lead to humans. All of those things are part of the domain of macroevolution and microevolution isn't sufficient to help us understand them.

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Is lateral gene transfer (LGT) Lamarckian?

There's an interesting discussion going on about lateral gene transfer (LGT) in eukaryotes. LGT is the process by which DNA from one species invades the genome of another species. It was apparently very common among primitive bacteria several billion years ago and it's still quite common in modern bacteria.

There are many reports of LGT in eukaryotes but some of them seem to be due to contamination from bacteria rather than true LGT. Many scientists are skeptical of these reports; notably Bill Martin (Heinrich Heine Universität, Düsseldorf, Germany) who suggests that almost all of them are artifacts and lateral gene transfer in eukaryotes is extremely rare [see Lateral gene transfer in eukaryotes - where's the evidence?].

The selfish gene vs the lucky allele

The Selfish Gene was published forty-one years ago (1976) and last year there was a bit of a celebration. I think we can all appreciate the impact that the book had at the time but I'm not sure it's as profound and lasting as most people believe ["The Selfish Gene" turns 40] [The "selfish gene" is not a good metaphor to describe evolution] [Die, selfish gene, die!].

The main criticisms fall into two categories: (1) the primary unit of selection is the individual organism, not the gene, and (2) the book placed too much emphasis on adaptation (Darwinism). I think modern evolutionary theory is based on 21st century population genetics and that view puts a great deal of emphasis on the power of random genetic drift. The evolution of a population involves the survival of individuals within the population and that, in turn, depends on the variation that exists in the population. Thus, evolution is characterized by changes in the frequencies of alleles in a population.

A philosopher tells us how to think clearly about evolutionary causes ... avoid adaptationism

I think philosophy has lost its way. The discipline gives credence to religious philosophers who write about god(s) and to other philosophers who reject determinism and think the mind-body problem is still an open question. Philosophers still debate the validity of the ontological argument. Philosophers of science have not even settled the question of what is science, let alone come up with a valid answer of how to do it. There are few other disciplines that are still respected after several hundred years of trying, and failing, to answer the most fundamental questions in their field. Many academic philosophy department are hotbeds of political correctness and just plain politics.

You MUST read this paper if you are interested in evolution

A reader alerted me to a paper that was just published in BMC Biology.¹ The author is Eugene Koonin. He makes the case for neutral evolution (random genetic drift) and against adaptationism. You may not agree with his take on evolutionary theory but you better be aware of it if you claim to be knowledgeable about evolution.

Koonin, E.V. (2016) Splendor and misery of adaptation, or the importance of neutral null for understanding evolution. BMC biology, 14:114. [doi: 10.1186/s12915-016-0338-2]

The study of any biological features, including genomic sequences, typically revolves around the question: what is this for? However, population genetic theory, combined with the data of comparative genomics, clearly indicates that such a “pan-adaptationist” approach is a fallacy. The proper question is: how has this sequence evolved? And the proper null hypothesis posits that it is a result of neutral evolution: that is, it survives by sheer chance provided that it is not deleterious enough to be efficiently purged by purifying selection. To claim adaptation, the neutral null has to be falsified. The adaptationist fallacy can be costly, inducing biologists to relentlessly seek function where there is none.

Suzan Mazur doesn't like Carl Zimmer

There weren't many science writers are the Royal Society meeting in London (UK) [New trends in evolutionary biology: biological, philosophical and social science perspectives]. Carl Zimmer was there and so was Suzan Mazur. Carl was there to learn and do some research. Suzan was there to promote herself as the main publicist of the paradigm shifters.

Carl Zimmer wrote a news article about the meeting for Quanta: Scientists Seek to Update Evolution. The subtitle was "Recent discoveries have led some researchers to argue that the modern evolutionary synthesis needs to be amended." It was a pretty fair article and pretty good reporting on what went on at the meeting. I would have been a bit more harsh about the success of the so-called "paradigm shifters" but Carl did a good job of conveying the skepticism exhibited by many at the meeting. [See Kevin Laland's new view of evolution for my take on these "revolutionaries."]

Why are academics such bad writers?

Not all academics are bad writers but the exceptions are few and far between. Several recent articles in The Chronicle of Higher Education have attempted to explain why we can't write. There are two types of academic writing. The style you use in your academic papers differs from the style you use in writing for a general audience. There's absolutely no debate about the style of writing in the academic literature: it is horrible and it needs to change.

I want to talk about the other kind of writing; the kind where academics try to explain things to non-academics. I'll concentrate on science writing although I'm sure the same issues apply to history, philosophy, and all the other academic disciplines. I'm particularly sensitive to this problem since I'm working on a book about genomes and junk DNA and it's very different than writing a biochemistry textbook.

The latest (Aug. 1, 2016) article is an interview with Steven Pinker, the well-known Harvard psychologist. He's published seven trade books and is widely perceived to be a good example of how academics should write for a general audience [Scholars Talk Writing: Steven Pinker].

Templeton gives $8 million to prove that there's more to evolution than natural selection

The Templeton Foundation will fund a group of researchers who promote something called "The Extended Evolutionary Synthesis" (EES). The grant is for $8 million (US). The project is headed by Kevin N, Laland of the University of St. Andrews (Scotland, UK) and Tobias Uller of Lund University in Sweden. You can read all about it at: Putting the Extended Evolutionary Synthesis to the Test.

There are two problems with this funding. The first is the source of the funds. I agree with Jerry Coyne and many others that Templeton Fund money is tainted because the clear purpose of the fund is to lend credence to religion [Templeton keeps up the woo]. Templeton will only fund projects that advance that objective.

The second problem is the science. The advocates of EES promote things like "developmental plasticity," "niche construction," "evo-devo," and "epigenetics"—all of these phenomena are supposed to play a major role in evolutionary theory, a role that is not covered by the Modern Synthesis.

I think that all of these processes may play a role in explaining the history of life on Earth¹ but so do plate tectonics, asteroid impacts, and endosymbiosis. The problem is that there's a difference between explaining the events behind the history of life and evolutionary theory. They are not the same thing.

The real question is whether any of these things need to be incorporated into modern evolutionary theory and whether they extend the Modern Synthesis. Personally, I don't think any of them make a significant contribution to evolutionary theory.

But my real beef is with the outdated view of evolution held by EES proponents. To a large extent they are fighting a strawman version of evolution. They think that the "Modern Synthesis" or "Neo-Darwinism" is the current view of evolutionary theory. They are attacking the old-fashioned view of evolutionary theory that was common in the 1960s but was greatly modified by the incorporation of Neutral Theory and increased emphasis on random genetic drift. The EES proponents all seem to have been asleep when the real revolution occurred.

When you listen to them, you get the distinct impression they have never read The spandrels of San Marco and the Panglossian paradigm: a critique of the adaptationist programme. I have no confidence in biologists who want to overthrow a view of evolutionary theory that's already been dead for half a century. I have no confidence in biologists who aren't at ease talking about non-adaptive evolution. This is the 21st century.²

Elizabeth Pennisi is all over this. She wrote an article for the April 22 (2016) edition of Science: Templeton grant funds evolution rethink. The opening sentence is very revealing ....

For many evolutionary biologists, nothing gets their dander up faster than proposing that evolution is anything other than the process of natural selection, acting on random mutations.

Damn right! I'm not an evolutionary biologist but my dander gets up whenever scientists make such a ridiculous claim.

Help is one the way, according to Elizabeth Pennisi because the Templeton Foundation is funding research to show that there's more to evolution than natural selection. Unfortunately, the "extended" version doesn't include random genetic drift and modern population genetics.

No wonder some evolutionary biologists are uneasy with an $8.7 million grant to U.K., Swedish, and U.S. researchers for experimental and theoretical work intended to put a revisionist view of evolution, the so-called extended evolutionary synthesis, on a sounder footing. Using a variety of plants, animals, and microbes, the researchers will study the possibility that organisms can influence their own evolution and that inheritance can take place through routes other than the genetic material.

I don't object to work on those subjects. My beef is with the idea that they pose a problem for our current understanding of evolutionary theory. More importantly, my main complaint is that the biologists who will spend all this money missed the real revolution that took place 50 years ago.

Here's how Pennisi describes the extended evolutionary synthesis. Her description is pretty accurate.

The extended evolutionary synthesis is a term coined in 2007 to imply that the preeminent current evolutionary theory, the so-called modern synthesis, needed to broaden its focus because it concentrated too much on the role of genes in evolution and lacked adequate incorporation of new insights from development and other areas of biology. The idea has gradually gathered momentum since its advocates first met in Germany in 2008 (Science, 11 July 2008, p. 196). Later, Kevin Laland, an evolutionary biologist at the University of St. Andrews in the United Kingdom, and several colleagues took up the cause, arranging for a point-counterpoint discussion in Nature in 2014 and a comprehensive review last year in the Proceedings of the Royal Society B's annual Darwin Review.

Advocates stress that animals, plants, and even microbes modify their environments, exhibit plasticity in their physical traits, and behave differently depending on the conditions they face. Chemical modifications of the DNA that affect gene activity—so-called epigenetic changes—seem to explain some of this flexibility. These and other factors suggest to some biologists that an organism's development is not simply programmed by the genetic sequences it inherits. For them, such plasticity implies that parents can influence offspring not just through their DNA but by passing on the microorganisms they host or by transmitting epigenetic marks to subsequent generations. “Innovation may be a developmental response that becomes stabilized through genetic changes,” explains Armin Moczek, an evolutionary developmental biologist at Indiana University, Bloomington.

Nor is evolution controlled only by natural selection, the winnowing process by which the fittest survive and reproduce, Laland and others argue. Organisms, by transforming their environments and responding to environmental factors, help control its course, they contend. As such, the extended synthesis “represents a nascent alternative conceptual framework for evolutionary biology,” Laland and dozens of colleagues wrote in a funding proposal to the Templeton Foundation last year.

This is a profoundly adaptationist view of evolutionary theory. The "extended" version merely adds a few more mechanisms that might improve adaptation.

Most of the EES proponents are working on animals, many are physiologists. They share an evo-devo view of evolution that emphasizes the role of natural selection. I share Michael Lynch's view that we live in a post-Darwinian world and nothing in evolution makes sense except in the light of population genetics. I agree with him that most scientists think of evolution as a soft science and that includes many biologists. It includes most of the EES proponents who probably couldn't tell you anything about population genetics beyond the fact that it's too mathematical. That doesn't stop them from criticizing modern evolutionary theory.

Natural selection is just one of several evolutionary mechanisms, and the failure to realize this is probably the most significant impediment to a fruitful integration of evolutionary theory with molecular, cellular, and developmental biology.

Michael LynchHere's a quote from Michael Lynch's book The Origins of Genome Architecture. In my view, it describes the group who were awarded $8 million to overthrow modern evolutionary theory.

Despite the tremendous theoretical and physical resources now available, the field of evolutionary biology continues to be widely perceived as a soft science. Here I am referring not to the problems associated with those pushing the view that life was created by an intelligent designer, but to a more significant internal issue: a subset of academics who consider themselves strong advocates of evolution but who see no compelling reason to probe the substantial knowledge base of the field. Although this is a heavy charge, it is easy to document. For example, in his 2001 presidential address to the Society for the Study of Evolution, Nick Barton presented a survey that demonstrated that about half of the recent literature devoted to evolutionary issues is far removed from mainstream evolutionary biology.

With the possible exception of behavior, evolutionary biology is treated unlike any other science. Philosophers, sociologists, and ethicists expound on the central role of evolutionary theory in understanding our place in the world. Physicists excited about biocomplexity and computer scientists enamored with genetic algorithms promise a bold new understanding of evolution, and similar claims are made in the emerging field of evolutionary psychology (and its derivatives in political science, economics, and even the humanities). Numerous popularizers of evolution, some with careers focused on defending the teaching of evolution in public schools, are entirely satisfied that a blind adherence to the Darwinian concept of natural selection is a license for such activities. A commonality among all these groups is the near-absence of an appreciation of the most fundamental principles of evolution. Unfortunately, this list extends deep within the life sciences.

The real revolution was the incorporation of nonadaptive mechanisms into evolutionary theory and the overthrow of adaptationism. That revolution is not complete. There are still thousands of biologists who remain strict Darwinists even as they try to promote different ways of achieving adaptation. Those biologists still dominate the popular press (e.g. Elizabeth Pennisi) and they are largely responsible for skepticism about junk DNA. That has to change. Evo-devo types need to listen to Michael Lynch when he says ...

Unfortunately, the emerging field of evolutionary developmental biology is based almost entirely on a paradigm of natural selection, and the near-absence of the concept of nonadaptive processes from the lexicon of those concerned with cellular and developmental evolution does not follow from any formal demonstration of the negligible contribution of such mechanisms but simply reflects the failure to consider them. [my emphasis ... LAM] There is no fundamental reason why cellular and developmental features should be uniquely immune to nonadaptive evolutionary forces. One could even argue that the stringency of natural selection is reduced in complex organisms with behavioral and/or growth from flexibilities that allow individuals to match their phenotypic capabilities to the local environment.

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1. Some of them are trivial and some are ineffective but that's been debated many times. I want to emphasize the fact that EES proponents don't understand modern evolutionary theory.

2. To be fair, some of these proponents do pay lip-service to non-adaptive evolution from time to time but it's clear that they don't really get it.

Michael Lynch on modern evolutionary theory

Of the Five Things You Should Know if You Want to Participate in the Junk DNA Debate, the most difficult to explain is "Modern Evolutionary Theory." Most scientists think they understand evolution well enough to engage in the debate about junk DNA. However, sooner or later they will mention that junk DNA should have been deleted by selection if it ever existed. You can see that their worldview leads them to believe that everything in biology has an adaptive function.

It's been a few years since I posted Michael Lynch's scathing comments on panadaptationism and how it applies to understanding genomes [Michael Lynch on Adaptationism and A New View of Evolution]. You're in for a treat today.

Here's what you need to know about evolution in order to discuss junk DNA. The first quotation is from the preface to The Origins of Genome Architecture (pages xiii-xiv). The second quotations are from the last chapter (page 366 and pages 368-369.

Contrary to popular belief, evolution is not driven by natural selection alone. Many aspects of evolutionary change are indeed facilitated by natural selection, but all populations are influenced by nonadaptive forces of mutation, recombination, and random genetic drift. These additional forces are not simple embellishments around a primary axis of selection, but are quite the opposite—they dictate what natural selection can and cannot do. Although this basic principle has been known for a long time, it is quite remarkable that most biologists continue to interpret nearly aspect of biodiversity as an outcome of adaptive processes. This blind acceptance of natural selection as the only force relevant to evolution has led to a lot of sloppy thinking, and is probably the primary reason why evolution is viewed as a soft science by much of society.

A central point to be explained in this book is that most aspects of evolution at the genome level cannot be fully explained in adaptive terms, and moreover, that many features could not have emerged without a near-complete disengagement of the power of natural selection. This contention is supported by a wide array of comparative data, as well as by well-established principles of population genetics. However, even if such support did not exist, there is an important reason for pursuing nonadaptive (neutral) models of evolution. If one wants to confidently invoke a specific adaptive scenario to explain an observed pattern of comparative data, then an ability to reject a hypothesis based entirely on the nonadaptive forces of evolution is critical.

The blind worship of natural selection is not evolutionary biology. It is arguably not even science.

Michael Lynch

Despite the tremendous theoretical and physical resources now available, the field of evolutionary biology continues to be widely perceived as a soft science. Here I am referring not to the problems associated with those pushing the view that life was created by an intelligent designer, but to a more significant internal issue: a subset of academics who consider themselves strong advocates of evolution but who see no compelling reason to probe the substantial knowledge base of the field. Although this is a heavy charge, it is easy to document. For example, in his 2001 presidential address to the Society for the Study of Evolution, Nick Barton presented a survey that demonstrated that about half of the recent literature devoted to evolutionary issues is far removed from mainstream evolutionary biology.

With the possible exception of behavior, evolutionary biology is treated unlike any other science. Philosophers, sociologists, and ethicists expound on the central role of evolutionary theory in understanding our place in the world. Physicists excited about biocomplexity and computer scientists enamored with genetic algorithms promise a bold new understanding of evolution, and similar claims are made in the emerging field of evolutionary psychology (and its derivatives in political science, economics, and even the humanities). Numerous popularizers of evolution, some with careers focused on defending the teaching of evolution in public schools, are entirely satisfied that a blind adherence to the Darwinian concept of natural selection is a license for such activities. A commonality among all these groups is the near-absence of an appreciation of the most fundamental principles of evolution. Unfortunately, this list extends deep within the life sciences.

....

... the uncritical acceptance of natural selection as an explanatory force for all aspects of biodiversity (without any direct evidence) is not much different than invoking an intelligent designer (without any direct evidence). True, we have actually seen natural selection in action in a number of well-documented cases of phenotypic evolution (Endler 1986; Kingsolver et al. 2001), but it is a leap to assume that selection accounts for all evolutionary change, particularly at the molecular and cellular levels. The blind worship of natural selection is not evolutionary biology. It is arguably not even science. Natural selection is just one of several evolutionary mechanisms, and the failure to realize this is probably the most significant impediment to a fruitful integration of evolutionary theory with molecular, cellular, and developmental biology.

Natural selection is just one of several evolutionary mechanisms, and the failure to realize this is probably the most significant impediment to a fruitful integration of evolutionary theory with molecular, cellular, and developmental biology.It should be emphasized here that the sins of panselectionism are by no means restricted to developmental biology, but simply follow the tradition embraced by many areas of evolutionary biology itself, including paleontology and evolutionary ecology (as cogently articulated by Gould and Lewontin in 1979). The vast majority of evolutionary biologists studying morphological, physiological, and or behavioral traits almost always interpret the results in terms of adaptive mechanisms, and they are so convinced of the validity of this approach that virtually no attention is given to the null hypothesis of neutral evolution, despite the availability of methods to do so (Lande 1976; Lynch and Hill 1986; Lynch 1994). For example, in a substantial series of books addressed to the general public, Dawkins (e,g., 1976, 1986, 1996, 2004) has deftly explained a bewildering array of observations in terms of hypothetical selection scenarios. Dawkins's effort to spread the gospel of the awesome power of natural selection has been quite successful, but it has come at the expense of reference to any other mechanisms, and because more people have probably read Dawkins than Darwin, his words have in some ways been profoundly misleading. To his credit, Gould, who is also widely read by the general public, frequently railed against adaptive storytelling, but it can be difficult to understand what alternative mechanisms of evolution Gould had in mind.

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Café Scientifique

Last night was my first visit to the Café Scientifique in Streetsville (Mississauga, Ontario, Canada). I had a great time discussing "Replaying the tape of life," Stephen Jay Gould, adaptationism, contingency, random genetic drift and lots of other things. This is a great group and I'll definitely be attending the next meeting.

The venue is perfect. We met in a room above a pub (The Franklin House) on the main street in Streetsville. There was plenty of good food and good beer.

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Rain on the Darwin sunshine

Here's a YouTube video of a talk by Michael Lynch from February 2015. He was talking at Darwin Week at the National Institute for Mathematical and Biological Synthesis at the University of Tennessee (USA).

The talk begins with a warning that evolution has gone beyond Darwinism. Lynch emphasizes, "Mutation, drift, and the origin of subcellular features." If you haven't been able to follow the discussion on the perils of adaptationism, then watch this lecture to get a sense of what it's all about.

I'm a big fan of Michael Lynch and I hope you will also be a fan after you learn more about his views.

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Rethinking evolutionary theory

I believe that Gould was correct when he pronounced the death of the Modern Synthesis [Is the "Modern Synthesis" effectively dead?] [Razib Khan doesn't like Gould and doesn't like new-fangled ideas like "neutralism" and "random genetic drift"] [Die, selfish gene, die!] [Gould on Darwinism and Nonadaptive Change] [Extending the Modern Synthesis at the Molecular Level ].

I agree with Arlin Stoltzfus in his description of the Modern Synthesis [Arlin Stoltzfus explains evolutionary theory]. I agree with him, and with Masatoshi Nei, that mutation and mutationism were downplayed in the Modern Synthesis [The Mutationism Myth, VI: Back to the Future] [Mutation-Driven Evolution]. That's one example of why the old-fashioned Modern Synthesis should be abandoned as a description of modern evolutionary theory.

Do you really "get" evolution?

Stephanie Keep is the new editor of Reports of the National Center for Science Education at NCSE (National Center for Science Education).

She tells an interesting story in her first post on the Science Laegue of Amercia blog [A New Finger in the Pie].

An editor friend of mine asked me the other day to read an activity she’s developing for middle school, one of the soon-to-be plethora of activities aligned to the Next Generation Science Standards. This particular one was about evolution, and asked kids to look for variation in a number of human traits and then infer adaptive explanations. For example, they could measure finger lengths and then come up with a reason that longer fingers are more adaptive than shorter ones. What followed was a half-hour conversation in which I tried my best to explain why that was a terrible idea for an activity. And here’s the thing—this friend of mine, she’s super-smart and has an advanced degree in biology from Harvard University. Now, she completely understood, once we discussed it, why that kind of activity will reinforce misconceptions about evolution (that every feature is adaptive, that you can infer a structure’s adaptive value from its current function, etc.), but we still had to have the discussion.

I have worked for the past decade-plus with scientists, science writers, and science educators, all of whom have the best intentions in the world, all of whom would have no problem declaring their allegiance to the cause of an authentic science education grounded in evolution. But—and I don’t want to point fingers at anybody here—many of them would have not batted an eye if that activity had come across their desks. And this, I believe, is one of the most important truths we have to face: many of us don’t really get evolution. It’s such a beautiful, simple, and powerful idea, but it’s also finicky, demanding vigilant attention to detail to be properly explained and explored.

Most of you will be familiar with this idea since I've been complaining about adaptationism for decades. In order to "get" evolution, you need to know about Neutral Theory and random genetic drift—and that's just for starters. We need to work much harder to dispel misconceptions about evolution.

Lot's of people don't really "get" evolution but, in fairness, they don't study it either. But if you are going to write about evolution—or teach it—then you'd better make sure you understand it. Unfortunately, there are far too many people like Stephanie Keep's friend. We have to fix that.

There's one group that spends an extraordinary amount of time "studying" evolution without ever "getting" it. I'm referring to creationists, especially the Intelligent Design Creationists, otherwise known as IDiots. They've been told time and time again that there's much more to evolution than just adaptation. Recently, some of them actually seemed to "get" the ideas of Neutral Theory and random genetic drift although that turned out to be an illusion. They still don't get evolution.

In any case, one of the creationists (Donald McLaughlin¹) has blogged about Stephanie Keep's story [see A New Hire at the National Center for Science Education Admits "Many of Us Don't Really Get Evolution"]. Here's part of what McLaughlin says,

Bear in mind, too, that the very educators who don't get evolution are also the ones who fuss and complain whenever a state legislator or science standards committee member proposes language about "teaching the strengths and weaknesses" of evolution. From the way they kvetch, you would think there are no weaknesses in evolutionary theory. But if many of them don't get evolution in the first place, how would they know?

Keep says that evolution is a "beautiful, simple, and powerful idea, but it's also finicky, demanding vigilant attention to detail to be properly explained and explored." Perhaps Keep could provide a helpful list of exactly what those details are so educators like her Harvard-trained friend can stay on the straight and narrow Darwinian path, lest they join the chorus calling for a new theory of evolution.

This is ironic and confused on so many levels that I'm not even going to try and point them out. I just post it here for your amusement.

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1. Here's his profile on the Discovery Institute website.

Donald McLaughlin joined Discovery Institute in August 2013, as a Development Officer and Regional Representative in the upper Midwest and Northeast regions. His areas of responsibility include cultivating and stewarding major gifts, and planned giving. Donald has had a successful career in development, including 8 years as a Regional Director of Advancement for Prison Fellowship Ministries, 2 years as National Director of Major Gifts for Teen Mania Ministries and 5 years as Regional Director of Advancement for Taylor University.

Donald is a 1975 graduate of Taylor University where he earned his BA in Speech and Drama. In 1977, he earned an MA in Clinical Audiology from Ball State University in Muncie, IN. While at Prison Fellowship, Donald also participated in the Centurions Program. Prior to his work in Development, Donald spent more than twenty years in financial services with both AG Edwards and Merrill Lynch. Donald lives in Granger Indiana, near South Bend, with his wife of 35 years, Elizabeth, who is Chair of the Communications Department at Bethel College in Mishawaka, IN. Donald enjoys reading, traveling, and music.

He also has a religious profile at: Donald McLaughlin.

The Third Fourth? Way

Back in 1997, James Shapiro wrote an article for the Boston Review entitled "A Third Way." It was a very confusing article. His main point seemed to be that conventional neo-Darwinism wasn't a complete picture of modern evolutionary theory.

That part wasn't news since by 1997 the ideas of Neutral Theory and random genetic drift had been around for thirty years. Apparently, Shapiro was three decades behind in his understanding of evolution.

Shapiro doesn't demonstrate that he understands population genetics and random genetic drift. This just one (of many) criticisms that I mentioned in my review of Shapiro's book Evolution: A View from the 21st Century in NCSE Reports [Evolution: A View from the 21st Century]. Shapiro responded to my review at: Reply to Laurence A Moran’s review of Evolution: A View from the 21st Century] and I discussed his response on my blog [James Shapiro Responds to My Review of His Book].

The "third" way, according to Shapiro's 1997 article, is not classic Darwinism and it's not creationism. Instead, it's a new way of looking at evolution.

What significance does an emerging interface between biology and information science hold for thinking about evolution? It opens up the possibility of addressing scientifically rather than ideologically the central issue so hotly contested by fundamentalists on both sides of the Creationist-Darwinist debate: Is there any guiding intelligence at work in the origin of species displaying exquisite adaptations that range from lambda prophage repression and the Krebs cycle through the mitotic apparatus and the eye to the immune system, mimicry, and social organization? Borrowing concepts from information science, new schools of evolutionists can begin to rephrase virtually intractable global questions in terms amenable to computer modelling and experimentation. We can speculate what some of these more manageable questions might be: How can molecular control circuits be combined to direct the expression of novel traits? Do genomes display characteristic system architectures that allow us to predict phenotypic consequences when we rearrange DNA sequence components? Do signal transduction networks contribute functional information as they regulate the action of natural genetic engineering hardware?

Questions like those above will certainly prove to be naive because we are just on the threshold of a new way of thinking about living organisms and their variations. Nonetheless, these questions serve to illustrate the potential for addressing the deep issues of evolution from a radically different scientific perspective. Novel ways of looking at longstanding problems have historically been the chief motors of scientific progress. However, the potential for new science is hard to find in the Creationist-Darwinist debate. Both sides appear to have a common interest in presenting a static view of the scientific enterprise. This is to be expected from the Creationists, who naturally refuse to recognize science's remarkable record of making more and more seemingly miraculous aspects of our world comprehensible to our understanding and accessible to our technology. But the neo-Darwinian advocates claim to be scientists, and we can legitimately expect of them a more open spirit of inquiry. Instead, they assume a defensive posture of outraged orthodoxy and assert an unassailable claim to truth, which only serves to validate the Creationists' criticism that Darwinism has become more of a faith than a science.

Now Shapiro has joined forces with some other "revolutionaries" and started a new website called "The Third Way." It has grandiose goals ....

The vast majority of people believe that there are only two alternative ways to explain the origins of biological diversity. One way is Creationism that depends upon supernatural intervention by a divine Creator. The other way is Neo-Darwinism, which has elevated Natural Selection into a unique creative force that solves all the difficult evolutionary problems. Both views are inconsistent with significant bodies of empirical evidence and have evolved into hard-line ideologies. There is a need for a more open “third way” of discussing evolutionary change based on empirical observations.

There's only one problem. I'm familiar with Shapiro's ideas and with the ideas of most of the other people listed on the website and I don't think any of them (except Eugene Koonin) have anything significant to say about evolutionary theory. Futhermore, most of them don't seem to understand that there's already been a revolution and population genetics, Neutral Theory, etc. won the day. They seem to have completely missed that revolution.

They are advocating a fourth way that skips right from adaptationism to something else.

They are like a group of would-be revolutionaries marching up Rue de Lyon in Paris only to discover that the Bastille has been replaced by an open square and an opera house.

Note: There aren't many biologists that are interested in this "Third Way" but the creationists are lapping it up [A Group of Darwin-Skeptical Scientists Seeking a "Third Way" in Biology Have Launched a New Website; Welcome to Them!].

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On the difference between Neutral Theory and random genetic drift

PZ Myers posted an interesting article on The state of modern evolutionary theory may not be what you think it is. He makes the point that there's more to evolution than natural selection.

I think this is an important point but I would not explain it the same way as PZ. He focuses attention on Neutral Theory and the fact that neutral, or nearly neutral, mutations are fixed by random genetic drift. Here's how he describes it ...

First thing you have to know: the revolution is over. Neutral and nearly neutral theory won. The neutral theory states that most of the variation found in evolutionary lineages is a product of random genetic drift. Nearly neutral theory is an expansion of that idea that basically says that even slightly advantageous or deleterious mutations will escape selection — they’ll be overwhelmed by effects dependent on population size. This does not in any way imply that selection is unimportant, but only that most molecular differences will not be a product of adaptive, selective changes.

The debate over adaptationism is a debate over mechanisms of evolution. Random genetic drift is a mechanism of evolution that results in fixation or elimination of alleles independently of natural selection. If there was no such thing as neutral mutations then random genetic drift would still be an important mechanism.

Let's say you have a clearly beneficial mutation with a huge selection coefficient of 0.1 (s = 0.1). Population genetics tells us that the probability of fixation is 2s or, in this case, 20%. That means that the allele will be eliminated from the population 80% of the time. That's random genetic drift. Similarly, some fairly deleterious mutations can sometimes be fixed by random genetic drift.

Random genetic drift is a mechanism of evolution that was discovered and described over 30 years before Neutral Theory came on the scene.

What Neutral Theory tells us is that a huge number of mutations are neutral and there are far more neutral mutations fixed by random genetic drift that there are beneficial mutations fixed by natural selection. The conclusion is inescapable. Random genetic drift is, by far, the dominant mechanism of evolution.

Many people seem to equate Neutral Theory with random genetic drift. They think that random genetic drift is only important when the alleles are neutral (or nearly neutral). Then they use this false equivalency as a way of dismissing random genetic drift because it only deals with "background noise" while natural selection is the mechanism for all the interesting parts of evolution. I think we should work toward correcting this idea by separating the mechanisms of evolution (natural selection, random genetic drift, and others) from the quality of alleles being produced by mutation (beneficial, detrimental, neutral).

The revolution is over and strict Darwinism lost. We now know that random genetic drift is an important mechanism of evolution and there's more to evolution than natural selection. Unfortunately, this blatantly obvious fact is not understood by the vast majority of people and teachers. There are even many scientists who don't understand evolution.

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Steven Pinker defends "neo-Darwinism," whatever that is

Jerry Coyne posted a couple of tweets (see below) from Steven Pinker (photo) at Dawkins responds to Dobbs.

We shouldn't be surprised at the first one since Pinker is an evolutionary psychologist with a strong tendency to adaptationism. I don't know exactly what he means by "neo-Darwinism" (does he?) but I strongly suspect that it's very much like Darwinism. I'd love to know whether he thinks Neutral Theory and random genetic drift have been successful challenges to neo-Darwinism. If not, then it must mean that neo-Darwinism has incorporated those views. In that case, neo-Darwinism must have begun in the 1970s and somebody picked a very bad name for this view of evolutionary theory.

I think it's more likely that Pinker is just not thinking about Neutral Theory and random genetic drift when he says that challenges to neo-Darwinism have all failed to hold water.

The second tweet means that molecular biologists never knew about tRNA genes or ribosomal RNA genes or the genes for other RNAs that have won Nobel Prizes. I find this very surprising. It's true that some biochemists and molecular biologists are a bit behind in their field but I don't think it's fair to say that "molecular biologists" (i.e. the knowledgeable experts in the field) re-defined the word "gene" in that way.

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"Reasons to Believe" in ENCODE

Fazale "Fuz" Rana is a biochemist at Reasons to Believe". He and his colleagues are Christian apologists who try to make their faith compatible with science. Fuz was very excited about the ENCODE results when they were first published [One of the Most Significant Days in the History of Biochemistry]. That's because Christians of his ilk were very unhappy about junk DNA and the ENCODE Consortium showed that all of our genome is functional.¹

Fuz is aware of the fact that some people are skeptical about the ENCODE results. He wrote a series of posts defending ENCODE.

1. Do ENCODE Skeptics Protest Too Much? Part 1 (of 3)
2. Do ENCODE Skeptics Protest Too Much? Part 2 (of 3)
3. Do ENCODE Skeptics Protest Too Much? Part 3 (of 3)

The first post is merely a list of the objections many of us raised.

Richard Dawkins Is a Scholar and a Gentleman

Most of you think of Richard Dawkins as a "strident atheist" who doesn't suffer fools gladly.¹ The first part of that reputation ("strident atheist") is unjust as Dawkins pointed out on several occasions when he was in Toronto earlier this week.

The second part ("doesn't suffer fools gladly") is quite true. Dawkins thinks that foolish things, like religion and other superstitions, deserve to be ridiculed.

Richard Dawkins and I agree on atheism but disagree on some aspects of evolution. I'm pleased to report that he didn't hold that against me when we met for brunch a few days ago. I guess that means I'm not a fool in his mind!

For those of you who have never had the pleasure of meeting him, I want to assure you that in person he is a very pleasant fellow and lives up to the very British expression, "a scholar and a gentleman."

Some of the people I met were wondering about the reasons why I disagree with some aspects of Richard's views on evolution. They haven't heard of Stephen Jay Gould and I find that very sad. I still believe that everyone interested in evolution has to read and understand the "Spandrels" paper.

Here's a short reading list ....

Michael Lynch on Adaptationism
What Does San Marco Basilica Have to do with Evolution?
Michael Ruse Defends Adaptationism
Richard Dawkins' View of Random Genetic Drift

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1. The phrase comes from the New Testament [Suffer fools gladly].

Educating an Intelligent Design Creationist: The Meaning of Darwinism

Intelligent Design Creationists love to refer to their opponents as "Darwinists." We all know why they do it. It's a rhetorical device designed to belittle those who accept evolution. The term makes it look like evolutionary biologists worship a man who died 130 years ago and it implies that we still believe in nineteenth century science. The term "Darwinist" also makes it easy to associate modern scientists with social Darwinism. That's a common strategy employed by creationists of all stripes. I get it. It has nothing to do with scientific debates about evolution.

But sometimes rhetoric gets in the way of understanding. There seem to be a few (very few) Intelligent Design Creationists who genuinely want to understand the issues—even if their motive is still to push a scientific view of creationism. They pop up from time to time on the Intelligent Design Creationist websites. Andyjones seems to be one of them. (I'm giving him the benefit of the doubt.)

Ford Doolittle's Critique of ENCODE

Ford Doolittle has never been one to shy away from controversy so it's not surprising that he weighs in against the misleading publicity campaign launched by ENCODE leaders last September (Doolittle, 2013). Recall that Ewan Birney and other prominent members of the consortium promoted the idea that our genome contained an extensive array of regulatory elements and that 80% of our genome was functional [Ewan Birney: Genomics' Big Talker] [ENCODE Leader Says that 80% of Our Genome Is Functional] [The ENCODE Data Dump and the Responsibility of Scientists].

This is the fourth paper that's critical of the ENCODE hype. The first was Sean Eddy's paper in Current Biology (Eddy, 2012). The second was a paper by Niu and Jiang (2012), and the third was a paper by Graur et al. (2013). In my experience this is unusual since the critiques are all directed at how the ENCODE Consortium interpreted their data and how they misled the scientific community (and the general public) by exaggerating their results. Those kind of criticisms are common in journal clubs and, certainly, in the blogosphere, but scientific journals generally don't publish them. It's okay to refute the data (as in the arsenic affair) but ideas usually get a free pass no matter how stupid they are.

In this case, the ENCODE Consortium did such a bad job of describing their data that journals had to pay attention. (It helps that much of the criticism is directed at Nature and Science because the other journals want to take down the leaders!)