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Wednesday 17 February 2016

The challenge of floral networking to Darwin

Secrets of the Plant "Intranet" Are Coming to Light
Evolution News & Views February 17, 2016 3:09 AM

Most companies are on the Internet these days, but many also keep an internal network called an "intranet" for passing messages within the organization. In both respects, flowering plants and conifers are similarly equipped. They send and receive messages through the air in the form of volatile organic compounds, and through the soil by networks of fungal hyphae. A tree under attack by beetles, for instance, can send out distress calls that other trees in the forest can pick up, giving them time to shore up their defenses.

The plant "intranet" is where things really get interesting. When you think about it, a plant has to keep in touch with itself. The roots underground need to know how things are going up top. The leaves and branches, in turn, need to know if there will be enough water and nutrients in the soil to proceed with costly enterprises like flowering and fruit bearing. Plants have a remarkable communications system that allows rapid signaling and response, comparable to an automated email system.

The messages come in the form of molecules that travel through the vascular bundles in the stems and roots. A paper in Current Biology by Chinese scientists explains part of what happens. In effect, they opened a plant's email and read it. The message was in the form of a transcription factor named HY5, a protein that binds to a gene and controls its transcription rate. Wikigenes says that HY5 "binds directly to the promoters of light-inducible genes, promoting their expression and photomorphogenic development." The email says, "Turn up the heat, guys -- the economy is booming!"

But HY5 should not turn up the heat if the roots aren't ready in the supply room down below. Here's where long-distance communication comes in (long distance, that is, in the context of a small plant). The Chinese researchers found that HY5 migrates from the shoot to the root with its message. They list these four highlights of their findings:

HY5 is essential for light-responsive coordination of the growth of shoots and roots.

Shoot-to-root translocated HY5 mediate light-activated root growth and N uptake.

Carbohydrate photosynthate-induced NRT2.1 expression and N uptake depend upon HY5.

HY5 contributes to maintain balance of C and N metabolism at varying light fluence. [Emphasis added.]

Did you catch that word "translocated"? That's the email system. HY5 travels down the plant's phloem vessels from "shoot to root" -- from top to bottom. Watch for the intranet analogy in the summary of the paper. (Gene names are italicized; protein names are not.)

Coordination of shoot photosynthetic carbon fixation with root inorganic nitrogen uptake optimizes plant performance in a fluctuating environment. However, the molecular basis of this long-distance shoot-root coordination is little understood. Here we show that Arabidopsis ELONGATED HYPOCOTYL5 (HY5), a bZIP transcription factor that regulates growth in response to light, is a shoot-to-root mobile signal that mediates light promotion of root growth and nitrate uptake. Shoot-derived HY5 auto-activates root HY5 and also promotes root nitrate uptake by activating NRT2.1, a gene encoding a high-affinity nitrate transporter. In the shoot, HY5 promotes carbon assimilation and translocation, whereas in the root, HY5 activation of NRT2.1 expression and nitrate uptake is potentiated by increased carbon photoassimilate (sucrose) levels. We further show that HY5 function is fluence-rate modulated and enables homeostatic maintenance of carbon-nitrogen balance in different light environments. Thus, mobile HY5 coordinates light-responsive carbon and nitrogen metabolism, and hence shoot and root growth, in a whole-organismal response to ambient light fluctuations.

The key to any intranet is movement of information-bearing signals. In human email systems, each message has a "header" of metadata signifying the sender and receiver and other information, so that the router on the communications channel knows what to do with it. Then there is the body of the message. The plant's messages, of course, are different from human email written in alphabetic text; they're more like signals indicating "on/off" or "speed up/slow down." They are encoded, though, by molecular text -- the language of DNA. Notice that there's nothing about HY5 that looks like or smells like the meaning of the message. The meaning involves a pre-ordained convention about what the presence of the signal indicates.

It's notable that the same signal can take on different meanings depending on context. The signal causes one reaction in the shoot, but a different reaction in the root. We also see a "To" and "CC" convention. HY5 lands on two genes: HY5 and NRT2.1. There's a unique aspect of this plant intranet in that it's "fluence-rate modulated," i.e., sensitive to message flow: the more signal, the more the response. Maybe that's like getting a flood of tweets.

Most importantly, the message is mobile and routable. HY5 has to carry its message over long distances and traverse numerous branching points to get to the intended recipient. As a result, just as with a corporate intranet, the plant benefits from "whole- organismal response" to what we might call the business environment. Just as a manufacturing plant needs to adjust its production to the availability of raw materials, a living plant must adjust its production to the availability of sunlight and soil nutrients.

The paper reads like a detective story. When they shined light of varying intensities on shoots, the roots grew. Intrigued by the rapid response of a distant part of the plant to the conditions at the top, they thought, Aha! -- "Shoot illumination promotes root growth, most likely via shoot-to-root signaling." It's no wonder that in the introduction to the paper, the scientists described it as "long-distance shoot-root communication." The hunt was on to find the emails.

Experiments honed in on the answer. Mutant plants that didn't grow stronger roots when illuminated were found to have a broken HY5 protein. Other tests confirmed that HY5 is the information-carrying molecule. But does it really travel long distance? To test that, they ran some experiments that first suggested "HY5 transcripts, HY5, or a HY5-dependent signal moves from shoot to root." Then they narrowed it down to HY5 itself. One clever test was fastening two other molecules onto HY5 in the shoots, and finding that none of them made it to the root. Why? "Most likely because its relatively large size prevents shoot-root mobility" -- i.e., the bigger emails clogged the communication channel.

But then, when they sent along a molecular scissors that cut off one of the hangers-on, the custom messages did arrive. Conclusion: "HY5 is a shoot-root phloem-mobile signal...." From there, they studied what the recipient of the "CC" email does (i.e., the gene NRT2.1). The second recipient, they found, promotes a gene that increases nitrate uptake.

In the conclusion, the authors recognized that what they were seeing was a case of real communications networking. The shoot is not just sending some sugar down the pipe for the roots to eat so they will work harder; sucrose is involved, but the HY5 protein transcription factor is a bearer of information. Here's how they express it in scientific jargon:

Although a previous study implicates phloem-mobile sucrose as a cotyledon-derived signal to control primary root elongation during early seedling development in Arabidopsis, the molecular mechanism of the shoot-root long-distance signaling regulating lateral root growth and N uptake remains unclear. Here, we show that HY5 is a shoot-root mobile signal that mediates light-regulated coupling of shoot growth and C assimilation with root growth and N uptake. This coupling is achieved via HY5 regulation of C fixation in the shoot and via sucrose-enhanced promotion of HY5-dependent N uptake in the root. In consequence, HY5 mediates homeostatic regulation of whole-plant C versus whole-plant N status. HY5 is already known to integrate multiple phytohormonal (e.g., abscisic acid) and environmental (e.g., low temperature) signaling inputs in the control of plant growth and development. Our discovery that HY5 is a mobile signal adds further dimension to this knowledge.


This is so cool; everyone should get a chill out of thinking that plants have email. They pass signals coded by a genetic language. They send them through communications channels to recipients. The recipients know what to do with that information. The resemblance to email is uncanny. When ID advocates see very similar concepts to email employed in living organisms like the humble rockcress, we have ample justification to celebrate. "You've got mail!"

Darwinism vs.the real world XXIX

Immune Defense: How Antibodies Work
Howard Glicksman February 16, 2016 4:08 PM

Editor's note: Physicians have a special place among the thinkers who have elaborated the argument for intelligent design. Perhaps that's because, more than evolutionary biologists, they are familiar with the challenges of maintaining a functioning complex system, the human body. With that in mind, Evolution News is delighted to offer this series, "The Designed Body." For the complete series,  see here. Dr. Glicksman practices palliative medicine for a hospice organization.

The body is constantly under attack from powerful microorganisms that, if given the chance, can cause serious infection and death. The body's first layer of defense is the skin and epithelium that lines the respiratory, gastrointestinal, and genitourinary tracts. If the microbes get past these barriers they come up against the body's immune system. The immune system can be divided into two parts.

The first is the innate immune system,which we have from birth and acts in the same way every time it encounters foreign matter. The second is the adaptive immune system, which develops over time and reacts in a specific way to the foreign matter it encounters. Without the first layer of defense or both components of the immune system, our earliest ancestors could not have lived long enough to reproduce.

In earlier articles I've shown how some of the immune cells and proteins of the innate system work together to defend the body from microbial attack. And in my immediately previous article I explored the immune cells of adaptive immunity: the lymphocytes, consisting of helper T-cells, which help other immune cells multiply and improve their killing ability; cytotoxic T-cells, which destroy infected host cells; and B-cells, each of whichproduces millions of identical antibodies. Now let's look at how antibodies -- the proteins of the adaptive immune system -- work to help the body's immune defense with extra intelligence, firepower, and precision accuracy.

Antibodies, also called immunoglobulins or gamma globulins,circulate in the blood as plasma proteins. When the first responders of innate immunity release chemicals to cause inflammation, this allows not only immune cells from the blood to come to the field of battle, but also proteins including immunoglobulins. Antibodies are good at helping other immune cells identify and kill bacteria, neutralizing toxins and limiting the effects of viruses before they can enter a cell. To understand how antibodies work, it is important to first look at their structure.

The antibody molecule consists of four chains of amino acids bonded to each other: two identical pairs of heavy and light chains joined together in the shape of a Y. The two connected heavy chains provide the basis of the Y-shaped structure while each light chain is connected to the outside of the branching portion of the heavy chain. The tips of the Y-shaped antibody molecule consist of the amino acids from the ends of each identical light and heavy chain. Together, they form a specific chemical pattern with a three-dimensional shape that is identical to the antigen receptors on the B-cell that produced them. These tips at the end of the antibody molecule act as antigen-binding sites and are known as the Fab portion (antigen binding fragment).

Human DNA is programmed to produce about one million different heavy chains and about ten thousand different light chains, each with their own unique amino acid pattern. Each B-cell produces only one specific antibody, made up of two pairs of identical heavy and light chains. That means that the body is able of make, as an estimate, over ten billion (one million times ten thousand) different antibodies, each with its distinct combination of binding sites. This gives the body a wide array of specific blood-borne sentries that can detect specific chemical patterns on different invading microbes. The amino acid structure that makes up the base of the Y-shaped antibody molecule remains constant and is called the Fc piece (constant fragment). It is the Fc piece that becomes activated after the Fab portions attach to the specific antigen and makes the antibodies ready for action.

There are a few ways that activated antibodies help the immune system defend the body from infection. As you may recall, the neutrophils and macrophages of the innate immune system have their own receptors that attach to large parts of foreign proteins on invading microorganisms. However, many pathogenic microbes have developed ways to evade detection and destruction by these phagocytic immune cells. They can often make themselves invisible, allowing them to multiply and spread throughout the body. When antibodies' Fab portions attach to the specific antigens on the cell surface of the pathogens, they activate, and the pathogens lose the ability to evade and resist the neutrophils and macrophages. These immune cells have receptors on their surface that attach to the Fc piece of the antibody once it activates, allowing them to see and capture the pathogen. This activity is called enhanced attachment, or opsonization (opsonein, Greek: to buy food); the antibodies help phagocytes attach to microbes and literally make microbial food available to them.

Complement activation is another very important mechanism by which antibodies help kill microbes and infected host cells. As we saw previously, there are three different pathways that activate the complement system. The most efficient one requires a specific antibody to activate its Fc piece by attaching its Fab to a specific antigen on the cell surface of the microbe. Complement attaching to the activated Fc piece triggers the various other complement proteins. These swing into action and sometimes form the Membrane Attack Complex, which drills a hole in the membrane surrounding the microbe and kills it. Some of the fragments of activated complement (e.g., C3b) can attach themselves to microorganisms as well. Neutrophils and macrophages have receptors for C3b that allow them to identify and attach to the pathogen and kill it through opsonization.

In addition to enhanced attachment and complement activation, attaching antibodies to specific antigens on infected host cells activates NK (natural killer) cells.These attach to the activated Fc piece and, in a process called antibody-dependent cellular cytotoxicity (ADCC), release chemicals into the infected cell, causing its death. Moreover, both viruses and bacteria have specific structures on their outer surfaces that allow them to grab human cells and cause infection.

When antibodies attach to the specific antigens on these outer structures, they block the virus or bacteria from attaching to human cells and prevent infection. Furthermore, some bacteria release toxins that must attach to receptors on the surface of host cells to cause damage. When antibodies attach to the specific molecular patterns on these toxins, they block them from attaching to the host cell. Finally, microbes have structures, like flagella and cilia for mobility, which allow them to spread throughout the body. When antibodies attach to antigens on these structures, they cause them to malfunction and inhibit their ability to spread and do damage.

In prior articles I explained that the body's immune system is irreducibly complex, because not only are the innate and adaptive immune systems each needed for survival, but each of their respective components is as well. It also demonstrates natural survival capacity, for our earliest ancestors could never have survived long enough to reproduce if they hadn't had enough properly working first responder immune cells in their tissues, or neutrophils and complement in their blood, or T-cells in their lymphatic systems to prevent infection. So what about antibodies?

Primary immunodeficiencies are genetic conditions a person is born with that result in a poor immune response to infection. One example involves defective B-cell function and an almost total absence of antibodies, called Agammaglobulinemia. Infants receive temporary immunity from their mothers by antibodies crossing through the placenta into their bloodstream. However, after six months, they start to have infections which, if it weren't for modern medicine, would quickly lead to death. This shows that even if our earliest ancestors had had all of the other parts of the immune system working properly, without antibodies, they would never have survived.

Finally, it's important to realize that just like the coagulation cascade and the complement system, this system must turn on only when needed and stay or turn off when not. When antibodies cause the body to overreact to itself or to relatively harmless antigens, this can lead to major debility and even death. Some allergies, such as hay fever and asthma, are caused by certain antibody responses to pollens. When applied to venom from a bee sting, such overreactions can cause anaphylactic shock. When antibodies react inappropriately to normal tissue and turn on the immune system in what is called autoimmune disease, this leads to inflammation, injury, and destruction of different tissues and organs. It's vital not only that all of the components of the immune system be present, but that they be properly controlled.

On December 14, 1799, George Washington was suffering from a severe case of tonsillitis. The theory of the day was that infections were caused by the presence of ill humors in the blood that must be treated by bloodletting. Over several hours, in the midst of an acute infection, his medical attendants removed about five pints of blood. Modern medical practitioners know that infections are caused by germs, not ill humors, and that bleeding someone who has an acute infection is not only likely to cause further weakness but possibly even death.

Even though microbes had been observed under the microscope for almost two hundred years, it was not until the late 19th century that medical science began to recognize that specific germs cause specific diseases. And it was not until Louis Pasteur disproved the theory of spontaneous generation (the belief that life could originate from inanimate matter) that medical science realized that many infectious diseases were indeed preventable.

Clearly, when it came to the understanding of infections, the medical profession of George Washington's day was in error. Moreover, their misguided notions of what caused disease led them to apply the standard treatment of the day (bloodletting), which likely contributed to his death.

This demonstrates how a strongly held, but erroneous, idea can lead to certain assumptions and actions that are detrimental to human development and prosperity. In other words, ideas have consequences. As presented by today's evolutionary biologists, the dominant theory of how life came into being would appear to involve a type of spontaneous generation called abiogenesis. The current thinking is that inanimate matter (chemical elements), under the influence of chance and the laws of nature alone, eventually became multi-system organisms with complex body plans, like us. For vertebrates such as fish, birds, reptiles, amphibians, and mammals, this means that the immune response needed for survival, as described in previous articles, arose solely by these processes.The consequences of this strongly held, but erroneous, idea are pervasive within our culture and affect almost every aspect of human endeavor.


Next time, we'll begin to look at the digestive system and how the body acquires what it needs to live, grow, and work properly.

Religious liberty remains under assault in Russia

Tuesday 16 February 2016

Out of Africa II

A brief history of the confederate battle banner

Electrons in slo mo?

Scientists discover electrons moving like honey in graphene
February 12, 2016 by Ben Robinson

Electrons which act like slow-pouring honey have been observed for the first time in graphene, prompting a new approach to fundamental physics.
Electrons are known to move through metals like bullets being reflected only by imperfections, but in graphene they move like in a very viscous liquid, University of Manchester researchers have found.
The possibility of a highly viscous flow of electrons in metals was predicted several decades ago but despite numerous efforts never observed, until now as reported in the journal Science.
The observation and study of this effect allows better understanding of the counterintuitive behaviour of interacting particles, where the human knowledge and developed mathematical techniques are lacking.
One-atom thick material graphene, first explored a decade ago by a team at The University of Manchester, is renowned for its many superlative properties and, especially, exceptionally high electrical conductivity.
It is widely believed that electrons in graphene can move 'ballistically', like bullets or billiard balls scattering only at graphene boundaries or other imperfections.
The reality is not quite so simple, as found by a Manchester group led by Sir Andre Geim in collaboration with Italian researchers led by Prof Marco Polini.
They observed that the electric current in graphene did not flow along the applied electric field, as in other materials, but travelled backwards forming whirlpools where circular currents appeared.Such behaviour is familiar for conventional liquids such as water which makes whirlpools when flowing around obstacles, for example, in rivers.
The scientists measured the viscosity of this strange new liquid in graphene, which consists not of water molecules but electrons. To the researchers surprise, the electron fluid can be 100 times more viscous than honey, even at room temperature.
The scientific breakthrough is important for understanding of how materials work at increasing smaller sizes required by the semiconducting industry because such whirlpools are more likely to appear at micro and nanoscale.
The observation also questions our current understanding of the physics of highly conductive metals, especially graphene itself.
The simultaneous existence of such seemingly incompatible properties, with electrons behaving like bullets and a liquid in the same material prompts a fundamental rethinking about our understanding of materials properties.
Professor Polini commented: "Giving decades long efforts to find even minor signs of a viscous flow in metals, we were flabbergasted that graphene exhibited not just some small blip on an experimental curve but the clear qualitative effect, a large backflow of electric current."
Sir Andre Geim, who received a Nobel Prize for graphene, added: "Graphene cannot stop amazing us. Now we need to think long and hard how to connect such contradictory behaviour as ballistic motion of electrons, which is undoubtedly seen in graphene, with this new quantum weirdness arising from their collective motion. A strong adjustment of our understanding of the physics is due."


Civil War V :The Dino to Bird controversy.

Study challenges bird-from-dinosaur theory of evolution - was it the other way around?:
(PhysOrg.com) -- A new study just published in the Proceedings of the National Academy of Sciences provides yet more evidence that birds did not descend from ground-dwelling theropod dinosaurs, experts say, and continues to challenge decades of accepted theories about the evolution of flight.
A new analysis was done of an unusual fossil specimen discovered in 2003 called "microraptor," in which three-dimensional models were used to study its possible flight potential, and it concluded this small, feathered species must have been a "glider" that came down from trees. The research is well done and consistent with a string of studies in recent years that pose increasing challenge to the birds-from-dinosaurs theory, said John Ruben, a professor of zoology at Oregon State University who authored a commentary in PNAS on the new research.
The weight of the evidence is now suggesting that not only did birds not descend from dinosaurs, Ruben said, but that some species now believed to be dinosaurs may have descended from birds.
"We're finally breaking out of the conventional wisdom of the last 20 years, which insisted that birds evolved from dinosaurs and that the debate is all over and done with," Ruben said. "This issue isn't resolved at all. There are just too many inconsistencies with the idea that birds had dinosaur ancestors, and this newest study adds to that."
Almost 20 years of research at OSU on the morphology of birds and dinosaurs, along with other studies and the newest PNAS research, Ruben said, are actually much more consistent with a different premise - that birds may have had an ancient common ancestor with dinosaurs, but they evolved separately on their own path, and after millions of years of separate evolution birds also gave rise to the raptors. Small animals such as velociraptor that have generally been thought to be dinosaurs are more likely flightless birds, he said.
"Raptors look quite a bit like dinosaurs but they have much more in common with birds than they do with other theropod dinosaurs such as Tyrannosaurus," Ruben said. "We think the evidence is finally showing that these animals which are usually considered dinosaurs were actually descended from birds, not the other way around."


Another study last year from Florida State University raised similar doubts, Ruben said.
In the newest PNAS study, scientists examined a remarkable fossil specimen that had feathers on all four limbs, somewhat resembling a bi-plane. Glide tests based on its structure concluded it would not have been practical for it to have flown from the ground up, but it could have glided from the trees down, somewhat like a modern-day flying squirrel. Many researchers have long believed that gliders such as this were the ancestors of modern birds.
"This model was not consistent with successful flight from the ground up, and that makes it pretty difficult to make a case for a ground-dwelling theropod dinosaur to have developed wings and flown away," Ruben said. "On the other hand, it would have been quite possible for birds to have evolved and then, at some point, have various species lose their flight capabilities and become ground-dwelling, flightless animals - the raptors. This may be hugely upsetting to a lot of people, but it makes perfect sense."
In their own research, including one study just last year in the Journal of Morphology, OSU scientists found that the position of the thigh bone and muscles in birds is critical to their ability to have adequate lung capacity for sustained long-distance flight, a fundamental aspect of bird biology. Theropod dinosaurs did not share this feature. Other morphological features have also been identified that are inconsistent with a bird-from-dinosaur theory. And perhaps most significant, birds were already found in the fossil record before the elaboration of the dinosaurs they supposedly descended from. That would be consistent with raptors descending from birds, Ruben said, but not the reverse.
OSU research on avian biology and physiology has been raising questions on this issue since the 1990s, often in isolation. More scientists and other studies are now challenging the same premise, Ruben said. The old theories were popular, had public appeal and "many people saw what they wanted to see" instead of carefully interpreting the data, he said.
"Pesky new fossils...sharply at odds with conventional wisdom never seem to cease popping up," Ruben wrote in his PNAS commentary. "Given the vagaries of the fossil record, current notions of near resolution of many of the most basic questions about long-extinct forms should probably be regarded with caution."

The Crisis continues II

Denton, Still a Theory in Crisis, Part 2:


February 16, 2016 Posted by Barry Arrington 

This is the second of a series of posts reviewing Michael Denton’s new book Evolution: Still a Theory in Crisis.

“Gaps among known species are sporadic and often small.  Gaps among known orders, classes, and phyla are systematic and almost always large.”  George Gaylord Simpson, “The History of Life,” in ed. Sol Tax, Evolution After Darwin (Chicago:  University of Chicago Press, 1960), 1:149.

“Unfortunately, the origins of most higher categories are shrouded in mystery; commonly new higher categories appear abruptly in the fossil record without evidence of transitional ancestral forms.”  D.M. Raup and Steven M. Stanley, Principles of Paleontology (San Francisco:  W.H. Freeman and Co., 1971), 306.

“The known fossil record fails to document a single example of phyletic evolution accomplishing a major morphologic transition and hence offers no evidence that the gradualistic model can be valid.”  Steven M. Stanley, Macroevolution:  Pattern and Process (San Francisco: W. H. Freeman, 1979), 39.

As I noted in part one of this series, Dr. Denton has no doubt that Darwinian evolution occurs.  Nor should he.  The term “bauplan” comes from the German “building plan” or “building scheme,” and is often translated in biology as “body plan.”  In chapter 2 (entitled Galápagos), Denton explains that the biosphere is replete with examples of minor variations of bauplans – such as the beaks of the finches of the Galápagos islands made famous by Darwin – that are doubtless due to purely Darwinian processes.  These minor variations of bauplans are often classified under the term “microevolution.”

Before we go any further, let us anticipate an objection.  Darwinists who post in these pages often howl in indignation over the term “microevolution.”  They say the term is never used by “real” biologists.  Perhaps they do not consider George Gaylord Simpson to be a “real” biologist:

“Micro-evolution involves mainly changes within potentially continuous populations, and there is little doubt that its materials are those revealed by genetic experimentation.  Macro-evolution involves the rise and divergence of discontinuous groups, and it is still debatable whether it differs in kind or only in degree from microevolution.”  George Gaylord Simpson, Tempo and Mode in Evolution (New York: Columbia University Press, 1944), 97

Or Stephen Jay Gould:

“As a Darwinian, I wish to defend Goldschmidt’s postulate that macroevolution is not simply microevolution extrapolated . . .”  Stephen Jay Gould, The Return of Hopeful Monsters, Natural History, 86 (June/July 1977), 24, 30

Or Douglas H. Erwin and James W. Valentine:

“Explanations of the Cambrian radiation of invertebrate marine phyla and classes have focused on species selection or traditional microevolutonary processes.”  Douglas H. Erwin and James W. Valentine, “‘Hopeful Monsters,’ Transposons, and the Metazoan Radiation,” Proceedings of the National Academy of Sciences, USA 81 (September 1984): 5482-5483

Eminent biologists have recognized and referred to the distinction between microevolution and macroevolution for nearly one hundred years.  Let us hope that we can dispense with the “real biologists don’t use the term ‘microevolution’” canard once and for all.

Denton uses the Galápagos finch beaks as an example of microevolution.  The finches of the various islands are closely related in terms of nest architecture, egg coloration and DNA.  Yet in other respects, including their beak morphology, they can be quite different.  Denton quotes Darwin’s correct inference regarding the origin of these differences: “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.”  Darwin was also correct about the causal mechanism that resulted in these changes: “Darwin also inferred (again rightly, as the work of subsequent researchers on Galápagos has amply confirmed) that the major causal mechanism responsible for their adaptive divergence—the shaping of their beaks for example—is the simple mechanism of natural selection.”

Denton concludes that evolution on this scale is caused by purely Darwinian mechanisms:

As far as the evolution of finch beaks is concerned, there is no need either at the morphological or genetic level to call for any causal agency other than cumulative selection. Here I concur with classic Darwinism. The beaks are clearly adaptations and their evolution is entirely explicable within a classic functionalist framework. . . . The lesson of the Galápagos, and one of the repeated mantras of Evolution: A Theory in Crisis (see Chapters 2 and 4) is simply this: Cumulative selection will work its magic as long as the novelty of interest is adaptive and there is a functional continuum (at the morphological or genetic level) leading from a putative ancestor species or structure A to a descendant species or structure B.

(emphasis in the original)

In summary, Denton has absolutely no problem with attributing evolutionary change to Darwinian mechanisms so long as the two conditions Darwin himself asserted are necessary are in place:  (1) the novelty is adaptive (otherwise there is nothing for natural selection to “select” for); and (2) there is a functional continuum – there can be no “gaps” in functional intermediates.

This brings us to another  important term: “saltation.”   In Origin of Species Darwin quoted six times the Latin sentence natura non facit saltus.  It means “nature does not take jumps.”  The word saltus means “leap” or “jump,” and in evolutionary theory a drastic or sudden change in an a line of organisms (a “jump”) is called a “saltation.”  Thus, Darwin himself asserted that his theory does not allow for saltations. Stephen Jay Gould added in his 2002 The Structure of Evolutionary Theory  that Darwinian evolution requires variation for natural selection to act upon, AND that variation must, by definition, be very small.  Otherwise, it would be the variation itself, and not natural selection, that would account for the evolutionary change.

Thus Darwinists, beginning with Darwin himself, have always insisted that the theory absolutely requires the “functional continuum” to which Denton alludes.  Saltations are not possible under the theory.  Gould goes so far as to say “For this reason . . . saltationist (or macromutational) theories have always been viewed as anti-Darwinian.”  Stephen Jay Gould, The Structure of Evolutionary Theory (Cambridge, MA: Belknap Press [Harvard], 2002), 111.

Functionalist evolutionary theory demands a continuous chain of functional intermediates for natural selection to work at all:

Darwin’s interminable series of transitional forms is necessary for straightforward mechanistic reasons (how else can one get from A to B by cumulative selection?), but it is also essential if the sole agency of change is to be natural selection.  Where a complex adaptation—no matter how complex—can be reached in a series of tiny adaptive steps, then natural selection can indeed function, in Dawkins’s description, as a blind watchmaker and change A into B no matter how complex the transition, without any other causal agency being involved.

But what if the continuous chain of functional intermediates is missing?  Here we get to the nub of the matter, because Denton claims that

many of the taxa-defining homologs actualized during the course of evolution have never been shown to be adaptive and even in the case of those homologs which are apparently adaptive, functional continuums are either unknown or very hard to envisage.

And if this is the case, certain conclusions follow ineluctably:

To acknowledge their absence [i.e., the absence of a continuous chain of functional intermediates] is to acknowledge that the paths of evolution must have been ordered and directed by additional causal factors, i.e., that cumulative selection is not the sole or even the major directive agency.

Denton writes that this “need for adaptive continuums brings us to the nub of the problem, the core contention of Evolution: A Theory in Crisis, and the major point defended here: Practically all the novel, taxa-defining homologs of all the main taxa are not led up to via adaptive continuums.  Moreover, as argued later in this book, many of these novel Bauplans do not convey any obvious impression of being adaptive . . .”

Denton concludes the chapter with this delightful observation of fine irony:


It is ironic that the very evidence for believing that microevolution has indeed occurred in cases like the finches—an empirically known or readily envisaged continuum of forms leading from an ancestral form A to descendant form B—is precisely the evidence that is lacking when attempting to account for macroevolution and the origin of the defining features (feathers, hands, mammary glands, hair, the placenta, flowers, body plan, etc.) of the major taxa.

On the scientific method.

Bacteria:Known troublemakers for design deniers

Derbyshire VI: Behe's Bacterial Flagellum--Still Stirring Up Trouble for Darwin's Defenders:
Jonathan Witt February 18, 2005 2:50 PM

John Derbyshire is on The Corner arguing that we can never safely infer that certain biological structures were designed. To a reader who asserted that organizational complexity cannot arise from impersonal processes, Derbyshire replies, "How do you know it can't? It is true that the genesis of organizational complexity is not currently well understood; but to leap from that to telling me we shall NEVER be able to find a natural-law explanation for it is just dogma."

Derbyshire's argument is worth confronting because it represents the opinion of leading Darwinists. Biologist Kenneth Miller, for instance, routinely makes just such an argument. Design theorist William Dembski responds thus:

Miller claims that the problem with anti-evolutionists like Michael Behe and me is a failure of imagination -- that we personally cannot "imagine how evolutionary mechanisms might have produced a certain species, organ, or structure." He then emphasizes that such claims are "personal," merely pointing up the limitations of those who make them. Let's get real. The problem is not that we in the intelligent design community, whom Miller incorrectly calls "anti-evolutionists," just can't imagine how those systems arose.
The problem is that Ken Miller and the entire biological community haven't figured out how those systems arose. It's not a question of personal incredulity but of global disciplinary failure (the discipline here being biology) and gross theoretical inadequacy (the theory here being Darwin's).

The particular mechanism Miller has in view here is the bacterial flagellum. Click here and scroll down for a good, brief description and animation of the bacterial flagellum, and here for an enlarged view with its parts labeled. Biochemist Michael Behe made this little engine that could famous by showing that it was irreducibly complex, like a mouse trap: "If any one of the components of the mousetrap (the base, hammer, spring, catch, or holding bar) is removed, then the trap does not function." With even four of these parts, it's utterly useless. The mousetrap is irreducibly complex.

What does irreducible complexity have to do with Darwinian evolution? Evolution by mutation and natural selection must proceed by one slight, functional improvement at a time. So how can it build an irreducibly complex propeller motor one step at a time if the motor can't propel at all until all of its parts are in place? It can't. Something else built it.

Behe's argument doesn't assume that none of the other parts could ever be used for anything else. The spring on a mousetrap could be taken and used in some other device. The base with cheese on it could feed a mouse. Several but not all of the parts of a bacterial flagellum--while completely useless as a rotary propulsion machine--can be used to transport proteins across a membrane. But this hardly provides a credible Darwinian pathway.

Imagine if a boy told a girl he could climb to Mars because there supposedly existed a natural ladder stretching from one planet to the other? The girl is skeptical, pointing out that nobody on earth has ever found such a ladder. The boy screams, "That's an argument from ignorance! Scientists are finding all sorts of new things all the time. Look! The moon! The moon is one step along the way. You see, everything is falling into place." The Darwinists' desperate efforts to spin away the clear significance of the bacterial flagellum is strangely akin to this sort of reasoning. Dembski explains:

Darwin's theory, without which nothing in biology is supposed to make sense, in fact offers no insight into how the flagellum arose. If the biological community had even an inkling of how such systems arose by naturalistic mechanisms, Miller would not -- a full six years after the publication of Darwin's Black Box by Michael Behe -- be lamely gesturing at the type three secretory system as a possible evolutionary precursor to the flagellum.
Miller and Derbyshire are like the boy convinced of the natural ladder to Mars, who finds the moon and yells "Ah ha! Now who dares to play the skeptic!" Well, design theorists do. Consider this passage from a peer-edited paper by biologist Scott Minnich and philosopher of science Stephen Meyer, in which they discuss recent evidence for the delicately orchestrated and information-rich proteins of the bacterial flagellum:

[I]f anything, TTSSs [Type Three Secretory Systems] generate more complications than solutions to this question. As shown here, possessing multiple TTSSs causes interference. If not segregated one or both systems are lost. Additionally, the other thirty proteins in the flagellar motor (that are not present in the TTSS) are unique to the motor and are not found in any other living system. From whence, then were these protein parts co-opted?
Also, even if all the protein parts were somehow available to make a flagellar motor during the evolution of life, the parts would need to be assembled in the correct temporal sequence similar to the way an automobile is assembled in factory. Yet, to choreograph the assembly of the parts of the flagellar motor, present-day bacteria need an elaborate system of genetic instructions as well as many other protein machines to time the expression of those assembly instructions. Arguably, this system is itself irreducibly complex. In any case, the co-option argument tacitly presupposes the need for the very thing it seeks to explain--a functionally interdependent system of proteins.

Now one letter writer, responding to Behe's column in The New York Times, complained that we only describe the bacterial flagellum as an outboard motor because we have no better analogy, not because it is an outboard motor. The letter writer argues that believing this molecular motor was designed is like the astronomer Percival Lowell mistaking Martian canyons for canals. The suggestion is that false design inferences have been made, so surely all of the design inferences in the natural sciences are false. In this case, the fallacious argument--a favorite among Darwinists--is doubly silly because the Martian canyons turned out to be far simpler, far less specified, than engineered canals; while the bacterial flagellum has turned out to be far more sophisticated than our outboard motors.

As Minnich and Meyer note, the discovery of molecular motors is opening a whole new field, where biology and engineering meet:

To paraphrase the original rendition of the Department of Energy's Genomes to Life web site, "the molecular machines present in the simplest cells, produced by evolution, dwarf the engineering feats of the 20th century." The dissection of the complexity and sophistication of ... machines like the bacterial flagellum are indeed a testimony to the power of modern molecular biological techniques. Yet, the elegant structural properties, efficiency, and the highly controlled genetic programming to produce these machines was neither anticipated nor predicted. The potential applications of this knowledge are legion and have spawned a new discipline focused on nanotechnology.
One needn't go far for examples. Here at Physics Today, well trained physicists are standing around this astonishing little machine, the bacterial flagellum, like neighborhood mechanics getting a chance to take apart and learn from a NASCAR racing engine.
Derbyshire, Miller and other Darwinists are mixed up about the direction of things. The more we KNOW about the bacterial flagellum, the less and less it is anything the Darwninian mechanism could produce. Moreover, there are strongly affirmative grounds for inferring design from the presence of irreducibly complex machines and circuits. Every time we know the causal history of an irreducibly complex system (like the NASCAR racing engine or an electronic circuit), it always turn out to have been the product of an intelligent cause.


Finally, the list of known biological mechanisms that appear irreducibly complex isn't shrinking, it's growing.

Soft bodies mean hard luck For Darwinian apologists

Derbyshire III: Soft Bodies a Femme Fatale for Darwinism
Jonathan Witt February 15, 2005 11:14 AM

As we saw in Derbyshire II, the pattern of the fossil record doesn't fit the Darwinian prediction of a gradually branching tree of life, even where punctuated equilibrium is invoked to shoehorn the transitional intermediates into those gaps John Derbyshire puts such faith in.

The problem gets even uglier when Darwinists try to explain away the fossil record leading up to the Cambrian Explosion. What story do these strata tell? Animals didn't exist; and then they did--not just dozens of species but dozen of phyla. If you want some idea of how large a category phyla is, consider that sharks, mice, humans and otters are all members of the same phylum.

If natural selection working on random genetic mutation built this menagerie of animals, it had to do it one extraordinarily tiny, functional improvement at a time, one generation at a time, over tens and even hundreds of millions of years. If we had even a tiny fraction of a fraction of the Precambrian life forms, we would have so many transitional forms we would be hard-pressed to draw the line between one phylum and another, so thoroughly would they bleed one form into the other. But we find no such fossil pattern in the Precambrian. 

Derbyshire suggests that the precursors of the many Cambrian phyla were soft-bodied and so never fossilized: "[S]oft body parts hardly ever get fossilized," he writes. "We are working from a pretty scanty data set here."

The problem is, many soft-bodied creatures did fossilize, and they tell a different story from the one Darwin told. Consider this passage in which Meyer et al., marshall evidence from mainstream evolutionists working in paleobiology:

While clearly the fossil record does not preserve soft body parts of organisms as frequently as hard body parts, it has preserved enough soft body animals and organs to render this version of the artifact hypothesis suspect. Indeed, entirely soft-bodied representatives of several phyla have been identified in the Cambrian. Soft-bodied organisms are also preserved in Precambrian strata around the world. Even so, these Precambrian organisms do not represent plausible transitional intermediates to representatives of the Cambrian phyla. In each case the jump in complexity (as measured by the number of cell types, for example) and the morphological disparity between the Precambrian and Cambrian organisms appears far too great. (See Section IV.B. below). Furthermore, the postulation of exclusively soft-bodied ancestors for hard-bodied Cambrian organisms seems implausible on anatomical grounds.54 Many phyla such as brachiopods and arthropods could not have evolved their soft parts first and then added shells later, since their survival depends in large part upon their ability to protect their soft parts from hostile environmental forces. Instead, soft and hard parts had to arise together.55 As Valentine notes in the case of brachiopods, "the brachiopod Baupl?�ne cannot function without a durable skeleton."56 To admit that hard-bodied Cambrian animals had not yet evolved their hard-bodied parts in the Precambrian effectively concedes that credible precursor animals themselves had not yet evolved. 57 As Chen and Zhou explain: "[A]nimals such as brachiopods and most echinoderms and mollusks cannot exist without a mineralized skeleton. Arthropods bear jointed appendages and likewise require a hard, organic or mineralized outer covering. Therefore the existence of these organisms in the distant past should be recorded either by fossil tracks and trails or remains of skeletons. The observation that such fossils are absent in Precambrian strata proves that these phyla arose in the Cambrian." (356-357)
There are other tactics for avoiding the growing body of paleontological evidence against Darwinism. Meyer deals with many of those in a peer-reviewed biology journal article here. A spirited rebuttal is here. Discovery Institute fellows show why the rebuttal lacks force here and here. A short, introductory piece on the controversy over the Cambrian Explosion is here. A collection of eye-opening quotations from mainstream paleontologists is here. Journalists seeking to comment on these issues can quickly distinguish themselves merely by doing their homework.


More to come on Derbyshire and the evidence for intelligent design.


Monday 15 February 2016

Total structural collapse.

Non-Adaptive Order: An Existential Challenge to Darwinian Evolution
Michael Denton February 15, 2016 12:07 AM 

Editor's note: In his new book Evolution: Still a Theory in Crisis, Michael Denton not only updates the argument from his groundbreaking Evolution: A Theory in Crisis (1985) but also presents a powerful new critique of Darwinian evolution. This article is one in a series in which Dr. Denton summarizes some of the most important points of the new book. For the full story,get your copy of Evolution: Still a Theory in Crisis. For a limited time, you'll enjoy a 30 percent discount at  CreateSpace by using the discount code QBDHMYJH.

At London's famous Natural History Museum in South Kensington, a statue of Richard Owen had been prominently placed for many decades at the head of the main staircase. But in a curiously symbolic event on May 23, 2008, the statue was moved to one of the adjacent balconies to make room for a statue of Charles Darwin, which now sits in pride of place.


The reason for this gesture? The Natural History Museum is a grand temple to Darwinian evolution, and Owen was a staunch defender of the alternative structuralist conception of nature -- a conception that, if true, would relegate Darwinian selectionism to a very trivial role in the evolution of life.Owen founded the museum and served as its first curator and director. He made huge contributions to comparative anatomy and paleontology in the 19th century, including coining the term "dinosaur" and defining the term "homology." Owen believed that there was a substantial degree of order inherent in living systems, manifest in what he termed "primal patterns," the grand taxa-defining homologs or ground plans that underlie the adaptive diversity of life.

Because of his vigorous opposition to the functional conception of nature, Owen was vilified by Huxley and other supporters of Darwin. After the publication of the Origin, Owen's contribution to biology was increasingly downplayed by the Darwin camp, and his rejection of the conception that all biological order was to "serve some utilitarian end" was dismissed as archaic and treated as based on failed metaphysical assumptions. Little wonder they moved his statue!

While many of the taxa-defining homologs -- including, among others, the feather, the poison claw of the centipede, the retractable claw of cats, the mammalian diaphragm, and mammary glands -- are clearly adaptive, a great many others, such as the odd number of segments in centipedes, the concentric whorls of the flower, the insect body plan, and the pentadactyl limb, convey the powerful impression of being basically non-adaptive Bauplans. The fact that many exhibit curious geometric and numeric features reinforces the impression that they are indeed abstract non-adaptive patterns, quite beyond the explanatory reach of any adaptationist or selectionist narrative.

In all those cases Darwinian explanations are simply ruled out of court. The difficulty of accounting for arbitrary geometric and numerical patterns in terms of bit-by-bit selection was one of the basic thrusts of William Bateson's vigorous attack on Darwinian orthodoxy, where he argued that such stories descend into "endless absurdity."1

If indeed a significant proportion of the taxa-defining primal patterns serve no specific adaptive function and never did, as common sense dictates and as Owen thought to be true of the Bauplan of the tetrapod limb, then I think a fair assessment has to bethatDarwinism(more specifically, cumulative selection) cannot supply an explanation for the origin of a significant fraction of the defining homologs of the Types and hence for the natural system itself.

References:

(1) Bateson, Materials for the Study of Variation, 410.

Sunday 14 February 2016

Peer reviewed findings re:probability and evolution

Microbes Vs.Darwin II

More on How Microbes Make Earth Habitable:

Evolution News & Views February 14, 2016 12:03 AM

Last week we discussed how microbes maintain the viability of life on our planet ("How Microbes Make Earth Habitable"). In the same vein, more news just arrived about the carbon and nitrogen cycles.

Following up on MIT's findings about plankton taking carbon to the ocean bottom, Ohio State has just concluded from the three-year Tara Oceans oceanography expedition that plankton -- and some viruses -- are "key to carrying carbon" from the atmosphere down to the seafloor sediments. They took pictures of microbes at different depths to learn which ones are carrying carbon downward as they sink to the bottom. The research has helped scientists understand "the interplay of organisms in the ocean and of their role in the health of the planet."

As for nitrogen, Current Biology posted a Primer on "The Nitrogen Cycle," confirming that it "is entirely controlled by microbial activities." Before man started producing chemical fertilizers, "nearly all of the reactive nitrogen in the biosphere was generated and recycled by microorganisms."

Microbes Follow Icebergs

Another interesting interaction between geology and life was reported by the BBC News. Mark Kinver writes that "Giant icebergs play [a] 'major role' in [the] ocean carbon cycle." An aerial image shows a brilliant bloom of phytoplankton following one such giant iceberg in its wake. What's happening? The bloom is "triggered by the distribution of nutrients -- such as iron -- from an iceberg's meltwater." What this signifies is important:

"We estimate that giant icebergs account for between 10% and 20% of the actual vertical rate of carbon going from the surface to the deep (Southern) Ocean," he suggested....

Plankton scientist Dr Richard Kirby, who was not involved in this study, observed: "The phytoplankton at the sunlit surface of the sea has played a central role in the sequestration of carbon over millennia to affect the atmospheric concentration of this greenhouse gas, and so the Earth's climate.

"This interesting paper shows how much we still have to learn about these microscopic organisms, and how a changing climate may affect them, and also the food web they support." [Emphasis added.]

Bacteria Attack Lignin

Readers of Evolution News may remember Ann Gauger and Matt Leisola's design inference about lignin, the complex molecule that gives wood its strength. They argued that no organism has exploited this energy-rich substance -- which is good news for us, because "the indigestibility of lignin may be an essential requirement for the balance of life," Gauger wrote. "Lignin slows the degradation of wood, thus allowing the buildup of humus in the soil, which in turn permits plant growth and all resulting life that depends on plants."

Now, news from Rice University says that bacteria use a "tag team" approach to break apart this complex substance that locks up more than half a plant's sugar and holds a third of the carbon in biomass. This finding does not impact the conclusions of Gauger and Leisola, because the bacteria "chew through" the lignin to get to the cellulose they can digest. But "it's a very slow process, which is why it can take years for dead trees to decompose." The rate of decomposition of this energy-rich substance is what's interesting for considerations of planetary carbon cycling and habitability.

Bacteria Prepare the Land for Habitation

Another interesting interaction of microbes with geology happens on land. Biocrusts are accumulations of cryptic bacteria that inhabit the surfaces of arid soils. A paper in Nature Communications notes the ecological impact of these microbial habitats:

Much of the arid soil surfaces can be populated by cryptic photosynthetic assemblages known as biological soil crusts (or biocrusts), which are known to impart stability against erosion, to modify the hydrological properties of soils, and to contribute significantly to arid land fertility.

Researchers from Arizona and California found that the bacteria, mostly the nitrogen-fixing variety, produce a secondary metabolite called scytonemin that acts as a "sunscreen". It strongly absorbs solar radiation and dissipates it as heat, raising soil temperatures as much as 10°C, an effect that is "not without consequences" for soil microbial communities. While potentially making deserts more arid, this effect is good for temperate and arctic zones: "biocrusts in cold climates, that is, in polar settings or during winter months when activity is limited by temperature, the warming can be expected to be largely beneficial to biological entities."

About 41 percent of the earth's surface is arid, and this is where biocrusts figure prominently. By producing this sunscreen molecule, bacteria protect the soil from harmful radiation while simultaneously raising the temperature in cold arid lands to promote the growth of complex plants in ecological succession -- all this while stabilizing the soil, reducing erosion and fixing nitrogen that higher plants need. It's another case that has just come to light of global benefit from the world's smallest organisms.

For these reasons, microbial effects on land surface albedo may have global scale repercussions historically and in the present, and should be evaluated in models of planetary radiation budgets as a new twist of biosphere-climate feedback interactions. This may shed some light into the apparent inconsistency in temperature changes recorded in arid lands. Contrary to model predictions, temperature has been shown to increase when removing vegetation there, an apparent paradox that could potentially be explained by biocrust colonization. Based on estimates of the global biomass of cyanobacteria in soil biocrusts, one can easily calculate that there must currently exist about 15 million metric tons of scytonemin at work, warming soil surfaces worldwide.

Big Animals Help Earth's Habitability, Too

From orbit, a bear would appear as small as a microbe. Current Biology published another indication that all living things, even the big ones, have a stake in keeping the earth habitable. In "Megafauna move nutrients uphill," Michael Gross points to research about whales, salmon, birds and bears that reveal large animals' roles in moving phosphorus and nitrogenous compounds from the deep ocean to the mountains. These "ecosystem engineers" perform an "important ecosystem service" by distributing nutrients to higher elevations.

Given the laws of gravity and the hydrological cycle, there is a strong likelihood that nutrients available on land, even though they may go through many cycles around the food web, will eventually be washed out to the sea. In the oceans, there is the risk that they will drop out of the photic zone and reach the sea floor, where they will be buried in sediment that may only be returned to circulation on geological timescales, some tens or hundreds of millions of years later.

Animals can make important contributions to stem this flow, as was first reported for whales back in 2010 (Curr. Biol. (2010) 20, R541). Researchers studying the ecology of sperm whales found that they harvest nutrients such as iron from great depths (often more than 1,000 metres), where they hunt cephalopods, but release them when they defecate near the surface.

The nutrients are incorporated into microbes, plankton, and fish that become prey for birds and mammals. These larger animals, in turn, transport the nutrients up rivers and mountains. Although Michael Gross focuses on how humans are disrupting this natural system, one can only stand in awe of how the living web distributes the very atoms and molecules needed for complex life around the globe.

Tiny Creatures, Major Roles

It takes more than a rocky planet in a habitable zone to sustain life. Some twenty factors are listed in the film The Privileged Planet relating to geology, the atmosphere, the magnetic field, and other abiotic phenomena. We've seen that that life itself maintains the habitability of the earth in surprising ways. By means of coded instructions in their genomes, the tiniest of creatures play major roles in maintaining the essential cycles of the planet: the hydrologic cycle, nitrogen cycle, oxygen cycle, carbon cycle, and more.


Evolutionists may weave stories about how these remarkable interactions arose gradually as life emerged and progressed. The instances above, though, should call into question whether any life could have subsisted on a bare earth without at least some of these processes already in operation. When these observations are combined with the other evidences of fine-tuning in the earth, the laws of physics, and the universe, the inference to design seems irresistible.

Is it time to give Darwin the pink slip.

On Darwin Day, Darwinism Is Well Past Its "Sell By" Date:
Michael Denton February 12, 2016 2:04 AM 



Today is Darwin Day, marking the birthday of Charles Darwin, who is celebrated around the world as a secular saint. Everywhere there will be eulogies to neo-Darwinism as a philosophy, touting the support it provides to the mechanistic worldview and the notion that life is an artifact of time and chance. Darwinism in that sense, almost akin to a faith, is indeed going strong.

Yet Darwinism as a scientific theory remains, as it always has been, a highly speculative evolutionary model. My new book,  Evolution: Still a Theory in Crisis, makes that clear. I document in detail old ideas and new research that come together to severely undermine classic Darwinism and point to a new non-Darwinian paradigm for biology in the 21st century.


As the book shows, key features of the biological realm flatly contradict the Darwinian mechanism of natural selection and the notion that all features of living things are or were in some ancestral form adaptive. My new book is a sequel to my 1985 work, Evolution: A Theory in Crisis , and it shows how the crisis has deepened over the past three decades.To understand the core weakness of the Darwinian worldview, it is important to understand what Darwinian natural selection requires. The process will work its magic, building up functional structures in organisms, only when two very strict conditions are met: First, the structure must be adaptive -- that is, helpful to the organism in flourishing in its environment -- and second, there must be a continuum of structures, functional all along the way, leading from an ancestor species to the descendent.

That is, the thing we are trying to explain must in some way help the creature survive, and between the creature and the creature's ancestor there must be a gradual change, each step of which is stable and enhances fitness, or success in reproduction.

Problem number one is that there are a great number of complex structures in nature that are not led up to by known functional pathways, and imagining what these pathways might have been is in most cases very hard. But this challenge is greatly compounded by an additional problem: that in many cases complex structures convey not the slightest evidence that they ever performed an adaptive function in putative ancestral forms. This may come as a surprise to the student of evolution. The trade language of biology has focused on the concepts of adaptation, fitness, and utility for so long that it has in a sense blinded us to the universe of apparently non-adaptive order that permeates the entire organic realm.

For example, what is the adaptive fitness of the shape of a maple leaf? Or the shape of any leaf, for that matter? Nor are examples of seemingly non-adaptive order limited to the shapes of leaves. Some of the best examples are embedded deep within the biological world -- among the characteristics that define and separate the basic kinds or types of plants and animals from each other.

Consider the pentadactyl (five-finger) design of the tetrapod limb, witnessed in the human arm and leg: one bone (the humerus in the upper arm, the femur in the upper leg), two bones (the radius and ulna in your lower arm, the tibia and fibula in the lower leg ), five fingers and five toes. This unique design occurs in the fore and hind limbs of all tetrapod (four-limbed) vertebrates, including human beings.

It is clear that in all tetrapod limbs the same basic design has been adapted to very different uses. However, given that the adaptive forms of the fore and hind limbs differ to some degree in every known tetrapod, it is very difficult to explain how the underlying pattern could have been arrived at so as to serve some adaptive end in a hypothetical fore and hind limb of an ancestral tetrapod. The Darwinian explanation, attributing the underlying structure to previous rounds of natural selection, is self-evidently ad hoc.

If we can't explain what specific adaptive function the pentadactyl design serves in any known extant or extinct species of tetrapod, there are no grounds for the Darwinian claim that there was some hypothetical species in some hypothetical environment where this unique design did serve some mysteriously obscure adaptive function in both limbs. In this case, even "just so stories" can't legitimate the Darwinian account.

The challenge to the Darwinian framework is not restricted to the tetrapod limb, but applies almost universally to a veritable universe of other novel structures -- the insect body plan, the concentric whorl pattern underlying all flowers, and the enucleated red blood cell found in all mammals, which was the subject of my own doctoral work at King's College in London.

Contributing further to the challenge inherent in so much non-adaptive order are revelations from the new field of evolutionary developmental biology (evo-devo). We now know that the paths of evolution have been highly constrained by a set of universally conserved developmental genetic mechanisms that transcend any immediate adaptive utility. Moreover, evo-devo implies that in the case of many novelties, internal constraints have played a decisive role in evolutionary origins.

In my new book, I detail vast quantities of evidence from the most up-to-date scientific literature, all supporting the radical idea that Darwinism played a very minor role in the history of life, and that evolutionary biology in the 21st century will have to seek an entirely new causal framework.

Darwinists will of course continue to insist that classic Darwinism can provide a completely plausible explanation of all evolutionary phenomena. But the reality is that Darwin's theory is well past its "sell by" date. By Darwin Day next year, we can confidently predict the situation will appear no less dire, and likely even more so.

Editor's note: Get your copy of Evolution: Still a Theory in Crisis now. For a limited time, you'll enjoy a 30 percent discount at CreateSpace   by using the discount code QBDHMYJH. 

Another failed Darwinian prediction VII

The pentadactyl pattern and common descent:

The pentadactyl structure—five digits (four fingers and a thumb for humans) at the end of the limb structure—is one of the most celebrated proof texts for evolution. The pentadactyl structure is found throughout the tetrapods and its uses include flying, grasping, climbing and crawling. Such diverse activities, evolutionists reason, should require diverse limbs. There seems to be no reason why all should need a five digit limb. Why not three digits for some, eight for others, 13 for some others, and so forth? And yet they all are endowed with five digits. As Darwin explained, “What can be more curious than that the hand of a man, formed for grasping, that of a mole for digging, the leg of the horse, the paddle of the porpoise, and the wing of the bat, should all be constructed on the same pattern, and should include similar bones, in the same relative positions?” (Darwin, 382)

Such a suboptimal design must be an artefact of common descent—a suboptimal design that was handed down from a common ancestor rather than specifically designed for each species. And the common descent pattern formed by this structure is often claimed as strong evidence for evolution. (Berra, 21; Campbell et. al., 509; Futuyma, 47; Johnson and Losos, 298;  Johnson and Raven, 286; Mayr, 26) One text calls it a “classic example” of evolutionary evidence. (Ridley, 45)

But this prediction is now known to be false as the digit structure in the tetrapods does not conform to the common descent pattern. In fact, appendages have various digit structures and they are distributed across the species in various ways. This is found both in extant species and in the fossil record. As evolutionist Stephen Jay Gould explained, “The conclusion seems inescapable, and an old ‘certainty’ must be starkly reversed.” (Gould)

This means that evolutionists cannot model the observed structures and pattern of distribution merely as a consequence of common descent. Instead, a complicated evolutionary history is required (Brown) where the pentadactyl structure re-evolves in different lineages, and appendages evolve, are lost, and then evolve again. And as one recent study concluded, “Our phylogenetic results support independent instances of complete limb loss as well as multiple instances of digit and external ear opening loss and re-acquisition. Even more striking, we find strong statistical support for the re-acquisition of a pentadactyl body form from a digit-reduced ancestor. … The results of our study join a nascent body of literature showing strong statistical support for character loss, followed by evolutionary re-acquisition of complex structures associated with a generalized pentadactyl body form.” (Siler and Brown)

References

Berra, Tim. 1990. Evolution and the Myth of Creationism. Stanford: Stanford University Press.

Brown, R., et. al. 2012. “Species delimitation and digit number in a North African skink.” Ecology and Evolution 2:2962-73.

Campbell, Neil, et. al. 2011. Biology. 5th ed. San Francisco: Pearson.

Darwin, Charles. 1872. The Origin of Species. 6th ed. London: John Murray.
http://darwin-online.org.uk/content/frameset?itemID=F391&viewtype=text&pageseq=1

Futuyma, Douglas. 1982. Science on Trial: The Case for Evolution. New York: Pantheon Books.

Gould, Steven Jay. 1991. “Eight (or Fewer) Little Piggies.” Natural History 100:22-29.

Johnson, G., J. Losos. 2008. The Living World. 5th ed. New York: McGraw-Hill.

Johnson, G., P. Raven. 2004. Biology. New York: Holt, Rinehart and Winston.

Mayr, Ernst. 2001. What Evolution Is. New York: Basic Books.

Ridley, Mark. 1993. Evolution. Boston: Blackwell Scientific.

Siler C., R. Brown. 2011. “Evidence for repeated acquisition and loss of complex body-form characters in an insular clade of Southeast Asian semi-fossorial skinks.” Evolution 65:2641-2663.