American Thought Leaders - Here’s What Darwinian Evolution Can’t Explain About the Origins of Species | Stephen Meyer
Episode Date: April 18, 2026For decades now, we’ve been told the biggest questions of how life and our universe came to be were settled. But what if they’re not?Stephen Meyer has spent his career digging into the deepest mys...teries of our existence. A philosopher of science, he is the founder of the Discovery Institute’s Center for Science and Culture and the author of the New York Times bestseller “Darwin’s Doubt” and “Return of the God Hypothesis.”“Many leading evolutionary biologists today are calling for a new theory of evolution, because they recognize that the mutation-natural selection mechanism has limited creative power,” Meyer says.While Charles Darwin’s theory of evolution and natural selection can explain small-scale variations—for instance, finch beak size changes, moth wing color changes, or bacteria developing antibiotic resistance—it cannot explain the origins of new species or new body plans, Meyer contends.Now, in a new film, “The Story of Everything,” coming to theaters April 30, Meyer lays out a case that could reshape how we think about life itself.“The scientific discoveries of the last one hundred years and right up to the present are pointing in a very different direction than people thought in the late 19th century,” Meyer says.Views expressed in this video are opinions of the host and the guest, and do not necessarily reflect the views of The Epoch Times.
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For decades now, we've been told the biggest questions of how life and our universe came to be were settled.
But what if they're not?
The scientific discoveries of the last 100 years and right up to the present are pointing in a very different direction than people thought in the late 19th century.
Stephen Meyer has spent his career digging into the deepest mysteries of our existence.
Natural selection is a nice job of explaining that small-scale variation,
but it doesn't do a good job of explaining the origin of what biologists call morphological innovation.
the origin of major new body plans or new form,
new organs, new tissues,
but especially new body plans in the history of life.
What if modern biology textbooks leave out the most important part of the story?
Darwinian evolution functions as a kind of secular religion.
It's the question of the origin of the first life itself.
How do you get life going?
That's something Darwin never addressed.
Meyer is a New York Times best-selling author
and founder of the Discovery Institute Center for Science and Culture.
and culture. Now in a new film, The Story of Everything, coming to theaters April 30th,
he lays out a case that could reshape how we think about life itself. This is American Thought
Leaders, and I'm Janie Kellick. Stephen Meyer, such a pleasure to have you on American Thought
Leaders. Great to be with here, Jan. Thank you for inviting me in such a beautiful studio as well.
You know, I have to offer you huge congratulations on the story of everything. It's a,
beautiful marvelous film and I hope it does incredibly well and at the outset I'll
recommend everybody go see it but let's start here okay back when I was studying
biology in my undergraduate degree third year in third year biology something
occurred to me and that was that people would say I believe in evolution and I
realized as I was studying evolution and
to study evolutionary biology, then when people said that, they meant different things.
Okay? And so, for example, what I first thought people were saying was that evolution by natural selection,
this kind of specific Darwinian mechanism, happens, right, which I think is true as a concept, right?
Like this, you can see it in viruses, for example. Indisputably true. Exactly. Indisputably true. However,
what struck me was that when people say,
that often they would really mean, I believe that that's where humans come from. There was this kind
of quasi-religious belief in it, right? Which was just odd to me because it was very obvious to me that
there were all these different, clearly there would have to be all these different mechanisms at play
to get the diversity of life. It's like we've been arguing almost at cross-purposes around this
question. That's where I want to start. Yeah, that's a great place to start because there's a
a great deal of equivocation around the term evolution.
It can be many different things.
And just initial observation or reaction to what you've said
is that there's a huge difference between the idea
that natural selection is a real process that takes place
and the claim that natural selection acting
on random variations and mutations has unlimited creative power.
It can be a process that is a real part
of biological phenomena without necessarily
having unlimited creative power.
And many leading evolutionary biologists today are now calling for a new theory of evolution
because they recognize that the mutation, natural selection mechanism, has limited creative
power, quite limited creative power.
I attended a conference in 2016, now 10 years ago, at the Royal Society in London that was
convened by a group of biologists and evolutionary biologists who have been calling for a new theory
of evolution precisely because they realize that the mechanism of mutation and selection
has such limited power.
That it does a nice job of explaining small scale variation and adaptation.
All the classic examples that we learn about in the biology textbooks, the same ones that
are repeated over and over again.
There's a fairly limited number of these, but the peppered moths that change coloration
from dark to light and dark again, or maybe it's the other way around, the Galapagos
finches with the beaks that get a little bigger, a little smaller, and change shape in response
to varying food supplies and weather patterns, antibiotic resistance, and so forth. Natural selection
is a nice job of explaining that small-scale variation, but it doesn't do a good job of explaining
the origin of what biologists call morphological innovation, the origin of major new body plans
or new form, new organs, new tissues, but especially new body plans in the history of life.
That we find again and again in the fossil record, that kind of morphological innovation occurs
very abruptly, and the mechanism of natural selection does not explain that well, runs out of
capability very quickly.
So we talk more about why that's the case, but the distinction between just the fact of a mechanism
that does something and the claim that it can do everything is often overlooked.
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So, you know, back in that same class that I was taking, there was a man who became my friend.
Actually, you know, we thought of us as kids then, I guess, but Dennis Venema, he had the audacity to do.
We all had to do a seminar as part of this seminar series, right?
And so he had the audacity in front of a group of people.
who are definitely committed to evolution, okay,
to do a seminar on flaws in evolutionary theory.
Okay, and he was used as an evangelical Christian.
Later actually became part of this biologos group,
which is, you know, quite committed now to the adequacy
of evolutionary theory and to the creative power
of natural selection.
So that's, anyway.
Yeah, yeah, no, no, that.
And so it's interesting, right?
But what I thought when I saw this,
because this is kind of like, you know,
the class is kind of, you know,
pitchforks and tiki torch becomes like this kind of thing.
Because people are so emotionally invested in this, right?
I have a friendly, well, of blessed memory,
of a friendly debating partner, Michael Ruse,
passed away last fall.
And he's on the other side of the issue, obviously.
He was, and he was a committed neo-Darwinist,
But he wrote an important book in which he acknowledged or really spotlighted the fact that for many of his colleagues,
Darwinian evolution functions as a kind of secular religion.
And you can see why, because it's answering one of the most fundamental questions that any worldview or religion has to answer,
which is what is the thing or the entity or the process from which everything else came.
And the Neo-Darwinian explanation of the origin of new forms of life is part of the answer to that really,
fundamental question, which is not only a scientific question, but a philosophical worldview question.
But Ruse's critique of some of his own colleagues was that because it functions like a secular
religion, sometimes there's a resistance to a more dispassionate scientific evaluation of its merits.
It's just like, to me, the eye. Just the eye, right? And we have a complex eye in an octopus, for example,
that's different in some foundational ways than a complex eye and a human being.
But no one's been able to explain to me how you get an eye with all the lens and all these
complex things through a process of natural selection.
I actually think you never get an eye through the process of natural selection because
there's just so many of these intermediate forms.
Actually, let's do this because I even think that maybe there's viewers out there who hear
about this natural selection of evolution.
You might not even understand the exact mechanism.
So let's just kind of define what it is very quickly and how, I mean, and if I'm wrong, you tell me, right?
But I just don't think you ever get an eye through natural selection.
Well, natural selection is the idea that the Darwinian process as a whole envisions differential reproduction,
that there would be organisms that would reproduce, leave offspring with varying traits,
that some of those traits would be more favored in a competition for survival.
and that those would be differentially,
or on a statistical basis,
passed on more frequently than those traits
that are not as advantageous.
And over time, the idea is that there would be
an accumulation of the more favorable traits
and that the differences that are represented
by those genetic or mutational variations
that arise in a population would eventually
become fixed in the population,
and there would be an overall directional change to the organism.
So something fundamentally new would arise.
Let's talk about the, I'll just use quickly to reframe with this example, right?
The Darwin's Finch, okay, the reason you get a finch that has a very, very long beak
is because there's some kind of food out there that a long beak can get very well.
Yeah, there's been a study of this by a couple called the grants,
and they showed that there were variations in the, in the,
weather patterns in the Galapagos, and that part of that resulted in, I think it was a series
of droughts, and so that there were only very hard nuts left, and so that the finches that
survived better were, on average, had a 5% longer, or not forgetting the exact figure,
beak that enabled them to crack through the nuts. And so you've got a small-scale variation
or adaptation of the structure of the beak to permit more effective.
Galapagos finch foraging.
But the bottom line is the ones that have the longer beaks in this case survive more often,
which is why over time you get a longer and longer beak.
Basically, that's the process, right?
Well, that's the claim that that process can go on in an unlimited way,
producing all forms of life that we see.
But how do you get an eye with that?
Let's go more fundamental.
The eye, like everything else in the body,
depends upon the function of large biomacromolecules
called proteins.
Proteins do all the important jobs in themselves.
They catalyze reactions, at very fast rates
that would not otherwise occur.
They build the structural parts of miniature machines.
They help process information.
And they're part of what, in the case of the eye,
part of what's called a biosynthetic pathway,
the vision cast.
that allows vision, even to get a light sensitive spot,
you have to have a whole series of proteins
that are interacting with each other in a kind of chain
to make light sensitivity possible.
And so if we want to explain the origin of anything novel in life,
we have to explain the origin of proteins.
Now we know proteins are built by reference to the information
that's stored on the DNA molecule.
And that information is stored in essentially a digital form.
form. There's a four-character digital code of little subunits along the spine of the DNA molecule
that function like alphabetic characters in the written text or the zeros and ones in a section of
software. Now, we know something from our experience of software, and that is that if you start to
change the zeros and ones in the section of software for doing something specific, for a specific
app or a program or an operating system, and you start to change them very much, you will degrade
the function of the code so that the app or the program or the operating system will no longer
work long before you will have made enough changes to produce something fundamentally new.
So when I ask in talks, I ask if there's computer programmers there, I'll ask you know,
if you start changing zeros and ones in a section of function and code, are you going to build
something new first or will you degrade what you have first?
And they laugh.
The answer's obvious.
Well, it turns out we've learned the same thing.
is true of the digital code in the DNA that makes the protein molecules. You can alter it a little bit,
and if you do, you can sometimes alter the function of the existing protein, provided you don't
change the overall structure of the protein that's called a fold. The fold makes possible sometimes
multiple functions that are related, but within that structure. But as you accumulate random mutations,
and usually between three and five, maybe up to seven percent, I mean maybe it's even 10 percent,
but a very small number of mutations in various proteins will cause the structure,
the structural stability of that fold that makes protein function possible at all to simply degrade.
There's a loss of what's called thermodynamic and structural stability.
The thing unravels.
But we've also learned that to build a new fold capable of a completely novel set of functions,
you have to, the sequence differences between them are on the order of 65 and sometimes as much as
80%. So the same thing holds in the gene protein world that holds in the computer science world,
that if you start randomly changing things at the genetic level, and that's what a mutation is,
as those accumulate, you're going to inevitably degrade and destroy the possibility of function
in what you have long before you will have changed it enough to produce something fundamentally
new that will create genetic and morphological novelty. So,
That's the problem.
And that applies not only to the origin of the eye,
because the eye depends on all these proteins
and what's called the vision cascade,
but it applies to virtually every significant biological change
that you could imagine.
So this is one of a legion, at least it was called a suite,
of fundamental problems with the idea
that the mutation selection mechanism
is fundamentally creative.
It's a real process.
People like me who hold to the theory of intelligent design,
affirm that it's a real process. It's part of what we know about how biology works,
but it has very limited creative power.
And this is actually, you know, one of the key arguments you make in the story of everything,
which I think you develop, you know, it's absolutely fascinating,
that the scientific discoveries that we've made in the realm of exactly the kinds of things that you talk about,
actually have given us a lot of information we didn't have that might have made us overlook that,
creative power that's somehow, you know, in the system but isn't explained by the random
mutation. Yeah, exactly. It's the advance of science that has made us more confident that there's
that there is a designing intelligence behind life in the universe. We don't deal a great,
a great deal with the question of biological evolution in the film. We talk a bit about the
miniature machines that are present inside cells and how difficult they are to explain by
a step-by-step gradual Darwinian process of natural selection. We look particularly at two machines
that I think are really fascinating. One is the bacterial flagellar motor that our colleague Michael Behe
has made famous. The other is the ATP synthase, which is a little turbine. So one's a rotary
engine, the other is a turbine. And they're inside cells. This is, you know, that we used to, in the
19th centuries, you were saying or alluding to it, the view was right after Darwin published
the origin, that the cell was a simple, homogeneous,
lobule of undifferentiated protoplasm.
That's a favorite quote of mine from Thomas Henry Huxley.
I like it because he was one of the great scientists in the 19th century,
and it now seems so ignorant to us.
Because as we've opened up the cell,
we found this exquisite realm of digital nanotechnology.
And if you look at these proteins,
they're made of multiple protein parts.
And if you have some, even a large set of those,
but not the totality of the parts, then you get no function.
Natural selection selects for functional advantage.
If the intermediate structures on the way to an eye or on the way to a flagellar motor or an ATP synthase
confer no function, then there's nothing there to be preserved and passed on by the process
of natural selection, and the evolutionary process will terminate before the system ever gets built.
So we do have a bit in the film about that.
It is a critique of biological evolution, but the film's much more concerned with the question of the origin of the first life itself.
How do you get life going? That's something Darwin never addressed.
Let's go back to third-year university on.
Yeah, sure. Okay.
It was a very strange thing for me because it became very clear to me that evolution by natural selection wasn't the only mode, right?
This is actually what my work became looking at alternate models of evolution because, again, it's like I still am.
perplexed in a way, unless we're really just talking about ideology, right?
And that's very cutting edge because that's where the field has gone.
People are saying we need a new theory.
There's got to be some other mechanism that provides the creative impulse or the creative
power that mutation and selection doesn't provide.
What did you find in your studies?
Well, no, so, I mean, I just, I had basically started.
I started a PhD, ended up finishing it as a master's.
my life got kind of thrown a massive curveball, if you will.
Sure, sure.
But no, I was looking at the hybridization between two species of lemur, actually.
Okay.
And just because I was curious, I had heard about this particular unusual situation
and this one reserve in Madagascar where it looked like two species were coming into one, right?
And I was just interested in, again, alternate models.
And I was like, oh, this looks exciting.
And I get to go to Madagascar.
I think there was a film about Madagascar with lots of lemurs.
Well, there was.
And in fact, in fact, nobody understood what I studied until that film.
Until the cartoon came out.
We needed to see the cartoon and then everybody knew.
Yeah, exactly.
But this is, you know, what I came to, right?
And I think when a lot of people say, I believe in evolution, right?
What they're saying is that human beings are meat,
or human beings are meat computers or something like that.
Right? Like it's just, we're not the product. There's no kind of, you know, divine inspiration here. There's no, we're not made in the, in the image of God, as certain faiths would describe Christianity notably and others. And there isn't that significance, you know.
Well, this gets back to that meaning of evolution. There are three basic meanings of evolution. One is that there's been change over time. And that can refer to small scale adaptation, like the Galapagos Finches or the Peppered Monies.
or it can refer to the idea that life on the planet now is different than it was a long time ago.
So if we look in the fossil record, we no longer have trilobites or triceratopses.
So the composition of life on the planet is different than it was as recorded in the fossil record a long time ago.
So that meaning of evolution, I think, is pretty much indisputable.
But then there's a second meaning of evolution that's the idea that there's been continuous change over time,
such that the best way to represent the history of life is a great branching tree, where the
base of the tree is represented by one or very few simple, presumably one-celled organisms,
and that we've had a kind of continuous and gradual morphing and changing of those very simple
forms into all the forms we see today, but everything is related by common ancestry.
That's a more controversial meaning, but then the most controversial meaning is the third meaning.
that, and that has to do with the action of mutation and natural selection, but not just
the idea that the process occurs, but rather that it occurs, it has sufficient creative
power to explain all of the change implied by that tree of life picture of the history
of life and also the appearance of design that living organisms manifest.
So a big part of the idea of Darwinism, of Darwinian evolution, was the idea that there is
this unguided, undirected process that can account for the appearance of design without
having, without the process having been designed or directed in any way. So it's inherently
materialistic. And that's where then it helps to underwrite a larger materialistic worldview.
Richard Dawkins has famously said Darwin made it possible to be an intellectually fulfilled
atheist. Well, why? Because you give an account of the appearance of design without there being a
designer. An undirected process is doing all the creative work.
There's this, you know, in preparation for this, we pulled a quote from Darwin,
from the origin of the species, you know, it's just appropriate even our discussion right now.
But if it could be demonstrated that any complex organ existed, which could not possibly
have been formed by numerous successive slight modifications, my theory would absolutely
break down. Yeah. Right? This is kind of in the sphere, in the context of the eye,
context of the molecular motors that we described.
And the creative power that you just described.
But let me, no, let's jump to something.
Can I comment on that briefly?
Just to clarify for your audience, because that's a quote that Michael Behe has highlighted
because it does establish a standard for the explanatory efficacy or sufficiency of Darwinian
theory that Darwin himself put forward.
And in the case of, if we look at the bacterial
leggeler motor that Michael Behe has made famous. It's got roughly 30 protein parts. It is a tiny
rotary engine that sits in the cell membrane of a bacterium. And it has a rotor, it has a stater,
it has u-joints and bushings. It has a long whip-like tail that functions like a propeller.
And if you have only some of those parts, but not all, say if you've got 26 or 25 or 24 or whatever it is,
the motor will not function.
So if you're trying to build a motor through natural selection and random variation,
you need to build that successively through a series, as Darwin is saying, a series of incremental
steps.
And as you add parts, presumably each, for that combination of parts to be preserved, the motor,
or that combination must confer some functional advantage on the organism.
The problem is if there's no, it comes when there's no functional advantage until
you have all of the parts or a core set of parts that are hard to reach to that gradual process.
And that's the mysterious part from a Darwinian point of view of all of these molecular machines.
They're multi-part, functionally integrated systems that require either all of the parts
or a very large core set of the parts to function at all, which means that the intermediate
steps would not be preserved and passed on, which again, it's natural selection only selects
for functional advantage.
advantage to get to a very complex endpoint, you're not going to be able to build it.
Let's talk about it.
So actually, again, speaking of the Biologos people, I think one of the most kind of compelling arguments for natural selection, right, being a major process, okay?
And I'm very curious how you just meant.
I think the Biologos people would point to this.
Basically, human and chimpanzee genetics are, you know, people say it's 98.
0.8% overlap.
That's kind of astonishing.
And then there's certain types of gene patterns
that people will point to.
The science has revealed, so people would say,
I think, that science has revealed, no, actually,
there is definitely a common ancestor.
And explain to me why the genetics are so similar, right?
Well, they're not.
Those numbers are dropping fairly precipitously.
But there's been, and the final number
when we compare gene sequences, I think is yet to be determined,
but it's dropping at least into the mid to low 90s
and probably going to go lower.
Okay, but there's a lot of similar,
there's a shocking amount of similarity
if there's no common ancestry.
There's a shocking, a lot of difference
between morphologically and behaviorally
between chimps and humans.
Clearly.
That cannot be accounted for by the two percent
of, the alleged small two percent of gene differences.
But there's a more interesting and more important study that's just come out in the journal gene.
And that is that the proteanome, the things that the genes make, the
ensemble of proteins that the genes make are in sequence comparisons running between 45 and
between only 45 and 65 percent similar.
And that tells us something very important.
How do you account for that?
Well, that the information processing systems in the two organisms are
are profoundly disparate, very different.
So the genes are functioning as,
the genetic information is functioning as essentially a library
that can put together proteins.
We also know that the same genes can be read
and concatenated differently to produce very different proteins.
And so what's, and this helps explain a longstanding mystery,
which is if our genetics are so similar,
then why are we behaviorally, morphologically, anatomically, so different?
And the answer is that the way that the information is processed,
the way it's expressed is very different in the two organisms.
And so if high degrees of similarity point to common ancestry,
what to very divergent modes of information processing point to, perhaps separate ancestry?
So I don't think this is all a closed question.
And I think we've kind of been given one little smidgen of what's really going on when we just analyzed the lowest level in the biological hierarchy and say, yeah, there's a lot of genes.
You know, for example, in both organisms, we have a gene for making hemoglobin.
Hemoglobin captures molecular oxygen in the blood.
There's really no reason for the gene for making that protein needs to be very different at all in the two organisms.
But to account for higher order anatomical structures and behavioral structures that are grossly different,
the genetic information is going to have to be expressed and processed very differently.
So the gene's function as a kind of library, and then there's something that's accessing the information.
You can pull this gene and this gene, you can put them together this way or this way,
or you might insert something else.
So the genetic text can be concatenated and aligned in different.
ways to produce completely different proteins for completely different biological functions.
So there's a great disparity in this information processing system between the two organisms,
and that's what accounts for the difference in the so-called proteanome.
And I think that's much more significant because it's telling us how an animal is actually
built is not just the bottom-up genes, it's how the genes are processed and expressed.
Something called a developmental gene regulatory network that we probably ought to talk about,
because it's one of the things that the mutation selection mechanism also can't explain.
It's a very important part of body plant development.
I think this question, right, of why would, for example, mammals, right, and with humans
and all be so much more similar genetically in terms of the code, right?
And then why would vertebrates be much more similar, right?
And then why would, you know, we have all this sort of, you know, classification of species.
And I remember Dennis telling me back in the day, because I think when he did that seminar,
third year three, that he was, I think he was pretty much a creationist at the time.
But he changed his mind and he changed his mind because he said, I looked at the genetic data.
And I saw these kinds of patterns.
And right, that's what made me think that there's sort of, you know, that there's more of a role of evolution by natural selection.
And it's not that he stopped being a Christian.
He very much stayed being a Christian,
but he thought it became a lot more compatible in his mind.
And that's indeed what he's been speaking about over years and so forth.
But how does that conceptually, how is that explained in your view?
Well, there's an assumption of genetic reductionism there.
The genes are the only thing that determines form.
The genes have information for making the small level,
small level protein parts.
But the proteins have to be arranged into biosynthetic pathways.
The pathways characterize different types of cells.
Different types of cells have to be arranged into different types of tissues and organs.
And different types of tissues have to be organized into different types of body plants.
And so the question of macro evolution is about the origin of new form, about the origin
of form at the higher level of body plans.
So the assumption that
that led to the conviction of common ancestry
on the basis of alleged high degrees of genetic similarity
overlooked the importance of all these other layers
of organization that have to be accounted for
in accounting for the origin of biological form.
And we now know that there are other layers,
there's information stored at higher levels beyond the genome.
And we know that there are processes that are at work
that are responsible for differentially expressing
that genetic information during the process of animal development.
And that's actually one of the, this is,
I would love to explain about something called
developmental gene regulatory networks.
Because genetic information alone will not make an animal, okay?
The genetic information has to be processed
and expressed in very specific ways.
And if I'll just say one thing is before you continue, right?
I mean, there is an explanation as to why things
that kind of are somewhat similar in form
would have similar genetic codes too, right?
because you need the similar types of proteins.
Well, exactly.
To do that kind of stuff.
The lower level parts, of course, are going to be very similar.
It's the way the lower level parts, the lower level protein parts and cells are organized into very different kinds of, we'll talk about animals for the present.
So something called a developmental gene regulatory network.
It's absolutely crucial to building a new form of animal, to building an animal form, an animal body,
plan. The idea is that as cells go through their division from you have a fertilized egg,
then it divides into two, and then it's four cells, and then into eight, 16, there's this
geometric expansion of the number of cells. And at different points along the way, different
parts of the genome are expressed to produce very specific proteins to service very specific
types of cells as they are differentiating one from another. So you have bone cells or nerve cells
or muscle cells and different types of proteins that are being being very specific types of cells.
built at just the right time so that those cells are being differentiated, say if it's a bone
cell from a muscle cell.
And what a developmental gene regulatory network does, what it is is a mapping of the genetic
information in the genome and the different gene products, the proteins and also something
called regulatory RNAs that regulate in turn.
So you have a gene, produces a regulatory RNA, and that regulatory RNA, will be a regulatory RNA,
will then either turn on or turn off other parts of the genome in different cells at just
the right time so that the right proteins are built in the right cell to allow for the differentiation
of cells as the animals developing. And this is all beautifully choreographed. Everything
turns on and off at just the right time. Now as scientists have mapped this, in particular
one scientist at Caltech with colleagues, scientists Eric Davidson, alas, passed away just a few years ago.
As they map this and the map the functional relationships involved, what they came back with
was something like a beautiful integrated circuit where you see all these if one to many
and many to one functional relationships.
But instead of being a circuit that is describing the flow of electricity, it's essentially
describing the flow of information and the way the information is controlling the animal development.
So that's just a fascinating piece of science.
It's just extraordinary.
Now, here's, but here's the rub here for macro evolutionary theory,
the idea that the mutation selection mechanism
can generate large-scale changes.
Changes sufficient to account for the change
of one body plan into another, where a body plan
is a unique organization of body parts and tissues.
Okay.
So what Davidson and colleagues found was that as you start
to alter, if you, by random means or otherwise,
you start to alter any of the core elements of these gene regulatory networks, the whole process
of animal development shuts down before you get to the termination point of a fully developed
animal form. But that creates a problem for evolutionary theory. Because if you want to change
body plan A, some animal form, maybe an arthropod of some kind, into body plan B, some other
kind of animal form, what we know is you've got to have a gene regulatory network, a new gene
regulatory network that's coordinating the expression of all that genetic information in a different way.
You can't get it little step by little step. You can't change it at all. I mean, very modest
changes are allowed, but very little. So if you can't change the body, the developmental gene
regulatory network into a fundamentally different one, you will never be able to change the body plan
into a fundamentally different one. So this creates a huge problem for the origin of animal body plans.
And the animal body plans arise abruptly in the fossil record we know.
I wrote a whole book about this called Darwin's Doubt, a book about what's called the Cambrian
explosion.
And so there are really profound mysteries.
Now, this is a problem not only for Neo-Darwinian evolutionary theory, but any theory of evolution,
because evolution is fundamentally about major change.
If you can't change the developmental gene regulatory networks in a significant way,
you will not be able to change body plants in a significant way.
So this is really a fundamental challenge to all forms of macroevolution.
And it underscores what we've been talking about
that the most important aspect of morphological development
and in turn evolutionary transformation
is not going to happen just at the genetic level.
It's going to happen at the level of the processing of that information.
and that's where things are highly constrained.
It's actually, if you think of, when you look at that, it's called the DGRN, a developmental gene
regulatory network, it looks like an integrated circuit, and it's also subject to the constraints
problem of engineering, and that is that more functionally integrated a system, the more
difficult it is to perturb any part of the system without defect to the whole.
And that applies to human integrated circuits.
It applies to this genetic integrated circuit that's responsible for body.
plan development. And if you can't change it much, you're not going to get a new body plan.
If you, you know, even with a watch, right, you take a part away, you add a part,
you think system stops working. That's right. That's right. I mean, why the hostility,
incredible hostility towards the idea that there's some kind of creative force? There seems to be this,
you know, deep disinterest
in exploring that there's some kind of creative force here.
Well, I don't think there's that much hostility
to the idea of a creative force,
more to the idea of a creative intelligence.
Well, okay, so yes.
And again, it doesn't have to be the Christian.
Thank you for correcting that.
Well, the creative force would put you more
in a pantheistic frame where maybe people
wouldn't be quite so hostile to that.
But we are the underlying ideology that has really governed
modern science since the late 19th century
is one of me.
materialism. There's a materialistic worldview that many scientists have in a sense bolted
onto science and said that science equals materialism, or more precisely, there's been a convention
that's arisen that says if you're going to explain something scientifically, you must explain it
by reference to strictly materialistic processes, matter and energy, natural processes,
no creative intelligence is allowed as a possible feature in your explanation.
So that and that itself is a kind of faith system we're talking about.
It's a presupposition, it's become a normative convention within science.
And it reflects an underlying commitment to not just a methodological convention, but to a metaphysical commitment in materialism.
And so now, and that's where I think my late friend Michael Ruse is
insight comes in, is that if evolutionary theory, if Neo-Darwinian or some other materialistic
evolutionary theory is being challenged, many people will sense in that a challenge not just
to the science that they hold, but also to the deeper worldview commitments or metaphysical commitments
that they have. And like all of us, if our deep metaphysical or religious beliefs are being challenged,
we can easily respond emotionally or less than objectively.
And so I think the debate gets very hot.
And I think less so in the last five or ten years,
I think there's a lot more acceptance that, first of all,
neo-Darwinism is not an adequate evolutionary theory.
We need a new one if we're going to operate within the framework
of materialistic evolutionary biology.
But an increasing number of scientists are now aligning
with our work on intelligent design.
They're using it to make new discoveries.
They think it's a useful framework for understanding life.
And there's a compelling argument for intelligent design
as part of the explanation for how things got here.
So great.
You've set up a very important question that I want to ask you.
You know, you come in.
You're someone that believes in God.
What should we, as viewers of the show,
or what should I understand about your suppositions
and how you came to research and,
believe what you do and explore this.
Yeah, sure.
It might be good just to define the theory, first of all.
The theory of intelligent design holds
that there are certain features of life and the universe
that are best explained as a product
of a designing intelligence, creative intelligence,
rather than a strictly undirected physical
or material process, such as in the biological realm,
natural selection acting on random mutations.
And the kinds of features we're talking about
are things like the digital code that's stored in the DNA molecule,
the complex information processing system
that not only takes that stored information
and processes and expresses it in the construction
of proteins and protein machines,
the presence of nanomachinery inside life,
certain patterns in the fossil record,
all these things are things that we think
would be our best explained because a creative intelligence
has played a role in the origin and history of life.
In the realm of physics, we have phenomena like the fine-tuning of the initial arrangement of matter and energy at the beginning of the universe,
and the fine-tuning of the laws and constants of physics.
The basic parameters of physics fall within very narrow ranges or tolerances, outside of which not only life, but even basic chemistry would be impossible.
Many physicists have come to the conclusion that that fine-tuning is the result of a fine-tuner, of a transcendent intelligence.
And if I may, you make that argument beautiful,
in the story of everything.
It's one of the three things we look at.
In the film, we look at the evidence for the beginning of the universe and with it the very
real possibility that we're looking at evidence of a creation event.
We also look at the discovery of the fine-tuning and we look at the interior of the cell
and the discoveries of the miniature machinery and the digital code that makes the proteins
that make the machines and make everything else inside living cells.
But as far as the theory of intelligent design, I attend a conference early in my scientific career.
I am working as a geophysicist for an oil company doing digital signal processing of seismic data.
It's an early form of information technology.
I attend a conference in which there is a very intense debate about the origin of the first life.
A new book has come out at the time called The Mystery of Life's Origin, and at the conference,
one of the leading chemical evolutionary theorists, someone who had formulated a very popular
theory about how the non-living chemicals in the so-called prebiotic soup or environment
had arranged themselves into the first living cells.
That scientist named Dean Kenyon at the conference repudiated his own work and said that he
thought it was time for the philosophers and the theologians to reopen what he called
the natural theological question, and that is.
is the idea of whether, the question of whether what we're seeing in nature is actually pointing
to the existence of a creative intelligence of a creator.
Okay.
And so you just told you and you're like, wow, that's interesting.
No, it was shocking.
It was a shocking sort of about face from a leading evolutionary biologist.
He worked on the theory of chemical evolution, how you get from chemistry to the first living
cells.
And both he and these other authors were intrigued with the idea that what we were looking at
was inside the cell was evidence of what they called an intelligent cause because the crucial
feature that had not been explained about the origin of life was the origin of the information
that was stored in the DNA molecule.
In 1953, Watson and Crick elucidate the structure of DNA as a double helix.
In 1958, Crick realizes that the chemical subunits along the spine of the DNA molecule are functioning
like alphabetic characters in a written text or like the digital characters in a section
in a machine code.
And so this puts the whole question of biological origins
in a completely different frame.
The scientists were able to fairly quickly
to figure out what the information on the DNA strand did,
where the information resides,
but the question of where it came from
has been unanswered from within an evolutionary framework.
And yet we know that information,
especially in a digital or alphabetic form,
always arises from a mind.
Bill Gates has said that DNA is like a software program,
but much more complex than any we've ever created.
Richard Dawkins has acknowledged it's like machine code.
Well, we know that computer code comes from a programmer,
and we know that whenever we see information
and we trace it back to its source,
whether we're talking about information in a book
or information in a hieroglyphic inscription
or information we're transmitting as we speak to each other,
information transmitted over a wire,
or always arises first in a mind, in an intelligence.
So the discovery of information,
of the foundation of life, I've argued, is a powerful indicator of the activity of a master programmer
or intelligence in the origin of life. And interestingly, the method of reasoning that I use
to come to that conclusion, it has a name, it's a scientific method, it's either called the method
of multiple competing hypotheses or the method of inference to the best explanation is the very
same method that Darwin used in the origin of species. We're using standard methods of
what are called historical scientific reasoning or forensic scientific reasoning to come to the
conclusion that intelligent design must have played an important causal role in the origin of life
as evolutionary biologists use in their own work. So we're not, there's no special pleading here.
It's not a special kind of science. We're using the same scientific methods, but we're just
coming to a different conclusion because we're taking the fact of information as a foundational
feature of living systems very seriously saying,
That has to be explained, and it has to be explained by reference to the same types of
causative processes that we see at work all around us.
We know that it takes a mind to generate information, so when we find it at the foundation
of life, the most logical thing to conclude is that a mind did, in fact, produce it.
One of the things that I've heard most often in people sort of dismissing intelligent design
as well, just say, oh, there's this amazing diversity, it's all fantastic, but you just want to
make it fit into this.
I love responding to arguments like that because they're transparently fallacious, right?
That's an argument from personal motivations.
It's a form of ad hominem argument.
That same accusation can be leveled at people who are developing Darwinian explanations.
As you've already pointed out, there's as a kind of religious fervor around this.
And I think the motivations of the proponents have to be set aside,
and we have to evaluate the arguments on the basis of the merit.
Because there is this fervor. This is my point. This is what we notice, right?
It can exist on both sides. Yes. Of course Christians would like to see evidence of a creator.
And yes, materialists would like to be able to explain things without reference to such a creator.
I mean, after all, it's Dawkins. It says that Darwin made it possible to be an intellectually fulfilled atheist.
And you can hear the sigh of relief in his voice as he says this.
In the film, we have a quote for him as saying that, where he says that, that, that, that,
that science has now emancipated us from the idea that design points to a designer.
Well, what's this idea of emancipation?
That sounds like you're looking for, so everybody has motivations, right?
The great thing about training in philosophy, and I'm a philosopher of science,
and it teaches you to say, okay, there are motivations, but let's set that aside.
Now let's evaluate the propositions, let's evaluate the evidence,
Let's evaluate the competing explanations and see which provide the best explanatory power.
And there's a key criterion of explanatory success that is part of the method of reasoning that I used to develop the case for intelligent design.
And it was the same method that Darwin used.
And it's the idea of causal adequacy.
If you want to explain something, you want to posit a cause which is known to produce the effect in question.
Charles Lylel, who was one of Darwin's mentors, the great geologist,
in his book Principles of Geology, there was a long subtitle.
It said, the changes on the earth's surface by reference to causes now in operation.
And the idea is that the explanation that's best is the one that's going to be,
that's positing a cause which is known to have the power to produce the effect in question.
And I came across this when I was thinking about whether or not there was the information,
in DNA that's inside the cell provided evidence for intelligent design.
Is there a scientific argument, a rigorous scientific argument that could be made to support
that conclusion?
And I asked myself the question, what is the cause now in operation that produces functional,
digital information?
And we know of one.
It's an intelligence.
One of the early scientists who applied the information sciences to analyzing
molecular biology, it was a man named Henry Quasler. And he was quoted as saying,
the creation of new information is habitually associated with conscious activity. That's what we
know from our uniform and repeated experience, which is the basis of all scientific knowledge.
It takes a mind, a conscious intelligence to generate information. And that's what we have
at the foundation of life. And that, by the way, is one of the key stories in the film.
The Watson and Crick discovery, the realization that we not only have a beautiful double helix molecule,
but inside the molecule is this information.
And then it's the question, where does that come from?
If you want to explain the origin of life, you've got to explain the origin of these large biomacromolecules
that make life work, especially the ones that are chock full of the information that build
all the important structures inside the cell.
Yeah, and just to be clear, we're talking about structured information, not like,
the information that a shotgun spatter?
Yeah, yeah, that's actually a very crucial distinction.
That there is in the field of engineering,
and there's a mathematical definition of information
that was formulated by really a great scientist in the late 1940s
named Claude Shannon.
And Shannon's idea of information is about,
essentially it's a measure of the improbability of a sequence
in an information carrying,
or the information carrying capacity or the improbability of a sequence in a channel of communication.
And the kind of information we're talking about in the DNA molecule or in a section of computer code or in a human language is that you...
Wildly improbable.
It's wildly improbable, but there's something else as well.
And that is that there's a specificity of arrangement of the characters that allow them to perform a communication function.
So you can have Shannon information without the sequence being functional or communicative.
It can be fun, you can have a sequence that's highly improbable that doesn't have any meaning in it
or that performs no communication function.
When Crick talked about the information in DNA, he was very careful to distinguish the kind of information
that was present in DNA from mere Shannon information.
He said, we're talking about the specificity of the sequence.
So it's the difference in a simple example that I use, well, we use in the film, is the difference between, you know, what the monkeys might type at the typewriter, which would have a calculable amount of Shannon information, but not be meaningful or functional, versus a line of poetry like time and tide, wait for no man.
The specificity of the arrangement of the characters gives that second symbol string something that's not present in the first, which is the ability to convey meaning or to perform a communication function.
and DNA performs the function of instructing the cellular machinery as to how to build the proteins and protein machines.
A good analogy that would, for younger audiences in particular, might be something like a 3D printer, a digital printer,
that we have digital information that produces a three-dimensional structure.
Or engineers would know about what's called CAD-CAM, computer-assistant design and engineering,
engineering where an engineer will sit at the console, write some code, it'll go down a wire,
it'll be translated into another machine code that can be read at a manufacturing apparatus,
and then that manufacturing apparatus, for example, if you're at the Boeing plant in Seattle,
where we are, might use that information to put rivets on the airplane wing at exactly the right
place. So you've got digital information producing a three-dimensional mechanical structure.
That's what's going on inside cells. That is the kind of technology that we have encountered.
in the interior of what used to be thought of a simple homogeneous globule of plasms.
So that, and to explain the origin of life, you've got to explain those complex interworkings,
and those inner workings, I think, scream design.
Yeah.
No, it's, I mean, it's fascinating.
We've really, as we've been talking here, we really covered, you know, a little bit more in-depth
or a lot, I mean, the substance of the interview has been about this, the third part,
which is the life aspect.
The biological part, right, as opposed to, like, you know,
kind of the origin itself, which everybody's now familiar with the Big Bang.
Yeah.
And, you know, but not the nuance.
I mean, again, fascinating.
I love, I also love the graphics that you've kind of created to sort of build the story.
The producers did a great job with that, with the production values.
There's 400 visual effects in the film.
There's gorgeous cinematography that takes you deep out into galactic space, and then the animations take people deep inside the cell.
where you can actually see these amazing processes.
And that's where I would really commend the film
because one picture, if one picture is worth a thousand words,
400 moving visual effects really are worth a lot more
than we can convey in an interview
because you see the evidence of design in front of you.
And I think that's what, for many people,
has given them an epiphany watching the film.
I mean, this has been quite some time,
time in the making for you. I mean, you've written quite a number of books that all point in
this direction, right? And now it's the story of everything. Everything. Well, it's a bit of a,
we admit it's a little bit pretentious title, but it's literally true. We're talking about the
universe, right? It's the story of where the universe came from, where it's finally tuned structure
came from, how that arose, and then how life arose within the universe. And those are the
three big questions we look at. And in each case, the scientific discoveries of the last 100
years and right up to the present are pointing in a very different direction than people thought
in the late 19th century, not towards the idea of a self-existing, self-creating, self-organizing
universe that can account for everything as a consequence of slow, gradual, undirected processes,
but rather something that bears the hallmarks of a mind.
Information is a hallmark of mind.
That kind of tight functional integration
that we see in circuits or in the eye.
If we find the kinds of features that we find in living systems
or in the fine-tuning of the universe,
in any other realm of experience,
we would immediately conclude that they were the product
of a creative intelligence.
And yet we're finding them in parts of nature
that we know we did not create.
So that implies that there was a creative intelligence that preceded us.
So what an amazing film you've put together.
Again, I want to encourage everyone to go see it.
And, you know, especially kind of this, another, one of the parts that we didn't talk at all about
is the kind of, you know, the unique set of variables that you call it the fine-tuning of the universe
to get the very specific elements.
This is something I almost knew nothing about.
And, you know, fascinating, compelling arguments you make in the film.
Yeah, a final thought as we finish up?
Well, I appreciated the deep dive that you've elicited on biology.
I forgot that you had such an extensive biology background,
so we talked quite a bit more about the question of biological evolution.
We went probably deeper on that here in the conversation that we do in the film.
In the film, we do quite a bit on the question of the origin of the first life.
And then the, I'll tell you what I like about the film, because it's an adaptation of my,
the third of my three books, the return of the God hypothesis.
And I think the producers did a fabulous job.
It weaves together a very compelling argument, and we've into that argument, stories of the
discoveries of these three different classes of evidence that we think have theistic implications,
the evidence that the universe had a beginning, that it was, as you say,
finely tuned from the beginning to make life possible, and then the discoveries about the inner
complexity and the informational complexity of the cell. But additionally, it tells some really
great stories. The stories of the scientists who have discovered those different things, but also
how those discoveries affected them at not just a scientific level, but at a deeper personal
level, how many of them shifted their overall worldview away from the strict materialism
that they had started with to something that was sympathetic to the idea that there was a
designing intelligence behind the universe.
Some even had full-blown religious conversions.
So we tell the stories of the scientists, and then the film is visually very beautiful
with the animations, the cinematography.
So for people who are believers in God, I think that's the...
I think this is one of those films you can bring friends to without feeling you're going to be embarrassed.
Just the opposite.
I think it will inspire some really great after-party discussions.
Absolutely.
You know, I do have one more question.
Yeah, sure.
And that is when you, as you're framing out, for example, these developmental pathways, the protein developmental pathways and so forth.
I was in the integrated circuit analogy.
I was thinking to myself, the people that believe that we believe that we, you know, we think,
we live in a simulation, this probably all makes a lot of sense to them.
So is that the, is this, is this still you're arguing?
We have a little nod to the simulation theory.
And the first thing to say about the simulation theory, which has become very popular
with a lot of tech people, is that that's a theory of intelligent design.
It implies that there was a master programmer.
But it also, it goes beyond that to suggest that somehow our reality is simulative of real reality,
that we're not really, there's something illusory.
about what we're experiencing.
And there I repaired to one of the classical arguments in philosophy from Descartes
where he also dealt with this idea that maybe we were the product of some kind of evil
demon that was deceiving us into thinking that we existed.
But then he argued, well, if we've been deceived into thinking we exist and we're thinking
conscious agents thinking that we exist, having this false thought, the very fact that we're
having thought and that we're consciously aware of something, even if it's allegedly
deceptive, means that we're actually alive and aware and therefore we do exist.
I think, therefore I am.
So I kind of think that this simulation idea, it's a way of talking about intelligent
design without going all the way to thinking about a God, but it does imply a master
programmer.
And I think the idea that our experience is in some way an illusion is itself
a self-defeating proposition.
So we refute it much more simply in the film
with David Berlinski saying something very dismissive
and quite funny about it.
So for people who are fans of Berlinski,
you'll definitely want to see that.
Well, Stephen Meyer, it's such a pleasure to have had you on.
It's been a great conversation, Yantan.
Thank you very much.
Thank you all for joining Stephen Meyer and me
on this episode of American Thought Leaders.
I'm your host, Yanya Kelek.
Has the universe always been here?
Is it finite?
Here is evidence for what can only be described as a supernatural event.
The universe, it bears everywhere the fingerprints of its creator.
Surprisingly, it is science that has revealed this.
We're dealing with a system of manifold complex design.
The concept of life is a cosmic phenomenon should have many consequences.
The question then was what does one do about it?
about it.