When I look at my fellow humans, I see ghosts of animals past. Glimpses of an epic story that's hidden inside us all. My name's Neil Shubin. As a scientist, I look at human bodies different from most people.
The way we grip with our hands. We can thank our primate ancestors for that. How we hear so many sounds.
That dates back to creatures the size of a shrimp. And the further back we go... The stranger it gets.
To reveal why we look the way we do, we'll travel through the distant reaches of our family tree. And meet an unusual cast of characters. The ancestors that shaped your body. The family you never knew you had.
From the badlands of Ethiopia... She's beautiful. To the shores of Nova Scotia... This is the spot.
We'll search for clues that lie buried in rock. His eyes are like gloves. And he's like, I found it, I found it. And search for answers written in our DNA. I think it gives us a glimpse into the brain of our ancestors.
I mean, I find that mind blowing. The adventure begins with a search for some of our most elusive relatives. Fish that crawled onto land hundreds of millions of years ago. From our necks and lungs to our limbs and hands, we owe a lot to these intrepid pioneers.
I really want to see why you're built the way you are. It's time to meet your inner fish. Look at that. Yeah. He's going right up the valley.
The Canadian Arctic is one of the most desolate regions of the planet. But there's nowhere else I'd rather spend the summer. What draws me here is treasure. My kind of treasure. Fossils hidden inside ancient rocks.
In particular, the fossils of long dead fish. But not just any old fish. I'm hunting for fish that carry the story of our own bodies inside of them. How I got here and what I found could change the way you think about yourself and your body.
This is a story that ends on top of the world with the most important discovery of my life. In the city of Chicago, with a room full of human cadavers. It was more than a decade ago, and I just moved to the University of Chicago as Chairman of the Anatomy Department. And I remember, you know, hanging around with the students around the tables here, just getting to know them and letting them get to know me.
They're launching their careers as future physicians, and there's some nerves and skittishness those first few days. almost invariably ask, Dr. Shubin, what kind of doctor are you? You know, are you a surgeon? Are you a cardiologist?
And I'd say, well, no, I'm a fish paleontologist. And I'd give this look like, what? I want my money back.
But it soon became clear that being a paleontologist, and not just any paleontologist, a fish paleontologist, is a very powerful way to teach human anatomy. Because often some of the best roadmaps to our own body ...are seen in other creatures. Not think your body has much in common with a fish, but I see a family resemblance.
On the surface you're not very fish-like, I'll admit. are related to them and the clues to that connection are etched in ancient stone. Fossils unearthed around the world reveal that fish are the first creatures with bony skeletons.
They have backbones and skulls, just like you and me. This shared anatomy connects us to fish and to a long line of other animals. To see what I mean, imagine the complete history of life on a giant family tree, from the first microscopic organisms billions of years ago to all animals alive today.
Our history lies on one branch of this tree of life. And we can trace our ancestry back. Around 400 million years ago, you'll find fish swimming in oceans and streams.
40 million years later, the first amphibians appear on land. Then we see reptiles, followed by the first mammals around 200 million years ago. And much later, we arrive at our special branch, primates.
This history tells us something remarkable. Every reptile, bird and mammal alive today is descended from ancient fish. And that includes us. So how does this legacy play out in our anatomy? Each one of us walking around in this lab today carries the history of life within us.
And the evidence is seen in every part of our bodies. And not just in our bones. Even the complex tangle of nerves inside the human head makes much more sense when you realize it's the same basic wiring found in fish. But there's one defining piece of human anatomy that seems remote from the world of fish.
And I vividly remember when it first captured my imagination. When I walked into the anatomy lab for the first time, I was sort of scared about what I was going to see, what I was going to feel. But the reality is, after the first few weeks, that fear turns into a sort of a cocky self-confidence. And these things, you know, when you dissect them, it doesn't look very human. like a wax model in a lot of ways but then you hit the hand and for me as I unwrapped the gauze and revealed the palm the fingers the fingernails something else hit me entirely and that was a deep sense of connection a connection to another human body lying on that slab this was not a wax model that I was dissecting this formerly was a person who lived a life just like I am living now I see the anatomy within the human hand.
I'm in awe of the intricate connections between bone, tendon, and muscle. Really it's through the action of these muscles through the tendons that the hand does its, you know, it does its magic if you will. So that when the muscles fire it pulls on these tendons and watch.
The fingers flex. Now, the fine muscles of our hand, these little tiny muscles that lie along the tendons, these are the muscles that control the fine motion of our fingers. These are the ones that are quintessentially primate and human. So where did this marvel of evolution come from? It clearly has deep roots in the past.
And you can see evidence of that in the bones of modern creatures. More than 150 years ago, scientists were finding connections between the hands and limbs of four-legged animals. Sir Richardsons Owen was an anatomist in the 19th century.
He was fortunate to be an anatomist in an age of discovery. And so people were coming back to London with new and oddball creatures for him to analyze. And in analyzing all the different creatures, he found common patterns. Although the overall shape and structure of each limb was very different, he started to see that there was an underlying theme.
It was as if the same set of bones was being squashed or extended to perform different functions. Here's a dog. Dogs, you know, run and jump.
What do you have? One bone, two bones, little bones, and then the digits, the equivalents of the fingers or toes. And, of course, here's a bird. Its limb has been modified into a wing, and it has one bone, two bones, lots of bones, and then digits. The amazing fact is, in each of these creatures, the skeletal architecture is largely the same as ours.
And what was utterly surprising is that the skeleton of every animal walking the earth today has this fundamental pattern of... One bone, two bones, little bones, fingers. Owen didn't know why creatures had that pattern. It was a mystery to him. It really took a new insight, an insight from Charles Darwin, which basically said the reason why animals have this common pattern.
is because at some time in the distant past, they all shared a common ancestor that had a version of this pattern too. According to Darwin, we should be able to trace the evolution of our limbs and hands by going back in time down our family tree. Starting with our primate ancestors, we see hands and limbs that look very similar to our own.
We go back a bit further to the first mammals, and we find deeper similarities in the paws. And we see how paws emerged from more distant relatives. And if we go back even further, we reach our most distant four-legged ancestors.
These animals, the earliest tetrapods, were among the first to have Owen's one bone, two bones, lots of bones pattern. But when we enter the underwater around 400 million years ago, Instead of animals with limbs, we find prehistoric fish with fins. And that brings us to a great mystery of biology.
How did we get from fish with fins to animals with arms and legs? Darwin boldly predicted that there must have been ancient animals, transitional forms, that bridged this gap. But what would such an animal look like? Would it have limbs? Or fins?
Or both? Such a creature reflects a critical step in the origin of the human hand. I set out to find one. I started my search back in the early 90s when I worked in Philadelphia.
I knew that finding this transitional fish was going to be a tall proposition. And the first question was, where to look? The world's a big place. The Earth is a giant planet.
And fossils are very small, so how do you find those things? Well, there's a checklist we run through. We look for places in the world that have rocks of the right age. If you're interested in the origin of dinosaurs, there's one age of rock to look at.
If you're interested in the origin of transitional creatures between water and land, there's another age of rock. Then you look for places in the world that have rocks of the right type, the kinds of rocks that are likely to hold fossils. We knew from previous discoveries that rocks from the Devonian era, around 360 million years old, were likely to contain early tetrapod fossils. And it turned out we had rocks of that age right here in Pennsylvania. To look for good sites, I teamed up with geologist Red Deschler, and we've been fossil hunting buddies ever since.
You know what, we've tried it through here, even going down into West Virginia. We are sort of maybe an odd couple. Neil is excitable and enthusiastic, which is wonderful. I'm enthusiastic as well, but I think maybe not quite as vociferous. I might tend to hunker down more and focus on recovering the material as we start to find it.
And Neil might be a little bit more, okay, what's over the next horizon? What's over the next hill? Neil is on that edge, always thinking about the new place to go.
Red and I would sit in the car with maps in one hand and geological papers in the other, and we'd tootle through these state roads, looking at the rock, saying, okay, what kind of rock is this again? What kind of age is it? But the problem in Pennsylvania is it's not a desert. The bedrock is not exposed to the surface.
You have forests, you have grass. Turns out the best exposures of rock in the state were made for us by the Pennsylvania Department of Transportation. because they would dynamite. They'd expose sections of the geological record. And we eventually hit this one road cut, giant exposure.
It's called Red Hill. It probably is. Oh, my God.
And then we knew, okay, this is the place to hit. We had ambitions to explore the globe, but our first expedition didn't take us to an exotic desert halfway around the world. It happened by the side of a Pennsylvania highway.
Had revisited Redhill one time when I was not there. He made a phone call to me. He says, I knew.
I think I found something really important. I said, what did you find? He said, I think I found a tetrapod.
I said, Red, are you kidding? I mean, no, you're not going to find a tetrapod on your second or third trip to Red Hill. This is going to take years of work.
So I... moving along this layer and saw a beautiful little fossil bone material chipped around it a little bit right right on this layer and lo and behold uncovered what turned out to be a very significant specimen This is the shoulder girdle of an early limbed animal. It was a new species. It was a whole new kind of animal. And although we only have a shoulder girdle, it's actually a very informative part of the skeleton.
It would be on the left side. The skull would go off in that direction. And the animal itself would be about a meter long.
And just from the shoulder girdle, we can learn things about how it may have held on to the animal. How it may have held on to the animal. that limb.
And of course it does compare to other animals that are similar from other parts of the world and we can use those to learn other aspects of Hynerpeton. These early four-legged animals belong to a group I like to call the Stegas. Some of the best specimens have been found in Greenland by a paleontologist named Jenny Clack, who began working there in the 80s.
The idea of transition between animals with fins and animals with limbs has been thought about for a long time. But until recently, there had only been three data points. something that was obviously a fish at one end, something that was obviously an animal with legs and walking around at the other end, and in the middle was this very peculiar thing called ichthyostega.
Using the latest scanning techniques to build a 3D model of ichthyostega, Jenny's trying to get a better sense of how this creature lived. She's working with animal motion expert Stephanie Pierce at London's Royal Veterinary College. Basically what we wanted to see was how much movement was possible at each of the limb joints and how this compared to modern animals. They compared Ichthyostega to modern tetrapods, like salamanders, to figure out how this fossil might have moved. Using pressure pads and high-speed cameras, they could measure how the limbs of modern animals work and compare this to the bones of Ichthyostega.
Ichthyostega's forelimbs could push the top half of the body off the ground, but the back end has got these paddle-like hind limbs which... are useful in water for swimming with, but on land act as stabilizers to stop the thing toppling over. The anatomy of the bones suggested that this four-legged animal had just come onto land. It was right at the edge of our search. But between these tetrapods and ancient fish, there is still a gap spanning millions of years.
If we could find an animal within that gap, we'd be filling in a crucial piece of evolutionary history. So now there was a new challenge. Where on earth should we look next? I remember sitting in the office, and we were doing this sort of usual banter one day about something geological.
We had a college textbook. And you just thumb it. through the diagrams in the book, and boom, there was this figure that changed our lives.
It was a map of North America, which highlighted three areas of Devonian rock of just the right type to hold fossil fish moving onto land. There were our Red Hill rocks in Pennsylvania. Been there, done that, worked on those very rocks. Then there were rocks in Greenland, which Jenny Clack had already searched. But it was that little...
Finally, there was this strip across northern Canada, and these rocks... were 10 million years older. I remember seeing that and saying to myself, holy cow, this is what we're looking for.
My heart was racing when I saw that, because no paleontologist had worked on that, expressly looking for early tetrapods. Then you dug out the arid... photos and that's when I got kind of terrified. I remember seeing this for the first time thinking you got to be kidding me. You know look at all this snow how do you work there?
Alright so 1, 2, 3, 4, 5, 6, 7, 8. Okay 2-6 is clear. Back in 1999, when we embarked on our first Arctic adventure, we had little idea what we were in for, nor that we were starting a search that would last for over a decade. Wow, that is a lot of stuff.
Here in the high arctic of Canada there are no human settlements for miles and miles No roads and all you've got is what you bring with you Here there's always the risk of being trapped by some of the worst weather on the planet. We're entering the valley now. Oh, there she is.
I'm looking right at the quarry. We had a narrow window during the month of July when the snow melts just long enough to let us in. We were trained fossil hunters, but now we would have to figure out how to become arctic explorers.
So when the helicopter drops you off in the Arctic for the first time, you're standing here saying, what am I doing here? You know, you're thinking, oh, polar bears. That's the first thing you look for. Is there anything on the landscape?
Everything white becomes a polar bear. The last thing on your mind are fossils. It's hard to believe when you look out across this frozen terrain that once this was a warm, watery world, swimming with life.
Here we are in the Arctic and we have a snowstorm coming and we're looking at rocks behind us, but there's this huge disconnect between the present and the past. What we see today is a valley with red and green rocks that are tilted, stacked one on top of the other. But that's not how it was in the past. These valleys have been carved by glaciers that have moved back and forth. And those red and green rocks actually at one point...
extended across the valley. And they were straight, they weren't tilted. Now look inside the rocks and what those rocks tell us, that this valley 375 million years ago was a giant flood plain.
And that flood plain was filled with rivers that swelled their banks and sometimes shrunk. But in those conditions formed swamps and streams of all different sizes. And inside those streams was diverse life.
Somewhere out there, we were hoping to find an intrepid fish on the brink of the historic transition to life on land. Could we ever find evidence of this momentous event buried in sediments that have been crushed and distorted by 375 million years of geological upheaval? When you think about everything that has to go right for a creature to be first a fossil and then a creature's fossil to be discovered by a paleontologist is like finding a needle in the haystack. We were determined to find that needle, if it was out there.
Back in Chicago, I had another way of tracing the anatomy we share with fish, using a different kind of window into our evolutionary history. I wasn't looking for fossils in the summers. I'd spend my time looking under a microscope at embryos.
And I was watching, at the time, bodies forming from egg to adult. And there's an incredible beauty to that process. In the early stages of development, all animals start as a single cell. They divide again and again until gradually a body emerges, with a front, a back, a top, and a bottom. It became very clear early on in the process some of the most important embryos were fish.
Because fish have the basic body plan in their embryos that was to become our own bodies. If you see an early fish embryo and a human embryo side by side, you'll see something remarkable. They look almost identical.
We really do look like fish. Both embryos have a head, a body, a tail, and many other similar features. And one of those similarities exists in the neck, or what's called the pharyngeal area. In both fish and people, what you find are a series of swellings called gill arches.
It turns out that in fish, those swellings become components of the gill apparatus. People, they become portions of our lower jaw, portions of our middle ear, part of our voice box. So this is a wonderfully elegant developmental process, but sometimes things go wrong. And when they do, your inner fish can come out.
So my kids are really good friends with the Richardsonssons. One day, I get an email from Seth, their father, who says, Doctor, my wife's a fish. And I said to myself, I gotta check this one out. We're here for the fish.
The fish is available, it's fresh. Come right through, I think if you go towards the back. Oh, we'll cut through it, yeah.
Hey Seth, is this your family album? Yes, exactly. So you're a fish. Now first off, if you are, and you're more of a fish than I am, I'm very jealous.
What? So prove it. Alright. But here it is. There's my gill.
Right there. So what happens during development is we all have gill arches. We all develop them. This little pit is a leftover from an ancient gill. And I am incredibly jealous of you, Molly, because you are more of a fish than I am.
We're all fish, but some are more fish than others. That's right. Some just haven't. involved very far. No, you're the lucky ones.
So what's really cool is when you know paleontology and developmental biology, many of the muscles and nerves and bones I'm using to talk to you with right now and many of the muscles and nerves and bones you're using to hear me with right now correspond to gill structures and fish. You know we see that in fossils, we see that in embryos, we see that in DNA, I mean and we see that in you. My brother-in-law's webbed feet. I love your family, by the way.
While features like fish gills have been retooled in their anatomy, other body parts perform the same job but end up in different places. Like testicles. Well, we're here to see some gun ads. Okay. Fish.
Oh. I'll just dissect this little guy here. Exactly. Yeah, if you could pop that bad boy, that would be...
Sure. It'll come right out of there. Yeah, so there you see, there's the heart, there's the liver, you know. The gonad is right there.
So you know what's funky about these things? Is the gonad is towards the chest, right near the heart. You know, but what's stunning is you and I, like every other mammal, you know, our gonad started up. and descend down to here. It might be better where they were.
No. Well, in some senses they would. Having gonads close to the heart is fine for our cold-blooded fishy relatives, not so good for warm-blooded mammals. Sperm can't stand the heat. So that's why our testicles have to drop to a cooler place, outside the body.
When a human embryo develops, the gonads start deep in the body just like they do in fish. and then descend through the body wall, mirroring evolution. But that creates a weak spot in males where our guts can pop through. This leaves us vulnerable to certain kinds of hernias.
And you think about why. humans have hernias it's because our testes descend right they start up here they go down into the scrotum and the body walls is it gets weaker because of that reconfiguration yeah and so you know we'll find you know we'll find that you have a weakness in the body wall in some cases folks get hernias that's why fish don't get hernias that's why fish don't get hernias. Flaws in the human body like our susceptibility to hernias remind us that we're all adapted from ancient ancestors we are every one of us just a jerry-rigged fish.
In July 2000, we were back in the Arctic for a second season, continuing the search for our elusive fossil. Now we've actually found float bone down to this level, so let's just stay close. We widened our explorations across the region, but we were finding hardly anything, let alone the transitional fossil of our dreams.
Then, just before we began to pull out, we were suddenly confronted with the real dangers of working in this wilderness. The team had separated into several different groups. We usually go out in pairs because it's a dangerous place. One pair went down the valley, another one up the valley, and we spread apart for the day.
2626, this is Bird Fjord. This is Bird Fjord, over. We all return to camp at the end of the day, and the idea is everybody needs to return back to camp by radio call at 7 o'clock when we make our safety check back to the station. And so we're making dinner and we're waiting for the radio call and, you know, come over here, and I was like, Hey, you guys see Jason?
No, I see Jason, you see Jason. I said, I asked you that question, you didn't see Jason. And all of a sudden it became, nobody saw Jason. Where's Jason?
This is our youngest member. We were looking out for him the entire season and no Jason. I mean, my heart was really beginning to race. I hear footsteps outside the tent. The tent fly opens and there's Jason.
His eyes are like globes. And he's like, I found it, I found it. Jason, why did you fly?
You find a polar bear? What? I mean, every pocket was burgeoning with bones.
He goes, I got these bones. He's laying them out on the table one after another. It's daylight 24 hours a day.
So we ran down to Jason's site and began that night to crawl it, looking for the layer that was kicking out the bones. As soon as we came to this bluff here and looked down, we saw why Jason was so excited. Because beneath our feet were fossil fish bones, fragments of fossil fish, many of them, thousands of them.
It wasn't just one fish, it was a whole aquarium. It was different species. It got better, because as we walked up the hill and we followed that carpet of fossil fragments, it stopped, meaning it likely came from one layer.
And if we had any luck at all, we'd find that layer and see what's inside. It took several weeks, but we eventually located the layer of rock from which the fossil fragments were spilling, and then looked for telltale signs of bones protruding, in the hope it might lead us to more complete specimens. You can see this tiniest little white fleck here.
That told us stop, you know, because that little white fleck shows the structure of a scale. And then you look carefully and it's clearly a scale on end. Once you see that scale on end, you see another piece of bone here, you see another piece of bone here. We're on the layer itself, so it's a matter of stop.
Now what we're going to do is remove this ice and rubble to expose the layer as a little plastic. To reach the buried fossils we'd need to mine the rock face, but we were running out of time. Alright, let's get that rock out of there.
Once again, our short window of snow-free weather ended. Now, are you guys looking for that flight tomorrow or were you guys delaying it until the 4th? We're about three away.
Okay, roger that. We'd have to wait another summer to dig out our ancient riverbed. A very different kind of scientific adventure was unfolding.
A revolution was underway in evolutionary biology. One that would reveal a profound genetic connection between fins and limbs. My lab would play a role in the search, but we were part of a much bigger effort. At the forefront of this quest was my colleague Cliff Tabin, a geneticist at Harvard University. Cliff had been focusing on how digits, like fingers, form.
And in his work, he relied on chick embryos. Chicken eggs offer a window into the process of development. If you take a chick egg and cut a hole in the shell and throw it away, you can see the embryo floating on top of the yolk. It's right there, it's accessible. You can start to probe what's important for it to form by removing little bits and saying, does that disrupt the process?
Or by moving tissue from one place to another and saying, what does that do? Cliff was following a long line of scientists using chickens to investigate how limbs develop. In the 1950s, John Saunders was one such scientist. Saunders and his team experimented on chicken embryos just a few days old.
They focused on little protrusions called limb buds from which the wings would eventually emerge. In one experiment, Saunders took a small patch of cells from one side of a bud and transplanted it to the opposite side to see what would happen. When he came back a week later, much to his surprise, he found that the chick embryo had grown a second set of digits, one a mirror image of the other.
That tiny patch of cells was clearly special. Somehow, it was telling the digits where to form. The way that we now think of it is that those cells instruct the rest of the limb by making a long-range signal, a beacon that they send out that the other cells see and respond to.
The identity of that signal was a great mystery that went unsolved for decades. But Cliff had a hunch. He and some colleagues suspected that this signal might be a single molecule that came from a single gene.
He based his suspicions on research that was changing how we understand the role of genes in making body parts. It was work that had been done on an entirely different animal. It's a tiny little creature that's really small, that breeds very rapidly, and that you can study in the laboratory. And it's this, the humble little fruit fly.
By studying how fruit flies develop, scientists have made some amazing discoveries. Individual genes can do complex things, like guiding the formation of entire body parts. There was one gene, dubbed Hedgehog, that caught Cliff's attention.
It stood out because it seemed to send out an organizing signal. In a fly, this signal, Hedgehog, told different cells to do things in a particular order depending on how close they were to the source of the signal. I wondered if a gene like Hedgehog might play a similar role in chickens.
So his team took the fly Hedgehog gene and looked for a match in the chicken. After months of searching, they found it. Then, remarkably, they discovered the gene was active in exactly the same patch of cells identified by Saunders.
They dubbed this new gene Sonic Hedgehog, after the video game character. So did Sonic Hedgehog produce the mysterious signal everyone wanted to find? Ultimately, we wanted to know whether this gene that we discovered, Sonic Hedgehog, really is the key signal for making the array of digits in the hand.
In a groundbreaking experiment, Cliff and his team added a bead containing pure sonic hedgehog to the wrong side of the growing limb bud, echoing Saunders'experiments. When he returned a week later, he found his chick had two sets of digits just like Saunders'chick. This was a major discovery.
Sonic Hedgehog, a single gene, was the source of the signal responsible for generating the pattern of the digits. And that really nails it. It really meant that we had the linchpin in our hands and could start looking at how that process worked in detail. It turns out Sonic Hedgehog shapes not just the wings of chickens, but the paws of mice and other animals, and even our own hands.
If you want to see just how important Sonic Hedgehog is to us, meet the Hubbard family. Can I count your fingers? Let me see.
I can count. I went to school too. One, two, three, four, five, six.
And six is special. Look at that hand. Kamani was born with an extra digit on each hand and foot. Grab me. Squeeze my finger as hard as you can.
Let me see your grip. No, harder than that. You can go way harder than that.
Oh! Oh! Oh! Why this happens had long been a mystery. It turns out that people like Kamani often have mutations that alter the effect of their sonic hedgehog gene.
With the condition of Kamani, I just want to know what's allowing him to be so different. The way our arms and legs originally develop in the womb is they push out from the body as a little bud. So we have four little buds sticking out of us as we're little embryos. Then those buds grow out, and eventually they grow out and they elongate. What you have is a paddle, a big broad paddle.
Just as in the chicken limb, Sonic Hedgehog sends out a signal to shape the pattern of our digits. When it's strong, a pinky forms. And as it weakens, one by one, different fingers are made until we end up with five. If we turn down Sonic Hedgehog, fewer fingers are made. But if we were to increase the effect...
of Sonic Hedgehog, we would get extra fingers like Kamani's. It is really quite beautiful that something as simple as a single signal moving through the limb could have such profound and differential effects on the digits. We now knew that Sonic Hedgehog played a powerful role in shaping the limbs of all sorts of four-legged animals.
So how far back did it go? Could it be a legacy passed down from the earliest fish? Back in my lab, that was a question my postdoc, Randy Don, was tackling. Randy was investigating an ancient type of fish, skates, whose embryos grow in a sack called a mermaid's purse. I guess the thing that struck me the most when I first opened a skate egg was how shockingly similar that embryo looks to a chicken embryo, a mouse embryo, a human embryo, as an embryo.
I should have understood, of course, they're going to look similar. But still, when you see that, you're thinking, there's 400 million years of evolution that separates me from that embryo. And at one stage in my life, that was exactly what I looked like. It's clear we have a shared genetic history with fish.
But do the genes that shape our hands also shape these skate fins? To find out, Randy manipulated the skate embryos like Cliff had done with the chick embryos. He put a bead containing the Sonic Hedgehog molecule on the opposite side of a growing fin bud. And it turns out that Sonic Hedgehog was sufficient... ...to cause a mirror image duplication, a second fin to form in the scape.
This is exactly what Sonic Hedgehog had done in Cliff's chickens. We were absolutely stunned, and you have to remember that this is a skate embryo, and what that tells us is that these very basic patterning mechanisms are performing the exact same functions in the skate, in the shark, in the chicken, in the mouse, all the way up to humans. It traced Sonic Hedgehog all the way back to life in ancient oceans. A gene that determines the shape of our hands was also shaping the fins of some of our most distant fish relatives. Our inner fish runs deep.
There was still a big mystery to solve. How did our fish ancestors make the transition onto land? And what did they look like?
We were still looking for our elusive fossil, frozen forever on the brink of this great transition. Each summer we returned to Jason's ancient riverbed to continue excavating. We needed to move lots of rock to expose the narrow seam containing the fossils.
But then we'd switch to brushes and dental picks to uncover the delicate fossilized bone. This is an incredibly funny paradox. You know, we're in this huge landscape.
And we're always cramped together, you know. My head's next to Red's feet. Mark's head's next to my feet.
It's this tiny little spot. It was in such a tiny corner of this vast landscape that we finally struck gold. Well, it was the second week of July in 2004. We're all working in series in this hall. And Steve says, hey, guys, what's this? Running over what we saw.
There was this V here, it was covered with rock, and as soon as we saw this V and we saw these teeth under it, it became very clear that this little V we're seeing is the tip of a snout, and that this was a snout of a flat-headed fish. We stopped in our tracks. A flat head was a likely sign of a transitional fish.
Here was the snout of exactly the creature we were looking for, and it was sticking out of the rock. So if we had any luck whatsoever, the rest of the creature would be, you know, encased in the rock. So we dug all the way around the fossil, leaving a chunk of rock that we then encased in plaster. We couldn't wait to see what was inside. Okay, we get home.
We knew we had a flat-headed fish, but how much of it did we have? Well, then the preparators had to take over. They removed the plaster jackets, and the first thing they did was to etuate the rock, exposing the front part of the snout.
Then about a month and a half goes by, and they start to find the orbits, the eye holes. And then we see the shoulder, and then we see the fins, and then we see more and more and more and more until we see pretty much the entire top side of the body. What's really wonderful about this specimen is that we have the head connected to a body, and the body is connected to the fins. So we know that this fin comes from this animal, and we know its size and how it fits together. Later, we found parts of other specimens, and some of these were really big, up to nine feet long.
The local Inuit people named our fossil Tiktaalik, which means large freshwater fish. And as we took stock of our discovery, the real excitement began. Here was an animal Darwin had predicted, a real anatomical mixture.
It had some features of fish, like scales and fins and gills. It also had lungs for breathing air. And, to our astonishment, it had a neck, the earliest one like ours ever found. But inside the fins lie the clincher.
We see an early version of Owen's one-bone, two-bones, lots-of-bones pattern that we see in our own limbs today. It even had a kind of wrist, the first signs of a link to the human hand. Every time you flex your wrist or shake your head, you can thank Tiktaalik and its Devonian cousins adapting to life in these ancient streams.
Another fish, Tiktaalik could use its neck to watch out for predators and to hunt smaller prey. Because those fins were strong enough to lift its body out of the water, a whole new frontier opened. Over millions of years, the two pairs of fins in fish like Tiktaalik would lead to the two pairs of limbs in every bony animal on Earth.
It's a powerful legacy we can see in our own arms and legs today. Well, to think about Tiktaalik, think about this. Think about a push-up. What are we doing when we do a push-up?
We're using the muscles that attach to our chest, that attach to the underside of our arm to give us the power to raise up. We use our elbows and we use flexion at the wrist, which is very important because it allows our palm to contact the ground. Here's the fin of Tiktaalik.
And what does it have? It has a massive surface for connection of muscles that would attach the shoulder to the underside of the upper arm. It has evidence of a highly mobile elbow.
elbow, and it even has a wrist that can flex so that the equivalent of the palm can contact the ground. Here's a fish that can do a push-up. I remember looking at the wrist of Tiktaalik for the first time, and at that moment I felt akin to what I felt in the anatomy lab when I saw the cadaver and its hand. The hand actually defines us in many ways. When you think about what makes our species unique and special, it's having thoughts and being able to make those thoughts real.
And the way our thoughts become real is through use of our hands to build things, to make things. Yet the basic form of this wonderfully complex, quintessentially human piece of anatomy can be traced back to the fins of ancient fish. It's an incredible evolutionary story that we can now unravel.
When Tiktaalik was first conceived, like every animal that has ever lived, it started as a single cell, which slowly formed into a body. Small buds appeared. And genes like Sonic Hedgehog shaped them into fins. For millions of years, fins like these evolved into a myriad of forms.
Like the limb of this early amphibian with eight fingers. As millions more years passed, new variations emerged. From the clawed limbs of reptiles that would colonize dry land, to the powerful arms of primates that could traverse through the trees, until eventually, a remarkable piece of anatomy arose that would itself transform the world. The human hand. This history is not just in our bone, flesh, and muscle.
It's in our DNA. And that's what connects us all the way back to our inner fish. Fundamental portions of our own bodies originally came about in fish living in water.
And the great transition from life in water to life in land set the stage for a whole new set of anatomical inventions that were themselves the form of the core for our own humanity.