In 1887, a scientist in Germany announced
the discovery of a fossil animal that was
totally new to science.
The thing was clearly a turtle.
I mean, it had a shell, with a flat plastron
on the bottom that was fused to a carapace
on top — so it had all the requirements
for what makes an official turtle.
But this was not only a whole new genus and
species of turtle, it was also the oldest
turtle that had ever been found at the time.
And this discovery ended up spawning a debate
over turtles that would last for more than
a century.
Like, where did turtles come from?
What lineage gave rise to these weird reptiles
with beaks for mouths and retractable necks?
And … how did the turtle get its shell?
Well, I don’t want to spoil it for ya, but
the answers would eventually cause scientists
to rethink the entire history of reptile evolution.
The German turtle that started all this was
called Proganochelys, which means “early
shell,” and it lived about 210 million years
ago, in the late Triassic Period.
At about a meter long, it was pretty big — about
half the length of the largest species alive
today.
But unlike modern turtles, Proganochelys hadn’t
yet developed the ability to retract its head
under its shell.
The fact that its shell was found intact was
really helpful, because that made it easy
to identify this animal as a true turtle.
But at the same time, it left a lot of open
questions about how that shell evolved, and
why it resembled modern turtles in some ways,
but not in others.
So the discovery of this creature kicked off
a debate about which major taxonomic group,
or clade, of reptiles that turtles belonged
to.
Now, most reptiles fall under the clade known
as eureptilia, or “true reptiles.”
This includes stuff like lizards, snakes,
dinosaurs, and birds.
But there’s also, parareptilia, or “side
reptiles.”
These are some of the earliest reptiles, all
of which are now extinct — like the spiky-cheeked
procolophonids and the mesosaurs, which were
probably the first aquatic reptiles.
Now, by and large, which clade you put turtles
in, depends on where you think its shell came
from.
Starting in the late 19th century, most paleontologists
thought that turtles belonged in the clade
we now call parareptilia, because they shared
the same basic skull structure with other
parareptiles.
And by the late 1940s, this theory became
even more specific, suggesting that turtles
were related to a particular group of extinct
parareptiles called pareiasaurs.
These are sometimes called the “ugliest
reptiles,” but we don't judge here
Bradysaurus, for example, lived around 260
million years ago, in the Permian Period,
and it was covered in a layer of hardened
scutes.
Likewise, a later pareiasaur called Anthodon
had more developed bony plates that formed
a layer of armor a lot like a turtle’s shell.
So it’s not too hard to see why a lot of
paleontologists thought that pareiasaurs were
closely related to turtles — and were maybe
even their direct ancestors.
The idea was that over time, the scutes found
in pareiasaurs could have fused into a solid
protective layer, eventually combining with
the ribs to form a shell.
But, you know how scientists are!
No one likes a good, rigorous, centuries-long
argument more than they do!
Enter the developmental biologists -- they
study how living things grow throughout the
course of their lives.
Starting in the late 1920s, some of these
biologists studied the embryonic growth of
modern turtles.
They found that, as turtles develop, bones
that basically function as a set of lower
ribs widen and fuse, forming the plastron.
Then another set of bones up top, which are
the “normal” ribs, do the same, widening
and fusing to form the carapace.
So these scientists proposed that turtle evolution
took a similar path, with widened ribs forming
first, and the shell later.
By the 1990s, the idea had really taken off.
Keep in mind, this was basically the opposite
of what the paleontologists were proposing
— that the shell on top evolved from scutes
that fused together before combining with
the ribs below.
And if the developmental biologists were right,
turtles wouldn’t be parareptiles; they’d
be much more similar to eureptiles.
So, both sides had some evidence to support
their cases.
But it was hard to resolve the debate without
more, and older, fossils.
Then, in 2008, researchers found one in China.
It was shaped a lot like a turtle, but it
only had the bottom part of the shell —
the plastron.
And it didn’t have a carapace
It was a shell-less turtle!
They called it Odontochelys, and it dated
to about 220 million years ago — around
10 million years before Proganochelys from
Germany.
The fact that it had a plastron without a
carapace was pretty strong evidence for the
developmental biologists’ hypothesis, that
the plastron evolved first.
But there was more.
Unlike all other known turtles, Odontochelys
had … teeth.
Its name actually means “toothed turtle.”
And those teeth looked nothing like pareiasaur
teeth.
Pareiasaurs had teeth with lots of little
cusps on them, like human molars.
But this turtle’s teeth were more like pegs.
So it looked like this ancient turtle didn’t
belong in the parareptile group.
It was a eureptile.
Eventually, this would be supported by several
other genetic studies done in the last few
decades, that compared the turtle genome with
that of other reptiles, and placed turtles
in a subgroup of eureptilia.
But while all that was going on, more species
got added to the turtle family tree.
In 2010, the discovery of Odontochelys led
researchers to reexamine another ancient species,
called Eunotosaurus.
It lived about 260 million years ago in Africa
-- long before Proganochelys, and the previously
found Odontochelys
The first fossil of this species was originally
found back in 1892, but most experts at the
time didn’t think it was a turtle ancestor,
because it didn’t have a shell.
But it did have wide, flat ribs.
And modern paleontologists noticed that it
bore more than a passing resemblance to Odontochelys.
Finally, in 2015, researchers discovered yet
another early turtle in Germany, which they
called Pappochelys, or “grandfather turtle.”
It lived about 240 million years ago, and
it had wide ribs, with a set of bones below
them that were partially fused — but not
to the point that they formed a plastron.
So old grandpa turtle seemed to mark a kind
of transitional stage between Eunotosaurus,
with its wider ribs, and Odontochelys, with
its full plastron.
Together, these discoveries helped fill out
the timeline of turtle evolution, and it became
clear that the first step in the evolution
of turtle shells was the formation of wider
ribs.
But there was still the question of why.
Why did turtles acquire these weirdly wide
ribs in the first place?
What purpose did they serve?
And why did they eventually develop into shells?
Well, in 2016, paleontologists again took
a closer look at Eunotosaurus -- which is
now considered the oldest of the turtle ancestors
-- and noticed something funny about it.
Most of us think of turtles as being adapted
for life in the water, with webbed feet or
flippers.
But Eunotosaurus seemed to have a lot of adaptations
for burrowing through dirt.
Its head was shaped basically like a shovel.
Its front legs were stronger than its rear
legs, and it had giant claws that would have
been great for digging.
So, the evidence pointed to life as a burrower.
And this could help explain
why it had those wide ribs ... and where turtle
shells came from.
Researchers proposed that wider ribs would’ve
been useful as an anchor when Eunotosaurus
Eunotosaurus was digging with its front legs
Wider ribs provide a more stabilized trunk,
which would have made it easier for the turtle
to keep its body in one place while it was
digging.
Other burrowing animals, like anteaters, have
similar adaptations.
Problem is, having wide ribs with such short
legs makes it awfully hard to walk.
Or at least, walk quickly.
In fact, the reason that turtles are so famously
slow is that their giant ribs make it hard
for them to swing their little legs forward.
So, ancestral turtles needed extra-wide ribs
for digging, but that also slowed them down.
Now they needed more protection.
And that’s when the ribs started to fuse
into a plastron, which eventually became a
full, protective shell.
Over time, the evolutionary purpose of the
turtle’s shell changed, from digging to
protection, and turtles as we know them became
a thing.
Of course, none of this is fully resolved.
In theory, it makes sense for wider ribs to
have evolved for digging, but right now that’s
just based on what we’ve seen in one species.
We still need a lot more evidence.
Turtles’ exact place among the eureptiles
isn’t settled either.
A lot of researchers think they’re more
closely related to a clade that includes animals
like crocodiles and birds.
But others argue that they’re closer to
a different group that includes lizards and
snakes.
Hopefully it won’t take another 130 years,
for an answer to that debate.
But either way, we now know that, on the tree
of life, the turtles’ branch isn’t turtles
all the way down.
It’s stacked with a diverse array of reptilian
characters, some of which have no shells,
others of which have partial shells, and others
still who sport the full, beautiful shells
and famously slow gaits that we know today.
Thanks for joining me!
And as always, I want to know what you want
to learn about!
So leave me a note in the comments below!
And be sure to go to youtube.com/eons and
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And if you’re interested in where things
came from, then you should definitely check
out The Origin of Everything, it's a show that
explores the social origins of our everyday
lives, like why we get letter grades in school,
and why the heart is a symbol of love.
Think of it as the Eons for understanding
modern society.
And you don’t have to go through millions
of years of history to learn the answers!
