Transcriber: TED Translators admin
Reviewer: Ivana Korom I do want to test this question
we're all interested in: Does extinction have to be forever? I'm focused on two projects
I want to tell you about. One is the Thylacine Project, and I hope everybody knows
what a Thylacine is, by now. The other one is the Lazarus Project, and that's focused
on the gastric-brooding frog. And it would be a fair question to ask, why have we focused on these two animals? Well, point number one, each of them
represents a unique family of its own. We've lost a whole family. That's a big chunk
of the global genome gone. I'd like it back. The second reason
is that we killed these things. In the case of the thylacine, regrettably,
we shot every one that we saw. We slaughtered them. In the case of the gastric-brooding frog,
we may have "fungicided" it to death. There's a dreadful fungus
that's moving through the world that's called the chytrid fungus, and it's nailing frogs all over the world. We think that's probably
what got this frog, and humans are spreading this fungus. And this introduces
a very important ethical point, and I think you will have heard
this many times when this topic comes up. What I think is important is that, if it's clear
that we exterminated these species, then I think we not only
have a moral obligation to see what we can do about it, but I think we've got a moral imperative
to try to do something, if we can. OK. Let me talk to you
about the Lazarus Project. It's a frog. And you think, frog. Yeah, but this was not just any frog. Unlike a normal frog,
which lays its eggs in the water and goes away
and wishes its froglets well, this frog swallowed its fertilized eggs, swallowed them into the stomach,
where it should be having food, didn't digest the eggs,
and turned its stomach into a uterus. In the stomach, the eggs
went on to develop into tadpoles, and in the stomach, the tadpoles
went on to develop into frogs, and they grew in the stomach until eventually the poor old frog
was at risk of bursting apart. It has a little cough and a hiccup,
and out comes sprays of little frogs. Now, when biologists saw this,
they were agog. They thought, this is incredible. No animal, let alone a frog,
has been known to do this, to change one organ
in the body into another. And you can imagine the medical world
went nuts over this as well. If we could understand how that frog is managing
the way its tummy works, is there information here
that we need to understand or could usefully use to help ourselves? Now, I'm not suggesting we want
to raise our babies in our stomach, but I am suggesting it's possible we might want to manage
gastric secretion in the gut. And just as everybody
got excited about it, bang! It was extinct. I called up my friend, Professor Mike Tyler
in the University of Adelaide. He was the last person who had this frog,
a colony of these things, in his lab. And I said, "Mike, by any chance -"
This was 30 or 40 years ago. "By any chance had you kept
any frozen tissue of this frog?" And he thought about it, and he went to his deep freezer,
minus 20 degrees centigrade, and he poured through
everything in the freezer, and there in the bottom was a jar
and it contained tissues of these frogs. This was very exciting, but there was no reason
why we should expect that this would work, because this tissue
had not had any antifreeze put in it, cryoprotectants, to look after it
when it was frozen. And normally, when water freezes,
as you know, it expands, and the same thing happens in a cell. If you freeze tissues, the water expands,
damages or bursts the cell walls. Well, we looked at the tissue
under the microscope. It actually didn't look bad.
The cell walls looked intact. So we thought, let's give it a go. What we did is something called
somatic cell nuclear transplantation. We took the eggs
of a related species, a living frog, and we inactivated the nucleus of the egg. We used ultraviolet radiation to do that. And then we took the dead nucleus
from the dead tissue of the extinct frog and we inserted those nuclei
into that egg. Now, by rights, this is
kind of like a cloning project, like what produced Dolly, but it's actually very different, because Dolly was live sheep
into live sheep cells. That was a miracle, but it was workable. What we're trying to do is take
a dead nucleus from an extinct species and put it into a completely different
species and expect that to work. Well, we had no real reason
to expect it would, and we tried hundreds
and hundreds of these. And just last February,
the last time we did these trials, I saw a miracle starting to happen. What we found was
most of these eggs didn't work, but then suddenly,
one of them began to divide. That was so exciting. And then the egg divided again.
And then again. And pretty soon,
we had early-stage embryos with hundreds of cells forming those. We even DNA-tested some of these cells, and the DNA of the extinct frog
is in those cells. So we're very excited.
This is not a tadpole. It's not a frog. But it's a long way along the journey to producing, or bringing back,
an extinct species. And this is news. We haven't announced this publicly before. We're excited. We've got to get past this point. We now want this ball of cells
to start to gastrulate, to turn in so that it will produce
the other tissues. It'll go on and produce
a tadpole and then a frog. Watch this space. I think we're going to have
this frog hopping glad to be back in the world again. (Applause) Thank you. (Applause) We haven't done it yet,
but keep the applause ready. The second project I want to talk
to you about is the Thylacine Project. The thylacine looks a bit,
to most people, like a dog, or maybe like a tiger,
because it has stripes. But it's not related to any of those.
It's a marsupial. It raised its young in a pouch,
like a koala or a kangaroo would do, and it has a long history,
a long, fascinating history, that goes back 25 million years. But it's also a tragic history. The first one that we see occurs
in the ancient rain forests of Australia about 25 million years ago, and the National Geographic Society is helping us to explore
these fossil deposits. This is Riversleigh. In those fossil rocks
are some amazing animals. We found marsupial lions. We found carnivorous kangaroos. It's not what you usually
think about as a kangaroo, but these are meat-eating kangaroos. We found the biggest bird in the world, bigger than that thing
that was in Madagascar, and it too was a flesh eater. It was a giant, weird duck. And crocodiles were not behaving
at that time either. You think of crocodiles
as doing their ugly thing, sitting in a pool of water. These crocodiles
were actually out on the land and they were even climbing trees
and jumping on prey on the ground. We had, in Australia, drop crocs.
They really do exist. (Laughter) But what they were dropping on
was not only other weird animals but also thylacines. There were five different kinds
of thylacines in those ancient forests, and they ranged from great big ones
to middle-sized ones to one that was
about the size of a chihuahua. Paris Hilton would have been able to carry one of these things around
in a little handbag, until a drop croc landed on her. At any rate, it was a fascinating place, but unfortunately,
Australia didn't stay this way. Climate change has affected the world
for a long period of time, and gradually, the forests disappeared,
the country began to dry out, and the number of kinds
of thylacines began to decline, until by five million years ago, only one left. By 10,000 years ago,
they had disappeared from New Guinea, and unfortunately, by 4,000 years ago,
somebodies, we don't know who this was, introduced dingoes -
this is a very archaic kind of a dog - into Australia. And as you can see, dingoes are very similar
in their body form to thylacines. That similarity meant
they probably competed. They were eating the same kinds of foods. It's even possible that aborigines were
keeping some of these dingoes as pets, and therefore they may have had
an advantage in the battle for survival. All we know is, soon after
the dingoes were brought in, thylacines were extinct
in the Australian mainland, and after that they only
survived in Tasmania. Then, unfortunately, the next sad part of the thylacine story
is that Europeans arrived in 1788, and they brought with them
the things they valued, and that included sheep. They took one look
at the thylacine in Tasmania, and they thought, hang on,
this is not going to work. That guy is going to eat all our sheep. That was not what happened, actually. Wild dogs did eat a few of the sheep,
but the thylacine got a bad rap. But immediately, the government said,
that's it, let's get rid of them, and they paid people
to slaughter every one that they saw. By the early 1930s, 3,000 to 4,000 thylacines
had been murdered. It was a disaster,
and they were about to hit the wall. Have a look at this bit of film footage. It makes me very sad because,
while it's a fascinating animal, and it's amazing to think
that we had the technology to film it before it actually plunged off
that cliff of extinction, we didn't, unfortunately,
at this same time, have a molecule of concern
about the welfare for this species. These are photos of the last
surviving thylacine, Benjamin, who was in the Beaumaris Zoo in Hobart. To add insult to injury, having swept this species
nearly off the table, this animal, when it died of neglect - The keepers didn't let it
into the hutch on a cold night in Hobart. It died of exposure, and in the morning,
when they found the body of Benjamin, they still cared so little for this animal
that they threw the body in the dump. Does it have to stay this way? In 1990, I was in the Australian Museum. I was fascinated by thylacines. I've always been obsessed
with these animals. And I was studying skulls, trying to figure out their relationships
to other sorts of animals, and I saw this jar, and here, in the jar,
was a little girl thylacine pup, perhaps six months old. The guy who had found it
and killed the mother had pickled the pup,
and they pickled it in alcohol. I'm a paleontologist, but I still knew
alcohol was a DNA preservative. But this was 1990,
and I asked my geneticist friends, couldn't we think
about going into this pup and extracting DNA, if it's there, and then somewhere
down the line in the future, we'll use this DNA
to bring the thylacine back? The geneticists laughed.
But this was six years before Dolly. Cloning was science fiction. It had not happened. But then suddenly cloning did happen. And I thought, when I became
director of the Australian Museum, I'm going to give this a go. I put a team together. We went into that pup
to see what was in it, and we did find thylacine DNA. It was a eureka moment.
We were very excited. Unfortunately, we also found
a lot of human DNA. Every old curator
who'd been in that museum had seen this wonderful specimen, put their hand in the jar,
pulled it out and thought, "Wow, look at that,"
plop, dropped it back in the jar, contaminating this specimen. And that was a worry. If the goal here was to get the DNA out and use the DNA down the track
to try to bring a thylacine back, what we didn't want happening when the information
was shoved into the machine and the wheel turned around
and the lights flashed, was to have a wizened old horrible curator
pop out the other end of the machine. It would've kept the curator very happy,
but it wasn't going to keep us happy. So we went back to these specimens
and we started digging around, and particularly,
we looked into the teeth of skulls, hard parts where humans
had not been able to get their fingers, and we found much better quality DNA. We found nuclear mitochondrial genes. It's there. So we got it. OK. What could we do with this stuff? Well, George Church,
in his book, "Regenesis," has mentioned many of the techniques
that are rapidly advancing to work with fragmented DNA. We would hope that we'll be able
to get that DNA back into a viable form, and then, much like we've done
with the Lazarus Project, get that stuff into an egg
of a host species. It has to be a different species.
What could it be? Why couldn't it be a Tasmanian devil? They're related, distantly, to thylacines. And then the Tasmanian devil is going
to pop a thylacine out the south end. Critics of this project say, hang on. Thylacine, Tasmanian devil?
That's going to hurt. No, it's not. These are marsupials. They give birth to babies
that are the size of a jelly bean. That Tasmanian devil's
not even going to know it gave birth. It is, shortly, going to think it's got the ugliest
Tasmanian devil baby in the world, so maybe it'll need some help
to keep it going. Andrew Pask and his colleagues
have demonstrated this might not be a waste of time. And it's sort of in the future,
we haven't got there yet, but it's the kind of thing
we want to think about. They took some of this same
pickled thylacine DNA and they spliced it into a mouse genome, but they put a tag on it so that anything
that this thylacine DNA produced would appear blue-green in the mouse baby. In other words, if thylacine tissues
were being produced by the thylacine DNA, it would be able to be recognized. When the baby popped up,
it was filled with blue-green tissues. And that tells us if we can get
that genome back together, get it into a live cell, it's going to produce thylacine stuff. Is this a risk? You've taken the bits of one animal and you've mixed them into the cell
of a different kind of an animal. Are we going to get a Frankenstein?
Some kind of weird hybrid chimera? And the answer is no. If the only nuclear DNA that goes
into this hybrid cell is thylacine DNA, that's the only thing that can pop out
the other end of the devil. OK, if we can do this,
could we put it back? This is a key question for everybody. Does it have to stay in a laboratory,
or could we put it back where it belongs? Could we put it back in the throne
of the king of beasts in Tasmania, restore that ecosystem? Or has Tasmania changed so much
that that's no longer possible? I've been to Tasmania. I've been to many of the areas
where the thylacines were common. I've even spoken to people,
like Peter Carter here, who when I spoke to him, was 90 years old, but in 1926, this man
and his father and his brother caught thylacines. They trapped them. And when I spoke to this man,
I was looking in his eyes and thinking, "Behind those eyes is a brain that has
memories of what thylacines feel like, what they smelled like,
what they sounded like." He led them around on a rope. He has personal experiences that I would give my left leg
to have in my head. We'd all love to have
this sort of thing happen. Anyway, I asked Peter, by any chance, could he take us back
to where he caught those thylacines. My interest was in whether
the environment had changed. He thought hard. It was nearly 80 years
before this that he'd been at this hut. At any rate, he led us
down this bush track, and there, right where he remembered, was the hut, and tears came into his eyes. He looked at the hut. We went inside. There were the wooden boards
on the sides of the hut where he and his father
and his brother had slept at night. And he told me, as it all
was flooding back in memories. He said, "I remember
the thylacines going around the hut wondering what was inside," and he said they made sounds
like "Yip! Yip! Yip!" All of these are parts of his life
and what he remembers. And the key question for me
was to ask Peter, has it changed? And he said no. The southern beech forests
surrounded his hut just like it was
when he was there in 1926. The grasslands were sweeping away. That's classic thylacine habitat. And the animals in those areas
were the same that were there when the thylacine was around. So could we put it back? Yes. Is that all we would do?
And this is an interesting question. Sometimes you might
be able to put it back, but is that the safest way
to make sure it never goes extinct again? And I don't think so. I think gradually, as we see species
all around the world, it's kind of a mantra that wildlife
is increasingly not safe in the wild. We'd love to think it is,
but we know it isn't. We need other parallel
strategies coming online. And this one interests me. Some of the thylacines
that were being turned in to zoos, sanctuaries, even at the museums, had collar marks on the neck. They were being kept as pets, and we know a lot
of bush tales and memories of people who had them as pets, and they say they were
wonderful, friendly. This particular one came in out of the forest to lick this boy and curled up around
the fireplace to go to sleep. A wild animal. And I'd like to ask the question.
We need to think about this. If it had not been illegal
to keep these thylacines as pets then, would the thylacine be extinct now? And I'm positive it wouldn't. We need to think
about this in today's world. Could it be that getting animals
close to us so that we value them, maybe they won't go extinct? And this is such a critical issue for us because if we don't do that, we're going to watch more of these animals
plunge off the precipice. As far as I'm concerned, this is why we're trying to do
these kinds of de-extinction projects. We are trying to restore
that balance of nature that we have upset. Thank you. (Applause)