Moonshots with Peter Diamandis - Why This Billionaire Is Bringing Back the Dire Wolf, Woolly Mammoth & More w/ Ben Lamm & Salim Ismail | EP #165
Episode Date: April 17, 2025In this episode, Ben, Salim, and Peter discuss the Dire Wolf breakthrough, which animals Colossal will be bringing back from extinction, and setting the record straight. Recorded on April 15th, 202...5 Views are my own thoughts; not Financial, Medical, or Legal Advice. Ben Lamm is a serial entrepreneur and the co-founder and CEO of Colossal Biosciences, a company leading the de-extinction movement through advanced gene-editing technologies, recently valued at over $10 B. He previously founded several successful tech ventures, including Chaotic Moon Studios, Conversable, and Hypergiant Industries, with a focus on AI, biotechnology, and space. Salim Ismail is a serial entrepreneur and technology strategist well known for his expertise in Exponential organizations. He is the Founding Executive Director of Singularity University and the founder and chairman of ExO Works and OpenExO. Learn more about Colossal Biosciences: https://colossal.com/ Join Salim's upcoming workshop on building an Exponential Organization: https://openexo.com Twitter: https://twitter.com/salimismail For free access to the Abundance Summit Summary click https://bit.ly/Diamandisbreakthroughs ____________ I only endorse products and services I personally use. To see what they are, please support this podcast by checking out our sponsors: Get started with Fountain Life and become the CEO of your health: https://fountainlife.com/peter/ AI-powered precision diagnosis you NEED for a healthy gut: https://www.viome.com/peter Get 15% off OneSkin with the code PETER at https://www.oneskin.co/ #oneskinpod _____________ I send weekly emails with the latest insights and trends on today’s and tomorrow’s exponential technologies. Stay ahead of the curve, and sign up now: Tech Blog _____________ Connect With Peter: Twitter Instagram Youtube Moonshots Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
The howl of a dire wolf hasn't been heard on planet Earth for more than 10,000 years.
13,000 years after the last dire wolf walked the Earth, scientists say they've now brought them back.
Ben, I have to say you pulled off what I think is the scientific miracle of the decade.
What's your roadmap here, pal?
So we're working on the man with, we're working on the Tasmanian tiger, we're working on the dodo.
I think we could save every species on the planet.
Save every species on the planet, that's pretty extraordinary.
Alright, so the extinction 101, and remember I'm not a scientist, I'm really curious and
I feel like I like to ask questions.
I don't know anything about it, so I can ask, you know, childlike questions about it and
then I get these answers.
One of the spin outs I can't wait for you to talk about
is the idea of artificial wounds.
I think that if we continue on the current course
and speed by the end of 2026,
we will have the world's first mammal birth fully ex utero.
This provides a bridge to future developments like this
that will break open all sorts of potential.
What's the next species that we can look forward to?
Um.
Now that's the moonshot, ladies and gentlemen.
Everybody, welcome to Moonshots.
I'm here with two incredible entrepreneurs
and two dear friends,
Salim Ismail, head of exponential organizations
who you all know and love,
and Ben Lam, the
founder, CEO of Colossal Biosciences.
Colossal has been all over the news around the world, one of the top stories in April,
the cover of Time Magazine.
And Ben, I have to say, you pulled off what I think is the scientific miracle of the decade.
You know, seeing Elon capture the super heavy booster on Starship was sort of the technological miracle,
but bringing back the Dire Wolf.
And so what I put out a blog yesterday because I was really pissed off about this. You know, this incredible achievement of bringing back to the planet Earth after over 10,000 years of extinction,
three direwolf pups, and a lot of people said amazing, but there were way too many people saying,
is this real? Is this crazy? What is this guy doing?
And to those haters out there, listen to this episode because I think this is an extraordinary
achievement that heralds a future of synthetic biology that's going to blow our minds as
much as AI is blowing our minds today.
So Ben, how are you feeling about this? What was all this controversy about?
Well, I feel great.
I've got weird tough skin, right?
I think that if anyone thought they were going to go into the de-extinction world,
which involves conservation, synthetic biology, AI,
there's actually about 31 different ways to classify an animal. involves conservation, synthetic biology, AI.
There's actually about 31 different ways to classify an animal.
You're dabbling into an area where a lot of people have a lot of opinions on a lot of
different topics.
I think that it would have been really naive to think that you're going to go into something
like this and not have a lot of skepticism
and a lot of negative feedback from the start.
And then you're gonna,
it's only gonna get worse as you're successful, right?
It doesn't go the other way.
And so we've talked about this for a long time is like,
what happens when we actually start
to show the world animals?
What, how does that feel?
But I feel fantastic.
The team feels fantastic
I think the only and I'll talk about the controversy the only thing that I think is a little
Sad in my mind. I think you nailed it in your blog post
Is it people miss the science like people miss the bad?
I'm sure we'll go to go into it today, but it's like and I look I'm not a scientist
Oh, it doesn't affect me. Like I sleep fine at night. But you know, we have these incredible women and men that
have spent the last, you know, 18 months, seven days a week, passionately in love with
bringing back the dire wolf. And whether you want to classify it as a dire wolf or colossal
dire wolf, or genetically modified gray wolf, whatever you want to do, which we'll get into that
conversation at some point. That doesn't matter. The fact
that they took 72,000 year old DNA from a skull in 13,000 year
old DNA from a tooth, mapped it and built a nearly complete
dire wolf genome, which before this, there was only 0.15% coverage of the
genome, to go to nearly complete genome and to then select the genes that drove the core
phenotypes of a direwolf, engineer it into a gray wolf cell, which for many don't know
this, it is the closest living relative. It's not the closest relative. It's the closest living relative on the planet, which is a non-model
species by the way. No one's ever done this. And then to clone that, where you have a healthy
birth of animals that exude phenotypes or physical attributes that are driven by genes
that have been lost for 12,000 years, it's magic.
It's a miracle. by genes that have been lost for 12,000 years, it's magic.
And I feel like-
It's a miracle.
It's a miracle.
And people just like,
and not to mention just the genome engineering, right?
So on our mouse, we announced the one mouse
a couple of months ago,
and we had eight edits in seven genes.
And we did it all at once using multiplex editing,
meaning we did it all at once,
100% delivery, 100% efficiency, zero off-target effects.
That's a miracle.
And yet we did get feedback on that.
There's like, people have made eight edits before,
but yeah, they made them sequentially
over eight generations.
And so to go from eight edits to 20 edits,
now using 15 of those edits being ancient DNA variants,
it's awesome.
And so the only thing that I was sad about
is I don't really
care what people call it, right?
I'm not asking people to go to our website or watch our
videos, I don't really care.
But I think it's sad for the scientists that at a minimum,
I think people could have elevated the incredible work
by the women and men at Colossal
and our academic contributors to the project.
Yeah. Salim, what question comes
and pops out at you? I mean, you saw the press going back and forth. I did, and I read your
blog post, but I thought that was phenomenally detailed. I've been tracking this for a while.
You know, we first talked about this at Singularity University, and the way we used to frame it was,
and this was going back 10, 15, 10, 12 years ago, was we essentially can
now navigate conservation in a completely different way, in a totally different mindset.
And there's some magic that comes from that.
So I've got a hundred questions, including as a company, your business model.
My biggest question though is how?
Because a lot of people have tried this in the past and I'd love for you to give our viewers a sense of how you went about
this because this provides a bridge to future developments like this that will break open
all sorts of potential. And I'd love for you to give some sense of the methodology used
on it.
Let me inject one thing here which is really important that this idea of de-extinction is not
just four years old right so Ben you co-founded with George Church who's the
scientific genius at Harvard Medical School a dear friend of both of ours I
dear say a very very close friend of yours at this point but he's been
dreaming about it for many years,
and it's been discussed for decades,
and it hasn't happened.
It's just now, in the last four years,
that the tech exists.
But I would say there's another thing that exists right now,
and for those moonshot entrepreneurs out there,
I want you to hear this,
it's the difference that a CEO can make, the difference that a moonshot CEO can make in
taking something from theory and making it real.
And Ben, of course, you've got multiple PhDs in biology and CRISPR and gene editing, right?
I mean, your background is-
I have no background in biology whatsoever. I know, that's the key I have no background in biology whatsoever.
I know, that's the key point.
No background in biology, but just a passion.
So if you could, let's bridge this into two parts.
Number one, what attributes do you have that enabled you to do this?
And number two, what was the tech that enabled this, you know, the dire wolf to come back
and will enable a multitude of other species?
We'll talk about those.
Everybody, I hope you're enjoying this episode.
You know, earlier this year, I was joined on stage at the 2025 Abundance Summit by a
rock star group of entrepreneurs, CEOs, investors focused on the vision and future for AGI, humanoid robotics, longevity, blockchain,
basically the next trillion dollar opportunities.
If you weren't at the Abundance Summit, it's not too late.
You can watch the entire Abundance Summit online by going to exponentialmastery.com.
That's exponentialmastery.com.
So fundamentally, I think that there's two things that if you're going to pursue a moonshotty
like approach to a project, there's two things that you have to remember.
One is entrepreneurship.
It's a team sport.
Like it is, it is a team sport.
You know, everyone's got to play their role.
Everyone's got to play it well.
A lot of times, you know, one or two people get the glory or the negativity. But it is a team sport, right?
Like you mentioned, I don't have a background in biology, so I have to trust our science teams
to be able to do what they do and I just have to empower them. And then the second thing is,
I think you have to be a little more persistent than time. And I think you have to think about
things in just knowing that like, you know,
whether you have a great day or a bad day, everyone talks about like the trough of disillusionment
and all these things. I think those things fundamentally don't matter. I think that if
you're doing a moonshot, you just have to be looking like I think about Colossal 50
years from now. I don't think about the Dire Wolf watch. Like people were like, oh my gosh, like, just to go go through a little bit of PTSD, because I think years from now. I don't think about the Dire Wolf launch. People were like, oh my gosh,
just to go through a little bit of PTSD,
because I think it's important.
I don't think anybody knows this.
I have yet to say this, but let me,
and then we'll get into the science that Salim asked,
but I do think this is important.
Day one, on Monday of last week,
and I think you could make a fun 24 hour,
or like a five day story
about this and just what happened last week. So we were not supposed to launch until Tuesday.
We launched on Monday because we went to a couple of, because the science is so detailed.
And if you just look at a press release without like the scientific papers, without all the
data, without sitting
down with the scientists, you could just say, oh, it's not a dire wolf, right?
I could easily have people get to that conclusion very easily.
But I think that what we did, which I thought was smart, was we went and spent hundreds
of hours with Time Magazine and with The New Yorker and with Rolling Stone and with a couple
of key outlets
and brought them completely unfold. We actually moved the wolves to a secure location and let
them see the wolves because we live in an AI generated world. Like who's not to say someone
couldn't just generate something, right? Like not that we did, we would never do that. But I mean,
but that's the level that we put into that. You know, we're certified by American Humane Society.
We flew the wolves on private jets.
We literally brought in American Humane Society.
We had, I mean, we had 15 personnel with them at all times.
We waited until they got acclimated to this new location.
Just think of it as so we spent a lot of time and thought into this, right?
Well then we're supposed to launch on Tuesday.
And so on Monday, we had all these people
that have covered us over the years.
We were gonna give them the heads up.
We actually did, had a scientific paper
and we had nine handouts, nine handouts
and an 11 page press release.
So we had a lot of material.
We were gonna give it to all these people under embargo.
So they didn't feel left out,
even though we went really deep with these other people
and we said, we think this is a story that's gonna persist.
So we did that.
Monday morning, I'm getting in the shower,
kissed my nine month old son,
say, oh, I'm gonna go get ready for work,
kiss him goodbye, about to get in the shower,
looked at my phone, it's the cover of the New Yorker.
New Yorker broke the embargo.
So that happened, and website's not live, the hundreds of press So that happened and websites not live,
the hundreds of press people that we worked with for years,
for years, that have covered us pretty favorably
when we didn't even have animals feel betrayed.
People are like, you know, Time Magazine's calling,
being like, you're on the cover of Time.
Like, what did you do?
Did you do this?
It's insane.
Wow.
So I'm in my car speeding to one of our labs
as fast as possible.
And it's like websites going live,
people on Twitter are like,
there's Laura Mipsum on the website.
And we're like, no shit,
the website wasn't supposed to be live.
It's like, we had about two hours of content for YouTube that explains all the making up. We were gonna roll out. We were just like, to be live. It's like we had about two hours of content for YouTube
that explains all the making of, we were gonna roll out.
We were just like, push everything live.
So that was Monday.
And then all those stories that we talked about
came out and they're all super positive,
but no one got to digest the scientific paper
didn't get submitted to bio archive.
There was just all this stuff.
So then Tuesday was, wait, oh, by the way, Monday,
we're gonna talk to all our scientific advisors,
give them an update on the project,
because we're worried that it could leak,
because it was just so cool.
Our scientific advisors started calling us,
being like, why didn't you tell us about that?
Like, it was an insane ripple effect.
Best laid plans.
No, no, it didn't, wait, wait, let me just give you,
I know, I know we've limited time,
but you have to know how crazy it was.
Yeah.
Then on Tuesday- They broke the embargo, that's really, really, really, that's nasty.
It gets way worse. It gets way worse. Then, so I called up Revive and Restore, who's an
incredible nonprofit. You know, I love Ryan and I love Stewart. They actually, to your point,
Peter, have been talking about De-Extinction for a long time, but they're a nonprofit, right? It's
like, this takes hundreds of millions of dollars
in systems theory modeling to actually achieve this, right?
You can't just do it with a non-profit.
And so I said, hey, just so you know,
I was going to call you today
to tell you about what's coming tomorrow,
but this just happened, and I will tell you,
we did meet with the Department of Interior,
and they're excited about classifying de-extinction
as a form of conservation, and the feedback was overwhelming classifying de-extinction as a form
of conservation.
And the feedback was overwhelming.
They're like, we've been trying to do this for 10 years.
Oh my gosh, this is huge.
That's Monday.
Well, then Tuesday, we get this academic backlash, which is, you know, no one cares about two
things.
The science, which blew my mind, and as I mentioned, I thought it was a travesty.
And no one cared about the fact that while we made three dire wolves, and yes they're dire wolves,
there were four red wolves that we cloned
using a new non-invasive cloning technique,
which I'm sure we'll talk about with you, Selim, in a second,
but we developed a new technique to clone
that's less invasive for animals.
We made four red wolves,
which are the most critically endangered wolves
on the planet.
There's only 15 left in the wild.
Wow. No one covered that either. Right. And then it became a philosophical and semantic
debate on what makes a species. But what's interesting is there's about 30, I thought
there's 11, there's about 31 ways to classify species in all these different ways. Right.
And so by many ways, a polar bear and a brown bear should not are considered the same species, but they
have a different species name and they look completely different phylogenetically. So
there's all these different reasons or different ways to do this. And so that became the discussion.
So then we're like, like fighting fire and just kind of like, not really trying to explain
ourselves, but just saying like, educating people, like not trying to persuade, but just
educating like, there's actually a lot trying to persuade, but just educating,
like, there's actually a lot of ways to do all this. So that was
Tuesday. And then Wednesday, and then by the way, conservation
community is super stoked about, you know, at least new tools
and conservation. So I was like, Okay, well, it's a win, whatever.
So then Wednesday, there's a cabinet meeting, which obviously
we're not a part of the presidential like like the US
cabinet, US cabinet, there's a cabinet meeting. And you know, we have yet to we've not a part of the presidential cabinet. Like the US cabinet. US cabinet. There's a cabinet meeting.
And we have yet to, we have not talked back
to the Department of Interior, so we don't know
the full context of the meeting, right?
Because we're not in the cabinet meetings,
we're not part of the cabinet of the United States.
And a comment was made about de-extinction.
And the Department of Interior and Secretary Burgum
is very passionate, he told us in the meeting with us,
that he's excited
about getting animals off the endangered species list,
but that's not removing them, that's recovering them.
That means that we have enough of them
that's healthy enough that they're no longer on the,
and he made a comment that we put things
on endangered species list, but they never come off.
And so how do we get animals off using technology?
And so we thought, but once again, we live in a
moderately polarizing climate right now. And so that became
and I don't know if they I can't think of the administration that
became de extinction is now being used to get rid of
endangered species. Like, wait, what? So that was my win. So that
was my Wednesday.
And then Thursday, I was like, we'll just answer whatever questions come up, right?
And so last week was a little bit of a crazy thing.
But going back to your original question, you know, at the end of the day, like that
was one week in time.
And Colossal is looking at 50 years.
And our goal with Colossal is to bring back these species,
as well as use all those technologies to save existing species.
And so in that model, you have to think on a 50-year horizon.
So if you get great press on day one, which we did,
and you get crazy press on day two, that's okay.
Those are two days in a 50 year journey.
And I think you have to think like that.
So let's talk about, I have so many questions, buddy.
And I'm so proud of you.
And just for full disclosure, I'm a seed investor
and advisor to Colossal Biosciences.
I've met Ben and there's something about you as a CEO, that have you've got the right phenotypic attributes that
people just want to support you. And what you've done, I mean,
how old is Bile is colossal these days?
So we were founded in September 2021. So okay, so you're four
years old. And you you went from a zero dollar valuation at a first conversation with George
Church to now you're say it, what's your valuation today?
Our current valuation is 10.2 billion.
10.2 billion, that's pretty insane in four years.
I want to talk about the business model but the science real quick, you know, sort of
de-extinction 101.
All right.
So de-extinction 101.
And remember, I'm not a scientist, but you basically in a so far, can I just pause for
a second?
I think this is so important.
When people think about moonshots, etc.
You have no background in biology to be doing this, right? Just as Elon has
no background in space or the car industry or the energy industry. It's people coming
in with a beginner's mind and an MTP, leveraging new technologies that are accelerating naturally.
And that formula gives you any possibility in the world. And I think that's such a huge
thing that we should drill down on. Anyway, back to the science field, I think it's so great.
I'm really curious and I feel like I like to ask questions and, you know, and George
will sometimes say that I'm the best student he's never had because I just, I like to ask
weird questions and he's like, I didn't think of it like that.
And those aren't like scientific breakthroughs.
They're just, I just, to your point,
I don't know anything about it.
So I can ask, you know, childlike questions about it.
And then I get these answers and you know, it's great.
Okay, onto the science.
Okay, so the science,
and one of the reasons why I've had to raise so much capital
is that you have to build the entire system, right?
So just like going to space
or even just building a software system, the whole system has to work. You
can't just design the software. You got to build the software, you got to build the hosting,
you got to build all the API calls. So you have to think about it. So we have, I think
like my background is mostly in software. So I try to think about things like how you
build software. And so you first have to get ancient DNA, right? And so there's kind of
three fundamental parts, right? There's ancient DNA, right? And so there's kind of three fundamental parts, right?
There's ancient DNA, there's the closest living relatives,
and then there's the tools to make it possible.
So ancient-
How old is the oldest ancient DNA?
Because I mean, I'm gonna ask you,
because everybody asks you, it's your number one question.
Can you bring back dinosaurs?
Is there any dinosaur DNA out there?
There is no dinosaur DNA.
George and I both agree philosophically that you should not ever say things are impossible
because maybe we don't fully understand it yet.
I think we're learning things every day, which is also not a very academic mindset I might have you.
Most academics think we know everything.
So I deal with that quite a bit.
But I think I know nothing. So I'm on the other side of the spectrum.
But right now, you can go on the other side of the spectrum.
But right now, you can go back a little over a million years. Our oldest, we have about
59 mammoth genomes that we're working with. And our oldest is a step mammoth, which I
would argue is still a woolly mammoth, but a step mammoth that's currently classified.
And it's 1.2 million years old.
Awesome. But most of the DNA we work with is,
depending on the project's hundreds to thousands of years
old in that kind of range.
We're still a long time.
It degrades, DNA degrades very rapidly.
Very, very rapidly, right?
The minute you get blood out of a system,
it starts to degrade, right?
And so, what we do is,
we first have to get fine ancient DNA, and you've got it, a lot of times, there's this thing calledgrade, right? So what we do is we first have to get fine ancient DNA and you've got it a lot of times
there's this thing called coverage, right?
Because these big DNA reading machines, they've gotten incredible, but they're not 100% accurate.
So the more coverage you can get, meaning the more times the full genome that you can read, the higher likelihood that they know it at 3081 that that's a C, right, versus a G, right?
And so it's giving it almost like a probabilistic score for each letter at each space and in
each position, right?
Yeah, in each position.
So the more coverage you can get, so if you only have like 1x, meaning that you got, there was, you do, this is a destructive sampling process, meaning you put it in, it's
like, you know, it's like, it's like when that old claw game, you put it in, and if
you don't get the teddy bear, you still lost your money, right? And so, you put the DNA
in, and you do this library prep, but it destroys the library in the sequencing process, right?
So, therefore, you've got to get enough DNA.
And the problem with ancient DNA is, to your point, Peter,
it degrades very quickly.
Cold, dry places are the best places we get DNA,
but it degrades very quickly because of heat,
acidification.
That's why I love brand tarpritz, it's terrible for this.
And also you have animals that die on top of animals.
You have animals that eat animals, defecate on animals.
You got bacteria.
So you have to then screen it
and make sure you understand what's truly endogenous.
Like what is actually that animal, right?
And so, and that's literally kind of a numbers game, right?
So sometimes you get zero DNA on species.
Sometimes you get a lot of endogenous DNA.
So the mosquitoes trapped in amber just isn't the thing.
It's just so not that we've tried, but amber is not a great storage vehicle. It's very porous.
It's not a great storage vehicle for DNA. So there is no DNA for that. And I don't think that we'll
get back to I don't want to ever say impossible is who knows? But people still think Loch Ness Monster is there.
So if some crazy lineage of dinosaur magically existed somewhere and died during the ice
age, that would be great.
But I don't know if that...I don't think that most likely did not happen.
So you can go back about a million years.
So then you get these pieces of DNA, you do the sequencing and we got about a million years. So then you get these pieces of DNA, you do the sequencing and you know, we got about a 13 X. So we had a full read of the genome 13 different times. And
for you can do what we do probably at five to six X, but you really, if you get north
of 10 or especially north of 20, then for what we do, which is called functional de-extinction,
because we're not trying to clone these extinct species. There's no living cells.
You can't clone from a dead cell, from bone.
You can't clone from a dead bone.
We're trying to identify and read the genome
and then use synthetic biology to engineer
in those lost genes to time.
And so once you read it, you compare it
to the closest living relative, because why would, you know, it's like if you're going to make a dire wolf, you shouldn't start with a frog
because there's hundreds of millions of you. That's a lot of changes, right? And so dire wolves,
for example, are 99.5% the same as gray wolves. And many people didn't know this until we just
submitted this paper, which is currently the number one paper on bio archives. We actually crashed bio archives on, so two other weird things. We crashed bio
archives on Friday, on Thursday when we uploaded, bio archives went down. It was the number one
research paper. I think it still is right now and it's on a preprint server. Oh, and also read
a Reddit shut down colossal for a week. They said, they literally
put out a statement. I don't know if this is happening before. There was a statement
last night that said, any mention of Colossal, Colossal Biosciences, dire wolves, any names
will be banned for one week. It's the craziest thing, dumbest thing I've ever seen. So anyway,
back to the science. So once you have, and there's no like GCP of species, which I think there needs to be.
We're actually advocating the federal government to do this.
There's no like biobank or bio vault like the equivalent of the seed vault that has
all these cells for wolves that are immortalized or pluripotent stem cells.
No one's done genome sequencing on all of this.
No one's done any of that.
So then we have to go do all that. And then you compare the two. And then once you identify those genes, we look for areas in coding regions
and in regulatory regions in the areas that we know will drive, or we at least believe
will drive certain types of phenotypes. And then we engineer them into the genetic donor.
In this case, it's the closest living relative being the gray wolf.
And then we identify those, we edit those into the gray wolf
and then we do a process called somatic cell
nuclear transfer, which is basically cloning,
which Dolly made famous, only we now use like robotics
and lasers and all kinds of stuff
to make it much more efficient.
You put it into a host and if everything goes well,
you get a healthy animal.
Ben, what percentage of your team and your tech
do you consider software versus biology?
How much is this as a biology company?
How much is software?
I'd say it's half and half.
And so, we spend a lot, like the sequencing,
like, once again, this goes back to education,
some people were critical where they're like, but they didn't use tiny tweezers to move
the DNA.
But they don't understand synthetic biology.
And so it's like, so this is awesome.
People were like, were you frustrated?
I got an interview over the weekend, like, were you frustrated by that comment?
I was like, no, this is an educational opportunity, right?
No, like, this is cool.
You think that you move the DNA from here over here, that's not how it works. We just read it. You've said this before, Peter,
it's just a different coding language. And so we read the code, and then we rewrite the code.
And we either change this code or we synthesize a block of code and stick it in. We don't move
it with tiny tweezers. How much of this is done by reusing CRISPR?
You know, CRISPR has become the catch-all for genome engineering, right? It's a combination.
So one of the things that we've done really well is there's knockouts, there's knock ins,
when you knock stuff out of the genome, you can knock stuff in the genome,
you can change individual letters. We do a lot of changing individual letters.
And some people trivialize that, which I think is insane.
I'll give you an example.
This is a conservation example that's amazing.
And this goes directly to your question.
So in one of our tools of just being
able to change the individual letters,
not doing a full knockout but changing this from a C to a G,
we have a project where in Australia they've actually introduced cane toads from South America. What's killing
all of the marsupials, specifically the northern quoll, they're critically endangered now because
they're eating this cane toad that they did not evolve next to and the neurotoxin kills them.
Well, guess what we found out when we studied snakes, obviously not mammals, and other small
mammals that eat cane toads in South America, that they have a similar change at one nucleotide.
So think of that, 3.5 billion base pairs, one letter, one change confers a 5,000 times
resistance to cane toad toxin.
So we've now made Dunnarts, which are the close
living relative before we wanted to work in the endangered species, we want to work in
a little model species. We've made dunnarts, which are another carnivorous marsupial that
are now 5,000 times more resistance to cane-toed toxins with one letter change. And so when
people say, but that, you know, making one letter change isn't that big a deal, I was
like, one letter change could change the entire animal.
You could literally like George, but our statement says you could make an entire
new species with one letter change.
That's extraordinary.
Wow.
And so, and then we also do DNA synthesis.
So if there's a lot of changes all at the same time, sometimes we'll synthesize
that block and just put that whole block in because it creates a lower probability of off-target effects because you'll potentially
only have off-targets at the ends versus like making 20 changes in a gene.
So, and where we're, what Colossal is probably, I would argue we're the best at is multiplexing,
meaning that we take all those technologies, put it all in one big array and kind of one big guide
and deliver it. And we're pretty good at that.
How much easier is the next species to de-extinct? Because when I look at what you're doing, if
I use the computing architectures and analogy, you've got hardware, you've got BIOS, you've
got operating system
applications, right? And you're essentially reinventing that entire stack
in different ways to cobble together what you're trying to do.
It's not like you're writing one little application that runs on a very
standardized well-understood stack. You're reinventing the whole stack
completely. Now that you've done it once, does the next time become exponentially easier and then much easier after that?
I think that the editing becomes exponentially easier
and the delivery becomes exponentially easier.
We're working on some things with, on the embryology side,
around how do you have a, and we're not there yet,
just to be clear.
We've not done this.
I don't want to claim we've done this.
We are working on some pretty interesting ideas around a universal donor egg where you
can have matched mitochondria because you can't go too insanely different.
I can't use a cow egg, which is a different size, to grow an elephant even if the size
work the same because you have the potential, let's say, for mitochondrial
rejection.
But if you can make a universal egg and you can match the mitochondria, then you have
a universal egg that can work for any species, which is pretty interesting.
And then you don't have to do the process of stem cell gammutogenesis.
So sometimes people are like, you guys haven't thought about embryology.
I was like, that's all we think about. And so to your question,
I think the editing, the comp bio scaling quite well,
right, software and compute.
The models that we're retraining on what works
gives us a better idea of what tools to use for what job.
So that's scaling really well.
The multiplex ability in off target
in the monoclonal screening,
so then screening all the cells,
we do a lot of sequencing.
We even do all of,
reason why we know that our animals are healthy
before we put them in is we screen the embryos.
We do full genotype sequencing.
You have to, yeah.
Which is insane.
Like it's a lot of money and time that we do all of that.
So the sequencing scaling,
we're getting better at the library
prep range of DNA. You know, I think that the big thing is, I think that we will get
to the point that we will be able to synthesize eventually full chromosomes. And I think we'll
get to the side, get to the point that we, I think it's a ways away, but I think we'll
get there. And then I think we'll be like,'ve already delivered, in publishing literature, 35 KB or 30 KB I think
is the biggest large cargo swap.
We've already done 100.
KB is a kilobase, a thousand.
Kilobase, so it's a thousand letters.
So we're gonna have been well.
Yeah, go ahead, sorry.
So I think that that's all scaling.
The two areas that I think will scale over time
is this goes back to your stack analogy,
is like the BIOS is similar, right?
But we have to create different,
like we have to create like the editing
and all the tools that you develop for the application layer
I think get better and better and better.
The two things that we are spending a lot of time on is that universal egg embryology
side to make that easier so it doesn't have to be a custom chip architecture for every
single species, right?
The second thing is, and kind of on the bio side, I think it's interesting to think about,
or what we've been trying to think about is how do we make it where, what
are the universal truths across certain genes or gene families or pathways, right?
So like dogs scale really well.
So if you have a Chihuahua and you have a Great Dane or you've got a Dire Wolf, right?
Dogs and wolves are dogs.
They scale really well, right? They
scale one to one, not all species scale really well. And so if you were to take like a goldfish
and try to make it the size of killer whale, it wouldn't scale like that. So there's only a couple
of clades of animals that scale like that. And so how does that work? And, you know, how does
that work like with elk coral and some of these gene families,
and how has that been replicatable across mammals?
And then separately,
what are those functional equivalents in birds?
So those are the things that we're trying to,
that don't scale as well as the media.
So all these cells kind of like a little bit different media,
which you know-
Media is the growth medium in which these cells
are getting nutrients and growing.
Are happening, yeah. Yeah. So Ben, one of the things about taking on a moonshot Media is the growth medium in which these cells are getting nutrients and growing.
Ben, one of the things about taking on a moonshot like this is along the way towards this massive
vision you're solving all these other problems that can easily become spin-out companies.
You've been doing that.
You spun out FormBio, which is fantastic.
And one of the spin outs I can't wait for you to talk about
is the idea of artificial wombs.
I mean, you just had a baby.
You didn't use an artificial womb.
You used your wife, which was great.
We have surrogates we can go to,
but this idea of an artificial womb
we've seen in science fiction for a while.
How far off are we from full gestation artificial wombs?
It's a great question.
So we have a 17 person team on it.
Our goal with artificial wombs because colossal to your point doesn't work on anything human
anytime that we have a technology that has an application to human.
We patented, we'veented a lot of technologies.
We actually patented some stuff recently around around p53 and cancer and whatnot.
And so which by the way p53 one of the reasons that whales live so long
is they've got extra copies of this p53 gene.
Yep and so do and so do elephants, you know, we breed,
I mean, I guess we all breed the same thing with whales,
but it's easier to study elephants than it is whales, right?
Because they still go underwater.
The, and so I think there's a lot of cool tech
that can come from that.
But on the artificial womb side, you know,
we spin everything out,
so we won't ever make an artificial womb for humans,
but I think that someone could potentially use our technology to do that. I will say
it's harder to grow an elephant, not ethically regulatory or philosophically or religiously.
It is harder biologically to grow some of the species we're working on than a human.
And I think that if we continue on the current course and speed
by the end of 2026, we will have the world's first mammal birth fully ex utero where we went from.
It would be a small, it would be an elephant, it would be small and then we'll scale from there.
But our vision for that, once again, goes back to conservation because imagine a world where you can
grow, everyone knows about the
northern white rhino, which we're the genetic rescue partner on, but imagine a world where you
could grow 200 genetically diverse northern white rhinos in a lab and then, you know,
without ever having to interfere with another animal or a rhino. And then that goes into those baby rhinos,
then those work with rewilding partners
with them back into the field.
So I think artificial wombs,
if you can do multiple different placental types,
will change conservation.
And I think we could productionize
endangered species development.
And I think we could saveize endangered species development. And we can I think we I think we could save every species on the
planet.
Well, let's let's pause on that moment. Save every species on the
planet. That's, that's pretty extraordinary.
When you said 2026, that's like next year.
No, I know.
It's right there. Okay. Yeah. So okay, I'm going to give you an
umbrella comment. And then you tell me how close we are to
this. Okay. One of the holy grails of synthetic biology, Okay, I want to give you an umbrella comment and then you tell me how close we are to this, okay?
One of the holy grails of synthetic biology when we used to talk about this was that if you get to that holy grail,
you essentially are looking at DNA as a Microsoft Word document, which we can edit.
And every one of our cells is governed by the DNA that tells it to be a liver cell or heart cell and how to operate, etc. If you get to that point, the human being of 50 trillion cells or whatever
is essentially a software engineering problem. How close are we to that point where you can
edit it as easily as you can edit a production?
It is a focus and funding problem. It's not a lack of knowledge problem. And so, like
everyone's spending all this time
on large language models, which is great.
If the same effort goes into that, into this,
solving specifically this, I think it's five years.
If it doesn't, I think it's 10.
God still, and by the way, AI is gonna be the biggest
accelerant to all of this.
Yeah, yeah, AI access to compute
and then eventually quantum, those combine with synthetic biology.
George has visions that are crazy about synthetic biology.
We've talked about like-
So define synthetic biology and let's talk about crazy.
Yeah, let's go crazy.
So there's lots of definitions for these things, but we look at synthetic biology as a way
that we can use data and AI and other tools to basically change life, engineer life, or
direct life in a specific way.
So that's things like making drought resistant plants, making drought resistant animals.
There's a terrible process that animals go through for dehorning them
because the cows are now, like everyone loves to think about cows in these beautiful fields
like they see on Yellowstone, but they're really not for the most part. And so they
dehorn them because a lot of times they're so close together, they'll stab each other
and they'll get infections that causes disease and go to the herd. So they physically dehorn
them. You can actually now, we could engineer them to just be hornless cows, right?
So then, you know, I'm not encouraging eating meat. I'm just telling you that is something that exists today.
And so synthetic biology affords us all these opportunities, right?
We've got a company called Breaking that we started which is about using synthetic biology to supercharge this microbe
that literally breaks the chemical bonds in plastics.
It doesn't make microplastic, doesn't eat plastic, it breaks, that's why I call it breaking,
it breaks the chemical bonds and plastics, right?
And so it just makes biomass as an output.
And so, you know, I think that we will eventually get to the CAD software of biology, you know,
you know, to Selim's point is like, I think that we will be able to cure most disease states.
I think that we will be able to do epigenetic cell resetting.
I think we'll be able to live youthful lives for as long as we want outside of natural
causes or outside of acts of God and some crazy thing that happens to you.
I think that we will...George and I talk about living one with nature and we have this vision
because George and I both believe that we're going to live hundreds of years. And so,
we think that there's, and so one of the things that we think that's pretty interesting is if we
can grow, like instead of like a tree grows and you chop it down, right, and you make a house,
why don't we make trees that like, like, why don't we make trees that like, this is literally George and I is like crazy.
Like, like, you know, people are gonna think, oh, these guys do like mushrooms. But we have
this idea of like, what if we could engineer trees to grow faster and grow in the shape
of a house? And like, what if you could use trees as water filtration? And what if you
could have bioluminescent fungi in there, right? And like, what, what if you could use trees as water filtration? What if you could have bioluminescent fungi in there?
What if you could literally build it,
engineer and tell a tree to grow in the form of a house?
That sounds psychotic,
but I don't think that's in the next five years,
but I think that's in the next hundred.
I think it's closer than people think
We are we as humans and all animals are effectively molecular robots
Right. Yeah, we're designed on a molecular basis and we
Function in different ways and one could imagine putting ethics and morals aside
function in different ways. And one could imagine putting ethics and morals aside that, and I use this always an example at Singular University for synthetic biology, I said I'm
going to engineer something that looks like a cat except it walks around your carpet and it eats
lint and it pees stain remover. And that's its purpose. And it just goes around and cleans the
house. Yeah. But you can imagine that. I'm not going to get into the alien conversation,
but if I were a future civilization, I would engineer the sort of aliens to,
you know, to pilot the spaceships and instead of robotic, robotic systems,
you want systems that are self-healing.
Yeah.
It's about 13 years ago, I had my two kids, my two boys, and I remember at that moment
in time, I made a decision to double down on my health.
Without question, I wanted to see their kids, their grandkids, and really, during this extraordinary
time where the space frontier and AI and crypto is all exploding. It was like the most exciting time ever to be alive.
And I made a decision to double down on my health.
And I've done that in three key areas.
The first is going every year for a fountain upload.
You know, fountain is one of the most advanced diagnostics and therapeutics companies.
I go there, upload myself, digitize myself, about 200
gigabytes of data that the AI system is able to look at to catch disease at inception. Look for
any cardiovascular, any cancer, neurodegenerative disease, any metabolic disease. These things are
all going on all the time and you can prevent them if you can find them at inception. So super important. So
fountain is one of my keys. I make it available to the CEOs of all my companies, my family members,
because health is in you wealth. But beyond that, we are a collection of 40 trillion human cells
and about another 100 trillion bacterial cells, fungi, viri, and we don't understand how that impacts us.
And so I use a company and a product called Viome. And Viome has a technology called Metatranscriptomics.
It was actually developed in New Mexico, the same place where the nuclear bomb was developed,
as a bio-defense weapon, and their
technology is able to help you understand what's going on in your body to understand
which bacteria are producing which proteins, and as a consequence of that, what foods are
your superfoods that are best for you to eat?
Or what foods should you avoid?
What's going on in your oral microbiome?
So I use their testing to understand my foods,
understand my medicines, understand my supplements,
and Viome really helps me understand
from a biological and data standpoint
what's best for me.
And then finally, you know, feeling good, being intelligent,
moving well is critical, but looking good.
When you look yourself in the mirror saying, you know, I feel great about life is so important.
Right. And so a product I use every day twice a day is called One Skin, developed by four incredible
PhD women that found this 10 amino acid peptide that's able to zap senile cells in your skin and really help you stay
youthful in your look and appearance.
So for me, these are three technologies I love and I use all the time.
I'll have my team link to those in the show notes down below.
Please check them out.
Anyway, I hope you enjoyed that.
Now back to the episode. What are some of the crazy conversations you have with
George when you're dreaming up without any limits? Let's hear some of that.
Well, I think the treehouse one is pretty crazy and weird.
Yeah, another one that we've talked about that, that I think could be, you
know, pretty interesting
is how do we engineer in, you've seen these,
you've probably heard about phages, right?
And these microbes that you can get in the dirt.
Every time they think it's a scoop of dirt,
they find new bacteria and stuff that doesn't exist, right?
So phages are viruses that infect bacteria
versus viruses that infect humans. And the numbers are, I think there's like a billion quadrillion phages on the planet.
There are more phages on the planet than there are stars in the universe.
Yeah, it's crazy.
It's the most insane.
Like every time you scoop, I think, a dirt, they just go like, literally you just go outside.
Everyone can make a discovery.
Just Google.
A number of phages on earth.
You'll be blown away.
It's crazy.
But they've been using these like lattice architectures
to actually, and they've shown that, you know,
in a typical scuba tube,
and this isn't with like synthetic,
yeah, not even taint, it's synthetic biology. With just a scuba tube, and this isn't with synthetic, not even tainted with synthetic biology,
with just a scuba tank, they can like three or four X the volume of oxygen that it can
hold using this kind of like structure from some of these phases.
And I think it's really interesting.
And so I think, so some of the stuff that we've, like George and I have also talked about is, you know, how do we
build self-healing outside of humans and outside of houses, but how do we build underwater
cities that are also self-healing, right?
And so that's probably our biggest and craziest dream is like, how do we, you know, if you
look at the world's, you know, what's interesting about space is it makes you think
about closed systems.
What's interesting about underwater is that it makes you think about closed systems, but
you don't have a, you have more of a stable temperature.
You don't have this like negative 500 to 500 degree, 500 or 250, 250, 500 degree variant
in the sun that's instantaneous.
You don't have the vacuum, you don't have the radiation.
It's also the cost per kilogram of sinking something is much cheaper than putting it
up in space.
And so we've talked a lot, one of the more weird ideas out there was we've talked a lot
about if you just look at the surface of the earth, you know, we could do a lot of cool things and you'd have to, it would force you
to build, you know, very sustainably cities underwater.
And so that's a project that we're interested in.
That may be a 2090 project, but I think we'll get there.
All right.
I got to ask you this question and I'm going to force some version of an answer. So a royal or a, you know, a deca-billionaire
comes to you and says, Ben, I know you say it's impossible,
but I wanna create a dinosaur.
How do you do it?
Now, I'm not saying you are doing it,
not saying you plan to do it, but sort of theoretically.
Yeah, so there is no dino DNA, right?
And so just to kind of give a shout out to the haters, Jurassic Park is not a movie about
dinosaurs, it's a movie about genetically modified birds
with dinosaur and frog alleles.
Or it's a movie about dinosaurs, depending on how you want to classify our dire wolves.
So there is no dino DNA.
If I were to try to go build a...
I don't think today you can... I don't think that you could bring back a dinosaur.
I think using synthetic biology in probably not today, but probably 10 years from now,
eight years from now, some period in time, you could do an ancestral state reconstruction of
what we know of the tree and I think that the phylogenetic tree
and I think that you could do a giant sequencing project and I think there's enough that is
conserved across multiple clades of birds and reptiles that you would probably be able
to go down to make like an archosaur which is probably at the very base of the tree, it's like a basal animal before it kind of stuff starts to get weird and split.
And yeah, I think that you could do that and then you would be engineering for phenotypes,
right?
So I think you'd be looking at, you know, looking to drive certain phenotypes. And I think a lot of those, at least we understand computationally at this point what those protein
coding regions are.
So I don't even know if it'd be less of a dinosaur than a dinosaur existed.
And so that's probably where I would start.
But I think it's a huge project.
I think it's a lot of money. I don I think it's a huge project. I think it's a lot of money.
I don't think it's a hundred million dollar project. I think it's quite more larger.
Is there any possibility that we can harvest DNA of a dinosaur and find that it is preserved
in some place, some way, somehow?
The problem is DNA degradation and fossilization. And you have to remember
when the dinosaurs perished, it was due
to extreme heat. And so, you know, there is dinosaur DNA in the form of birds, right? Birds
that exist in their dinosaurs. And so, but I do think that I don't think you'll ever get to the
point that you will have dinosaur DNA. There's people like Dr. Kenneth Lacovara, who's arguably
the number one paleontologist in the world, who discovered the four biggest dinosaurs,
including Dreadnoughtus, which is the biggest dinosaur. He called me last week when everyone
was debating all this stuff. Well, not debating all this, they're only debating the name.
And he said he had the same problem with Dreadnoughtus. He said that it was the biggest dinosaur and
he did it based on kilograms and all this stuff. And a lot of dinosaurs, they find like
a bone and they're like, it looked like this. But this one, it was a nearly, you can Google
and I don't know what percent, but it was like 40 or 60. It's very, very complete for a large dinosaur.
And he found in Argentina, so super cool story.
And he had people that called him
and he said it was so annoying
because they wanted to argue not like US
versus metric system,
but they wanted to come up with a dinosaur mass unit.
And so he got into this big debate when it came.
One of the biggest dinosaur discoveries ever, and in a large part of it was because I think
he said it was like 60 tons or something like that.
And people wanted to debate a metric that everyone could agree on of dinosaur mass,
which is ludicrously absurd, right?
But Kenneth, one of the things he's done that's pretty cool is he's demineralized dinosaur
bones where we can get those amino acids.
And what his long-term goal is, it'd be cool if you could pick up a dinosaur bone, and
this is his work, not ours.
We are not doing this.
So I just want to make sure I give him full credit.
It'd be cool if you could pick up a dinosaur bone and know you found it in Montana or North
Dakota.
So you could say, is this a T-rex bone?
Is this a Triceratops?
And let's say that you didn't have like the the dating of the geological
formations around it, you could demineralize a piece of the bone and based on the amino acids
say oh this is a triceratops bone which is kind of cool. So those are like single, I mean those
are like, I mean you can't glean any data on how to build the animal out of that.
So listen, I remember at the very beginning,
we're talking about your vision.
It started with the woolly mammoth.
It sort of went off into thylacine
and discussions about the dodo bird, about the dire wolf.
And so how many different species
have you had conversations about bringing back?
Rough order magnitude because you must be getting calls from all different parts of the world
2025 yeah, what's your roadmap here pal?
So we're working on the man with work on the test me and tiger working on the dodo
You know given our most recent round of funding, we will most likely expand those into other
avian and non-avian species. We have not quite cracked the code on the primordial germ cells,
so it's a little bit different in birds and mammals. This goes back to that media question.
It's like getting the media that PGCs wanna grow in
for birds is pretty hard.
And once we do that,
once we show we can do it for pigeon,
which has never been done before
because Dodo's for pigeons,
just like dire wolves for wolves.
Once we do that,
then I'd probably feel confident
in adding another avian species,
but there's amazing species out there
and there's some we can't do until we get further
in the tech, like my favorite animal is,
you should look this up, it's the stellar sea cow.
It's the coolest damn animal ever.
So I don't know anyone in the world
that doesn't like manatees.
Like manatees are just awesome, right?
They're harmless, they're cute, they're vegetarians,
they're kind of tubby, they move kind of slow,
they do great stuff for the ecosystem.
Nobody, there's not like Facebook hate groups
for man in town, right?
If they are, those people should go straight to jail.
And-
Or else I'll be there.
Yeah, or apparently we do that too now.
And so there was this thing called the Stellar Sea Cow, and I'm probably going to butcher
the year so someone will yell at me online about it, but it went extinct like 60 years
or 30 years after it was discovered.
And it was all upon the Pacific Northwest.
And apparently the kelp forests there were even thicker
because it would eat and defecate.
And they are whale-sized.
They're literally bigger than whales.
Manatees.
Wow.
And they were apparently really docile.
And they would just swim up to people.
And they're curious, I guess, like dolphins,
like ballad as dolphins are.
And people would just spear them and kill them.
Curiosity is a bad evolutionary trait for...
For large, slow moving megafauna, for sure.
We've seen the rise of...
We've seen the rise of early human on continents
and the decline of megafauna
be inversely related, nearly one-to-one.
Once humans move to a certain scale on a continent or subcontinent, the megafauna drops at a
very predictable rate.
Which kind of makes sense, right?
We all work together, kill a couple of big things.
A lot of times the big things have single bursts, long gestations. You don't
have to kill all of them to send them down on a decline. But I would love to do the stellar
sea cow. And I will say publicly, it's, I've said a hundred times, no one listens to me.
It's a hundred percent on the list. We just can't grow it in anything. So I got to get
artificial wombs to work and we got to get it to work for elephants.
And then eventually we could do seller seek out. I would love to do seller seek out.
Amazing.
What is the business model that gets your evaluation of where it is? Is it spinning
off breakthrough medical ideas?
It's really, I would say originally, and this is what's been cool, you know, like one of the things I think we're good at
is we're also good at saying what we don't know.
And the original pitch deck, which Peter saw,
which was moderately shitty, was,
hey, George Church says he can bring back a mammoth.
We're pretty sure that we make money somewhere in there,
but we don't know, right?
That was kind of a pitch deck.
And so here's how it's evolved.
And here's kind of the three ways that it's evolved.
It then became tech, which is working, right?
We've spun out two companies publicly, FormBio and Breaking.
We've spun out a third one that we can't talk about yet, but I'm super excited about.
Its valuation is already over $100 million in the seed.
I think it's super cool.
I don't think it'll have any philosophical debates
on what to call it.
It is very cool.
So it's cool.
It's like it is what it is.
And so I'm super stoked about that one.
We have another one in embryology
that we're really excited about that we're working on,
that we gotta go a little further on, working on, that we got to go a little
further on, but I think it'd be helpful to IDF clinics. So there's technology, which you get.
There is a long-term, and this is not really a science thing. This is more of working
with governments and working with auditors, ecologists and whatnot. But you've probably
heard about carbon credits. There's now a new thing called biodiversity credits. It's getting
a lot of traction because some of the problems with carbon credits is not that they're manipulatable,
but they're sort of manipulatable on some level. But certain things like biodiversity credits aren't,
right? Like you can understand and quantify the value
that a forest elephant brings to Gabon.
Like that's now a thing.
Like it's like research by people like PWC,
it's certified by Lloyd's of London.
And so where there now is becoming a biodiversity economy
where in part of that it's really helpful
because if you can put the value
of an animal, right, this is the old hunting adage, right, where people are like, well,
if we kill a lion for $100,000, it's a good thing because we're putting or saying that
lions were $100,000, don't poach them. I feel a saw, I'm not a hunter, I've never killed anything
intentionally, probably a goldfish, but like that wasn't intentional. But it's like,
I wouldn't like I as not a hunter, I at least can step back and understand what they're trying to stay there on some level, even though I think that's partly manipulated so that they can achieve what
they want to achieve. What I'll tell you though, is that I do think that if you do put things of
value, people tend to protect.
And so if you can protect an animal
and it has a certain value that you can trade against,
it becomes some sort of a commodity play.
And what we're seeing is with this Paris Agreement
that 62% of the pledges pledge nature-based solutions,
rewilding, restoring ecosystems, restoring bogs, all these types of things in wetlands.
And animals are critical to all of that.
And so where we think that market's going is accommodation of biodiversity credits,
nature and carbon credits into what will probably end up being called nature credits that's
highly quantifiable.
And the variant trade on it will probably be based on sexy factor, right?
You have a lot of these companies that cannot become carbon negative because they're in
the mining business, they're in the extraction economy, right?
And we still live on some level, we still live in the world where there's not unlimited, you know, solar, there's unlimited solar, but there's not unlimited, you know,
cold fusion and stuff like that yet, right? And so, like, until that happens, we still
have some, there'll still be a transitional period where you have an extraction economy.
Well, if you put a value on nature, then you can create annuities based on that.
And so we're working on models around rewilding that turns the animals into annuities.
And so if we can show that we can make these animals with this genetic diversity, think
about an annuity that's not only growing and is highly valued because of a company like
Chevron or Simutomo or Exxon or whoever would buy those credits because they have to be from a compliance perspective or kind of an ESG in their kind of social good perspective.
They are also annuities that multiply because they have more babes, they cause more of a car.
So that's the second thing that we are now pretty deep in, right? And so the science has to work
to do that, which is proving to be on the right track. And then the third thing that's interesting is while we open
source, we didn't know this, I talked to Peter about this offline like six months ago, but
we open source all of our technologies for conservation. So anybody can use our technologies
for conservation. We also started a foundation with $50 billion to go fund conservation projects,
right? They're innovative.
By the way, congratulations on that.
And I just, people need to hear that.
That's huge.
Yeah, nobody talks about that.
But it's not a dire wolf.
Yeah, what embargo?
And so those are my life.
But the, but yeah, the foundation is great.
And I, we're working right now to get another big donation
that once again aren't coming from conservation.
They're coming from tech people that were trying to bring tech into conservation.
So this is new money to conservation.
But what we're finding is, I think you'll love this, Salim, because it goes directly
to open source software.
If you build open source software, you build a community, people start to use it,
devs start to use it, but then you have someone like the Red Hat Microsoft-type opportunity,
where it's like, okay, we want to go implement this at scale for Cisco. We don't want our
developers to do that. We love that you have all this documentation. You guys made this code. We
want you to do it, right? And so while we open-source all this for, you guys made this code, we want you to do it, right? And so,
while we open source all this for governments and NGOs and everyone else, we are now having
governments saying, in our hands, we think we can get this done, but in your hands, we'll pay you.
And there's one government that's trying to get a recovery of a species. It's going to cost them
about $300 million to get to that species, and it's going to cost them about $300 million to get to
that species and it's going to take 23 years.
We can do it in less than three and we can do it for like $70 million.
And so it's not just the $33 million, it's like, and that could go to more recovery efforts
or education or water or whatever.
It's the fact that we can recover species in less than two decades.
And so we're starting to see these government opportunities like biovaults and other things
where it's like, you know, this is work, right?
So it's not free.
It'd be easy if it was all just free.
But you know, we're now saying, how do we build a consortium of partners around the
world where we can also biobank all species,
but not just put them in a freezer? How do we build pluripotent stem cells? How do we do immortalized
cell lines? How do we do sequencing? Well, all of that's compute money, right? Someone's got to pay
for that. So I think that we can offer this redundancy model as well as this acceleration
if people want it.
But once again, we're happy to have people just use all of our stuff for free.
Then when am I going to go to LA Zoo and see a colossal dire wolf or a,
you know, some woolly mammoth?
I mean, that has to be a important future business line
where it's scientific education, right?
I mean, you'd have lines winding around
any of these facilities.
It's a really great question and we get it a lot.
And in the early days, we had a lot of folks
from that community want to like, where do we, what do we have
to do to sign up first, both nationally and internationally?
But you know, as we've spent a lot of time thinking about it, I think it's more likely
that you will see them in a ecological preserve being back in their natural habitat, then
you're going to see them in Los Angeles.
So you do have to travel, unfortunately, you have to travel to their locations. But I also think that
one of the things that we've started to have conversations with governments is the brand
building that that can do for the country. So we're talking to Northern States of the
United States, and we don't want to be exclusive. So like our exclusion know, our exclusionary, you know, like people argue the zoo thing to us all
the time in a positive way.
They're like, but if you made a zoo, like what about kids that want to see this and
get inspired by it?
Because there's been all these studies that show that zoos actually are good for people
care more about animals if they go to zoos as a kid.
There's like actual peer reviewed science that shows that like not all zoos are Tiger
King. There's great zoos like the San Diego Zoo that do great stuff. Groups like the AZA and others
are trying to do more for conservation. So you've got that, right? You've got that. And
we're seeing that that works. What I would tell you though is, you know, our focus is on rewilding
back into the ecosystem. And so the two things that we've talked about,
and I don't know where we'll end up on it is, you know, we've said to like Tasmania,
you should, once, you know, once we have enough thylacines and once they're back in genetically
diverse to be reintroduced, we've gone through a very thoughtful feasibility study of rewilding
them. They're benefiting the ecosystem. You should offer ecotourism to see them back there, right?
And then, you know, not like there's like, there's this thing that I didn't even know
existed, but there's like a sloth cam and there's like a bald eagle cam and there's
all these cams.
But it's like, how do if you can't, we don't want to be exclusionary.
So if you can't afford to go to Tasmania, which is really not the easiest place to get
to, I go several times a year, how do we bring that experience to you without making it about
exhibition of the animals?
And so we've been talking a lot about this.
We've actually been talking to a lot of education partners, including the Australian government,
about how do we do content, right? Which I know isn't the same Peter's like seeing a mammoth in real
life. But you know, and so we don't have an answer. I think the short answer is we'll
put animals back into the wild with collaborations with indigenous people groups and private
land owners and governments for the purpose of ecosystem restoration. And then how do
we put the science on display? Because the animals are. And then how do we put the science on display?
Because the animals are awesome,
but how do we bring the science on display, right?
Because that is something that Jurassic Park nailed,
regardless of how you feel about Jurassic Park, the movie,
a lot of people know about genetics
because of Jurassic Park.
And who cares about the Rotten Tomatoes score?
That did something.
Like there are geneticists today that don't wanna make make dinosaurs but went into genetics because that movie got them excited about genetics
And so we were filming a doc you series we you know, we'd like to build more educational content
What I hear Ben is you've got an incredible respect
for the life that you're bringing back and it's not your goal to commercialize
it in a crass fashion.
Right.
And so I would rather us put animals back on ecological reserves, protect them.
We don't even know, I mean, you know, but very few people know where the actual wolves
are. We'd rather get them back in the wild, doing their thing in the wild. Maybe
there's ecotourism like Kruger National Park, where money goes back to help the environment,
help the indigenous people, help the local communities. Maybe we do something like that
in collaboration with governments. But then, you know, but to your question, how do we
also, it is awesome science. So how do we, so we're trying to film everything.
How do we put science on display, not animals on display?
And we don't have an answer yet.
I have a fun question.
You and I have a common friend
who's another extraordinary moonshot entrepreneur
by the name of Palmer Lucky.
Yeah, Palmer's great. Yeah, Palmer's amazing.
I'll be doing a follow-up podcast with him in a couple of weeks. And when I get
together with him, I brainstorm, okay, what would be a great X-Prize? You know,
what should we be doing? Because he's one of the teams competing in our Wildfire
Prize, right? In fact, he was the very first person to register to compete in
the X-Pri Prize wildfire and he's
got a crazy solution which I love.
But we brainstorm and so one of the prize ideas that we kicked around over dinner was
the idea of an uplift prize.
Can we uplift a species?
Can we take a dog and make it far more intelligent or shall we say plant of the apes?
Introduce the genes that increase intelligence to these animals.
Is that something that's putting aside the moral ethical?
It's a very Palmer lucky point.
It's about as Palmer lucky as it gets right in.
Sometimes Palmer gets a mixed rap, but he is so brilliant.
He's so passionate about the safety of America.
And you know, I've seen the people attack him online and
it's like I want people like Palmer that wake up every day
that are that smart and that are like
working on a defensive weapon system or an offensive weapon system that is a deterrent
for some bad guy not to hurt my kid.
And so I, I, you want them on your, you want them on your side.
Yeah.
You want them on yours.
We are lucky to have Palmer.
I I'm a huge, I mean, obviously he's a friend,
full disclosure, and I think very highly of him,
but sometimes he gets this polarizing thing
because he's like, you know, it's cute to, you know,
go to the grocery store and drive your car or Tesla
or whatever and think that that all is free.
And it's just not, and you've got to have
our incredible armed forces and people supplying
them like Palmer to make our way of life possible so that we can do this and we can do it. It's
wonderful that we can debate whether we can call it a dire wolf or not versus someone killing us
for that. Right. And that's fucking amazing. And so anyway, back to your question. I think that
And so anyway, back to your question. I think that there are genes associated with, that could be associated with intelligence.
There's been studies been done in mice.
I think that you can do non-invasive sequencing of really smart animals.
Colossal is never going gonna work outside of humans.
We also drew the line at non-human primates
because we get the Neanderthal question all the time.
And so we just said, great, sorry.
And then people will get sad.
They're like, but what about giant pitacophus?
And I'm like, ah, there's not really any DNA anyway.
So no, we're not making giant apes.
That's just not, that's not what we are trying to do
at this company.
King Kong is coming back. Yeah, King Kong is not here though. And so I would say that for us,
I do think that if you could make smarter animals like, you know, dogs or cats or something that you
have that type of relationship with. I think that's interesting.
But you also have to be careful, right? Because I think it's a very important ethical thing to really think through because it's a slippery slope because then what happens when you make smarter
livestock, right? Then it's even worse for livestock, right? And so it's hard. I mean, it's hard
balancing some of the ethical questions in the name of progress of synthetic biology,
you know, also. So that's what we've, I know it sounds like a cop out, but that's why we've
drawn some of these lines saying, hey, we're just not gonna do this, we're not gonna do
that. Because even though I'm not philosophically against some of those things saying, hey, we're just not gonna do this, we're not gonna do that, because even though I'm not philosophically against some of those things,
we will never work in some of those categories. How do you deal with the invasive species
problem? Like for example, the Scottish went into New Zealand and took the gorse bush with them,
figuring that would make good fencing, and that took over the island and totally messed up the ecosystem.
So an area I love is gene drives. Like nobody, and you know what's crazy is like certain people, like the US hasn't been as pro gene drives as I think they should be.
But island nations like New Zealand and Australia are like, okay, we're in trouble with invasive species. We have to have new things.
And I love gene drives because cats, for example.
Define the gene drive for folks.
So gene drives are technologies that you can develop
where you can introduce them to a population
where it will silence or change certain genes
within that organism.
And you can deliver it by food or other things.
And so right now, Australia is like the face
of mammalian extinction, and it's because of cats.
They've interviewed like everyone's cats,
cats love to have baby cats, kittens,
and the people let their feral cats get out to get feral,
and then they're killing and decimating
these small marsupials.
Well, there's people now that kill cats in Australia, right?
And in America, like you'd go to,
like God knows what would happen
if you shot a cat in America.
But it's like, you know, to Australia,
if it's not their personal house cat, they hate them.
They despise cats because it's killing their most unique,
they have these unique animals
that no one else has in the world, right?
And so a way to handle that in a very thoughtful way that is healthy for the animals
is you introduce gene drives where that cat eats it instead of it's not poisoned, it doesn't
die. It has an offspring. So it does have another generation, but that offspring cannot
give rise to more offspring. It's effectively sterile. So then after a few generations, there just are no more cats, but they get to live out
their natural lives.
They just don't get to over procreate, right?
This got a lot of attention back about five, six years ago when gene drives were being
put forward to basically decimate mosquito populations. And everyone, I think the biggest concern is, you know, everyone's seen one too many
movies, right?
And so like you got Resident Evil, and then people are like, oh, you make a gene drive
and then it turns it's all into zombies, right?
It just doesn't work like that.
And so, but I do I that, or like one of the mission
impossibles, I think they had targeted like a bio weapon
around that stuff.
And so you have to be thoughtful about this,
but I do think that you can silence certain,
or not I think you can silence certain procreation
in animals using gene drives, especially where it's invasive.
And I mean, we're doing kind of the opposite of a gene drive with these marsupials, right?
If we make super coals, then we don't have to engineer
all of the other marsupials to eat coals,
because the coals are to eat the cane toads.
The coals love eating the cane toads.
So then they eat the cane toads, so then they don't die.
So their numbers rebound and they recover.
But at the same time, there's other marsupials that don't eat those cane toads. So then they don't die, so their numbers rebound and they recover. But at the same time, there's other marsupials that don't eat those cane toads.
So then they don't die because there's less cane toads.
So people think this is playing God, people think this is geoengineering, but I mean,
we introduced the cane toads.
And we found the forest.
We're geoengineering by default anyway.
So every day, every day.
And so we should
start being thoughtful on this.
I love the arguments that GMO is bad for you. It's like, oh my god, that's all
we've ever done is genetically modified everything. We've just been shitty at it.
By selective.
I use the analogy.
I use the analogy of film photography to digital photography.
We've been doing breeding for thousands of years and nobody says anything.
Now we've got the digital photography.
We can do it at scale.
And everybody's like, oh my God, we should be, what are we doing for our...
Look at a pug.
Yeah.
Look at any of the specials.
Oh my God, we should breed a bunch of stuff together that ends with a pug.
Oh my God. Ben, quantum sciences, quantum computation, quantum tech.
How much do you think about that as the next layer?
Yeah, where does that fit in?
I mean, I think it will be a game changer for specifically simulation design for editing. And if you feed enough data into the model on top of quantum, you could get, I think, pretty good
at predicting not just genotype to phenotype relationships, but you could get pretty good
at understanding what negative effects would be from editing.
And so, and predictions of editing, like,
hey, here's the 50 spots you should go edit.
We always say the better we are at computing,
this annoys people, but it's true, every edit has a risk.
Every edit has a risk.
It just has a risk.
And we don't, to the question you asked earlier about
when do we know everything about the genome?
I think for humans, it's that, but for all life, who knows?
It's going to take quantum to get the AI before we can truly understand it for all life.
I think what's interesting about quantum is if you could simulate these things and simulate
those edits, we always say the less edits we can make, they get the desired outcomes and the loss phenotypes,
that's the safest for the animal.
That's the, and so like, if you could,
if it takes a thousand edits, make a thousand edits.
But if you can do it in three, do it in three, right?
It's, we have a very programming,
like this won't come to surprise to you,
but we think about this like programming, right?
It's like, if you could do something in three lines of code
versus a thousand lines of code,
you should do it in three lines of code.
So I think quantum will be a game changer.
I just, I don't, like I meet with like,
I see Will every year from MIT, he's great.
And it's just like, but it's like,
I never know, like quantum
sensing is here, but in quantum sensors are here. But it's like in like quantum comms is
kind of here ish. But it's like, I don't know when we're really gonna get there. I thought
Microsoft's breakthrough earlier or last late last year on some of their chip architecture is really interesting
But you know, when is it gonna be truly here still to me is a question mark
It's it's two years every two years
You employ ethicists in the company don't you yeah
What are they what are they debating right now?
Well, I mean, every single species we bring on, we go through a pretty rigorous process
and include obviously them in that.
Right now, we're talking to them about, one of the biggest things we're talking to them
about is the current conservation.
We were opening sources in is the current conservation. We're opening sources
in these technologies for conservation. We're making Red Bulls working on these projects,
but then you get the... It's kind of our ethicist right now, our focus mostly on
how do we recognize... I think that conservation is a bipartisan issue. And by the way, we hear that from the government,
not just, we don't just believe that. It's like both sides of the aisle, like go look at who
retweeted us, right? It's like you've got Biden's number one advisor and you've got Elon. Like you
kind of have both sides of the aisle, right? And as far as the political spectrum, and we think
that these are really important technologies and conservation are important.
Right now the bioethicists are helping us think through
how do we educate the existing people on,
and how do we bridge,
how do we show these technologies off
from an ethics perspective,
but also be able to rise above the politicizing of it on either side, not just one side.
And so they're going kind of a step beyond even the bioethics side, thinking about how do we have these dialogues?
Because, you know, I was really sad that within a 24-hour period, we made a huge leap forward for conservation using these technologies by the federal government,
but because it was by this government, it's seemingly bad.
And I don't philosophically agree with that.
And so I think that we worked great
with the last administration,
we're working great with this administration,
there's pros and cons to every administration.
And so I think we just have to,
I watch Bill Maher every week to probably show you where I lean on a lot of these things.
And Bill Maher's show last week was really telling, right?
And if you haven't watched,
I highly recommend people watching it.
That was a great episode.
I think having a,
a refusal to have a dialogue
because one party or another party is super
polarizing, you can acknowledge they're doing bad things or you can acknowledge
you don't agree with them, but refusing to have a dialogue that is as ignorant
as things that you may accuse another administration of doing.
I think it's a testament. There's a testament here to your ethics and your MTP,
where you're able to work with either side of that aisle
because of the, and the objectives, the open sourcing.
I love the fact that you're open sourcing everything.
It's such a huge thing for the world.
It's really great to have somebody like you
be at the forefront of something like this,
because it could go so badly so many other ways,
and you're navigating that very fine line
of breaking through science,
but doing it in a very, very thoughtful,
ethical, even a spiritual kind of way.
So I just wanna hats off to you and all that.
No, it's really kind of you.
I got feedback, pretty negative feedback
from someone I respect in the community,
in the conservation community,
because they said that I was empowering this administration
and I was like, there's a difference
between empowering and educating.
And if you don't educate people and you don't show up,
I think it's always better,
we showed up for the last administration,
we're gonna show up for this administration
and we're gonna show up for the next administration
because like we said at the beginning of this,
we are looking at conservation and de-extinction,
we're looking at this on a 50-year horizon.
And that goes beyond a four-year party
or an eight-year party, it goes way beyond that.
And this to me is as big of as an existential threat
as anything else.
My 13-year-old heard I was doing this,
so he did a quick book run in his class,
and his class collectively asked the following question, what's the next species that we can look forward
to?
I don't want to let your kids down.
We are on target for the mammoth by end of 2028.
We feel good about that.
But the editing is moving really fast.
We have done 300 edits in a Dunnart cell. And so, if the
Dunnart, this is a bad non-answer, but if there's a 13 and a half day gestation on the
thylacine, if the, if editing progresses at the same exponential rate than it is, I think
the thylacine could be the mammoth. And if we saw PGCs in dodo's because of the easiness,
not easiness, but the easy or it's a pretty self-contained system
being an egg.
And you don't have to solve IVF or smacks on
the transfer in a non-model species.
Then the dodo could be.
So I mean, right now it's kind of a three horse race
and it's unclear who's gonna win.
Not that it's a competition,
we love all the species equally.
Gestation periods play into this, right?
So what is the gestation period of an elephant?
22 months.
22 months.
Wow, for any pregnant women out there,
can you imagine 22 months carrying?
Crazy.
And the thylacine is how many, how long?
13 and a half days.
Yeah, talk about two ends of the extreme.
And the chickens, a chicken, which is what we use
as a surrogate, we use these genetically modified chickens
for the surrogates for 30 days with the Dodo.
Yeah.
Ben, you know, so let me have a closing question,
but I just want to say thank you
for all the work that you're doing.
I've never, I have said this over and over again,
the difference that a individual can
make in birthing a company is extraordinary.
And I want all the entrepreneurs out there listening to understand that right.
It's you can have the idea you can have access to technology.
But if you've got a compelling CEO who builds a moonshot team, is driven by a clear measurable vision and passion,
you've attracted hundreds of millions of dollars at a $10 billion valuation, which is, I don't want to say it's insane, but it's massively impressive.
And you're executing over and over again. So thank you.
And in four years, yeah, in four years,
I remember that I have to say one thing.
I remember the early, in the earliest days,
because when you started Colossal,
the idea of a de-extinction company for the woolly mammoths
had been around for some period of time
and people had been working on it.
And it had been extremely slow
in the non-profit world and people were upset that this moved into the for-profit world.
But guess what? It's like hitting the, you know, the acceleration button when you did that.
Well, that's one of the, that is one of the things that we often get is like, there's an article that came out a couple weeks ago said you can't trust a for-profit. It's like,
often is like, there's an article that came out a couple weeks ago says you can't trust a for profit.
It's like, well, we are very honest that we are going to make a lot of money off the rewilding.
Like I said that here, like we think that we'll make billions of dollars on the animals
being back in their natural habitats.
We also think that we will make, you know, billions of dollars off of the tech that we're
building.
And so for us to be able to give that technology and subsidize, people don't realize this
unless they've done technology development.
They think of research and development as free.
Well, it's typically a lot of research
and very little that goes into development
because a lot of this stuff just doesn't work.
I love that there's a metaphor merging in my head,
which is you're not just incubating
and bringing back old species,
you're actually an incubator and a womb yourself
for breakthrough technologies that change everything, that change humanity and change
everything, which I think is awesome.
It's very meta.
Yeah.
And we're, I mean, look, we're having fun and I think we're making a difference and
so that's all we can do.
It's weird that I get to say I'm jealous about somebody's job, but I think you might have
it. It is a 365, seven day a week, but I like, I don't have, I always joke that I don't have
friends or hobbies.
So, I mean, I do have friends, but I work with all of them in some level, right?
On some level.
So, I just, it's fun.
I love what we do.
Amazing.
Ben Lam, CEO of Colossal Biosciences,
thank you, buddy, for your work.
Please give my best to George.
I'll be chatting with him shortly as well.
Salim, as always, love having you
in this conversation with me and for everybody.
So where do folks go to learn more about Colossal?
So we're just at Colossal on X and the unit where
they can go to colossal.com
and find the rest of our social channels.
And when you go, if you listen to this podcast, you know, go to your friends and say, did
you hear about the miracle that occurred last week?
It's extraordinary.
Three dire wolf pups that have been extinct off the face of the earth for 12,000 years
are back again.
And that is incredible.
They're also cute.
They're also cute.
Congrats on the baby, which is a real startup.
Yeah, it is a real startup.
I'm learning that in a hard way too.
It's a self-learning startup.
I have my own large language model continually growing.
It's interesting.
You have to be looking at the birth and your son
very differently given the business that you're in.
Yeah, my son has no idea, obviously, what I do.
And I think he'll really like it or not.
I think it'll be a moderately binary outcome.
I just can't wait to see what he'll do.
Peter and I, neither of our 13 year olds have any idea what we do either, so don't take it the wrong way.
He's pretty curious.
Like at an early age, he's really weirdly curious.
And so I think he'll dig it.
We'll see.
We'll see what kind of pets he grows up with in his teenage years.
Awesome.
All right. take care guys.
If you enjoyed this episode,
I'm gonna be releasing all of the talks,
all the keynotes from the Abundance Summit
exclusively on exponentialmastery.com.
You can get on-demand access there.
Go to exponentialmastery.com. Okay, Martin, let's try one.
Remember, big.
You got it.
The Ford It's a Big Deal event is on.
How's that?
A little bigger.
The Ford It's a Big Deal event.
Nice.
Now the offer?
Lease a 2025 Escape Active All-Wheel Drive from 198 bi-weekly at 1.99% APR for 36 months with $27.55 down.
Wow, that's like $99 a week.
Yeah, it's a big deal.
The Ford It's a Big Deal Event. Visit your Toronto area Ford store or Ford.ca today.