a16z Podcast - All About Synthetic Biology
Episode Date: July 6, 2022Over the last 20 years, the idea of “designing biology” has gone from science fiction to just science, as the field of synthetic biology has exploded, with applications from therapeutics to manufa...cturing and more. In this episode from January 2019, one of the pioneers in the field, professor James J. Collins of MIT, joins a16z general partner on the Bio + Health fund, Vijay Pande, and editorial partner Hanne Winarsky, to discuss the origins of synthetic biology or "synbio", to what "engineering and designing" biology really looks like in action and the disciplinary differences between how biologists and engineers see the world.
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Over the last 20 years, the idea of designing biology has gone from science fiction
to just science, as the field of synthetic biology has exploded, with applications from
therapeutics to manufacturing and more.
In this episode from January 2019, one of the pioneers in the field, Professor James J. Collins
of MIT, joins A16Z General Partner on the BioHealth Fund, Fiji Pondi, an editorial partner
Hannah Wynarski, to discuss the origins of SynBio, including what engineering and designing
biology really looks like in action, and the disciplinary differences between how biologists and
engineers see the world and much more.
Hi, and welcome to the A16Z podcast. I'm Hannah, and in this episode, General Partner on
the Biofund, Vijay Ponday and I talk all about the field of synthetic biology with Jim Collins,
professor of bioengineering at MIT, and one of the pioneers of the discipline of synthetic biology.
We talk about what engineering and designing biology really looks like when instead of engineering
electrons, you're engineering toggle switches for genes, including the scientific story behind
the creation of that very first gene toggle on and off switch. We also talk about the
disciplinary differences and synergies between how biologists and engineers see the world,
what the engineering and design principles, techniques, or approaches that work best when
applied to science, how that looks different when building a company in the space and thinking about,
for example, platforms versus products, and even how it's changing education in the field all the way
down to middle school. So let's start at the very beginning. How did the field first begin to
emerge? What's the sort of founding story behind SynBio? Yeah, you know, the very beginning really was
the island of misfit toys. So if you go back to the 1990s, the dominant story was the genome
effort. And what's interesting is the biomedical engineers did not play a major role in the genome
effort. In biomedical engineering departments, the curriculum, the research interests more or less
stopped at the tissue level and was only beginning to get interested in the cellular level.
In the late 90s, however, as the genome effort was really picking up speed and beginning to produce
these parts lists for different organisms, the leaders of the genome effort began turning to
the engineers and increasingly to physicists.
to figure out, help them figure out, how these parts put together.
Can you explain what the missing information specifically was?
So the sequencing would lead you to the ability to annotate the genome,
to identify coding regions, identify the genes, identify promoters,
but couldn't really give you information about dentaline networks
that were making up these living cells.
So in what way were the genes, the proteins, the RNA elements interconnected
and leading to the interesting biology and disease biology.
The notion even of network was not dominant or even prominent within molecular biology.
You said one thing that really struggling was you said it was not necessarily biologists, computer science and physicists.
You then had this effort to really try to pull the physicists and the engineers into molecular biology.
And why them?
I think because we deal with complexity well.
To get after what became systems biology was the recognition that you needed to embrace complexity.
Before the network, what was the predominant kind of idea?
You had really the fixation.
on the actions of single protein, single genes, and at the level of kind of integrating those,
you had pathways. And you began to see efforts primarily out of Stanford, beginning to use
mathematical modeling that opened up the doors for folks like me to do basically systems biology.
Could you reverse engineer these networks? And let's actually explain what you mean by that,
reverse engineering a large scale network, because that's not a concept that's native to traditional.
It's an engineering concept. So it's a strong electrical engineering.
engineering concepts. So the notion is that you have a system that's interconnected or
wired together. And so the example that could relate to many of the listeners would be the
wiring system or the wiring setup of your house. Say you buy a new house and you've got a
circuit breaker box down in the basement. And let's say it's not labeled by the previous owners.
Just like my house. Just like my house. So what do you do? You go down and you flip the different
switches on or off and you discover what they connect. You see you're beginning to reverse engineer the
circuitry of your house. You then, through additional experiments that you're
running the microwave same time with your toaster, that in fact, oh, those two circuits are
actually interconnect even further that's not represented by that. And you begin to infer the
underlying structure of the wiring diagram of your house. But our first response was to run away
from that problem as fast as we could, because there were insufficient data to do it. In the late
90s, we just had micro-rays, a peer technology that is no longer in vogue, but would allow you to
survey thousands of genes in their expression states simultaneously within a given cell. These are
incredibly expensive. And when I got pulled in, there were only seven publicly available
data sets. So the idea you could reverse engineer a large-scale network was ludicrous.
And what were those types of data that were lacking? So there was largely expression
data set. And in those days, it was really microarrays. So we, even though the technology
just appeared, we didn't have those data sets, we didn't have a wet lab, we didn't have the
capability. And so we began to think about, could you put together molecular parts in a network?
Could we instead take a tinkerer's approach to molecular biology? So the expression is the output.
What's the input?
Like, how were you perturbing it then?
Well, so on that time, we had no perturbation, right?
Pertubation would be that you're going to kick the system,
where you're going to stimulate the system in some light.
Flip the light switch on.
Let's say you have your radio on in your kitchen upstairs with the volume on.
You're going to run downstairs.
You're going to flip the switches one by one until you hit the volume go off.
That's a perturbation to your circuit that allows you to map out the circuit.
We introduced techniques to do that.
But even before we get there, we stumbled into what became,
synthetic biology, where we said, okay, could we instead of figuring out how these large-scale
networks are wired together, could we put them together ourselves? Could we do it with intense?
So could we design circuits with a desired architecture and a desired function?
And that's the key difference, right, in this entire approach, that you're designing.
Exactly. We are really doing biology by design. In some cases, we're taking natural parts
and putting them in new and different ways. In other cases, we're building new parts and then
putting those together in new or even established architectures. We spent about nine months thinking
about what we wanted to build, and we arrived at building a genetic toggle switch, and this was
motivated by electrical engineering, where toggle switches, which are also called flip-flops,
R.S. latches are very simple memory elements, memory switches that can be flipped between zero-one
in the binary state or on-off by just a transient electrical signal. Toggle switches are at the heart
a digital memory. And we
cycled through many different
schematics and circuit diagrams and arrived
at one that was basically a mutually inhibitory
network where we have
two genes that are set up so they always want to be
on, but they're arranged so they're trying
to shut each other off. And
we showed mathematically
and computationally that
you should be able to have it as a bi-stable
system. It either wants to exist in state A,
gene one is on, and gene two is off.
Or state B, gene two is on and gene one is off.
And in principle, you should be able to flip it
between those states by transient delivering a chemical that would shut off your currently
active gene, allowing the gene that had been kept off by that active gene, allowed to come
on that now would produce enough protein that would shut off the gene that had been on,
and you can remove your stimulus, and you flip from state to state B or state B to state.
It's like electrical engineering except not electrons.
It's now a wet circuit, but in this case we actually did mathematical modeling computation.
And now the next segue was I reached out to Eric Eisenstadt, who was a program officer
at the Office of Neighbor Research, who was running a gene circuit.
modeling program, and I told him what we're doing, and I more or less called him once a month
for over about six months, said, could you give us money to try to build this in a lab?
And he kept putting me off, putting off, and I basically warmed down.
I said, you know, I think this could be really big, but we need to be able to build this,
and I'd like this to be part of your program.
And was the reason why it wasn't clearly, I mean, clearly having an on-off switch like that
seems incredibly powerful, why was it not immediately just because it seemed so hard to do?
We had talked to about six or seven very serious molecular biologists who told us this couldn't happen.
This couldn't work.
They said, for it to work, you're going to have to have a very tight off state, two very tight off states.
That's going to be impossible.
You're going to have to introduce a very large plasmid.
It's going to put a burden on the cell.
The cell's not going to like this foreign element.
The joke was they used to pat us on our heads and say, boy, stick to engineering because biology is really complicated.
I mean, those do sound like reasonable concerns.
I had an incredibly talented graduate student, Tim Gardner, who was a mechanical engineering trained student,
out of Princeton. Tim presented our modeling. This was a famous O&R meeting where he was more
or less shouted off the stage by some very serious molecular biologists, including a future Nobel
Prize winner who said it was impossible. This could not work. And in part, Tim, who was green in
molecular biology, had been a mechanical engineer who had designed autonomous helicopters to fly
around Princeton, didn't know any molecular biology, presented this engineering concept.
Nonetheless, in nine months, he had a functioning bi-stable toggle switch. At the same time we were
doing this, Michael Illowitz and Stan Liebler, who were two physicists sitting in both the
physics department at Princeton and the molecular biology department at Princeton,
were taking a remarkably similar approach to synthetic gene circuits, completely independent
of us, and enbeknownst to us, in that we worked in E. coli with three different repressor
proteins using dynamical modeling. They worked in E. coli with the same three repressor
proteins using dynamic modeling. And instead of creating a toggle switch that consisted of two
genes trying to shut each other off.
They created what they called a repressulator,
a ring oscillator, similarly motivated by
electronics, electrical engineering. They consisted
of three genes in series. A tries to
shut off, B, B tries to shut off, C, C
tries to show up A. Well, it's the same parts, just
different circuit. Exactly same parts, different circuit.
They submitted to nature. We submit ours to nature.
They end up being published at the
launch, the turn of the century, in
January, late January, in nature
back to back. The next week,
the head editorial said, oh,
you know, physicists are beginning to move into
molecular biology, and they said you should look back at those two papers because there's something
interesting going on. You know, you raise an interesting point about how everyone on the biology side
thought this wasn't possible, almost like the biologists, some of them have an immune response
against engineering. That's a great way to put it. And that seems to continue even to today.
It is, I have many, many close friends and colleagues who are biologists, but I think
within different academic disciplines, there's often too much tribalism. So the very common
critique that we get to, so they're not biologists, or they're not chemists, or they don't
know basic biology.
on a basic chemistry.
And I'm not, yes, yes, yes, and yes.
I don't think it's fair, though.
And I think that these problems
really can benefit from a interdisciplinary approach
and different perspectives.
We don't know the detail at the level
that the biologists do.
And one of the more common critiques we'll get
and any time we submit papers to molecular biology journals
is that all the columns have,
they don't have sufficient controls that were done.
But I maintain that in almost every biology experiment
paper I've read, they've never had the controls
that I'd like to see,
which is the idea that you can knock out a gene
and that what's lacking
and now can be attributed the gene
is absurd from a system.
It's interesting because, you know,
if you think about an electro engineer
to a physicist,
an electric engineer might not understand
like a PNP junction
and a transistor the way a physicist might.
Right.
But can still use them
and make parts out of them
and still make things.
And so I think there's just a role
for each one of them.
But there's a fundamental difference
between sort of doing science
and doing engineering.
Yes.
And that culture clash is pretty distinct.
Yeah, I was just going to say
it's not entirely just that academic tribalism,
right?
It's a discomfort
with a different kind of mode
of knowledge. I would love to hear if you can describe a little bit more what beyond the tribalism
is valid, what you try to think about, or what you reject entirely. Yeah, no, it's fair. I think
the differences in science and engineering are healthy and valuable. I think in many cases,
engineering benefits from science, and that most of the work that we do from an applied
standpoint is really looking to see in what way can we utilize or exploit principles, discoveries
that have been made in science and move toward an application.
the same way, science benefits tremendously from engineering in that as a new technology gets
developed, it can just open up the ability to address and answer new and different questions.
And so there really is a great synergy. And it becomes interesting on the conference.
Well, there's a synergy, but there is still a sort of a nominal difference in how they view
the world. It is very different, right, in that the engineer often is very purposeful,
whereas the scientist is really driven more by curiosity. Can we discover? Can we learn more?
And it's not that the engineer doesn't want to learn one.
An engineer can do remarkably well in many instances with little, if any, understanding of mechanism.
And that we'll get after a black box, so you can represent a model that gives you some sense of relation to be the input and output of, say, going back to our perturbation.
And yet that model may have little, if anything, to do with the underlying biology, but it nonetheless has predictive value that's useful to get after a given application of purpose.
That drives my biologist friends nutty.
But that doesn't mean that the engineer is uninterested in mechanism.
that the more we know about mechanism, the better we can do, the more fac-out we are.
And the more predictive of the model.
The more predictive of the model, absolutely.
Let's talk quickly about the bacteria.
So why E. coli?
You know, on E. coli, the E. coli was easy to pick.
It was and remains really the workhorse.
Broadly molecular biology.
It's been very well studied.
It's still not fully understood.
But we had a number of well-characterized parts, established protocols.
And so a couple engineers could relatively quickly get up to speed to do experiments on it.
Having said all that, I'll give two points.
One is that when I first moved into space,
I was told not to work on bacteria
because everything's been worked out.
We understand it turned out to be far from true.
And second, linked to that is that it's fascinating to me
that this still is a high percentage of the genes
are not functioning-outitated in the E. coli, 30 to 40%.
Not unless it was enough there that we could begin to design
and build with some level of predictability
and some level of comfort that you could insert these circuits
and get them to function the way you like.
Can you tell us about the latest in bacteria
that you guys are now working on.
It was then a very nice piece by Louis Serrano and Attila Bexki
that came out also in E. coli about four months later in nature.
And then it was about going to have years of nothing coming out
because the field didn't exist.
You had a number of modeling papers,
but nobody really had experiments going.
We and others then got excited about engineering bacteria,
and particularly E. coli, as living technologies,
as programmable cells that could sense something in the environment,
make a decision, and act on it.
And in 2004, began creating these programmable cells
to be wholesale biosensors.
But the notion of putting it in somebody's body was crazy.
The idea of the microbiome was not prominent.
Nobody was talking about it.
And so we talked about how you could engineer these,
place them on chips, computer chips,
electronic chips, and placed them in a quad of the university to see,
was there an anthrax release or was there detectors?
Detectors.
Detectors of lead paint in a home or on lead on imports.
And showed that you could engineer these quite readily.
And then by the late 2000,
early this decade, a lot of excitement arose.
Could you engineer bacteria to serve as living diagnostics and living therapeutics?
Could we engineer bacteria to detect and treat cholera?
And we decided to engineer lactoccus lactose lactose,
which is found in dairy products, fermented milks,
and showed you could engineer it to eavesdrop on cholera
by taking the quorum sensing system out of cholera
and repurposing it into our lactose.
And that you could then harness
the natural lactic acid-producing capability of lactis to treat or inhibit cholera infections.
It's incredible that you were tackling from the very beginning both the diagnostic
and the therapeutic aspects. Did that not seem like biting off a lot?
No. No, I mean, engineers, we probably take on too much. We, engineers are famous for being
able to focus, but do it with lack of focus, in the sense that they can take on big problems,
and thus lack of focus, but take on those big problems and try to accomplish it.
We thought for sure it would be fine, even though it's really viewed as two distinct fields.
And we launched what became SynLogic.
And in a matter of small number of years, they now have multiple clinical trials.
They're a public company, and they're using engineered E. coli to treat different rare genital metabolic disorders to treat inflammatory bowel disease and now to treat cancer.
What are the engineering principles that you tend to think are the most useful in this crossover space that are kind of your north stars?
I mean, part of is that like, you know, when one is trained as an engineer, you learn certain principles.
Do you think bioengineers can take some of those existing engineering principles and bring them over?
Or are bioengineers inventing new engineering principles?
You know, it's an interesting question.
I think that in many cases it's more techniques and approaches than it would be principles.
I tend to think of principles really being technically grounded notions that have established a relationship
between certain variables of parameters that you come in.
So what's interesting is that a major challenge in engineering biology, more broadly,
specifically synthetic biology, is that we don't really know the design principles.
That's right.
And that we'll put things together, and they'll be motivated by electrical engineering,
but recognizing that obviously we're not making it in electrical or electronic circuit.
But in many cases, the circuits don't work at the level as well as we like or as we predicted.
And I think it reveals that we don't have those design principles in that establishing the
relationships, for example, that really got electrical engineers, we're still, I wouldn't
say haphazably put them together, but it's still very much a try.
trial and error, and it leaves great opportunities for getting after design principles.
At present, I think for really the first two decades of synthetic biology, it's really been
more engineering approach, and that is this idea that you can design a schematic for your
circuit, find the right parts, put them together, and begin now characterizing both the parts
and they're functioning in a circuit, and iterably improve upon the behavior.
The engineering will go after in a highly parallel fashion.
So as he was doing the toggle switch, he would explore two dozen possibilities simultaneously
and do it relatively quickly and identify the one or the couple that gave him the closest
to what he was going after.
And then he would expand around that after a couple weeks and do this iteratively and get
through what could be basically many dozens and hundreds of possibilities.
Was that because of just a different approach or was the technology actually enabling him
to do that for the first time?
It was really, I think, more of the approach.
And the distinction is that the young biologists in my lab will instead pick one design, one embodiment of that design, and they're going to drill down in great detail over, instead of two weeks, over six weeks, realize that it didn't work, and then they're going to go and create the next design on the basis of that, drill down one by one.
More cereal.
And they will have a much greater in-depth understanding of that one case.
but it's going to take them 20 times longer
to get to a functioning prototype.
And so there is where there still is really
a cultural divide on the approaches.
Would they argue there's something lost
when you do it simultaneously,
the engineering-led approach?
You know, I haven't heard them say that it's lost.
Because otherwise, they would say that...
Like, why not?
Yeah, you know, there would be interesting
is that I do think they feel
that they'd like to get an in-depth understanding.
And again, it's now coming up
against the culture clashes.
The scientist is curious, wants to understand.
is looking for discovery, the engineer wants to get it to work.
And doesn't necessarily care do they understand how it works, but that it worked.
You know, the scientist really wants to understand,
and making it work is proof of understanding,
but understanding is the real ends, and making it work is the means.
Whereas from the engineer, making it work is the ends.
Yes.
And understanding is the means.
Yes.
And because both care about the ends, the means actually they care less about.
Yeah.
And so they're optimizing for different things,
even though from the surface they may look like they're doing the same thing.
And I'll draw an interesting further distinction on level of comfort is that I've been in the
Sin Bio world now for about two decades, and I have yet to get significant buy-in from the
engineers in my lab for doing directed evolution.
So you would think after you get your prototype that's working okay, but not at the level
that you like, that you would be open to using one of the great techniques.
Noble prize winning techniques.
Nobel by Francis Arnold, who's considered part of our community, and she's marvelous
and a great pioneer.
That you would use directed evolution techniques
to optimize U.S.
is taking advantage of this beautiful feature biologic systems.
It is completely foreign and an enthema to the engineers
in that they view it as cheating,
that they want to be able to themselves retweak this system
by design to get it to functionally.
The chemists and the biologists in my lab
much more readily are embracing.
That's kind of funny.
And I think there's now going to be three prongs
Because, you know, the success of direct evolution over most rational methods,
let's say protein design, enzyme design, something like that.
It's just really hard to do that rationally.
There's a third arm, you have rational design where maybe trying to use physics and quantum mechanics,
the directed evolution where you just sort of optimize for some function.
Machine learning is an interesting way to sort of have it both ways.
And that, you know, from all the data you get for directed evolution,
could you use that to actually come up with a predictor or readout?
I do think machine learning within synthetic biology is one of the,
the next frontiers.
And the challenge there is a couple levels.
One is can we have enough data to feed the models?
And by there, the data is can we generate enough diversity
and can we functionally characterize that diversity to feed the algorithm?
Absolutely.
I think the marriage of direct evolution with synthetic biology really is also the future,
coupled to machine learning.
Synthetic biology allows you to cheat in that it can move you in that genotype, phenotype space
into an area that you can't get to readily through.
through evolution.
Can you break that down?
If I'm going to tweak a system, whether it's naturally evolving or I'm going to use directed
evolution to evolve it, you're really going to move incrementally.
Now, at fairnish, maybe you get a five-fold or even a hundredfold or 200-fold after many,
many rounds, as Francis showed, for enzymatic activity.
But in cases still, that you're going to be kind of starting in some place, say if you've
got on your x-axis genotype and your y-axis phenotype, you're stuck over in this
corner.
direct evolution will allow you to move from that corner,
but you're going to stay in the general space.
You're going to kind of randomly move around.
Synthetic biology allows you to take your starting point
far away from that corner.
Or to hop over into another spot
and then fluctuate around using direct evolution.
And so it's the marriage of the two
that allows you to explore spaces
that would take hundreds of years,
if not millions or billions,
or what really has happened on the planet.
It sounds like wormholes to another spot.
You've seen evolutionary approaches applied to electronic circuits, right?
Where they make a radio and it's just like some bizarre circuit that works.
But it's hard for human beings to understand.
It's funny with biologists and engineers are two different cultures.
The machine learning is like a third one still, possibly.
Do you think that science as a whole will be moving in this direction going forward more with this blend of engineering approaches?
There's been a blending between science engineering, especially in any of these interdisciplinary activities.
I have Stanford colleagues that were trained as in.
engineers, but are writing science papers and doing science. And, you know, I'm trained as a
physicist, but, you know, I've moved into engineering. And I think when you're at the
interdisciplinary sort of interface, a lot of people do whatever it takes. Yeah. And so that
spirit is there. Now, there will be people who stay in their domains that are, that just
love biology or just doing biology, and that's all they want to do. And that's also fine. But I think
the rise of the interface has really sort of led to this new area. I do see more and more of the
interface between quantitative approaches and science, not per se engineering, but quantitative
advances of really getting after data analytics. And embracing this notion that machine learning
and more broadly, computer-based modeling and data analysis, is becoming dominant as people are
trying to figure out how to embrace our increased ability to collect a lot of data and analyze data.
Yes, one thing that I was talking about internally and almost as an investing theme is, you know,
we're a synthetic biology on the hype cycle. You know, my read-on is it's gone past
peak hype, and it's sort of in the, now getting into production, getting too useful.
Synthetic biology has been hampered by basically too much hype from its very beginning.
And I think there's multiple reasons for that.
One is that it's a very romantic, exciting field.
This idea that you can engineer life to address some of the world's biggest problems is exciting.
And second is that I think we've had an unchecked field that is not yet an established discipline.
And so you have fringe elements that will grab their 15 minutes of fame to,
put out stuff that is frankly not realistic.
Sounds right, likely will work, but could take centuries to accomplish.
And we've been hurt by that.
Now, if you go back to the mid-2000s, our field took a strong left turn toward bioenergy.
And there are many factors driving it, starting around 2004, where you had gas prices
going north of Fort Hollis at the first time.
You had then President Bush calling for alternatives to petroleum.
You had large oil companies looking for alternatives.
you had venture capitalists seeing, boy, there was a real opportunity here.
And they heard about this exciting new space inthetic biology
where people were engineering bacteria and fungi
to invert different food stuffs and sunlight into fuel.
Sounds like a panacea.
Sounds brilliant.
And they poured hundreds of millions of dollars into it.
You had Department of Energy and other national funding
similarly pouring huge monies in.
And it was too early.
Too early in that you had brilliant academics
showing that you could do this in small bioreactors
in their lab at university.
But to think you could scale this up to the million-liter bioreactor was absurd.
And that you had loss of efficiencies, you just couldn't compete economically.
And so many of these early companies got to be pretty good at producing $1 worth of gasoline,
but it cost them $8 to do it, which was a horrible business model.
Yeah.
Unless gas went up 10x.
Unless gas went up 10x.
Yeah.
And so, you know, that part of the fuel collapsed on itself on the hype.
What happened then in the late 2000s when the bioenergy focused.
hit Earth, came back down, is that the field got grounded and really began building out
more broadly tools, constructs, platforms, and turned toward biomedicine. I think the field got
really re-grounded and saw that there was great potential. And alongside that, you had other
developments in biotech that were complementary to synthetic biology, broadly engineered cell
therapy outside of Sinbao, but like Carti therapy. And you then had the biotech discovery
or development, I should say, of the century,
which is on CRISPR, enabling very rapid, easy,
inexpensive genome editing that together now opened up possibilities
that just weren't going to be readily apparent to us 10 years ago.
I mean, in other directions that go for molecules
that are just worth more than oil.
I mean, a barrel of perfume is a lot more expensive than a barrel of oil.
Yeah, and so then the question is,
can you gain a lot by engineering a living cell to produce it
versus using a chemist in a regular petri dish?
Yeah, yeah, yeah.
And that's where I think the jury's still out on many of these companies.
It seems like they can make it.
Now, the question is, is this our business model there?
Yeah.
I'd love to know about company building in this space, what that looks like.
How is it actually different building a company in this space versus traditional bio?
Yeah, and there's like two models.
There's how to build a traditional bio company and how to build like an engineering-driven tech company.
And this seems distinct from both.
You have to make a decision.
And that is, are you a platform company or are you a product company?
and what happens is that the companies in this space
typically are being launched by the academic
as the academic comes in thinking they can do everything
and so they want it to be a platform company
that's feeding a product company
and when you then talk to the real company builders
and say no we've got to make commitment
and I think they're hybrids
I mean you can have these multi-product platform companies
let's break it down what you specifically mean by that
so by that I mean that on a platform company
would be that I'm going to develop internal capabilities
they'll allow me, for example, to engineer bacteria to sense different things and produce
molecules that would have an impact.
To make many, many products.
To make many, many products.
And it might be that I'll be in focus on therapeutics, but that I could have the capability
to engineer E. coli that would allow me to address 20 different diseases.
And that my model then might be I'm going to team up and partner with farmer and large
biotech.
The product company would be, no, you know what I'm going to, I'm going to engineer bacteria
to go after your recycled disorders.
And I'm going to launch a clinical trial.
and that's my product.
I'm going to move it toward clinic.
I could build and maybe have one or two other internal programs.
But it's a struggle.
In what way are you going to play it in this space?
And you see companies that are playing both ways.
Synlogic is really a product.
It's a therapeutic company that is focusing on developing
therapeutic products that will go into patients
and that they themselves,
maybe through partnerships to market them, but develop them.
Ginko, BiWorks, which I'm not involved,
is more of a platform company,
developing capabilities to engineer organisms to optimize enzymes and through a partnership model
could have a platform. The platform companies in this place are playing to the technology investors
and the product companies are playing more toward the traditional biotech investors.
I think that's starting to change in that I think there's been cycles. So even the biotech investors
are curious about platforms. I'm encouraged to hear that, right? It goes booms and bust. So when the
NASDAQ collapsed 17 years ago in 2001, the local biotechs ran from platforms. Prior to that, from
98 to 2001, it was platform
happy. And then they
became fixated in their products to a fault
in that many of the companies would rush
a molecule into trials
to say they had a product. And most of those
molecules were horrible and ended up failing. The other thing that happens
is that it's very tempting
once you've built a platform and you actually have
an asset that is, let's say, past
phase one or phase two, that becomes
worth so much. It's a hard
financial decision to take money away
from that and put it to other things. And then
you become a platform company becomes a
a single asset company.
And I think that the model is that if you can move your assets, develop assets, move them
at trials, you then also have that struggle.
Do you now flesh out your platform to, and I see that in companies I advise and I'm involved
with?
And I'm a big believer that you should also have the long view, that it's worth building
that internal capability, whether it's around design or whether it's around manufacturing.
So, for example, having the ability to manufacture your product in-house significantly
increases your value.
What is the go-to-market like in this space when you're building these synthetic bio products or platforms?
What is the way you see this kind of entering the system?
How is that process happening?
I think the challenge is really making a commitment as to what is your go-to-market.
Because in many cases, these early companies, particularly coming out academically, are aspirational in that you want to take on all these problems.
And yet, if you're really then going to get down, it's very hard to go to market.
your choice. And then it really becomes specific. So in one area I'm involved with
is diagnostics, is it through a partnership model, or are you really going to develop
a product, get it to approval, and now we're introducing the market? Well, that poses
all fascinating new challenges of who's going to manufacture, how you're going to distribute,
what are your distribution? And in many cases, I think in synthetic biology, it's still
at a stage where either they're following traditional paths, and the traditional paths in
therapeutic space and even diagnostics is through partnerships. And so it's a
what stage. But then it's the challenge is at what point you partner. You partner too early,
you're not going to get as much value for your investors. And so can you hold it off? Can you maybe
partner off maybe less essential, less central? Well, and part of it is that, you know,
syntag biology has the hope to do so many different things. And almost now you have the challenge
of figuring out of all the things you could do. What should you do? It is. You know, and that's a
hard choice to make because it's really opportunity costs on the negative that will drive many of these
companies bad. And it's really what makes or breaks companies. And separate from the technology,
It really comes down to the team that can make those decisions and that has the flexibility to change up depending on markets to change or opportunities that come or go.
I wanted to think about how this field is now sort of percolating down into education.
And I was really surprised to read that it's percolating quite far down into these, you call them bio bits, these kits, these classroom kits.
Can you tell us a little bit about those and what kinds of kids are using them with their learning?
Yeah, so I'm 53 years old.
The best Christmas present I ever got was when I was in third grade.
from my dad's mom
and it was one of the old classic chemistry kits
big yellow tin
that had these powdered chemicals
and I did all these different experiments
and they had fantastic combustibles
and explosives.
I don't think you can't buy those anymore.
You cannot buy them.
Because you can't blow yourself up.
You can't blow yourself up
or poison things
and set things on fire.
But you have these marvelous hands-on activities
for chemistry.
You have marvelous hands-on activity
for electronics, robotics,
mechanical-ident-old erected kit.
But you don't have anything
for biotech.
And this motivated us
could we develop synthetic biology tool?
So these BioBits kits are new synthetic biology educational kits
that my lab have co-developed with Mike Jewett from Northwestern.
So with Ali Huang, Peter Nigh Gunn, and Jess Stark,
grad students and postdocs in our respective labs,
we developed these kits that are basically motivated by chemistry kits,
but for synthetic biology.
Mom's not going to be happy if Sally's growing her brother's stem cells in the kitchen.
And what we used were self-free extract.
So you can open up a living cell,
remove the machinery of the cell.
And typically you'd play with these in a test tube or petri-dives,
but we showed you could freeze-dry them in pellet form.
And so now you have shelf-stable, room-temperature-stable,
pellets that you then add to water,
and in now your test tube at your home,
you have the machinery of a cell that's outside a living cell.
Oh my gosh, it's like those owl pellets
that you can bring home from preschools, but for cells.
But it's for cells that now allow you to play with how proteins are made,
how circuits are made, and we created these biobit kits that already go down to the middle school
level, really with the idea to introduce kids at an early age to the ability to engineer biology,
given that I think in many ways this century is going to be the century of biology and really
put a point on it. I think it's going to be the century of synthetic biology. And we need to get
the youth excited about the potential of this field to really change the world.
So what do you think changes when you start introducing that framework and that mindset so early?
What do you think in kind of biology, design thinking fundamentally changes?
Well, I think you expose the young people, so they begin to see the world differently.
So if you're a designer, you're going to see a problem and think about how you can design it.
Just the way your chemistry set did.
Well, you think about some of the greatest challenges that we face right now, world hunger, global warming, these types of things are inherently interlaced between chemistry and biology.
Yes.
And if you want to have impact on these things, you'll have to be able to engineer biology to some extent.
Yes.
I think that synthetic biology will provide solutions.
that are going to contribute to solving broadly environmental challenges.
You're increasingly seeing companies turn towards synthetic circuits
to alter traits in a programmable fashion of plants
and to enable them to be more robust to pathogens.
I think climate is really just beginning to excite the community
and broadly environmental issues on two counts.
One is, in what way could we use algae and other organisms
to pull more carbon out of the atmosphere?
Can we help reverse the trend on using biology?
And second, can we address issues such as the breakdown of coral reefs?
So could we create synthetic ecosystems, synthetic microbiomes for coral reefs to make them heat-tolerant
and to prevent the bleaching of schemes?
So I think those two areas are ones that I see in the next 10 years.
We're going to see a good amount of activity.
And we need more talent in these spaces.
We've got to reach out and make them comfortable with these technologies
and introduce from the concepts the eventual design principles.
And that's just the next 10 years.
I mean, we talk about the biocentric.
The finding is, I think, people tend to overestimate what, you know,
what people can do in a few years.
That's what generally feel like and underestimate what you can do in 10 years.
I don't even think we can conceptualize what 50 years is going to look like.
Thank you so much for joining us on the A16Z podcast.
Thanks for having me.
Thank you.