So this is a talk about gene drives,
but I'm going to start by
telling you a brief story.
20 years ago, a biologist
named Anthony James
got obsessed by the idea
of making mosquitos
that didn't transmit malaria.
It was a great idea,
but pretty much a complete failure.
For one thing, it turned out to be
really hard
to make a malaria resistant mosquito.
James managed it, finally,
just a few years ago
by adding some genes
that make it impossible
for the malaria gene
to survive inside the mosquito.
But that just created another problem.
Now that you've got malaria-resistant
mosquito,
how do you get it to replace
all the malaria-carrying mosquitos?
There are a couple options,
but plan A was basically to breed up
a bunch of the new genetically-engineered mosquotos,
release them into the wild,
and hope that they pass on their genes.
The problem was that you'd
have to release
literally 10x the number of native
mosquitos to work.
So in a village with 10,000 mosquitos,
you release an extra 100,000.
As you might guess, this was not
a very popular strategy
with the villagers.
(Laughter)
Then, last January, Anthony James
got an email
from a biologist named
Ethan Bier.
Bier said that he and his grad student,
Valentino Gantz,
had stumbled on a tool that could not only
guarentee
that a particular gene trait
would not be inherited,
but that it would spread
incredibly quickly.
If they were right, it would basically
solve the problem
that he and James had been
working on for 20 years.
As a test, they engineered
two mosquitos
to carry the anti-malaria gene
and also this new tool,
a gene drive,
which I'll explain in a minute.
Finally, they set it up so that
any mosquitos
that had inherited the
anti-malaria gene
wouldn't have the usual white eyes,
but would instead have red eyes.
That was pretty much just
for convenience
so they could tell just at a glance
which was which.
So they took their two
anti-malarial, red eye mosquitos
and put them in a box with 30
ordinary white-eyed ones
and let them breed.
In two generations,
those had produced 38,000 grandchildren.
That is not the surprising part.
This is the surprising part:
given that you started with just
two red-eyed mosquitos
and 30 white-eyed ones,
you expect mostly white-eyed
descendents.
Instead, when James opened the box,
all 38,000 mosquitos had red eyes.
When I asked Ethan Bier
about this moment,
he became so excited, tht he was
literally shouting into the phone.
That's because getting only
red-eyed mosquitos
violates a rule that is the
absolute cornerstone of biology,
Mendelian genetics.
I'll keep this quick, but Mendelian genetics
says when a male and female mate,
their baby inherits half of its
DNA from each parent.
So if our original mosquito was aa
and our new mosquito is aB,
where B is the anti-malarial gene,
the babies should come out
in four permutations:
aa, aB, aa and Ba.
Instead, with the new gene drive,
they all came out aB.
Biologically, that shouldn't
even be possible.
So what happened?
The first thing that happened
was the arrival
of a gene-editing tool
known as CRISPR in 2012.
Many of you have probably heard
about CRISPR,
so I'll just say briefly that CRISPR
is a tool that allows researchers
to edit genes very precisely,
easily and quickly.
It does this by harnessing a mechanism
that already existed in bacteria.
Basically, there's a protein
that acts like a scissors
and cuts the DNA,
and there's an RNA molecule
that directs the scissors
to any point on the genome you want.
The result is basically a word processor
of genes.
You can take an entire gene out,
put one in,
or even edit just a single letter
within a gene.
And you can do it in nearly any species.
Okay, remember how I said
that gene drives
originally had two problems?
The first is that it was hard
to engineer a mosquito
to be malaria resistant.
That's basically gone now,
thanks to CRISPR.
But the other problem was
logistical.
How do you get your trait to spread?
This is where it gets clever.
A couple years ago, a biologist
at Harvard named Kevin Esvelt
wondered what would happen
if you made it so that
CRISPR inserted not only
your new gene,
but also the machinery
that does the cutting and pasting.
In other words, what if CRISPR
also copy and pasted itself.
You'd end up with a perpetual
motion machine for gene editing.
And that's exactly what happened.
This CRISPR gene drive
that Esvelt created
not only guarantees that a trait
will get passed on,
but if its used in the germline cell,
it will automatically copy and paste
your new gene
into both chromosomes of every
single individual.
It's like a global search and replace,
or in science terms,
it makes a heterozygous trait
homozygous.
So, what does this mean?
For one thing, it means we have
a very powerful,
but also somewhat alarming new tool.
Up until now, the fact that gene drives
didn't work very well
was actually kind of a relief.
Normally when we mess around
with an organisms's genes,
we make that thing less evolutionarily fit.
So biologists can make all the mutant
fruit flies they want
without worrying about it.
If some escape, natural selection
just takes care of it.
What's remarkable and powerful
and frightening about gene drives
is that that will no longer be true.
Assuming that your trait does not
have a big evolutionary handicap,
like a mosquito that can't fly,
the CRISPR-based gene drive
will spread the change relentlessly
until it is in every single individual
in the population.