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They may look ordinary, but
in September these tomatoes
became the first CRISPR-edited
food to go on sale to the public.
The tomatoes were developed
by Hiroshi Ezura (pictured) at
the University of Tsukuba in
Japan. They are available only
in Japan and have five times
the normal amount of the
nutrient GABA.
A lot more CRISPR foods
could soon start to arrive on
supermarket shelves in many
countries. Next up could be
a red sea bream edited to
produce more flesh. Others
in development include
wheat that produces less
of a carcinogenic substance
when toasted, a lettuce that
stays greener for longer and
strawberries that are less likely
to go mushy if damaged.CRISPR-
edited food
goes on sale
BiotechnologyRIGHT
:^ BEN^ PET
ER
CATC
HPOL
E;^ TOP:^ DEEPMINDIT TOOK decades for scientists to
unlock the structure of just 17 per
cent of the proteins in the human
body. But UK-based AI company
DeepMind raised the bar to
98.5 per cent in July when it
announced that its AlphaFold
model could quickly and reliably
calculate the way proteins fold. This
could lead to targeted drugs that
bind to specific parts of molecules.
We caught up with Pushmeet
Kohli at DeepMind to see how work
is progressing with mapping almost
every one of the more than
100 million known proteins that
have been sequenced from across
the tree of life.Were you surprised at the
success of AlphaFold, considering
that figuring out protein folding
previously required vast
supercomputers?
We went in with the thesis that
machine learning and AI had a role
to play. But a lot of the team were
uncertain as to whether this
problem was solvable. It came
as a very pleasant surprise.You plan to release many more
protein structures. Why not leave
the problem with scientists who
now have access to AlphaFold?
We open-sourced the model and
the code so anyone on the planet
can find the structure of any protein
that they want. We’re already seeing
universities and labs across the
world using our code. But the reason
we’re expanding the database
release is because there’s a lot
of time and investment involved,
and you don’t want different people
finding the structure of the same
protein again and again, right? ItInvestigating protein-folding
becomes easier with AI
DeepMind released 3D models of the
human proteome, and there is more
to come, finds Matthew SparkesInterviewA 3D model of a
fruit fly protein
from DeepMindwill be very useful if we actually just
do it once and for all, for everyone.Which are you working on first?
We’ve received feedback from the
community as to which organisms
and which types of proteins we
should prioritise next. So we’re
working along that road map,
eventually moving into what
we have committed to, which
is releasing the structure of
the entire protein universe.Does that involve new work, or
just applying AlphaFold at scale?
The team has been constantly
improving the accuracy of the
model. But we also want to expand
what AlphaFold can do. So, we’d
worked on single proteins, but
complexes are important because
when you look at the biologicalProfile
Pushmeet Kohli heads the
Robust and Reliable AI and AI
for Science teams at DeepMindmechanisms at play, it’s very
infrequent that there will be a
single protein just interacting with
some other sort of small molecule
in isolation. So, composite
structures – that’s what we have
been expanding AlphaFold to do.Will you ever reach a point where
you have mapped everything,
and AlphaFold can retire?
Proteins will change, life changes.
As evolution operates, you will see
different types of proteins coming
into play. And so AlphaFold will
have a life, not only in complexes,
but also in thinking about how
the structure is evolving.And what about covid-19?
Very early on, we found the
structure of all the SARS-CoV-2
proteins. Some had been
experimentally validated, but
many were very difficult to figure
out by experimental methods.
When scientists actually found the
structures, it was interesting to see
that ours were nicely consistent.
Now, with variants, again there
is an element that these small
mutations lead to changes in the
structure, but AlphaFold is not
currently sensitive to very small
changes. So we want to make sure
that future versions of AlphaFold
are able to really be sensitive
to mutations. ❚Michael Le Page18/25 December 2021 | New Scientist | 23