Nature Communications,
Год журнала:
2023,
Номер
14(1)
Опубликована: Июнь 1, 2023
Abstract
Although
homologous
protein
sequences
are
expected
to
adopt
similar
structures,
some
amino
acid
substitutions
can
interconvert
α-helices
and
β-sheets.
Such
fold
switching
may
have
occurred
over
evolutionary
history,
but
supporting
evidence
has
been
limited
by
the:
(1)
abundance
diversity
of
sequenced
genes,
(2)
quantity
experimentally
determined
(3)
assumptions
underlying
the
statistical
methods
used
infer
homology.
Here,
we
overcome
these
barriers
applying
multiple
a
family
~600,000
bacterial
response
regulator
proteins.
We
find
that
their
DNA-binding
subunits
assume
divergent
structures:
helix-turn-helix
versus
α-helix
+
β-sheet
(winged
helix).
Phylogenetic
analyses,
ancestral
sequence
reconstruction,
AlphaFold2
models
indicate
facilitated
switch
from
into
winged
helix.
This
structural
transformation
likely
expanded
specificity.
Our
approach
uncovers
an
pathway
between
two
folds
provides
methodology
identify
secondary
structure
in
other
families.
Signal Transduction and Targeted Therapy,
Год журнала:
2023,
Номер
8(1)
Опубликована: Март 14, 2023
Abstract
AlphaFold2
(AF2)
is
an
artificial
intelligence
(AI)
system
developed
by
DeepMind
that
can
predict
three-dimensional
(3D)
structures
of
proteins
from
amino
acid
sequences
with
atomic-level
accuracy.
Protein
structure
prediction
one
the
most
challenging
problems
in
computational
biology
and
chemistry,
has
puzzled
scientists
for
50
years.
The
advent
AF2
presents
unprecedented
progress
protein
attracted
much
attention.
Subsequent
release
more
than
200
million
predicted
further
aroused
great
enthusiasm
science
community,
especially
fields
medicine.
thought
to
have
a
significant
impact
on
structural
research
areas
need
information,
such
as
drug
discovery,
design,
function,
et
al.
Though
time
not
long
since
was
developed,
there
are
already
quite
few
application
studies
medicine,
many
them
having
preliminarily
proved
potential
AF2.
To
better
understand
promote
its
applications,
we
will
this
article
summarize
principle
architecture
well
recipe
success,
particularly
focus
reviewing
applications
Limitations
current
also
be
discussed.
Nature,
Год журнала:
2023,
Номер
625(7996), С. 832 - 839
Опубликована: Ноя. 13, 2023
AlphaFold2
(ref.
1)
has
revolutionized
structural
biology
by
accurately
predicting
single
structures
of
proteins.
However,
a
protein's
biological
function
often
depends
on
multiple
conformational
substates2,
and
disease-causing
point
mutations
cause
population
changes
within
these
substates3,4.
We
demonstrate
that
clustering
multiple-sequence
alignment
sequence
similarity
enables
to
sample
alternative
states
known
metamorphic
proteins
with
high
confidence.
Using
this
method,
named
AF-Cluster,
we
investigated
the
evolutionary
distribution
predicted
for
protein
KaiB5
found
predictions
both
conformations
were
distributed
in
clusters
across
KaiB
family.
used
nuclear
magnetic
resonance
spectroscopy
confirm
an
AF-Cluster
prediction:
cyanobacteria
variant
is
stabilized
opposite
state
compared
more
widely
studied
variant.
To
test
AF-Cluster's
sensitivity
mutations,
designed
experimentally
verified
set
three
flip
from
Rhodobacter
sphaeroides
ground
fold-switched
state.
Finally,
screening
families
without
fold
switching
identified
putative
oxidoreductase
Mpt53
Mycobacterium
tuberculosis.
Further
development
such
bioinformatic
methods
tandem
experiments
will
probably
have
considerable
impact
energy
landscapes,
essential
illuminating
function.
PLoS Computational Biology,
Год журнала:
2022,
Номер
18(8), С. e1010483 - e1010483
Опубликована: Авг. 22, 2022
The
unprecedented
performance
of
Deepmind's
Alphafold2
in
predicting
protein
structure
CASP
XIV
and
the
creation
a
database
structures
for
multiple
proteomes
sequence
repositories
is
reshaping
structural
biology.
However,
because
this
returns
single
structure,
it
brought
into
question
Alphafold's
ability
to
capture
intrinsic
conformational
flexibility
proteins.
Here
we
present
general
approach
drive
model
alternate
conformations
through
simple
manipulation
alignment
via
silico
mutagenesis.
grounded
hypothesis
that
must
also
encode
heterogeneity,
thus
its
rational
will
enable
sample
conformations.
A
systematic
modeling
pipeline
benchmarked
against
canonical
examples
applied
interrogate
landscape
membrane
This
work
broadens
applicability
by
generating
be
tested
biologically,
biochemically,
biophysically,
use
structure-based
drug
design.
AlphaFold2
has
revolutionized
protein
structure
prediction
by
leveraging
sequence
information
to
rapidly
model
folds
with
atomic-level
accuracy.
Nevertheless,
previous
work
shown
that
these
predictions
tend
be
inaccurate
for
structurally
heterogeneous
proteins.
To
systematically
assess
factors
contribute
this
inaccuracy,
we
tested
AlphaFold2's
performance
on
98-fold-switching
proteins,
which
assume
at
least
two
distinct-yet-stable
secondary
and
tertiary
structures.
Topological
similarities
were
quantified
between
five
predicted
experimentally
determined
structures
of
each
fold-switching
protein.
Overall,
94%
captured
one
conformation
but
not
the
other.
Despite
biased
results,
estimated
confidences
moderate-to-high
74%
residues,
a
result
contrasts
overall
low
intrinsically
disordered
are
also
heterogeneous.
investigate
contributing
disparity,
variation
within
multiple
alignments
used
generate
Unlike
regions,
whose
show
conservation,
regions
had
conservation
rates
statistically
similar
canonical
single-fold
Furthermore,
lower
than
either
or
regardless
conservation.
high
fold
switchers
indicate
it
uses
sophisticated
pattern
recognition
search
most
probable
conformer
rather
biophysics
protein's
structural
ensemble.
Thus,
is
surprising
its
often
fail
proteins
properties
fully
apparent
from
solved
Our
results
emphasize
need
look
as
an
ensemble
suggest
systematic
examination
sequences
may
reveal
propensities
stable
Nature Communications,
Год журнала:
2024,
Номер
15(1)
Опубликована: Март 27, 2024
Abstract
This
paper
presents
an
innovative
approach
for
predicting
the
relative
populations
of
protein
conformations
using
AlphaFold
2,
AI-powered
method
that
has
revolutionized
biology
by
enabling
accurate
prediction
structures.
While
2
shown
exceptional
accuracy
and
speed,
it
is
designed
to
predict
proteins’
ground
state
limited
in
its
ability
conformational
landscapes.
Here,
we
demonstrate
how
can
directly
different
subsampling
multiple
sequence
alignments.
We
tested
our
against
nuclear
magnetic
resonance
experiments
on
two
proteins
with
drastically
amounts
available
data,
Abl1
kinase
granulocyte-macrophage
colony-stimulating
factor,
predicted
changes
their
more
than
80%
accuracy.
Our
worked
best
when
used
qualitatively
effects
mutations
or
evolution
landscape
well-populated
states
proteins.
It
thus
offers
a
fast
cost-effective
way
at
even
single-point
mutation
resolution,
making
useful
tool
pharmacology,
analysis
experimental
results,
evolution.
bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2022,
Номер
unknown
Опубликована: Окт. 17, 2022
Abstract
AlphaFold2
(AF2)
has
revolutionized
structural
biology
by
accurately
predicting
single
structures
of
proteins
and
protein-protein
complexes.
However,
biological
function
is
rooted
in
a
protein’s
ability
to
sample
different
conformational
substates,
disease-causing
point
mutations
are
often
due
population
changes
these
substates.
This
sparked
immense
interest
expanding
AF2’s
capability
predict
We
demonstrate
that
clustering
an
input
multiple
sequence
alignment
(MSA)
similarity
enables
AF2
alternate
states
known
metamorphic
proteins,
including
the
circadian
rhythm
protein
KaiB,
transcription
factor
RfaH,
spindle
checkpoint
Mad2,
score
with
high
confidence.
Moreover,
we
use
identify
minimal
set
two
predicted
switch
KaiB
between
its
states.
Finally,
used
our
method,
AF-cluster,
screen
for
families
without
fold-switching,
identified
putative
state
oxidoreductase
DsbE.
Similarly
DsbE
thioredoxin-like
fold
novel
fold.
prediction
subject
future
experimental
testing.
Further
development
such
bioinformatic
methods
tandem
experiments
will
likely
have
profound
impact
on
energy
landscapes,
essential
shedding
light
into
function.
Nature Communications,
Год журнала:
2024,
Номер
15(1)
Опубликована: Фев. 5, 2024
Abstract
The
ability
to
computationally
generate
novel
yet
physically
foldable
protein
structures
could
lead
new
biological
discoveries
and
treatments
targeting
incurable
diseases.
Despite
recent
advances
in
structure
prediction,
directly
generating
diverse,
from
neural
networks
remains
difficult.
In
this
work,
we
present
a
diffusion-based
generative
model
that
generates
backbone
via
procedure
inspired
by
the
natural
folding
process.
We
describe
as
sequence
of
angles
capturing
relative
orientation
constituent
atoms,
denoising
random,
unfolded
state
towards
stable
folded
structure.
Not
only
does
mirror
how
proteins
natively
twist
into
energetically
favorable
conformations,
inherent
shift
rotational
invariance
representation
crucially
alleviates
need
for
more
complex
equivariant
networks.
train
diffusion
probabilistic
with
simple
transformer
demonstrate
our
resulting
unconditionally
highly
realistic
complexity
structural
patterns
akin
those
naturally-occurring
proteins.
As
useful
resource,
release
an
open-source
codebase
trained
models
diffusion.
Nature Communications,
Год журнала:
2024,
Номер
15(1)
Опубликована: Авг. 24, 2024
Abstract
Recent
work
suggests
that
AlphaFold
(AF)–a
deep
learning-based
model
can
accurately
infer
protein
structure
from
sequence–may
discern
important
features
of
folded
energy
landscapes,
defined
by
the
diversity
and
frequency
different
conformations
in
state.
Here,
we
test
limits
its
predictive
power
on
fold-switching
proteins,
which
assume
two
structures
with
regions
distinct
secondary
and/or
tertiary
structure.
We
find
(1)
AF
is
a
weak
predictor
fold
switching
(2)
some
successes
result
memorization
training-set
rather
than
learned
energetics.
Combining
>280,000
models
several
implementations
AF2
AF3,
35%
success
rate
was
achieved
for
switchers
likely
AF’s
training
sets.
AF2’s
confidence
metrics
selected
against
consistent
experimentally
determined
failed
to
discriminate
between
low
high
conformations.
Further,
captured
only
one
out
seven
confirmed
outside
sets
despite
extensive
sampling
an
additional
~280,000
models.
Several
observations
indicate
has
memorized
structural
information
during
training,
AF3
misassigns
coevolutionary
restraints.
These
limitations
constrain
scope
successful
predictions,
highlighting
need
physically
based
methods
readily
predict
multiple
