Molecular basis of proton sensing by G protein-coupled receptors
Cell,
Год журнала:
2025,
Номер
unknown
Опубликована: Янв. 1, 2025
Язык: Английский
Molecular basis of proton-sensing by G protein-coupled receptors
bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2024,
Номер
unknown
Опубликована: Апрель 18, 2024
Abstract
Three
proton-sensing
G
protein-coupled
receptors
(GPCRs),
GPR4,
GPR65,
and
GPR68,
respond
to
changes
in
extracellular
pH
regulate
diverse
physiology
are
implicated
a
wide
range
of
diseases.
A
central
challenge
determining
how
protons
activate
these
is
identifying
the
set
residues
that
bind
protons.
Here,
we
determine
structures
each
receptor
understand
spatial
arrangement
putative
proton
sensing
active
state.
With
newly
developed
deep
mutational
scanning
approach,
determined
functional
importance
every
residue
activation
for
GPR68
by
generating
∼9,500
mutants
measuring
effects
on
signaling
surface
expression.
This
unbiased
screen
revealed
that,
unlike
other
proton-sensitive
cell
channels
receptors,
no
single
site
critical
recognition
GPR68.
Instead,
network
titratable
extend
from
transmembrane
region
converge
canonical
class
GPCR
motifs
GPCRs.
More
broadly,
our
approach
integrating
structure
interrogation
defines
new
framework
understanding
rich
complexity
signaling.
One-sentence
summary
The
protonation
networks
governing
human
pH-sensing
GPCRs
uncovered
integrative
cryo-EM
scanning.
Язык: Английский
Proton perception and activation of a proton-sensing GPCR
Molecular Cell,
Год журнала:
2025,
Номер
unknown
Опубликована: Апрель 1, 2025
Язык: Английский
Graph‐based algorithms to dissect long‐distance water‐mediated H‐bond networks for conformational couplings in GPCRs
British Journal of Pharmacology,
Год журнала:
2024,
Номер
unknown
Опубликована: Апрель 18, 2024
Abstract
Changes
in
structure
and
dynamics
elicited
by
agonist
ligand
binding
at
the
extracellular
side
of
G
protein
coupled
receptors
(GPCRs)
must
be
relayed
to
cytoplasmic
receptors.
To
decipher
role
water‐mediated
hydrogen‐bond
networks
this
relay
mechanism,
we
have
developed
graph‐based
algorithms
analysis
methodologies
applicable
datasets
static
structures
distinct
GPCRs.
For
a
reference
dataset
bovine
rhodopsin
solved
same
resolution,
show
that
graph
analyses
capture
internal
protein–water
network.
The
extended
rhodopsins
opioid
suggest
mechanism
whereby
inactive
place
much
core
network
required
for
long‐distance
structural
change,
with
extensive
local
H‐bond
clusters
observed
high
resolution
water
molecules.
Язык: Английский
Elucidating the Activation Mechanism of the Proton-sensing GPR68 Receptor
Journal of Molecular Biology,
Год журнала:
2024,
Номер
436(16), С. 168688 - 168688
Опубликована: Июнь 25, 2024
GPR68
is
a
proton-sensing
G-protein
Coupled
Receptor
(GPCR)
involved
in
variety
of
physiological
processes
and
disorders
including
neoplastic
pathologies.
While
few
other
GPCRs
have
been
shown
to
be
activated
by
decrease
the
extracellular
pH,
molecular
mechanism
their
activation
remains
largely
unknown.
In
this
work,
we
used
combined
computational
vitro
approach
provide
new
insight
into
receptor.
Molecular
Dynamics
simulations
were
model
changes
residue
interactions
motions
triggered
pH.
Global
local
rearrangements
consistent
with
partial
observed
upon
protonation
inactive
state.
Selected
histidine
transmembrane
acidic
residues
found
significantly
upshifted
pKa
values
during
simulations,
consistently
previously
hypothesised
role
through
Moreover,
novel
pairing
between
region
was
highlighted
both
sequence
analyses
simulation
data
tested
site-directed
mutagenesis.
At
last,
identified
unknown
hydrophobic
lock
that
might
stabilise
conformation
regulate
transition
active
Язык: Английский
Breaking the one‐site myth: the multifaceted world of proton sensing in GPCRs
FEBS Journal,
Год журнала:
2025,
Номер
unknown
Опубликована: Май 26, 2025
Proton‐sensing
GPCRs
detect
extracellular
acidification
and
play
a
pivotal
role
in
maintaining
pH
homeostasis,
influencing
processes
such
as
inflammation,
cancer
progression,
neuropathic
pain.
While
initially
believed
to
rely
solely
on
histidine
protonation
for
activation,
emerging
evidence
suggests
that
acidic
triads,
beyond
residues,
are
crucial
proton
sensing.
Variations
distribution
sequence
composition
among
these
receptors
point
distinct
activation
mechanisms
within
the
proton‐sensing
GPCR
family.
This
Viewpoint
consolidates
findings
from
previously
published
studies
explore
structural
molecular
intricacies
of
recognition,
receptor
downstream
signaling
GPCRs.
By
integrating
insights
dynamics
simulations,
evolutionary
analysis,
studies,
functional
assays,
we
highlight
complex
multifaceted
nature
Collectively,
reveal
unrecognized
network
critical
residues
sites,
reshaping
our
understanding
function.
Beyond
mechanistic
insights,
this
compilation
offers
new
perspectives
targeting
pathways
therapeutic
intervention
various
diseases.
Язык: Английский
Elucidating the activation mechanism of the proton-sensing GPR68 receptor
bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2023,
Номер
unknown
Опубликована: Дек. 9, 2023
ABSTRACT
GPR68
is
a
proton-sensing
G-protein
Coupled
Receptor
(GPCR)
involved
in
variety
of
physiological
processes
and
disorders
including
neoplastic
pathologies.
While
few
other
GPCRs
have
been
shown
to
be
activated
by
decrease
the
extracellular
pH,
molecular
mechanism
their
activation
remains
largely
unknown.
In
this
work,
we
used
combined
computational
vitro
approach
provide
new
insight
into
receptor.
Molecular
Dynamics
simulations
were
model
changes
residue
interactions
motions
triggered
pH.
Global
local
rearrangements
consistent
with
partial
observed
upon
protonation
inactive
state.
Selected
histidine
transmembrane
acidic
residues
found
significantly
upshifted
p
K
values
during
simulations,
consistently
previously
hypothesised
role
through
Moreover,
novel
pairing
between
region
was
highlighted
both
sequence
analyses
simulation
data
tested
site-directed
mutagenesis.
At
last,
identified
unknown
hydrophobic
lock
that
might
stabilise
conformation
regulate
transition
active
state.g
Язык: Английский