Expert Opinion on Therapeutic Targets,
Год журнала:
2025,
Номер
unknown, С. 1 - 13
Опубликована: Фев. 7, 2025
Spinal
and
Bulbar
Muscular
Atrophy
(SBMA)
is
a
slowly
progressive,
X-linked,
sex-limited
degenerative
disorder
affecting
lower
motor
neurons
skeletal
muscle
which
lacks
disease-modifying
therapies.
This
disease
caused
by
CAG/polyglutamine
(polyQ)
tract
expansion
in
the
androgen
receptor
(AR)
gene,
its
pathogenesis
driven
toxic
gain-of-function
mechanisms.
Affected
men
develop
proximal
limb
bulbar
weakness
along
with
signs
of
partial
insensitivity.
Toxicity
polyQ
AR
mediated
protein
misfolding
nuclear
translocation
that
follow
ligand
binding,
resulting
disruption
downstream
homeostatic
review
highlights
what
known
about
how
this
has
been
leveraged
to
test
potential
therapeutic
approaches.
The
focus
on
strategies
alleviate
toxicity
SBMA,
including
those
alter
function,
diminish
expression
encoding
or
promote
clearance
misfolded,
mutant
protein.
We
discuss
emerging
mitigate
toxicity,
gene
editing,
RNA
targeted
therapies,
efforts
harness
proteostatic
These
promising
approaches
are
discussed
context
challenges
for
drug
discovery
faced
when
attempting
treat
rare
progressive
neurodegenerative
disorder.
Abstract
Clustered
regularly
interspaced
short
palindromic
repeats/CRISPR-associated
protein
(CRISPR/Cas)
technologies
have
evolved
rapidly
over
the
past
decade
with
continuous
discovery
of
new
Cas
systems.
In
particular,
RNA-targeting
CRISPR-Cas13
proteins
are
promising
single-effector
systems
to
regulate
target
mRNAs
without
altering
genomic
DNA,
yet
current
Cas13
restrained
by
suboptimal
efficiencies.
Here,
we
show
that
U1
promoter-driven
CRISPR
RNAs
(crRNAs)
increase
efficiency
various
applications,
including
RNA
knockdown
and
editing,
modifying
effector.
We
confirm
U1-driven
crRNAs
exported
into
cytoplasm,
while
conventional
U6
mostly
confined
nucleus.
Furthermore,
reveal
end
positions
expressed
promoter
consistent
regardless
guide
sequences
lengths.
also
demonstrate
crRNAs,
but
not
U6-driven
can
efficiently
repress
translation
genes
in
combination
catalytically
inactive
proteins.
Finally,
counteract
inhibitory
effect
miRNAs.
Our
simple
effective
engineering
enables
unprecedented
cytosolic
applications.
Molecular Therapy — Nucleic Acids,
Год журнала:
2023,
Номер
33, С. 750 - 761
Опубликована: Авг. 8, 2023
Mutations
in
Rhodopsin
(RHO)
gene
commonly
cause
autosomal
dominant
retinitis
pigmentosa
(adRP)
without
effective
therapeutic
treatment
so
far.
Compared
with
genomic
DNA-targeting
CRISPR-Cas9
system,
Cas13
edits
RNA
for
applications,
avoiding
the
risk
of
causing
permanent
changes
genome.
In
particular,
a
compact
and
high-fidelity
Cas13X
(hfCas13X)
recently
has
been
developed
to
degrade
targeted
minimal
collateral
effects
could
also
be
packaged
single
adeno-associated
virus
efficient
vivo
delivery.
this
study,
we
engineered
single-guide
hfCas13X
specifically
knock
down
human
mutant
transcripts
RHO-P23H
effect
on
wild-type
transcripts.
Moreover,
alleviated
adRP
progression
both
overexpression-induced
humanized
hRHOP23H/WT
mouse
models.
Our
study
indicates
potential
treating
caused
by
RHO
mutations
other
genetic
diseases.
Abstract
Huntington’s
disease
(HD)
is
an
inherited
neurodegenerative
disorder
caused
by
the
abnormal
expansion
of
CAG
trinucleotide
repeats
in
Huntingtin
gene
(HTT)
located
on
chromosome
4.
It
transmitted
autosomal
dominant
manner
and
characterized
motor
dysfunction,
cognitive
decline,
emotional
disturbances.
To
date,
there
are
no
curative
treatments
for
HD
have
been
developed;
current
therapeutic
approaches
focus
symptom
relief
comprehensive
care
through
coordinated
pharmacological
nonpharmacological
methods
to
manage
diverse
phenotypes
disease.
International
clinical
guidelines
treatment
continually
being
revised
effort
enhance
within
a
multidisciplinary
framework.
Additionally,
innovative
cell
therapy
strategies
actively
researched
developed
address
complexities
improve
outcomes.
This
review
endeavours
elucidate
emerging
HD,
offering
detailed
insight
into
looking
forward
future
paradigms.
Considering
complexity
underlying
mechanisms
driving
synergistic
strategy
that
integrates
various
factors—such
as
distinct
types,
epigenetic
patterns,
genetic
components,
cerebral
microenvironment—may
significantly
In
future,
we
eagerly
anticipate
ongoing
innovations
interdisciplinary
research
will
bring
profound
advancements
refinements
HD.
Biology,
Год журнала:
2025,
Номер
14(2), С. 129 - 129
Опубликована: Янв. 26, 2025
Neurodegenerative
disorders
(NDs)
cause
progressive
neuronal
loss
and
are
a
significant
public
health
concern,
with
NDs
projected
to
become
the
second
leading
global
of
death
within
two
decades.
Huntington’s
disease
(HD)
is
rare,
ND
caused
by
an
autosomal-dominant
mutation
in
huntingtin
(HTT)
gene,
severe
brain
resulting
debilitating
motor,
cognitive,
psychiatric
symptoms.
Given
complex
pathology
HD,
biomarkers
essential
for
performing
early
diagnosis,
monitoring
progression,
evaluating
treatment
efficacy.
However,
identification
consistent
HD
challenging
due
prolonged
premanifest
stage,
HD’s
heterogeneous
presentation,
its
multiple
underlying
biological
pathways.
This
study
involves
10-year
bibliometric
analysis
biomarker
research,
revealing
key
research
trends
gaps.
The
also
features
comprehensive
literature
review
emerging
biomarkers,
concluding
need
better
stratification
patients
well-designed
longitudinal
studies
validate
biomarkers.
Promising
candidate
wet
biomarkers—
including
neurofilament
light
chain
protein
(NfL),
microRNAs,
mutant
HTT
protein,
specific
metabolic
inflammatory
markers—
discussed,
emphasis
on
their
potential
utility
stage.
Additionally,
reflecting
structural
deficits
motor
or
behavioral
impairments,
such
as
neurophysiological
(e.g.,
tapping,
speech,
EEG,
event-related
potentials)
imaging
MRI,
PET,
diffusion
tensor
imaging)
evaluated.
findings
underscore
that
discovery
validation
reliable
urgently
require
improved
patient
studies.
Reliable
particularly
crucial
optimizing
clinical
management
strategies,
enabling
personalized
approaches,
advancing
trials
HD-modifying
therapies.
Expert Opinion on Therapeutic Targets,
Год журнала:
2025,
Номер
unknown, С. 1 - 13
Опубликована: Фев. 7, 2025
Spinal
and
Bulbar
Muscular
Atrophy
(SBMA)
is
a
slowly
progressive,
X-linked,
sex-limited
degenerative
disorder
affecting
lower
motor
neurons
skeletal
muscle
which
lacks
disease-modifying
therapies.
This
disease
caused
by
CAG/polyglutamine
(polyQ)
tract
expansion
in
the
androgen
receptor
(AR)
gene,
its
pathogenesis
driven
toxic
gain-of-function
mechanisms.
Affected
men
develop
proximal
limb
bulbar
weakness
along
with
signs
of
partial
insensitivity.
Toxicity
polyQ
AR
mediated
protein
misfolding
nuclear
translocation
that
follow
ligand
binding,
resulting
disruption
downstream
homeostatic
review
highlights
what
known
about
how
this
has
been
leveraged
to
test
potential
therapeutic
approaches.
The
focus
on
strategies
alleviate
toxicity
SBMA,
including
those
alter
function,
diminish
expression
encoding
or
promote
clearance
misfolded,
mutant
protein.
We
discuss
emerging
mitigate
toxicity,
gene
editing,
RNA
targeted
therapies,
efforts
harness
proteostatic
These
promising
approaches
are
discussed
context
challenges
for
drug
discovery
faced
when
attempting
treat
rare
progressive
neurodegenerative
disorder.
