Nature Communications,
Год журнала:
2025,
Номер
16(1)
Опубликована: Янв. 6, 2025
While
the
genetic
regulation
of
nodule
formation
has
been
well
explored,
molecular
mechanisms
by
which
abiotic
stresses,
such
as
salt
stress,
impede
remain
largely
elusive.
Here,
we
identify
four
APETALA2/Ethylene
Responsive
Factor
(AP2/ERF)
transcription
factors,
GmERF13s,
that
are
induced
stress
and
play
key
roles
in
salt-repressed
nodulation.
Loss
GmERF13
function
increases
density,
while
its
overexpression
suppresses
Moreover,
stress-inhibited
is
greatly
attenuated
loss-of-function
mutants,
whereas
it
becomes
more
pronounced
when
overexpressed.
Furthermore,
GmERF13s
can
interact
with
Lateral
Organ
Boundaries
Domain
16
(GmLBD16a),
attenuates
GmLBD16a's
binding
capacity
on
Expansin17c
(GmEXP17c)
promoter.
Additionally,
salt-induced
expression
relies
abscisic
acid
signaling,
direct
promotion
facilitated
GmABI5,
illustrating
their
involvement
enhancing
expression.
Collectively,
our
study
reveals
a
mechanism
impedes
nodulation
through
GmERF13-GmLBD16a-GmEXP17
module
soybean.
Salt
inhibits
legume
Here
reported
mutants
factor
gene
alleviate
this
inhibitory
effect.
Further
investigations
reveal
regulated
regulates
formation.
Nature Communications,
Год журнала:
2023,
Номер
14(1)
Опубликована: Авг. 19, 2023
Abstract
Drought
severely
damages
crop
production,
even
under
conditions
so
mild
that
the
leaves
show
no
signs
of
wilting.
However,
it
is
unclear
how
field-grown
plants
respond
to
drought.
Here,
we
through
six
years
field
trials
ridges
are
a
useful
experimental
tool
mimic
drought
stress
in
field.
Mild
reduces
inorganic
phosphate
levels
activate
starvation
response
(PSR)
soybean
Using
Arabidopsis
thaliana
and
its
mutant
grown
pots
controlled
environments,
demonstrate
PSR
occurs
before
abscisic
acid
progressive
plays
crucial
role
plant
growth
Our
observations
laboratory
using
model
provide
insight
into
molecular
relationship
between
nutrition
response.
Journal of genetics and genomics/Journal of Genetics and Genomics,
Год журнала:
2023,
Номер
51(4), С. 379 - 393
Опубликована: Сен. 17, 2023
Soybean
(Glycine
max
[L.]
Merr.)
is
an
important
crop
that
provides
protein
and
vegetable
oil
for
human
consumption.
As
soybean
a
photoperiod-sensitive
crop,
its
cultivation
yield
are
limited
by
the
photoperiodic
conditions
in
field.
In
contrast
to
other
major
crops,
has
special
plant
architecture
symbiotic
nitrogen
fixation
system,
representing
two
unique
breeding
directions.
Thus,
flowering
time,
architecture,
three
critical
or
yield-determinative
factors.
This
review
summarizes
progress
made
our
understanding
of
these
yield-determining
factors
soybean.
Meanwhile,
we
propose
potential
research
directions
increase
production,
discuss
application
genomics
genomic-assisted
breeding,
explore
address
future
challenges,
particularly
those
posed
global
climate
change.
International Journal of Molecular Sciences,
Год журнала:
2024,
Номер
25(3), С. 1441 - 1441
Опубликована: Янв. 24, 2024
Soybean
being
a
major
cash
crop
provides
half
of
the
vegetable
oil
and
quarter
plant
proteins
to
global
population.
Seed
size
traits
are
most
important
agronomic
determining
soybean
yield.
These
complex
governed
by
polygenes
with
low
heritability
as
well
highly
influenced
environment
genotype
x
interactions.
Although,
extensive
efforts
have
been
made
unravel
genetic
basis
molecular
mechanism
seed
in
soybean.
But
these
were
majorly
limited
QTL
identification,
only
few
genes
for
isolated
their
was
elucidated.
Hence,
elucidating
detailed
regulatory
networks
controlling
soybeans
has
an
area
research
from
past
decades.
This
paper
describes
current
progress
architecture,
mechanisms,
sizes
soybeans.
Additionally,
main
problems
bottlenecks/challenges
researchers
currently
face
also
discussed.
review
summarizes
comprehensive
systematic
information
regarding
understanding
will
help
future
work
on
Nature Communications,
Год журнала:
2025,
Номер
16(1)
Опубликована: Янв. 6, 2025
While
the
genetic
regulation
of
nodule
formation
has
been
well
explored,
molecular
mechanisms
by
which
abiotic
stresses,
such
as
salt
stress,
impede
remain
largely
elusive.
Here,
we
identify
four
APETALA2/Ethylene
Responsive
Factor
(AP2/ERF)
transcription
factors,
GmERF13s,
that
are
induced
stress
and
play
key
roles
in
salt-repressed
nodulation.
Loss
GmERF13
function
increases
density,
while
its
overexpression
suppresses
Moreover,
stress-inhibited
is
greatly
attenuated
loss-of-function
mutants,
whereas
it
becomes
more
pronounced
when
overexpressed.
Furthermore,
GmERF13s
can
interact
with
Lateral
Organ
Boundaries
Domain
16
(GmLBD16a),
attenuates
GmLBD16a's
binding
capacity
on
Expansin17c
(GmEXP17c)
promoter.
Additionally,
salt-induced
expression
relies
abscisic
acid
signaling,
direct
promotion
facilitated
GmABI5,
illustrating
their
involvement
enhancing
expression.
Collectively,
our
study
reveals
a
mechanism
impedes
nodulation
through
GmERF13-GmLBD16a-GmEXP17
module
soybean.
Salt
inhibits
legume
Here
reported
mutants
factor
gene
alleviate
this
inhibitory
effect.
Further
investigations
reveal
regulated
regulates
formation.
