Journal of Sustainable Agriculture and Environment,
Journal Year:
2025,
Volume and Issue:
4(1)
Published: March 1, 2025
ABSTRACT
Reducing
N₂O
emissions
from
farmlands
is
crucial
to
mitigate
climate
change.
A
recent
scientific
breakthrough
employed
an
innovative
method
inoculate
farmland
soil
with
a
bacterium,
resulting
in
significant
reduction
of
emissions.
This
commentary
identifies
promising
environments
and
practices
for
further
emission
reduction.
Microorganisms,
Journal Year:
2025,
Volume and Issue:
13(2), P. 233 - 233
Published: Jan. 22, 2025
The
plant
microbiome,
found
in
the
rhizosphere,
phyllosphere,
and
endosphere,
is
essential
for
nutrient
acquisition,
stress
tolerance,
overall
health
of
plants.
This
review
aims
to
update
our
knowledge
critically
discuss
diversity
functional
roles
rice
as
well
microbiome
engineering
strategies
enhance
biofertilization
resilience.
Rice
hosts
various
microorganisms
that
affect
cycling,
growth
promotion,
resistance
stresses.
Microorganisms
carry
out
these
functions
through
nitrogen
fixation,
phytohormone
metabolite
production,
enhanced
solubilization
uptake,
regulation
host
gene
expression.
Recent
research
on
molecular
biology
has
elucidated
complex
interactions
within
microbiomes
signalling
mechanisms
establish
beneficial
microbial
communities,
which
are
crucial
sustainable
production
environmental
health.
Crucial
factors
successful
commercialization
agents
include
soil
properties,
practical
field
conditions,
genotype.
Advances
engineering,
from
traditional
inoculants
synthetic
biology,
optimize
availability
resilience
abiotic
stresses
like
drought.
Climate
change
intensifies
challenges,
but
innovations
microbiome-shaping
genes
(M
genes)
offer
promising
solutions
crop
also
discusses
agronomic
implications
emphasizing
need
further
exploration
M
breeding
disease
traits.
Ultimately,
we
provide
an
current
findings
rice,
highlighting
pathways
productivity
sustainably
while
minimizing
impacts.
International Journal of Molecular Sciences,
Journal Year:
2025,
Volume and Issue:
26(4), P. 1466 - 1466
Published: Feb. 10, 2025
The
advancement
of
multi-omics
tools
has
revolutionized
the
study
complex
biological
systems,
providing
comprehensive
insights
into
molecular
mechanisms
underlying
critical
traits
across
various
organisms.
By
integrating
data
from
genomics,
transcriptomics,
metabolomics,
and
other
omics
platforms,
researchers
can
systematically
identify
characterize
elements
that
contribute
to
phenotypic
traits.
This
review
delves
recent
progress
in
applying
approaches
elucidate
genetic,
epigenetic,
metabolic
networks
associated
with
key
plants.
We
emphasize
potential
these
integrative
strategies
enhance
crop
improvement,
optimize
agricultural
practices,
promote
sustainable
environmental
management.
Furthermore,
we
explore
future
prospects
field,
underscoring
importance
cutting-edge
technological
advancements
need
for
interdisciplinary
collaboration
address
ongoing
challenges.
bridging
this
aims
provide
a
holistic
framework
advancing
research
plant
biology
agriculture.
Abstract
Plant
growth‐promoting
rhizobacteria
(PGPR)
associated
with
roots
produce
several
biomolecules
that
stimulate
plant
growth.
The
study
aimed
to
assess
the
potential
of
PGPR
for
tomato
(
Solanum
lycopersicum
L.)
growth
enhancement.
Three
isolates
Pseudomonas
PIA2
and
PIA3,
Bacillus
isolate
BIA1)
were
evaluated
promotion
under
greenhouse
conditions.
experiment
was
conducted
in
three
replications
using
Maya
Melkesalsa
varieties
a
completely
randomized
design.
Treatment
BIA1
resulted
highest
fresh
weights
shoots
(29.05
g)
(3.72
variety
(TC1)
28.69
2.76
g
(TC2),
respectively.
showed
maximum
(25.05
(3.26
TC2.
Tomato
plants
treated
exhibited
significant
increases
height,
by
40.1%
22.6%
TC1
45.2%
27.6%
TC2,
Besides,
treatments
increased
dry
weight
46.6%
30.2%
73.3%
68.7%,
For
54.9%
34.4%
68.1%
48.9%,
results
generally
could
be
used
foster
Further
field
conditions
are
highly
recommended.
Trends in Microbiology,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 1, 2025
Within
both
abiotic
and
host
environments,
bacteria
typically
exist
as
diverse,
multispecies
communities
have
crucial
roles
in
human
health,
agriculture,
industry.
In
these
communities,
compete
for
resources,
competitive
interactions
can
shape
the
overall
population
structure
community
function.
Studying
bacterial
dynamics
requires
experimental
model
systems
that
capture
different
interaction
networks
between
their
surroundings.
We
examine
recent
literature
advancing
such
systems,
including
(i)
silico
models
establishing
theoretical
basis
how
cell-to-cell
influence
level
dynamics,
(ii)
vitro
characterizing
specific
interbacterial
interactions,
(iii)
organ-on-a-chip
revealing
physiologically
relevant
parameters,
spatial
mechanical
forces,
encounter
within
a
host,
(iv)
vivo
plant
animal
connecting
responses
to
interactions.
Each
of
has
greatly
contributed
our
understanding
be
used
synergistically
understand
competition
influences
architecture.
Microorganisms,
Journal Year:
2025,
Volume and Issue:
13(1), P. 148 - 148
Published: Jan. 13, 2025
Synthetic
microbial
community
(SynCom)
application
is
efficient
in
promoting
crop
yield
and
soil
health.
However,
few
studies
have
been
conducted
to
enhance
pepper
growth
via
modulating
rhizosphere
communities
by
SynCom
application.
This
study
aimed
investigate
how
inoculation
at
the
seedling
stage
impacts
microbiome
using
high-throughput
sequencing
technology.
significantly
increased
shoot
height,
stem
diameter,
fresh
weight,
dry
chlorophyll
content,
leaf
number,
root
vigor,
tips,
total
length,
root-specific
surface
area
of
20.9%,
36.33%,
68.84%,
64.34%,
29.65%,
27.78%,
117.42%,
35.4%,
21.52%,
39.76%,
respectively,
relative
control.
The
Chao
index
Bray–Curtis
dissimilarity
fungal
increased,
while
bacterial
decreased
inoculation.
abundances
key
taxa
such
as
Scedosporium,
Sordariomycetes,
Pseudarthrobacter,
norankSBR1031,
norankA4b
with
inoculation,
positively
correlated
indices
growth.
Our
findings
suggest
that
can
effectively
regulate
morphology
regulating
increasing
abundance
like
Sordariomycetes
thereby
benefiting
nutrient
acquisition,
resistance
improvement,
pathogen
crops
ensure
sustainability.
Bacteria,
Journal Year:
2025,
Volume and Issue:
4(1), P. 12 - 12
Published: March 3, 2025
In
the
recent
past,
microbiome
manipulation
has
emerged
as
a
promising
approach
to
improve
plant
growth
performance
by
exploring
deep
insight
of
plant–microbe
interactions.
The
exploration
either
present
on
an
ectosphere
or
endosphere
can
provide
far
better
understanding
about
potential
application
plant-associated
microbes
for
improvement
growth,
protection
from
pathogen
invasion,
and
tolerance
environmental
stresses
diverse
nature.
this
context,
next-generation
sequencing
methods,
omics
approaches,
synthetic
biology
have
made
significant
progress
in
research
are
being
frequently
used
explore
intriguing
role
microorganisms.
Despite
successfulness
conventional
incorporation
CRISPR/Cas9,
RNA
interference
technology,
rhizosphere
engineering,
other
techniques
appear
be
enhancing
performance,
against
biotic
abiotic
stress
factors.
review
presents
significance
microbe
interaction,
vital
functional
aspects,
collaborative
action,
constraints,
finally
latest
developments
bioengineering
approaches
destined
modulation
with
objective
host
challenged
stressors.