Biochemical Journal,
Год журнала:
2019,
Номер
476(19), С. 2705 - 2724
Опубликована: Окт. 11, 2019
Abstract
Plants
growing
in
soil
develop
close
associations
with
microorganisms,
which
inhabit
the
areas
around,
on,
and
inside
their
roots.
These
microbial
communities
associated
genes
—
collectively
termed
root
microbiome
are
diverse
have
been
shown
to
play
an
important
role
conferring
abiotic
stress
tolerance
plant
hosts.
In
light
of
concerns
over
threat
water
nutrient
facing
terrestrial
ecosystems,
especially
those
used
for
agricultural
production,
increased
emphasis
has
placed
on
understanding
how
conditions
influence
composition
functioning
ultimate
consequences
health.
However,
under
will
not
only
reflect
shifts
greater
bulk
community
from
plants
recruit
but
also
responses
stress,
include
changes
exudate
profiles
morphology.
Exploring
relative
contributions
these
direct
plant-mediated
effects
focus
many
studies
recent
years.
Here,
we
review
impacts
affecting
specifically
flooding,
drought,
nitrogen
phosphorus
availability,
that
interact
ultimately
shape
microbiome.
We
conclude
a
perspective
outlining
possible
directions
future
research
needed
advance
our
complex
molecular
biochemical
interactions
between
soil,
plants,
microbes
determine
stress.
Proceedings of the National Academy of Sciences,
Год журнала:
2018,
Номер
115(18)
Опубликована: Апрель 16, 2018
Significance
Drought
remains
a
critical
obstacle
to
meeting
the
food
demands
of
coming
century.
Understanding
interplay
between
drought
stress,
plant
development,
and
microbiome
is
central
this
challenge.
Here,
we
demonstrate
that
causes
enrichment
distinct
set
microbes
in
roots,
composed
almost
entirely
monoderms,
which
lack
outer
membranes
have
thick
cell
walls.
We
under
drought,
roots
increase
production
many
metabolites,
monoderms
inhabiting
drought-treated
rhizosphere
exhibit
increased
activity
transporters
connected
with
some
these
same
compounds.
The
discovery
drought-induced
associated
shifts
metabolite
exchange
microbe
reveal
potential
blueprint
for
manipulating
microbiomes
improved
crop
fitness.
Annual Review of Microbiology,
Год журнала:
2019,
Номер
73(1), С. 69 - 88
Опубликована: Май 15, 2019
Microorganisms
colonizing
plant
surfaces
and
internal
tissues
provide
a
number
of
life-support
functions
for
their
host.
Despite
increasing
recognition
the
vast
functional
capabilities
microbiome,
our
understanding
ecology
evolution
taxonomically
hyperdiverse
microbial
communities
is
limited.
Here,
we
review
current
knowledge
genotypic
phenotypic
traits
as
well
allogenic
autogenic
factors
that
shape
microbiome
composition
functions.
We
give
specific
emphasis
to
impact
domestication
on
assembly
how
insights
into
microbiomes
wild
relatives
native
habitats
can
contribute
reinstate
or
enrich
microorganisms
with
beneficial
effects
growth,
development,
health.
Finally,
introduce
new
concepts
perspectives
in
research,
particular
community
theory
mechanistic
framework
unravel
interplay
distinct
ecological
processes-i.e.,
selection,
dispersal,
drift,
diversification-that
structure
microbiome.
Annual Review of Phytopathology,
Год журнала:
2017,
Номер
55(1), С. 565 - 589
Опубликована: Июнь 24, 2017
The
innate
immune
system
of
plants
recognizes
microbial
pathogens
and
terminates
their
growth.
However,
recent
findings
suggest
that
at
least
one
layer
this
is
also
engaged
in
cooperative
plant-microbe
interactions
influences
host
colonization
by
beneficial
communities.
This
involves
sensing
microbe-associated
molecular
patterns
(MAMPs)
pattern
recognition
receptors
(PRRs)
initiate
quantitative
responses
to
control
host-microbial
load,
whereas
diversification
MAMPs
PRRs
emerges
as
a
mechanism
locally
sculpts
assemblages
plant
populations.
suggests
more
complex
management
role
the
for
controlled
accommodation
microbes
pathogen
elimination.
finding
similar
strategies
are
deployed
symbionts
dampen
consistent
with
hypothesis
but
implies
different
selective
pressures
on
due
contrasting
outcomes
fitness.
reciprocal
interplay
between
microbiota
likely
plays
critical
shaping
plant-microbiota
combinations
maintaining
homeostasis.
The
plant
microbiome
represents
one
of
the
key
determinants
health
and
productivity
by
providing
a
plethora
functional
capacities
such
as
access
to
low-abundance
nutrients,
suppression
phytopathogens,
resistance
biotic
and/or
abiotic
stressors.
However,
robust
understanding
structural
composition
bacterial
present
in
different
microenvironments
especially
relationship
between
below-ground
above-ground
communities
has
remained
elusive.
In
this
work,
we
addressed
hypotheses
regarding
niche
differentiation
stability
within
ecological
niches.
We
sampled
rhizosphere
soil,
root,
stem,
leaf
endosphere
field-grown
poplar
trees
(Populus
tremula
×
Populus
alba)
applied
16S
rRNA
amplicon
pyrosequencing
unravel
associated
with
habitats.
found
that
variability
microbiomes
(P.
P.
is
much
lower
than
microbiomes.
Furthermore,
our
data
not
only
confirm
reports
at
soil–root
interface
but
also
clearly
show
additional
fine-tuning
adaptation
stem
compartment.
Each
compartment
an
unique
for
communities.
Finally,
identified
core
niches
Populus.
Understanding
complex
host–microbe
interactions
could
provide
basis
exploitation
eukaryote–prokaryote
associations
phytoremediation
applications,
sustainable
crop
production
(bio-energy
efficiency),
secondary
metabolites.
Frontiers in Plant Science,
Год журнала:
2017,
Номер
8
Опубликована: Дек. 22, 2017
Plant-derived
protein
hydrolysates
(PHs)
have
gained
prominence
as
plant
biostimulants
because
of
their
potential
to
increase
the
germination,
productivity
and
quality
a
wide
range
horticultural
agronomic
crops.
Application
PHs
can
also
alleviate
negative
effects
abiotic
stress
due
salinity,
drought
heavy
metals.
Recent
studies
aimed
at
uncovering
mechanisms
regulating
these
beneficial
indicate
that
could
be
directly
affecting
plants
by
stimulating
carbon
nitrogen
metabolism,
interfering
with
hormonal
activity.
Indirect
play
role
enhance
nutrient
availability
in
growth
substrates,
uptake
nutrient-use
efficiency
plants.
Moreover,
stimulation
microbiomes.
Plants
are
colonized
an
abundant
diverse
assortment
microbial
taxa
help
acquire
nutrients
water
withstand
biotic
stress.
The
substrates
provided
PHs,
such
amino
acids,
provide
ideal
food
source
for
plant-associated
microbes.
Indeed,
recent
evidence
microbiomes
modified
application
supporting
hypothesis
might
acting,
least
part,
via
changes
composition
activity
communities.
has
great
meet
twin
challenges
feeding
growing
population
while
minimizing
agriculture's
impact
on
human
health
environment.
However,
fully
realize
further
required
shed
light
conferring
products,
well
identify
product
formulations
methods
optimize
benefits
under
agro-ecological
conditions.
ABSTRACT
Plant
roots
support
complex
microbial
communities
that
can
influence
plant
growth,
nutrition,
and
health.
While
extensive
characterizations
of
the
composition
spatial
compartmentalization
these
have
been
performed
in
different
species,
there
is
relatively
little
known
about
impact
abiotic
stresses
on
root
microbiota.
Here,
we
used
rice
as
a
model
to
explore
responses
microbiomes
drought
stress.
Using
four
distinct
genotypes,
grown
soils
from
three
fields,
tracked
drought-induced
changes
rhizosphere
(the
soil
immediately
surrounding
root),
endosphere
interior),
unplanted
soils.
Drought
significantly
altered
overall
bacterial
fungal
compositions
all
communities,
with
compartments
showing
greatest
divergence
well-watered
controls.
The
response
microbiota
stress
was
taxonomically
consistent
across
cultivars
primarily
driven
by
an
enrichment
multiple
Actinobacteria
Chloroflexi
,
well
depletion
several
Acidobacteria
Deltaproteobacteria
.
some
overlap
observed
drought-responsive
taxa
were
compartment
specific,
pattern
likely
arising
preexisting
compositional
differences,
plant-mediated
processes
affecting
individual
compartments.
These
results
reveal
stress,
addition
its
well-characterized
effects
physiology,
also
restructuring
suggest
possibility
constituents
might
contribute
survival
under
extreme
environmental
conditions.
IMPORTANCE
With
likelihood
global
climate
will
adversely
affect
crop
yields,
potential
role
enhancing
performance
makes
it
important
elucidate
variation.
By
detailed
characterization
effect
root-associated
rice,
show
undergo
major
involve
shifts
relative
abundances
diverse
set
bacteria
drought.
microbes,
particular
those
enriched
water
deficit
conditions,
could
potentially
benefit
they
tolerance
other
stresses,
provide
protection
opportunistic
infection
pathogenic
microbes.
identification
future
isolation
microbes
promote
be
mitigate
losses
adverse
climate.
Microorganisms
serve
important
functions
within
numerous
eukaryotic
host
organisms.
An
understanding
of
the
variation
in
plant
niche-level
microbiome,
from
rhizosphere
soils
to
canopies,
is
imperative
gain
a
better
how
both
structural
and
functional
processes
microbiomes
impact
health
overall
holobiome.
Using
Populus
trees
as
model
ecosystem,
we
characterized
archaeal/bacterial
fungal
microbiome
across
30
different
tissue-level
niches
replicated
deltoides
hybrid
trichocarpa
×
individuals
using
16S
ITS2
rRNA
gene
analyses.
Our
analyses
indicate
that
varied
primarily
broader
habitat
classes
(leaves,
stems,
roots,
soils)
regardless
genotype,
except
for
communities
leaf
niches,
which
were
greatly
impacted
by
genotype.
Differences
between
tree
genotypes
are
evident
elevated
presence
two
potential
pathogens,
Marssonina
brunnea
Septoria
sp.,
on
P.
may
turn
be
contributing
divergence
composition.
Archaeal/bacterial
diversity
increased
leaves,
stem,
root,
soil
habitats,
whereas
was
greatest
stems
soils.
This
study
provides
holistic
structure
bioenergy
relevant
host,
one
most
complete
any
plant.
As
such,
it
constitutes
detailed
atlas
or
map
further
hypothesis
testing
significance
individual
microbial
taxa
specific
habitats
baseline
comparisons
other
species.
