Journal of Animal Ecology,
Journal Year:
2024,
Volume and Issue:
93(2), P. 221 - 230
Published: Jan. 8, 2024
Abstract
Intraspecific
trait
variation
(ITV),
potentially
driven
by
genetic
and
non‐genetic
mechanisms,
can
underlie
variability
in
resource
acquisition,
individual
fitness
ecological
interactions.
Impacts
of
ITV
at
higher
levels
biological
organizations
are
hence
likely,
but
up‐scaling
our
knowledge
about
importance
to
communities
comparing
its
relative
effects
population
community
has
rarely
been
investigated.
Here,
we
tested
the
on
morphological
traits
microcosms
protist
contrasting
strains
showing
different
(i.e.
averages
variance)
growth,
composition
biomass
production.
We
found
that
lead
populations
across
several
generations.
Furthermore,
declined
organization:
directly
altered
performance,
with
cascading
indirect
consequences
for
productivity.
Overall,
these
results
show
drivers
have
distinct
communities,
impacts
organization
might
mediate
biodiversity–ecosystem
functioning
relationships.
Proceedings of the National Academy of Sciences,
Journal Year:
2021,
Volume and Issue:
118(42)
Published: Oct. 12, 2021
Significance
Microbes
regulate
nutrient
flux
and
carbon
storage
within
ecosystems,
making
them
essential
to
the
global
cycle
ecosystem
responses
climate
change.
Understanding
how
change
will
alter
microbial
communities
this
feed
back
influence
pace
of
requires
linking
processes
across
levels
organization,
from
individual
organisms
whole
ecosystems.
We
show
that
physical
characteristics
(traits)
protist
species
their
populations
respond
changes
in
temperature.
These
species-level
temperature
also
composition,
dynamics,
functioning
communities.
Using
traits
understand
complex,
multilevel
with
can
help
us
anticipate
possible
consequences
rapid
The Science of The Total Environment,
Journal Year:
2024,
Volume and Issue:
926, P. 171971 - 171971
Published: March 26, 2024
Phototrophic
protists
are
a
fundamental
component
of
the
world's
oceans
by
serving
as
primary
source
energy,
oxygen,
and
organic
nutrients
for
entire
ecosystem.
Due
to
high
natural
seasonality
their
habitat,
temperate
could
harbour
many
well-adapted
species
that
tolerate
ocean
warming.
However,
these
may
not
sustain
ecosystem
functions
equally
well.
To
address
uncertainties,
we
conducted
30-day
mesocosm
experiment
investigate
how
moderate
(12
°C)
substantial
(18
warming
compared
ambient
conditions
(6
affect
composition
(18S
rRNA
metabarcoding)
(biomass,
gross
oxygen
productivity,
nutritional
quality
–
C:N
C:P
ratio)
North
Sea
spring
bloom
community.
Our
results
revealed
warming-driven
shifts
in
dominant
protist
groups,
with
haptophytes
thriving
at
12
°C
diatoms
18
°C.
Species
responses
primarily
depended
on
thermal
traits,
indirect
temperature
effects
grazing
being
less
relevant
phosphorus
acting
critical
modulator.
The
Phaeocystis
globosa
showed
highest
biomass
low
phosphate
concentrations
relatively
increased
some
replicates
both
treatments.
In
line
this,
ratio
varied
more
presence
P.
than
temperature.
Examining
further
under
warming,
our
study
lowered
productivity
but
accumulation
whereas
remained
unaltered.
Although
exhibited
resilience
elevated
temperatures,
diminished
functional
similarity
heightened
compositional
variability
indicate
potential
repercussions
higher
trophic
levels.
conclusion,
research
stresses
multifaceted
nature
communities,
emphasising
need
holistic
understanding
encompasses
trait-based
responses,
effects,
dynamics
face
exacerbating
changes.
Ecology and Evolution,
Journal Year:
2023,
Volume and Issue:
13(1)
Published: Jan. 1, 2023
Biomass
dynamics
capture
information
on
population
and
ecosystem-level
processes
(e.g.,
changes
in
production
over
time).
Understanding
how
rising
temperatures
associated
with
global
climate
change
influence
biomass
is
thus
a
pressing
issue
ecology.
The
total
of
species
depends
its
density
average
mass.
Consequently,
disentangling
responds
to
increasingly
warm
variable
ultimately
understanding
temperature
influences
both
mass
dynamics.
Here,
we
address
this
by
keeping
track
experimental
microbial
populations
growing
carrying
capacity
for
15
days
at
two
different
temperatures,
the
presence
absence
variability.
We
develop
simple
mathematical
expression
partition
contribution
assess
responses
either
one
shifts.
Moreover,
use
time-series
analysis
(Convergent
Cross
Mapping)
variability
reciprocal
effects
vice
versa.
show
that
through
dynamics,
which
have
opposite
can
offset
each
other.
also
biomass,
but
effect
independent
any
or
Last,
shift
significantly
across
regimes,
suggesting
rapid
environment-dependent
eco-phenotypic
underlie
responses.
Overall,
our
results
connect
phenotypic
explain
shedding
light
play
cosmopolitan
abundant
microbes
as
world
experiences
temperatures.
Functional Ecology,
Journal Year:
2022,
Volume and Issue:
36(8), P. 1887 - 1899
Published: May 20, 2022
Abstract
Understanding
how
food
webs
will
respond
to
globally
rising
temperatures
is
a
pressing
issue.
Temperature
effects
on
are
likely
underpinned
by
differences
in
the
thermal
sensitivity
of
consumers
and
resources,
or
asymmetries.
We
identify
three
sources
asymmetry
portion
performance
curves:
inter‐
thermy
variation
across
thermoregulatory
groups,
intra‐
within
group
rate
‐dependent
different
ecological
rates
temperature.
use
large
empirical
dataset
sensitivities
groups
explore
prevalent
asymmetries
real
consumer–resource
interactions.
then
develop
theory
illustrate
web
temperature
responses
mediated
magnitude
direction
these
this
model
show
possible
conditions
under
which
could
warming
as
currently
expected,
when
that
may
not
be
case.
Our
results
suggest
inter
‐thermy,
intra
‐thermy
common
natural
webs.
all
have
important
species
abundances
trophic
levels
well
maximum
position
web.
Both
(i.e.
more
strongly)
their
(the
difference
responses)
determine
response
and,
consistent
with
current
expectations,
top
predator
abundance
almost
always
declines
temperature,
even
though
increase.
While
our
shows
can
varied,
much
explained
considering
study
provides
new
data
theoretical
insights
into
widely
varying
observed
laboratory,
experimental
observational
settings,
clarifies
prey
ecology
influence
overall
changing
world.
Read
free
Plain
Language
Summary
for
article
Journal
blog.
Frontiers in Microbiology,
Journal Year:
2022,
Volume and Issue:
13
Published: April 7, 2022
Temperature
strongly
influences
microbial
community
structure
and
function,
in
turn
contributing
to
global
carbon
cycling
that
can
fuel
further
warming.
Recent
studies
suggest
biotic
interactions
among
microbes
may
play
an
important
role
determining
the
temperature
responses
of
these
communities.
However,
how
predation
regulates
microbiomes
under
future
climates
is
still
poorly
understood.
Here,
we
assess
whether
by
a
key
bacterial
consumer—protists—influences
response
function
freshwater
microbiome.
To
do
so,
exposed
communities
two
cosmopolitan
protist
species—
Tetrahymena
thermophila
Colpidium
sp.—at
different
temperatures,
month-long
microcosm
experiment.
While
biomass
respiration
increased
with
due
shifts,
changed
over
time
presence
protists.
Protists
influenced
rate
through
direct
indirect
effects
on
structure,
predator
actually
reduced
at
elevated
temperature.
Indicator
species
analyses
showed
were
mostly
determined
phylum-specific
density
cell
size.
Our
study
supports
previous
findings
driver
but
also
demonstrates
large
mediate
Proceedings of the Royal Society B Biological Sciences,
Journal Year:
2025,
Volume and Issue:
292(2045)
Published: April 1, 2025
To
buffer
the
effects
of
local
environmental
changes,
organisms
may
modify
their
phenotypic
traits
(i.e.
plasticity)
or
disperse
towards
other
potential
habitats
dispersal
plasticity).
Despite
extensive
work
studying
either
‘local
plasticity’
‘dispersal
independently,
little
is
known
about
covariation
and
interplay.
These
strategies
are
classically
viewed
as
alternatives.
However,
this
expectation
has
been
challenged
by
theoretical
suggesting
that
they
instead
evolve
together
under
some
contexts.
Here,
we
experimentally
quantified
morphological,
movement
plasticity
in
response
to
thermal
changes
12
strains
ciliate
Tetrahymena
thermophila
.
We
showed
not
alternative
strategies,
with
half
expressing
simultaneously
all
dimensions
changes.
Furthermore,
extent
morphological
weakly
but
significantly
differed
between
residents
dispersers.
Interestingly,
found
no
these
different
dimensions,
which
pleads
for
contexts
favour
evolution
each.
The
fact
affect
expression
one
another
opens
interesting
perspectives
joint
consequences
FEMS Microbiology Ecology,
Journal Year:
2023,
Volume and Issue:
99(3)
Published: Feb. 24, 2023
Abstract
Climate
change
is
affecting
how
energy
and
matter
flow
through
ecosystems,
thereby
altering
global
carbon
nutrient
cycles.
Microorganisms
play
a
fundamental
role
in
cycling
are
thus
an
integral
link
between
ecosystems
climate.
Here,
we
highlight
major
black
box
hindering
our
ability
to
anticipate
ecosystem
climate
responses:
viral
infections
within
complex
microbial
food
webs.
We
show
understanding
predicting
responses
warming
could
be
challenging—if
not
impossible—without
accounting
for
the
direct
indirect
effects
of
on
different
microbes
(bacteria,
archaea,
fungi,
protists)
that
together
perform
diverse
functions.
Importantly,
rising
temperatures
associated
with
influence
viruses
virus-host
dynamics
crucial
this
task,
yet
severely
understudied.
In
perspective,
(i)
synthesize
existing
knowledge
about
virus-microbe-temperature
interactions
(ii)
identify
important
gaps
guide
future
investigations
regarding
might
alter
web
functioning.
To
provide
real-world
context,
consider
these
processes
may
operate
peatlands—globally
significant
sinks
threatened
by
change.
stress
affects
biogeochemical
cycles
any
hinges
disentangling
temperature
