Nervous
systems
coordinate
effectors
across
the
body
during
movements.
We
know
little
about
cellular-level
structure
of
synaptic
circuits
for
such
body-wide
control.
Here
we
describe
whole-body
connectome
a
segmented
larva
marine
annelid
Platynereis
dumerilii
.
reconstructed
and
annotated
over
9,000
neuronal
non-neuronal
cells
in
serial
electron
microscopy
dataset.
Differentiated
were
classified
into
202
92
cell
types.
analyse
modularity,
multisensory
integration,
left-right
intersegmental
connectivity
motor
ciliated
cells,
glands,
pigment
muscles.
identify
several
segment-specific
types,
demonstrating
heteromery
larval
trunk.
At
same
time,
segmentally
repeated
types
head,
trunk
segments
pygidium
suggest
homology
all
segmental
regions.
also
report
descending
ascending
pathways,
peptidergic
multi-modal
mechanosensory
girdle.
Our
work
provides
basis
understanding
coordination
an
entire
animal.
Philosophical Transactions of the Royal Society B Biological Sciences,
Journal Year:
2021,
Volume and Issue:
376(1821), P. 20190764 - 20190764
Published: Feb. 8, 2021
Discussions
of
the
function
early
nervous
systems
usually
focus
on
a
causal
flow
from
sensors
to
effectors,
by
which
an
animal
coordinates
its
actions
with
exogenous
changes
in
environment.
We
propose,
instead,
that
much
sensing
was
The
mechanisms
specifying
neuronal
diversity
are
well
characterized,
yet
it
remains
unclear
how
or
if
these
regulate
neural
circuit
assembly.
To
address
this,
we
mapped
the
developmental
origin
of
160
interneurons
from
seven
bilateral
progenitors
(neuroblasts)
and
identify
them
in
a
synapse-scale
TEM
reconstruction
Drosophila
larval
central
nervous
system.
We
find
that
lineages
concurrently
build
sensory
motor
neuropils
by
generating
hemilineages
Notch-dependent
manner.
Neurons
hemilineage
share
common
synaptic
targeting
within
neuropil,
which
is
further
refined
based
on
temporal
identity.
Connectome
analysis
shows
hemilineage-temporal
cohorts
connectivity.
Finally,
show
proximity
alone
cannot
explain
observed
connectivity
structure,
suggesting
hemilineage/temporal
identity
confers
an
added
layer
specificity.
Thus,
demonstrate
also
govern
formation
function,
principles
broadly
applicable
throughout
Neuron,
Journal Year:
2023,
Volume and Issue:
111(22), P. 3554 - 3569.e7
Published: Aug. 22, 2023
Although
neuronal
subtypes
display
unique
synaptic
organization
and
function,
the
underlying
transcriptional
differences
that
establish
these
features
are
poorly
understood.
To
identify
molecular
pathways
contribute
to
diversity,
single-neuron
Patch-seq
RNA
profiling
was
performed
on
Drosophila
tonic
phasic
glutamatergic
motoneurons.
Tonic
motoneurons
form
weaker
facilitating
synapses
onto
single
muscles,
while
stronger
depressing
multiple
muscles.
Super-resolution
microscopy
in
vivo
imaging
demonstrated
active
zones
more
compact
enhanced
Ca2+
influx
compared
with
their
counterparts.
Genetic
analysis
identified
properties
mapped
gene
expression
for
several
cellular
pathways,
including
distinct
signaling
ligands,
post-translational
modifications,
intracellular
buffers.
These
findings
provide
insights
into
how
transcriptomes
drive
functional
morphological
between
subtypes.
Proceedings of the National Academy of Sciences,
Journal Year:
2023,
Volume and Issue:
120(11)
Published: March 10, 2023
How
does
neural
activity
drive
muscles
to
produce
behavior?
The
recent
development
of
genetic
lines
in
Hydra
that
allow
complete
calcium
imaging
both
neuronal
and
muscle
activity,
as
well
systematic
machine
learning
quantification
behaviors,
makes
this
small
cnidarian
an
ideal
model
system
understand
the
transformation
from
firing
body
movements.
To
achieve
this,
we
have
built
a
neuromechanical
’s
fluid-filled
hydrostatic
skeleton,
showing
how
by
activates
distinct
patterns
column
biomechanics.
Our
is
based
on
experimental
measurements
assumes
gap
junctional
coupling
among
cells
calcium-dependent
force
generation
muscles.
With
these
assumptions,
can
robustly
reproduce
basic
set
behaviors.
We
further
explain
puzzling
observations,
including
dual
timescale
kinetics
observed
activation
engagement
ectodermal
endodermal
different
This
work
delineates
spatiotemporal
control
space
movement
serve
template
for
future
efforts
systematically
decipher
transformations
basis
behavior.
Frontiers in Neuroscience,
Journal Year:
2023,
Volume and Issue:
17
Published: Feb. 16, 2023
Neurodegenerative
Diseases
(NDDs)
are
a
group
of
disorders
that
cause
progressive
deficits
neuronal
function.
Recent
evidence
argues
sphingolipid
metabolism
is
affected
in
surprisingly
broad
set
NDDs.
These
include
some
lysosomal
storage
diseases
(LSDs),
hereditary
sensory
and
autonomous
neuropathy
(HSAN),
spastic
paraplegia
(HSP),
infantile
neuroaxonal
dystrophy
(INAD),
Friedreich’s
ataxia
(FRDA),
as
well
forms
amyotrophic
lateral
sclerosis
(ALS)
Parkinson’s
disease
(PD).
Many
these
have
been
modeled
Drosophila
melanogaster
associated
with
elevated
levels
ceramides.
Similar
changes
also
reported
vertebrate
cells
mouse
models.
Here,
we
summarize
studies
using
fly
models
and/or
patient
samples
which
demonstrate
the
nature
defects
metabolism,
organelles
implicated,
cell
types
initially
affected,
potential
therapeutics
for
diseases.
bioRxiv (Cold Spring Harbor Laboratory),
Journal Year:
2024,
Volume and Issue:
unknown
Published: March 17, 2024
Abstract
Nervous
systems
coordinate
effectors
across
the
body
during
movements.
We
know
little
about
cellular-level
structure
of
synaptic
circuits
for
such
body-wide
control.
Here
we
describe
whole-body
connectome
a
segmented
larva
marine
annelid
Platynereis
dumerilii
.
reconstructed
and
annotated
over
9,000
neuronal
non-neuronal
cells
in
serial
electron
microscopy
dataset.
Differentiated
were
classified
into
202
92
cell
types.
analyse
modularity,
multisensory
integration,
left-right
intersegmental
connectivity
motor
ciliated
cells,
glands,
pigment
muscles.
identify
several
segment-specific
types,
demonstrating
heteromery
larval
trunk.
At
same
time,
segmentally
repeated
types
head,
trunk
segments
pygidium
suggest
homology
all
segmental
regions.
also
report
descending
ascending
pathways,
peptidergic
multi-modal
mechanosensory
girdle.
Our
work
provides
basis
understanding
coordination
an
entire
animal.
Current Opinion in Neurobiology,
Journal Year:
2020,
Volume and Issue:
65, P. 129 - 137
Published: Nov. 23, 2020
The
larva
of
Drosophila
melanogaster
is
emerging
as
a
powerful
model
system
for
comprehensive
brain-wide
understanding
the
circuit
implementation
neural
computations.
With
an
unprecedented
amount
tools
in
hand,
including
synaptic-resolution
connectomics,
whole-brain
imaging,
and
genetic
selective
targeting
single
neuron
types,
it
possible
to
dissect
which
circuits
computations
are
at
work
behind
behaviors
that
have
interesting
level
complexity.
Here
we
present
some
recent
advances
regarding
multisensory
integration,
learning,
action
selection
larva.
