bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2020,
Номер
unknown
Опубликована: Дек. 9, 2020
ABSTRACT
Flexible
behaviors
over
long
timescales
are
thought
to
engage
recurrent
neural
networks
in
deep
brain
regions,
which
experimentally
challenging
study.
In
insects,
circuit
dynamics
a
region
called
the
central
complex
(CX)
enable
directed
locomotion,
sleep,
and
context-
experience-dependent
spatial
navigation.
We
describe
first
complete
electron-microscopy-based
connectome
of
Drosophila
CX,
including
all
its
neurons
circuits
at
synaptic
resolution.
identified
new
CX
neuron
types,
novel
sensory
motor
pathways,
network
motifs
that
likely
extract
fly’s
head-direction,
maintain
it
with
attractor
dynamics,
combine
other
sensorimotor
information
perform
vector-based
navigational
computations.
also
numerous
pathways
may
facilitate
selection
CX-driven
behavioral
patterns
by
context
internal
state.
The
provides
comprehensive
blueprint
necessary
for
detailed
understanding
underlying
flexible
navigation,
state-dependent
action
selection.
Making
inferences
about
the
computations
performed
by
neuronal
circuits
from
synapse-level
connectivity
maps
is
an
emerging
opportunity
in
neuroscience.
The
mushroom
body
(MB)
well
positioned
for
developing
and
testing
such
approach
due
to
its
conserved
architecture,
recently
completed
dense
connectome,
extensive
prior
experimental
studies
of
roles
learning,
memory,
activity
regulation.
Here,
we
identify
new
components
MB
circuit
Drosophila,
including
visual
input
output
neurons
(MBONs)
with
direct
connections
descending
neurons.
We
find
unexpected
structure
sensory
inputs,
transfer
information
different
modalities
MBONs,
modulation
that
dopaminergic
(DANs).
provide
insights
into
circuitry
used
integrate
outputs,
between
central
complex
inputs
DANs,
feedback
MBONs.
Our
results
a
foundation
further
theoretical
work.
Flexible
behaviors
over
long
timescales
are
thought
to
engage
recurrent
neural
networks
in
deep
brain
regions,
which
experimentally
challenging
study.
In
insects,
circuit
dynamics
a
region
called
the
central
complex
(CX)
enable
directed
locomotion,
sleep,
and
context-
experience-dependent
spatial
navigation.
We
describe
first
complete
electron
microscopy-based
connectome
of
Annual Review of Neuroscience,
Год журнала:
2022,
Номер
45(1), С. 63 - 85
Опубликована: Янв. 5, 2022
Locomotion
is
a
universal
motor
behavior
that
expressed
as
the
output
of
many
integrated
brain
functions.
organized
at
several
levels
nervous
system,
with
brainstem
circuits
acting
gate
between
areas
regulating
innate,
emotional,
or
motivational
locomotion
and
executive
spinal
circuits.
Here
we
review
recent
advances
on
involved
in
controlling
locomotion.
We
describe
how
delineated
command
govern
start,
speed,
stop,
steering
also
discuss
these
pathways
interface
cord
diverse
important
for
context-specific
selection
A
recurrent
theme
need
to
establish
functional
connectome
from
Finally,
point
unresolved
issues
concerning
function
locomotor
control.
Nature Communications,
Год журнала:
2022,
Номер
13(1)
Опубликована: Авг. 8, 2022
Abstract
To
navigate
towards
a
food
source,
animals
frequently
combine
odor
cues
about
source
identity
with
wind
direction
location.
Where
and
how
these
two
are
integrated
to
support
navigation
is
unclear.
Here
we
describe
pathway
the
Drosophila
fan-shaped
body
that
encodes
attractive
promotes
upwind
navigation.
We
show
neurons
throughout
this
encode
odor,
but
not
direction.
Using
connectomics,
identify
local
called
h∆C
receive
input
from
previously
described
pathway.
exhibit
odor-gated,
direction-tuned
activity,
sparse
activation
of
in
reproducible
direction,
activity
required
for
persistent
orientation
during
odor.
Based
on
connectome
data,
develop
computational
model
showing
can
promote
goal
such
as
an
source.
Our
results
suggest
processed
by
separate
pathways
within
goal-directed
Nature Neuroscience,
Год журнала:
2023,
Номер
26(4), С. 682 - 695
Опубликована: Март 23, 2023
Knowing
one's
own
behavioral
state
has
long
been
theorized
as
critical
for
contextualizing
dynamic
sensory
cues
and
identifying
appropriate
future
behaviors.
Ascending
neurons
(ANs)
in
the
motor
system
that
project
to
brain
are
well
positioned
provide
such
signals.
However,
what
ANs
encode
where
they
convey
these
signals
remains
largely
unknown.
Here,
through
large-scale
functional
imaging
behaving
animals
morphological
quantification,
we
report
encoding
targeting
of
hundreds
genetically
identifiable
adult
fly,
Drosophila
melanogaster.
We
reveal
states,
specifically
conveying
self-motion
anterior
ventrolateral
protocerebrum,
an
integrative
hub,
discrete
actions
gnathal
ganglia,
a
locus
action
selection.
Additionally,
AN
projection
patterns
within
predictive
their
encoding.
Thus,
ascending
populations
poised
inform
distinct
hubs
ongoing
behaviors
may
important
substrate
computations
required
adaptive
behavior.
In
most
animals,
a
relatively
small
number
of
descending
neurons
(DNs)
connect
higher
brain
centers
in
the
animal’s
head
to
circuits
and
motor
(MNs)
nerve
cord
body
that
effect
movement
limbs.
To
understand
how
signals
generate
behavior,
it
is
critical
these
pathways
are
organized
onto
MNs.
fly,
Drosophila
melanogaster
,
MNs
controlling
muscles
leg,
wing,
other
systems
reside
ventral
(VNC),
analogous
mammalian
spinal
cord.
companion
papers,
we
introduced
densely-reconstructed
connectome
Male
Adult
Nerve
Cord
(MANC,
Takemura
et
al.,
2023),
including
cell
type
developmental
lineage
annotation
(Marin
which
provides
complete
VNC
connectivity
at
synaptic
resolution.
Here,
present
first
look
organization
networks
connecting
DNs
based
on
this
new
information.
We
proofread
curated
all
ensure
accuracy
reliability,
then
systematically
matched
DN
axon
terminals
MN
dendrites
with
light
microscopy
data
link
their
morphology
inputs
or
muscle
targets.
report
both
broad
organizational
patterns
entire
network
fine-scale
analysis
selected
interest.
discover
direct
DN-MN
connections
infrequent
identify
communities
intrinsic
linked
control
different
systems,
putative
for
walking,
dorsal
flight
steering
power
generation,
intermediate
lower
tectulum
coordinated
action
wings
legs.
Our
generates
hypotheses
future
functional
experiments
and,
together
MANC
connectome,
empowers
others
investigate
richer
mechanistic
detail.
