How
information
is
integrated
across
different
forms
of
learning
crucial
to
understanding
higher
cognitive
functions.
Animals
form
classic
or
operant
associations
between
cues
and
their
outcomes.
It
believed
that
a
prerequisite
for
conditioning
the
formation
classical
association.
Thus,
both
memories
coexist
are
additive.
However,
two
can
result
in
opposing
behavioral
responses,
which
be
disadvantageous.
We
show
Drosophila
olfactory
rely
on
distinct
neuronal
pathways
leading
responses.
Plasticity
cannot
formed
simultaneously.
If
plasticity
occurs
at
pathways,
interference
them
disrupted.
Activity
navigation
center
required
prevent
pathway
enable
it
pathway.
These
findings
fundamentally
challenge
hierarchical
views
active
processes
coexistence
memories.
Cell,
Год журнала:
2024,
Номер
187(10), С. 2574 - 2594.e23
Опубликована: Май 1, 2024
High-resolution
electron
microscopy
of
nervous
systems
has
enabled
the
reconstruction
synaptic
connectomes.
However,
we
do
not
know
sign
for
each
connection
(i.e.,
whether
a
is
excitatory
or
inhibitory),
which
implied
by
released
transmitter.
We
demonstrate
that
artificial
neural
networks
can
predict
transmitter
types
presynapses
from
micrographs:
network
trained
to
six
transmitters
(acetylcholine,
glutamate,
GABA,
serotonin,
dopamine,
octopamine)
achieves
an
accuracy
87%
individual
synapses,
94%
neurons,
and
91%
known
cell
across
D.
melanogaster
whole
brain.
visualize
ultrastructural
features
used
prediction,
discovering
subtle
but
significant
differences
between
phenotypes.
also
analyze
distributions
brain
find
neurons
develop
together
largely
express
only
one
fast-acting
GABA).
hope
our
publicly
available
predictions
act
as
accelerant
neuroscientific
hypothesis
generation
fly.
The
central
complex
(CX)
plays
a
key
role
in
many
higher-order
functions
of
the
insect
brain
including
navigation
and
activity
regulation.
Genetic
tools
for
manipulating
individual
cell
types,
knowledge
what
neurotransmitters
neuromodulators
they
express,
will
be
required
to
gain
mechanistic
understanding
how
these
are
implemented.
We
generated
characterized
split-GAL4
driver
lines
that
express
or
small
subsets
about
half
CX
types.
surveyed
neuropeptide
receptor
expression
using
fluorescent
situ
hybridization.
About
neuropeptides
we
examined
were
expressed
only
few
cells,
while
rest
dozens
hundreds
cells.
Neuropeptide
receptors
more
broadly
at
lower
levels.
Using
our
GAL4
drivers
mark
found
51
85
types
least
one
21
multiple
neuropeptides.
Surprisingly,
all
co-expressed
molecule
neurotransmitter.
Finally,
used
identify
whose
activation
affects
sleep,
identified
other
link
circadian
clock
CX.
well-characterized
genetic
information
on
neurotransmitter
provide
should
enhance
studies
The
central
complex
(CX)
plays
a
key
role
in
many
higher-order
functions
of
the
insect
brain
including
navigation
and
activity
regulation.
Genetic
tools
for
manipulating
individual
cell
types,
knowledge
what
neurotransmitters
neuromodulators
they
express,
will
be
required
to
gain
mechanistic
understanding
how
these
are
implemented.
We
generated
characterized
split-GAL4
driver
lines
that
express
or
small
subsets
about
half
CX
types.
surveyed
neuropeptide
receptor
expression
using
fluorescent
situ
hybridization.
About
neuropeptides
we
examined
were
expressed
only
few
cells,
while
rest
dozens
hundreds
cells.
Neuropeptide
receptors
more
broadly
at
lower
levels.
Using
our
GAL4
drivers
mark
found
51
85
types
least
one
21
multiple
neuropeptides.
Surprisingly,
all
co-expressed
neurotransmitter.
Finally,
used
identify
whose
activation
affects
sleep,
identified
other
link
circadian
clock
CX.
well-characterized
genetic
information
on
neurotransmitter
provide
should
enhance
studies
Current Opinion in Behavioral Sciences,
Год журнала:
2024,
Номер
57, С. 101390 - 101390
Опубликована: Апрель 9, 2024
The
central
complex
(CX)
is
a
highly
conserved
region
of
the
insect
brain,
and
its
ubiquitous
occurrence
suggests
that
neural
circuits
are
fundamental
importance.
While
overall
layout
has
not
changed
since
evolution
flight,
substantial
variations
exist
in
internal
organization
all
CX
components.
By
changing
details
system
repeating
columns
layers,
these
differences
affect
almost
crystalline
thus
characteristic
neuroarchitecture
directly
links
structure
with
function.
neuropil
level
changes
suggest
widespread
cellular
architecture
circuits,
data
at
deeper
levels
mostly
limited
to
fruit
fly
Drosophila.
Nevertheless,
interspecies
neuron-level
have
begun
emerge.
Whereas
small
compared
astounding
degree
conservation,
they
reveal
evolvable
aspects
circuitry,
providing
promising
starting
points
for
future
research
using
comparative
circuit-level
analysis.
bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2024,
Номер
unknown
Опубликована: Окт. 22, 2024
The
central
complex
(CX)
plays
a
key
role
in
many
higher-order
functions
of
the
insect
brain
including
navigation
and
activity
regulation.
Genetic
tools
for
manipulating
individual
cell
types,
knowledge
what
neurotransmitters
neuromodulators
they
express,
will
be
required
to
gain
mechanistic
understanding
how
these
are
implemented.
We
generated
characterized
split-GAL4
driver
lines
that
express
or
small
subsets
about
half
CX
types.
surveyed
neuropeptide
receptor
expression
using
fluorescent
Temporal
patterning
of
neural
progenitors
is
an
evolutionarily
conserved
mechanism
generating
diversity.
In
Drosophila
,
postembryonic
neurogenesis
requires
the
RNA
binding
proteins
(RBPs)
Imp/IGF2BP
and
Syp/SYNCRIP.
However,
how
they
coachieve
their
function
not
well
understood.
Here,
we
elucidate
in
vivo
temporal
interactome
landscapes
Imp
Syp
during
larval
brain
development.
bind
a
highly
overlapping
set
mRNAs
encoding
involved
neurodevelopment.
We
identify
transcripts
differentially
occupied
by
Imp/Syp
over
time,
featuring
network
known
previously
unknown
candidate
regulators
that
are
post-transcriptionally
regulated
Imp/Syp.
Furthermore,
physical
coevolutionary
relationships
between
sites
reveal
combinatorial,
rather
than
competitive,
mode
molecular
interplay.
Our
study
establishes
framework
for
dissecting
coregulation
RBP
networks
as
providing
resource
understanding
fate
specification.
The
central
complex
(CX)
plays
a
key
role
in
many
higher-order
functions
of
the
insect
brain
including
navigation
and
activity
regulation.
Genetic
tools
for
manipulating
individual
cell
types,
knowledge
what
neurotransmitters
neuromodulators
they
express,
will
be
required
to
gain
mechanistic
understanding
how
these
are
implemented.
We
generated
characterized
split-GAL4
driver
lines
that
express
or
small
subsets
about
half
CX
types.
surveyed
neuropeptide
receptor
expression
using
fluorescent
situ
hybridization.
About
neuropeptides
we
examined
were
expressed
only
few
cells,
while
rest
dozens
hundreds
cells.
Neuropeptide
receptors
more
broadly
at
lower
levels.
Using
our
GAL4
drivers
mark
found
51
85
types
least
one
21
multiple
neuropeptides.
Surprisingly,
all
co-expressed
neurotransmitter.
Finally,
used
identify
whose
activation
affects
sleep,
identified
other
link
circadian
clock
CX.
well-characterized
genetic
information
on
neurotransmitter
provide
should
enhance
studies
The
central
complex
(CX)
plays
a
key
role
in
many
higher-order
functions
of
the
insect
brain
including
navigation
and
activity
regulation.
Genetic
tools
for
manipulating
individual
cell
types,
knowledge
what
neurotransmitters
neuromodulators
they
express,
will
be
required
to
gain
mechanistic
understanding
how
these
are
implemented.
We
generated
characterized
split-GAL4
driver
lines
that
express
or
small
subsets
about
half
CX
types.
surveyed
neuropeptide
receptor
expression
using
fluorescent
situ
hybridization.
About
neuropeptides
we
examined
were
expressed
only
few
cells,
while
rest
dozens
hundreds
cells.
Neuropeptide
receptors
more
broadly
at
lower
levels.
Using
our
GAL4
drivers
mark
found
51
85
types
least
one
21
multiple
neuropeptides.
Surprisingly,
all
co-expressed
molecule
neurotransmitter.
Finally,
used
identify
whose
activation
affects
sleep,
identified
other
link
circadian
clock
CX.
well-characterized
genetic
information
on
neurotransmitter
provide
should
enhance
studies
Current Biology,
Год журнала:
2024,
Номер
34(21), С. 4951 - 4967.e5
Опубликована: Окт. 8, 2024
Highlights•Sleep-regulating
23E10
dFB
neurons
originate
from
late
larval
type
II
NSCs•DL1
and
DM1
NSCs
specifically
produce
neurons•Ecdysone
signaling
in
is
essential
for
neuronal
fate•E93
regulates
fate
sleep
homeostasisSummaryComplex
behaviors
arise
neural
circuits
that
assemble
diverse
cell
types.
Sleep
a
conserved
behavior
survival,
yet
little
known
about
how
the
nervous
system
generates
neuron
types
of
sleep-wake
circuit.
Here,
we
focus
on
specification
Drosophila
23E10-labeled
dorsal
fan-shaped
body
(dFB)
long-field
tangential
input
project
to
layers
neuropil
central
complex.
We
use
lineage
analysis
genetic
birth
dating
identify
two
bilateral
stem
cells
(NSCs)
generate
neurons.
show
adult
express
ecdysone-induced
protein
93
(E93)
loss
ecdysone
or
E93
results
their
misspecification.
Finally,
knockdown
impairs
behavior.
Our
provide
insight
into
extrinsic
hormonal
acts
diversity
required
These
findings
suggest
some
disorders
might
derive
defects
cell-specific
temporal
neurodevelopmental
programs.Graphical
abstract
bioRxiv (Cold Spring Harbor Laboratory),
Год журнала:
2024,
Номер
unknown
Опубликована: Окт. 6, 2024
Abstract
To
navigate
towards
an
unknown
food
source,
animals
must
accumulate
evidence
about
the
location
of
a
goal
and
store
this
information
in
working
memory.
Here
we
identify
population
local
neurons
fan-shaped
body
Drosophila
that
exhibits
both
integration
memory
dynamics.
Imaging
from
these
during
virtual
odor-guided
navigation
reveals
bump
activity
is
activated
by
odor,
but
can
outlast
odor
stimulus
several
seconds.
Persistent
associated
with
persistent
movement
direction
adopted
arguing
represent
directional
When
fly
navigates
plume,
slowly
ramps
up
successive
encounters,
indicating
it
integrates
over
time.
We
do
not
observe
dynamics
set
neighboring
neurons,
although
populations
show
slow
modulation
correlated
engagement
task.
Silencing
first
impairs
encounters
persistence
upwind
heading.
Our
work
identifies
small
group
genetically-identified
integrate
stochastic
sensory
to
support
complex
natural
environments.
