Model
Digital Document
Publisher
Florida Atlantic University
Description
In the developing CNS, presynaptic neurons often have exuberant overgrowth and
form excess (and overlapping) postsynaptic connections. Importantly, these excess
connections are refined during circuit maturation so that only the appropriate connections
remain. This synaptic rearrangement phenomenon has been studied extensively in
vertebrates but many of those models involve complex neuronal circuits with multiple
presynaptic inputs and postsynaptic outputs. Using a simple escape circuit in Drosophila
melanogaster (the giant fiber circuit), we developed tools that enabled us to study the
molecular development of this circuit; which consists of a bilaterally symmetrical pair of
presynaptic interneurons and postsynaptic motorneurons. In the adult circuit, each
presynaptic interneuron (giant fiber) forms a single connection with the ipsilateral,
postsynaptic motorneuron (TTMn). Using new tools that we developed we labeled both
giant fibers throughout their development and saw that these neurons overgrew their targets and formed overlapping connections. As the circuit matured, giant fibers pruned
their terminals and refined their connectivity such that only a single postsynaptic
connection remained with the ipsilateral target. Furthermore, if we ablated one of the two
giant fibers during development in wildtype animals, the remaining giant fiber often
retained excess connections with the contralateral target that persisted into adulthood.
After demonstrating that the giant fiber circuit was suitable to study synaptic
rearrangement, we investigated two proteins that might mediate this process. First, we
were able to prevent giant fibers from refining their connectivity by knocking out
highwire, a ubiquitin ligase that prevented pruning. Second, we investigated whether
overexpressing Netrin (or Frazzled), part of a canonical axon guidance system, would
affect the refinement of giant fiber connectivity. We found that overexpressing Netrin (or
Frazzled) pre- & postsynaptically resulted in some giant fibers forming or retaining
excess connections, while exclusively presynaptic (or postsynaptic) expression of either
protein had no effect. We further showed that by simultaneously reducing (Slit-Robo)
midline repulsion and elevating Netrin (or Frazzled) pre- & postsynaptically, we
significantly enhanced the proportion of giant fibers that formed excess connections. Our
findings suggest that Netrin-Frazzled and Slit-Robo signaling play a significant role in
refining synaptic circuits and shaping giant fiber circuit connectivity.
form excess (and overlapping) postsynaptic connections. Importantly, these excess
connections are refined during circuit maturation so that only the appropriate connections
remain. This synaptic rearrangement phenomenon has been studied extensively in
vertebrates but many of those models involve complex neuronal circuits with multiple
presynaptic inputs and postsynaptic outputs. Using a simple escape circuit in Drosophila
melanogaster (the giant fiber circuit), we developed tools that enabled us to study the
molecular development of this circuit; which consists of a bilaterally symmetrical pair of
presynaptic interneurons and postsynaptic motorneurons. In the adult circuit, each
presynaptic interneuron (giant fiber) forms a single connection with the ipsilateral,
postsynaptic motorneuron (TTMn). Using new tools that we developed we labeled both
giant fibers throughout their development and saw that these neurons overgrew their targets and formed overlapping connections. As the circuit matured, giant fibers pruned
their terminals and refined their connectivity such that only a single postsynaptic
connection remained with the ipsilateral target. Furthermore, if we ablated one of the two
giant fibers during development in wildtype animals, the remaining giant fiber often
retained excess connections with the contralateral target that persisted into adulthood.
After demonstrating that the giant fiber circuit was suitable to study synaptic
rearrangement, we investigated two proteins that might mediate this process. First, we
were able to prevent giant fibers from refining their connectivity by knocking out
highwire, a ubiquitin ligase that prevented pruning. Second, we investigated whether
overexpressing Netrin (or Frazzled), part of a canonical axon guidance system, would
affect the refinement of giant fiber connectivity. We found that overexpressing Netrin (or
Frazzled) pre- & postsynaptically resulted in some giant fibers forming or retaining
excess connections, while exclusively presynaptic (or postsynaptic) expression of either
protein had no effect. We further showed that by simultaneously reducing (Slit-Robo)
midline repulsion and elevating Netrin (or Frazzled) pre- & postsynaptically, we
significantly enhanced the proportion of giant fibers that formed excess connections. Our
findings suggest that Netrin-Frazzled and Slit-Robo signaling play a significant role in
refining synaptic circuits and shaping giant fiber circuit connectivity.
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