Danielle V. Riboul scite author profile

Danielle V. Riboul

3Publications

29Citation Statements Received

427Citation Statements Given

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Florida Atlantic University

Publications

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Physiologic and nanoscale distinctions define glutamatergic synapses in tonic vs phasic neurons

Han

et al. 2022

Preprint

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Neurons exhibit a striking degree of functional diversity, each one tuned to the needs of the circuitry in which it is embedded. A fundamental functional dichotomy occurs in activity patterns, with some neurons firing at a relatively constant “tonic” rate, while others fire in bursts - a “phasic” pattern. Synapses formed by tonic vs phasic neurons are also functionally differentiated, yet the bases of their distinctive properties remain enigmatic. A major challenge towards illuminating the synaptic differences between tonic and phasic neurons is the difficulty in isolating their physiological properties. At theDrosophilaneuromuscular junction (NMJ), most muscle fibers are co-innervated by two motor neurons, the tonic “MN-Ib” and phasic “MN-Is”. Here, we employed selective expression of a newly developed botulinum neurotoxin (BoNT-C) transgene to silence tonic or phasic motor neurons. This approach revealed major differences in their neurotransmitter release properties, including probability, short-term plasticity, and vesicle pools. Furthermore, Ca2+imaging demonstrated ~two-fold greater Ca2+influx at phasic neuron release sites relative to tonic, along with enhanced synaptic vesicle coupling. Finally, confocal and super resolution imaging revealed that phasic neuron release sites are organized in a more compact arrangement, with enhanced stoichiometry of voltage-gated Ca2+channels relative to other active zone scaffolds. These data suggest that distinctions in active zone nano-architecture and Ca2+influx collaborate to differentially tune glutamate release at synapses of tonic vs phasic neuronal subtypes.

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Mitochondrial phosphagen kinases support the volatile power demands of motor nerve terminals

Justs

Sempertegui

Riboul

et al. 2022

Preprint

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Neural function relies on cellular energy supplies meeting the episodic demands of synaptic activity, but little is known about the extent to which power demands (energy demands per unit time) fluctuate, or the mechanisms that match supply with demand. Here, in individually-identified glutamatergic motor neuron terminals of Drosophila larvae, we leveraged prior macroscopic estimates of power demand to generate profiles of power demand from one action potential to the next. These profiles show that signaling demands can exceed non-signaling demands by 17-fold within milliseconds, and terminals with the greatest fluctuation (volatility) in power demand have the greatest mitochondrial volume and packing density. We elaborated on this quantitative approach to simulate adenosine triphosphate (ATP) levels during activity and drove ATP production as a function of the reciprocal of the energy state, but this canonical feedback mechanism appeared to be unable to prevent ATP depletion during locomotion. Muscle cells possess a phosphagen system to buffer ATP levels but phosphagen systems have not been described for motor nerve terminals. We examined these terminals for evidence of a phosphagen system and found the mitochondria to be heavily decorated with an arginine kinase, the key element of invertebrate phosphagen systems. Similarly, an examination of mouse cholinergic motor nerve terminals found mitochondrial creatine kinases, the vertebrate analogues of arginine kinases. Knock down of arginine kinase in Drosophila resulted in rapid depletion of presynaptic ATP during activity, indicating that, in motor nerve terminals, as in muscle, phosphagen systems play a critical role in matching power supply with demand.

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Physiologic and Nanoscale Distinctions Define Glutamatergic Synapses in Tonic vs Phasic Neurons

Han

et al. 2023

J. Neurosci.

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Neurons exhibit a striking degree of functional diversity, each one tuned to the needs of the circuitry in which it is embedded. A fundamental functional dichotomy occurs in activity patterns, with some neurons firing at a relatively constant “tonic” rate, while others fire in bursts - a “phasic” pattern. Synapses formed by tonic vs phasic neurons are also functionally differentiated, yet the bases of their distinctive properties remain enigmatic. A major challenge towards illuminating the synaptic differences between tonic and phasic neurons is the difficulty in isolating their physiological properties. At theDrosophilaneuromuscular junction (NMJ), most muscle fibers are co-innervated by two motor neurons, the tonic “MN-Ib” and phasic “MN-Is”. Here, we employed selective expression of a newly developed botulinum neurotoxin (BoNT-C) transgene to silence tonic or phasic motor neurons inDrosophilalarvae of either sex. This approach highlighted major differences in their neurotransmitter release properties, including probability, short-term plasticity, and vesicle pools. Furthermore, Ca2+imaging demonstrated ∼two-fold greater Ca2+influx at phasic neuron release sites relative to tonic, along with an enhanced synaptic vesicle coupling. Finally, confocal and super-resolution imaging revealed that phasic neuron release sites are organized in a more compact arrangement, with enhanced stoichiometry of voltage-gated Ca2+channels relative to other active zone scaffolds. These data suggest that distinctions in active zone nano-architecture and Ca2+influx collaborate to differentially tune glutamate release at tonic vs phasic synaptic subtypes.SIGNIFICANCE STATEMENT:“Tonic” and “phasic” neuronal subtypes, based on differential firing properties, are common across many nervous systems. Using a recently developed approach to selectively silence transmission from one of these two neurons, we reveal specialized synaptic functional and structural properties that distinguish these specialized neurons. This study provides important insights into how the input-specific synaptic diversity is achieved, which could have significant implications for the development of therapeutic interventions for neurological disorders that involve changes in synaptic function.

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