fm1-43 and Paralysis

fm1-43 has been researched along with Paralysis* in 1 studies

Other Studies

1 other study(ies) available for fm1-43 and Paralysis

Article	Year
Cellular bases of activity-dependent paralysis in Drosophila stress-sensitive mutants. Journal of neurobiology, 2004, Sep-05, Volume: 60, Issue:3 Stress-sensitive mutants in Drosophila have been shown to exhibit activity-dependent defects in neurotransmission. Using the neuromuscular junction (NMJ), this study investigates synaptic function more specifically in two stress-sensitive mutants: stress-sensitive B (sesB), which encodes a mitochondrial ADP/ATP translocase (ANT); and Atpalpha(2206), a conditional mutant of the Na+/K+ ATPase alpha-subunit. Mechanical shock induces a period of brief paralysis in both homozygous and double heterozygous mutants, but further analysis revealed distinct activity-dependent neurotransmission lesions in each mutant. Basal neurotransmission appeared similar to wild-type controls in both mutants under low frequency stimulation. High frequency stimulation, however, caused pronounced synaptic fatigue as well as slow and incomplete synaptic recovery in sesB mutants while Atpalpha(2206) mutants displayed an increase (25-fold) in synaptic failures. Perhaps to compensate for these activity dependent defects, the neuromuscular synapse was found to be overgrown in both mutants. Passive electrotonic stimulation, which initiates synaptic transmission independent of action potentials, ameliorated synaptic failures and resulted in increased neurotransmission amplitude in Atpalpha(2206) mutants. In addition, spontaneous synaptic vesicle fusion rates were increased in Atpalpha(2206) mutants, suggesting that, in the absence of action potential requirements, these synaptic terminals are healthy, if not hyperactive. Dye labeling studies revealed aberrant synaptic vesicle cycling in sesB mutants indicating a reduction of functional synaptic vesicles. We therefore postulate that both stress-sensitive mutants harbor unique neurotransmission defects: Atpalpha(2206) mutants are unable to maintain ionic gradients required during repetitive action potential propagation, and sesB mutants cannot maintain synaptic vesicle cycling during periods of high demand. Topics: Animals; Behavior, Animal; Calcium; Drosophila; Electrophysiology; Evoked Potentials; Excitatory Postsynaptic Potentials; Genes, Insect; Hot Temperature; In Vitro Techniques; Larva; Mitochondria; Mutation; Neuromuscular Junction; Paralysis; Physical Stimulation; Presynaptic Terminals; Pyridinium Compounds; Quaternary Ammonium Compounds; Stress, Physiological; Synaptic Transmission; Synaptic Vesicles; Time Factors	2004

Article

Year

Cellular bases of activity-dependent paralysis in Drosophila stress-sensitive mutants.

Journal of neurobiology, 2004, Sep-05, Volume: 60, Issue:3

Stress-sensitive mutants in Drosophila have been shown to exhibit activity-dependent defects in neurotransmission. Using the neuromuscular junction (NMJ), this study investigates synaptic function more specifically in two stress-sensitive mutants: stress-sensitive B (sesB), which encodes a mitochondrial ADP/ATP translocase (ANT); and Atpalpha(2206), a conditional mutant of the Na+/K+ ATPase alpha-subunit. Mechanical shock induces a period of brief paralysis in both homozygous and double heterozygous mutants, but further analysis revealed distinct activity-dependent neurotransmission lesions in each mutant. Basal neurotransmission appeared similar to wild-type controls in both mutants under low frequency stimulation. High frequency stimulation, however, caused pronounced synaptic fatigue as well as slow and incomplete synaptic recovery in sesB mutants while Atpalpha(2206) mutants displayed an increase (25-fold) in synaptic failures. Perhaps to compensate for these activity dependent defects, the neuromuscular synapse was found to be overgrown in both mutants. Passive electrotonic stimulation, which initiates synaptic transmission independent of action potentials, ameliorated synaptic failures and resulted in increased neurotransmission amplitude in Atpalpha(2206) mutants. In addition, spontaneous synaptic vesicle fusion rates were increased in Atpalpha(2206) mutants, suggesting that, in the absence of action potential requirements, these synaptic terminals are healthy, if not hyperactive. Dye labeling studies revealed aberrant synaptic vesicle cycling in sesB mutants indicating a reduction of functional synaptic vesicles. We therefore postulate that both stress-sensitive mutants harbor unique neurotransmission defects: Atpalpha(2206) mutants are unable to maintain ionic gradients required during repetitive action potential propagation, and sesB mutants cannot maintain synaptic vesicle cycling during periods of high demand.

Topics: Animals; Behavior, Animal; Calcium; Drosophila; Electrophysiology; Evoked Potentials; Excitatory Postsynaptic Potentials; Genes, Insect; Hot Temperature; In Vitro Techniques; Larva; Mitochondria; Mutation; Neuromuscular Junction; Paralysis; Physical Stimulation; Presynaptic Terminals; Pyridinium Compounds; Quaternary Ammonium Compounds; Stress, Physiological; Synaptic Transmission; Synaptic Vesicles; Time Factors

2004