Influence of general anesthetics on a specific neural pathway in Drosophila melanogaster

The neural pathway that governs an escape response of Drosophila to sudden changes in light intensity can be artificially induced by electrical stimulation of the brain and monitored by electrical recording from the effector muscles. We have refined previous work in this system to permit reliable as...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 1996-09, Vol.93 (19), p.10446-10451
Main Authors: Lin, M.Q. (National Institute of Mental Health, Bethesda, MD.), Nash, H.A
Format: Article
Language:English
Subjects:
ANESTESICOS
Anesthesia
ANESTHESIQUE
Anesthetics
Anesthetics, General - pharmacology
Animals
Brain
CEREBRO
Drosophila
DROSOPHILA MELANOGASTER
Drosophila melanogaster - physiology
Electric potential
Electric Stimulation - methods
Electrodes
Electrophysiology
ENCEPHALE
Escape Reaction
GANGLION NERVEUX
GANGLIOS
General anesthetics
HALOTANO
HALOTHANE
Halothane - pharmacology
INHIBICION
INHIBITION
Insects
Light
LUMIERE
LUZ
Male
Medical genetics
MUSCLE
Muscles - innervation
Muscles - physiology
MUSCULOS
NERF
NERVIOS
Nervous system
NEUROFISIOLOGIA
Neurology
Neurons
Neurons - drug effects
Neurons - physiology
NEUROPHYSIOLOGIE
SISTEMA NERVIOSO
SYSTEME NERVEUX
TEJIDOS ANIMALES
Time Factors
TISSU ANIMAL
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Description
Summary:The neural pathway that governs an escape response of Drosophila to sudden changes in light intensity can be artificially induced by electrical stimulation of the brain and monitored by electrical recording from the effector muscles. We have refined previous work in this system to permit reliable ascertainment of two kinds of response: (i) a short-latency response that follows from direct excitation of a giant fiber neuron in the interior of the fly brain and (ii) a long-latency response in which electrical stimulation triggers neurons in the optic ganglia that ultimately impinge on the giant fiber neuron. The general anesthetic halothane is reported here to have very different potencies in inhibiting these two responses. The long-latency response is obliterated at concentrations similar to those that cause gross behavioral effects in adult flies, whereas the short-latency response is only partially inhibited at doses that are 10-fold higher. Three other volatile anesthetic agents show a similar pattern. Thus, as in higher organisms, the Drosophila nervous system is differentiated into components of high and low sensitivity to general anesthetics. Moreover, this work shows that one of the sensitive components of the nervous system lies in the optic lobe and is readily assayed by its effect on downstream systems; it should provide a focus for exploring the effects of genetic alteration of anesthetic sensitivity.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.93.19.10446