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1.
Article in English | MEDLINE | ID: mdl-28087331

ABSTRACT

Aging has significant effects on the locomotor performance of insects including Drosophila. Using a protocol for the high-throughput analysis of fly locomotion in a circular arena, we examined age-dependent behavioral characteristics in adult flies. There are widely used wild-type and genetically engineered background lines including the Canton-S strain and the w1118 strain, which has a null mutation of the white gene. Under standard rearing conditions, we found similar survival and median lifespans in Canton-S (50days) and w1118 (54days) strains, however, w1118 flies maintained stable body mass for up to 43days, whereas Canton-S flies gained body mass at young age, followed by a gradual decline. We also tested the behavioral performance of young and old flies. Compared with young w1118 flies (5-10days), old w1118 flies (40-45days) had an increased boundary preference during locomotion in small circular arenas, and increased speed of locomotor recovery from anoxia. Old Canton-S files, however, exhibited unchanged boundary preference and reduced recovery speed from anoxia relative to young flies. In addition, old w1118 flies showed decreased path length per minute and reduced 0.2s path increment compared with young flies, whereas old Canton-S flies displayed the same path length per minute and the same 0.2s path increment compared with young flies. We conclude that age-dependent behavioral and physiological changes differ between Canton-S and w1118 flies. These results illustrate that phenotypic differences between strains can change qualitatively, as well as quantitatively, as the animals age.


Subject(s)
Aging , Drosophila Proteins/genetics , Drosophila melanogaster/growth & development , Gene Deletion , Animals , Animals, Genetically Modified/genetics , Animals, Genetically Modified/growth & development , Animals, Genetically Modified/physiology , Behavior, Animal , Body Size , Cell Hypoxia , Drosophila Proteins/metabolism , Drosophila melanogaster/genetics , Drosophila melanogaster/physiology , Flight, Animal , Kinetics , Longevity , Species Specificity
2.
J Insect Physiol ; 58(11): 1511-6, 2012 Nov.
Article in English | MEDLINE | ID: mdl-23017334

ABSTRACT

Environmental temperature is one of the most important abiotic factors affecting insect behaviour; virtually all physiological processes, including those which regulate nervous system function, are affected. At both low and high temperature extremes insects enter a coma during which individuals do not display behaviour and are unresponsive to stimulation. We investigated neurophysiological correlates of chill and hyperthermic coma in Drosophila melanogaster. Coma resulting from anoxia causes a profound loss of K(+) homeostasis characterized by a surge in extracellular K(+) concentration ([K(+)](o)) in the brain. We recorded [K(+)](o) in the brain during exposure to both low and high temperatures and observed a similar surge in [K(+)](o) which recovered to baseline concentrations following return to room temperature. We also found that rapid cold hardening (RCH) using a cold pretreatment (4°C for 2h; 2h recovery at room temperature) increased the peak brain [K(+)](o) reached during a subsequent chill coma and increased the rates of accumulation and clearance of [K(+)](o). We conclude that RCH preserves K(+) homeostasis in the fly brain during exposure to cold by reducing the temperature sensitivity of the rates of homeostatic processes.


Subject(s)
Brain/metabolism , Cold Temperature , Drosophila melanogaster/metabolism , Potassium/metabolism , Acclimatization , Animals , Coma/metabolism , Homeostasis , Hypoxia/metabolism , Male
3.
Neuroreport ; 9(11): 2589-93, 1998 Aug 03.
Article in English | MEDLINE | ID: mdl-9721938

ABSTRACT

We investigated the effects of heat shock on the temperature sensitivity of synaptic transmission in the motor circuit for flight in Locusta migratoria. In heat shocked animals synaptic transmission failed at 5-6 degrees C higher than in control animals and recovery of transmission was more than three times faster upon return to room temperature. We also found that synaptic delay was rendered insensitive to increases in temperature by heat shock. Thus we have shown in the locust that heat shock has important protective effects on synaptic transmission, thereby extending the upper temperature limit for the motor patterns that generate flight. This is the first description of an effect of heat shock that preserves neuronal communication under subsequent stressful conditions.


Subject(s)
Flight, Animal/physiology , Grasshoppers/physiology , Hot Temperature , Motor Neurons/physiology , Muscles/physiology , Synaptic Transmission/physiology , Animals , Electric Stimulation , Electrophysiology , Excitatory Postsynaptic Potentials/physiology , Ganglia, Invertebrate/cytology , Ganglia, Invertebrate/physiology , In Vitro Techniques , Interneurons/physiology , Muscles/innervation , Neuropil/physiology , Synapses/physiology
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