苍蝇的逃避飞行启动。

Escape flight initiation in the fly.

作者信息

Hammond Sarah, O'Shea Michael

机构信息

Sussex Centre for Neuroscience, School of Life Sciences, University of Sussex, Brighton, BN1 9QG, UK.

出版信息

J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2007 Apr;193(4):471-6. doi: 10.1007/s00359-006-0203-9. Epub 2007 Jan 13.

DOI:10.1007/s00359-006-0203-9

PMID:17221263

Abstract

Visually evoked escape flight initiation in Drosophila, according to the accepted account, involves a rapid extension of the middle legs that propels the fly into the air while the wings are still folded. This description has remained unchallenged and is accounted for in terms of the activation of a simple neural circuit, the Giant fibre (GF) system. The accepted description of escape is however inconsistent with the sequence of events recorded when the GF system is stimulated. Specifically, previous electrophysiological recordings have shown that the wing depressor muscles are activated before the wings are in a position to be depressed because they have not yet been elevated. Here we show that the accepted behavioural description is wrong. Escape flight initiation actually begins with wing elevation. The current model of the GF system is revised to account for the actual sequence of events that occur when a fly escapes.

摘要

根据公认的说法，果蝇中视觉诱发的逃避飞行启动涉及中腿的快速伸展，这会在翅膀仍折叠时将果蝇推向空中。这一描述一直未受到质疑，并根据一个简单的神经回路——巨纤维（GF）系统的激活来解释。然而，公认的逃避描述与刺激GF系统时记录的事件顺序不一致。具体而言，先前的电生理记录表明，翅膀下压肌在翅膀尚未处于可下压位置时就被激活了，因为它们还没有抬起。在这里，我们表明公认的行为描述是错误的。逃避飞行启动实际上始于翅膀抬起。GF系统的当前模型被修订，以解释果蝇逃避时实际发生的事件顺序。

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苍蝇的逃避飞行启动。

Escape flight initiation in the fly.

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