果蝇趋光性、趋化性和多感官整合背后的计算过程。

Computations underlying Drosophila photo-taxis, odor-taxis, and multi-sensory integration.

作者信息

Gepner Ruben, Mihovilovic Skanata Mirna, Bernat Natalie M, Kaplow Margarita, Gershow Marc

机构信息

Department of Physics, New York University, New York, United States.

Center for Neural Science, New York University, New York, United States.

出版信息

Elife. 2015 May 6;4:e06229. doi: 10.7554/eLife.06229.

DOI:10.7554/eLife.06229

PMID:25945916

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4466338/

Abstract

To better understand how organisms make decisions on the basis of temporally varying multi-sensory input, we identified computations made by Drosophila larvae responding to visual and optogenetically induced fictive olfactory stimuli. We modeled the larva's navigational decision to initiate turns as the output of a Linear-Nonlinear-Poisson cascade. We used reverse-correlation to fit parameters to this model; the parameterized model predicted larvae's responses to novel stimulus patterns. For multi-modal inputs, we found that larvae linearly combine olfactory and visual signals upstream of the decision to turn. We verified this prediction by measuring larvae's responses to coordinated changes in odor and light. We studied other navigational decisions and found that larvae integrated odor and light according to the same rule in all cases. These results suggest that photo-taxis and odor-taxis are mediated by a shared computational pathway.

摘要

为了更好地理解生物体如何基于随时间变化的多感官输入做出决策，我们确定了果蝇幼虫对视觉和光遗传学诱导的虚拟嗅觉刺激做出反应时所进行的计算。我们将幼虫启动转向的导航决策建模为线性-非线性-泊松级联的输出。我们使用反向相关性来拟合该模型的参数；参数化模型预测了幼虫对新刺激模式的反应。对于多模态输入，我们发现幼虫在转向决策的上游线性组合嗅觉和视觉信号。我们通过测量幼虫对气味和光线协调变化的反应来验证这一预测。我们研究了其他导航决策，发现幼虫在所有情况下都根据相同的规则整合气味和光线。这些结果表明，趋光性和趋化性是由共享的计算途径介导的。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/711b/4466338/2539ca862d0a/elife06229f001.jpg

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果蝇趋光性、趋化性和多感官整合背后的计算过程。

Computations underlying Drosophila photo-taxis, odor-taxis, and multi-sensory integration.

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