Marie P. Suver scite author profile

Localizing the sources of stimuli is essential. Most organisms cannot eat, mate, or escape without knowing where the relevant stimuli originate. For many, if not most, animals, olfaction plays an essential role in search. While microorganismal chemotaxis is relatively well understood, in larger animals the algorithms and mechanisms of olfactory search remain mysterious. In this symposium, we will present recent advances in our understanding of olfactory search in flies and rodents. Despite their different sizes and behaviors, both species must solve similar problems, including meeting the challenges of turbulent airflow, sampling the environment to optimize olfactory information, and incorporating odor information into broader navigational systems.

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An Array of Descending Visual Interneurons Encoding Self-Motion inDrosophila

Suver

et al. 2016

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The means by which brains transform sensory information into coherent motor actions is poorly understood. In flies, a relatively small set of descending interneurons are responsible for conveying sensory information and higher-order commands from the brain to motor circuits in the ventral nerve cord. Here, we describe three pairs of genetically identified descending interneurons that integrate information from wide-field visual interneurons and project directly to motor centers controlling flight behavior. We measured the physiological responses of these three cells during flight and found that they respond maximally to visual movement corresponding to rotation around three distinct body axes. After characterizing the tuning properties of an array of nine putative upstream visual interneurons, we show that simple linear combinations of their outputs can predict the responses of the three descending cells. Last, we developed a machine vision-tracking system that allows us to monitor multiple motor systems simultaneously and found that each visual descending interneuron class is correlated with a discrete set of motor programs.

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Encoding of Wind Direction by Central Neurons in Drosophila

Suver

Matheson

Sarkar

et al. 2019

Neuron

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Marie P. Suver

Octopamine Neurons Mediate Flight-Induced Modulation of Visual Processing in Drosophila

Algorithms for Olfactory Search across Species

An Array of Descending Visual Interneurons Encoding Self-Motion inDrosophila

Encoding of Wind Direction by Central Neurons in Drosophila

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