Behavioral Discrimination and Olfactory Bulb Encoding of Odor Plume Intermittency

Overview

Journal Elife

Specialty Biology

Date 2024 Mar 5

PMID 38441541

Authors

Ankita Gumaste

Keeley L Baker

Michelle Izydorczak

Aaron C True

Ganesh Vasan

John P Crimaldi

Justus Verhagen

Affiliations

Soon will be listed here.

Abstract

In order to survive, animals often need to navigate a complex odor landscape where odors can exist in airborne plumes. Several odor plume properties change with distance from the odor source, providing potential navigational cues to searching animals. Here, we focus on odor intermittency, a temporal odor plume property that measures the fraction of time odor is above a threshold at a given point within the plume and decreases with increasing distance from the odor source. We sought to determine if mice can use changes in intermittency to locate an odor source. To do so, we trained mice on an intermittency discrimination task. We establish that mice can discriminate odor plume samples of low and high intermittency and that the neural responses in the olfactory bulb can account for task performance and support intermittency encoding. Modulation of sniffing, a behavioral parameter that is highly dynamic during odor-guided navigation, affects both behavioral outcome on the intermittency discrimination task and neural representation of intermittency. Together, this work demonstrates that intermittency is an odor plume property that can inform olfactory search and more broadly supports the notion that mammalian odor-based navigation can be guided by temporal odor plume properties.

Citing Articles

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Behavioral discrimination and olfactory bulb encoding of odor plume intermittency.

Gumaste A, Baker K, Izydorczak M, True A, Vasan G, Crimaldi J Elife. 2024; 13.

PMID: 38441541 PMC: 11001298. DOI: 10.7554/eLife.85303.

Dynamics of odor-source localization: Insights from real-time odor plume recordings and head-motion tracking in freely moving mice.

Tariq M, Sterrett S, Moore S, Lane L, Perkel D, Gire D bioRxiv. 2023; .

PMID: 38014041 PMC: 10680624. DOI: 10.1101/2023.11.10.566539.

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