Metabolic activity organizes olfactory representations

Author:

Qian Wesley W12ORCID,Wei Jennifer N2,Sanchez-Lengeling Benjamin2ORCID,Lee Brian K2,Luo Yunan3ORCID,Vlot Marnix4,Dechering Koen4ORCID,Peng Jian3,Gerkin Richard C12ORCID,Wiltschko Alexander B12

Affiliation:

1. Osmo

2. Google Research, Brain Team

3. Department of Computer Science, University of Illinois

4. TropIQ Health Sciences

Abstract

Hearing and vision sensory systems are tuned to the natural statistics of acoustic and electromagnetic energy on earth and are evolved to be sensitive in ethologically relevant ranges. But what are the natural statistics of odors, and how do olfactory systems exploit them? Dissecting an accurate machine learning model (Lee et al., 2022) for human odor perception, we find a computable representation for odor at the molecular level that can predict the odor-evoked receptor, neural, and behavioral responses of nearly all terrestrial organisms studied in olfactory neuroscience. Using this olfactory representation (principal odor map [POM]), we find that odorous compounds with similar POM representations are more likely to co-occur within a substance and be metabolically closely related; metabolic reaction sequences (Caspi et al., 2014) also follow smooth paths in POM despite large jumps in molecular structure. Just as the brain’s visual representations have evolved around the natural statistics of light and shapes, the natural statistics of metabolism appear to shape the brain’s representation of the olfactory world.

Funder

Google Research

Publisher

eLife Sciences Publications, Ltd

Subject

General Immunology and Microbiology,General Biochemistry, Genetics and Molecular Biology,General Medicine,General Neuroscience

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