An evolutionarily conserved scheme for reformatting odor concentration in early olfactory circuits

Shen, Yang, Banerjee, Arkarup, Albeanu, Dinu F, Navlakha, Saket (February 2025) An evolutionarily conserved scheme for reformatting odor concentration in early olfactory circuits. bioRxiv. ISSN 2692-8205 (Submitted)

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Abstract

Understanding how stimuli from the sensory periphery are progressively reformatted to yield useful representations is a fundamental challenge in neuroscience. In olfaction, assessing odor concentration is key for many behaviors, such as tracking and navigation. Initially, as odor concentration increases, the average response of first-order sensory neurons also increases. However, the average response of second-order neurons remains flat with increasing concentration – a transformation that is believed to help with concentration-invariant odor identification, but that seemingly discards concentration information before it could be sent to higher brain regions. By combining neural data analyses from diverse species with computational modeling, we propose strategies by which second-order neurons preserve concentration information, despite flat mean responses at the population level. We find that individual second-order neurons have diverse concentration response curves that are unique to each odorant — some neurons respond more with higher concentration and others respond less — and together this diversity generates distinct combinatorial representations for different concentrations. We show that this encoding scheme can be recapitulated using a circuit computation, called divisive normalization, and we derive sufficient conditions for this diversity to emerge. We then discuss two mechanisms (spike rate vs. timing based) by which higher order brain regions may decode odor concentration from the reformatted representations. Since vertebrate and invertebrate olfactory systems likely evolved independently, our findings suggest that evolution converged on similar algorithmic solutions despite stark differences in neural circuit architectures. Finally, in land vertebrates a parallel olfactory pathway has evolved whose second-order neurons do not exhibit such diverse response curves; rather neurons in this pathway represent concentration information in a more monotonic fashion on average, potentially allowing for easier odor localization and identification at the expense of increased energy use.

Item Type: Paper
Subjects: organism description > animal behavior
organism description > animal behavior > olfactory
organs, tissues, organelles, cell types and functions > tissues types and functions > olfactory bulb
organs, tissues, organelles, cell types and functions
organs, tissues, organelles, cell types and functions > tissues types and functions
CSHL Authors:
Communities: CSHL labs > Albeanu lab
CSHL labs > Navlakha lab
CSHL labs > Banerjee lab
SWORD Depositor: CSHL Elements
Depositing User: CSHL Elements
Date: 18 February 2025
Date Deposited: 26 Mar 2025 13:19
Last Modified: 26 Mar 2025 13:19
Related URLs:
URI: https://repository.cshl.edu/id/eprint/41835

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