This is a continuation of an existing program funded by an RO1 that seeks to understand fundamental questions about the nature of the olfactory stimulus and its discrimination by primary sensory receptors, in order to better grasp the nature of the signal being forwarded to the brain. We supplement the standard organic chemistry approach to odor classification with one that includes a biological perspective based in principles of medicinal chemistry pioneered in the pharmaceutical industry and drug development. This allows us to not only consider physical chemical characteristics of molecules but also how they interact with the many olfactory receptors. This work, like much of olfactory cellular studies, utilized monomolecular stimuli to probe receptor function. However the olfactory system is usually confronted with complex stimulus blends of between tens and hundreds of components. To better understand the complexity of mixture discrimination we have begun utilizing a novel microscopic technique, SCAPE ? that allows us to visualize large numbers of individual neurons in an intact tissue with single cell temporal and spatial resolution. Preliminary data from that work showed a remarkable and unexpected degree of inhibition and enhancement of responses by one component of the mixture on other components of the mixture. This raises a fundamental issue in olfactory discrimination as there appears to be considerable interaction between stimuli at the primary receptor, raising crucial questions about how the brain perceives and manages signals that differ depending on the presence of particular odors in a blend. It appears that many, if not all, odors can act as either an agonist or antagonist at different receptors. Thus depending on whether or not an antagonist to odor X, for example, exists in the blend, the signal from odor X will appear different to the brain. This level of complexity is unusual in sensory systems where signal processing of this sort occurs in the brain not the primary receptors. Understanding higher brain processing olfactory signals will require a greater understanding of the initial events at primary receptors. The olfactory code is more than the additive contributions of the olfactory receptors.

Public Health Relevance

The olfactory system utilizes a family of receptors to recognize odors that are closely related to the receptors used for neurotransmission and hormonal regulation in the brain and other bodily systems. Understanding how the olfactory receptors detect and discriminate between a vast number of small organic molecules, many of which are similar to drugs in their chemical structure and physical characteristics, will allow us to adopt better strategies for drug development, including better control of side effects, greater efficacy and less tolerance development.

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
2R01DC013553-06A1
Application #
9886739
Study Section
Chemosensory Systems Study Section (CSS)
Program Officer
Sullivan, Susan L
Project Start
2014-07-15
Project End
2024-11-30
Budget Start
2019-12-09
Budget End
2020-11-30
Support Year
6
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Columbia University (N.Y.)
Department
Biology
Type
Graduate Schools
DUNS #
049179401
City
New York
State
NY
Country
United States
Zip Code
10027
Poivet, Erwan; Tahirova, Narmin; Peterlin, Zita et al. (2018) Functional odor classification through a medicinal chemistry approach. Sci Adv 4:eaao6086
Poivet, Erwan; Peterlin, Zita; Tahirova, Narmin et al. (2016) Applying medicinal chemistry strategies to understand odorant discrimination. Nat Commun 7:11157