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Antagonism in olfactory receptor neurons and its implications for the perception of odor mixtures
Natural environments feature mixtures of odorants of diverse quantities, qualities and complexities. Olfactory receptor neurons (ORNs) are the first layer in the sensory pathway and transmit the olfactory signal to higher regions of the brain. Yet, the response of ORNs to mixtures is strongly non-ad...
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| Published in: | eLife 2018-04, Vol.7 |
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| description | Natural environments feature mixtures of odorants of diverse quantities, qualities and complexities. Olfactory receptor neurons (ORNs) are the first layer in the sensory pathway and transmit the olfactory signal to higher regions of the brain. Yet, the response of ORNs to mixtures is strongly non-additive, and exhibits antagonistic interactions among odorants. Here, we model the processing of mixtures by mammalian ORNs, focusing on the role of inhibitory mechanisms. We show how antagonism leads to an effective 'normalization' of the ensemble ORN response, that is, the distribution of responses of the ORN population induced by any mixture is largely independent of the number of components in the mixture. This property arises from a novel mechanism involving the distinct statistical properties of receptor binding and activation, without any recurrent neuronal circuitry. Normalization allows our encoding model to outperform non-interacting models in odor discrimination tasks, leads to experimentally testable predictions and explains several psychophysical experiments in humans. |
| doi_str_mv | 10.7554/elife.34958 |
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Olfactory receptor neurons (ORNs) are the first layer in the sensory pathway and transmit the olfactory signal to higher regions of the brain. Yet, the response of ORNs to mixtures is strongly non-additive, and exhibits antagonistic interactions among odorants. Here, we model the processing of mixtures by mammalian ORNs, focusing on the role of inhibitory mechanisms. We show how antagonism leads to an effective 'normalization' of the ensemble ORN response, that is, the distribution of responses of the ORN population induced by any mixture is largely independent of the number of components in the mixture. This property arises from a novel mechanism involving the distinct statistical properties of receptor binding and activation, without any recurrent neuronal circuitry. 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| subjects | Action Potentials Aroma compounds Computational and Systems Biology decoding encoding Humans Ligands mixture interaction Models, Neurological Neuroscience normalization odor perception Odorant receptors Odorants Odors Olfactory discrimination Olfactory discrimination learning Olfactory Perception Olfactory receptor neurons Olfactory Receptor Neurons - metabolism Psychophysics Ratios Sensory evaluation Signal transduction Smell - physiology |
| title | Antagonism in olfactory receptor neurons and its implications for the perception of odor mixtures |
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