Abstract
Each olfactory cortical hemisphere receives ipsilateral odor information directly from the olfactory bulb and contralateral information indirectly from the other cortical hemisphere. Since neural projections to the olfactory cortex are disordered and non-topographic, spatial information cannot be used to align projections from the two sides like in the visual cortex. Therefore, how bilateral information is integrated in individual cortical neurons is unknown. We have found, in mice, that the odor responses of individual neurons to selective stimulation of each of the two nostrils are highly matched, such that odor identity decoding optimized with information arriving from one nostril transfers very well to the other side. Remarkably, these aligned responses are nevertheless asymmetric enough to allow decoding of stimulus laterality. Computational analysis shows that such matched odor tuning is incompatible with purely random connections but is explained readily by Hebbian plasticity structuring bilateral connectivity. Our data reveal that despite the distributed and fragmented sensory representation in the olfactory cortex, odor information across the two hemispheres is highly coordinated.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
↵* Lead Author.
Additional data has been added (Figure S3I-J); new analysis and simulations have been done (Figure 6; Figure S8); new discussion acknowledging additional work has been included.