Chokshi, V. B.; Chang, Y.-T.; Ra, D. M.; Erzurumlu, R. S.; O'Connor, D. H.

Mice rely heavily on their sophisticated whisker somatosensory system to explore and navigate their surroundings. The primary whisker somatosensory cortex (wS1) receives sensory input through the lemniscal pathway, which exclusively carries signals from the contralateral side of the face due to a complete crossover of axonal projections from the brainstem to the thalamus. This contralateral whisker input organization is disrupted in mice with a conditional knockout of the Robo3 gene (Robo3cKO mice), leading to abnormal bilateral representations of the whiskers in wS1. We investigated the behavioral and neural consequences of these bilateral whisker representations in Robo3cKO mice. Performance on a discrimination task in which mice reported whether a left-side or a right-side whisker was deflected was on par with that of wild-type littermates. Unilateral optogenetic inhibition of wS1 showed that activity in the wS1 contralateral to a stimulated whisker was required for mice to report its side correctly, despite a representation of that whisker in the uninhibited hemisphere. Single-unit recordings in wS1 and the whisker primary motor cortex (wM1), a major downstream target of wS1, showed abnormal bilateral whisker responses in wS1 but largely normal responses in wM1, suggesting that the bilateral responses in wS1 were filtered out along the sensorimotor processing stream. Our results demonstrate that the brain can adapt to fundamental alterations in tactile input to construct accurate sensorimotor representations.