Recent studies have revealed a surprising degree of functional specialization in rodent visual cortex. Anatomically, suggestions have been made about the existence of hierarchical pathways with similarities to the ventral and dorsal pathways in primates. Here we aimed to characterize some important functional properties in part of the supposed "ventral" pathway in rats. We investigated the functional properties along a progression of five visual areas in awake rats, from primary visual cortex (V1) over lateromedial (LM), latero-intermediate (LI), and laterolateral (LL) areas up to the newly found lateral occipito-temporal cortex (TO). Response latency increased Ͼ20 ms from areas V1/LM/LI to areas LL and TO. Orientation and direction selectivity for the used grating patterns increased gradually from V1 to TO. Overall responsiveness and selectivity to shape stimuli decreased from V1 to TO and was increasingly dependent upon shape motion. Neural similarity for shapes could be accounted for by a simple computational model in V1, but not in the other areas. Across areas, we find a gradual change in which stimulus pairs are most discriminable. Finally, tolerance to position changes increased toward TO. These findings provide unique information about possible commonalities and differences between rodents and primates in hierarchical cortical processing.high-level vision; population coding; position tolerance; rodent research; single-unit recordings MONKEYS HAVE BEEN the preferred animal model for vision.
Monocular enucleation (ME) drastically affects the contralateral visual cortex, where plasticity phenomena drive specific adaptations to compensate for the unilateral loss of vision. In adult mice, complete reactivation of deprived visual cortex involves an early visually driven recovery followed by multimodal plasticity 3 to 7 weeks post ME (Van Brussel et al. [2011] Cereb. Cortex 21:2133-2146). Here, we specifically investigated the age dependence of the onset and the exact timing of both ME-induced reactivation processes by comparing cortical activity patterns of mice enucleated at postnatal day (P) 45, 90, or 120. A swifter open-eye potentiated reactivation characterized the binocular visual cortex of P45 mice. Nevertheless, even after 7 weeks, the reactivation remained incomplete, especially in the monocular cortex medial to V1. In comparison with P45, emergent cross-modal participation was demonstrated in P90 animals, although robust reactivation similar to enucleated adults (P120) was not achieved yet. Concomitantly, at 7 weeks post ME, somatosensory and auditory cortex shifted from a hypoactive state in P45 to hyperactivity in P120. Thus, we provide evidence for a presensitive period in which gradual recruitment of cross-modal recovery upon long-term ME coincides with the transition from adolescence to adulthood in mice.
Unilateral cortical lesions cause disturbances often spreading into the hemisphere contralateral to the injury. The functional alteration affecting the contralesional cortex is called transhemispheric diaschisis and is believed to contribute to neurological deficits and to processes of functional reorganization post-lesion. Despite the profound implications for recovery, little is known about the cellular mechanisms that underlie this phenomenon. In the present study, transhemispheric diaschisis was investigated with an in vivo-ex vivo model of unilateral lesions, induced by an infrared laser in rat visual cortex. Visually evoked cortical activity was evaluated by the expression level of the cellular activity marker zif268, which showed an elevation in the cortex contralateral to the lesion. In vitro patch-clamp recordings from layer 2/3 pyramidal neurons revealed a shift in the excitatory–inhibitory balance in favor of excitability, particularly expressed in the undamaged hemisphere. Layer 5 principal neurons displayed an increased spontaneous firing rate contralateral to the lesion, while cells of the injured cortex displayed a reduced firing upon somatic current injection. These data suggest that a cortical lesion triggers an enhanced neuronal activity in the hemisphere contralateral to the damage. Our findings constitute an important step toward the understanding of transhemispheric diaschisis on the cellular level.
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