Abstract
The lattice-like structure of the cerebellar cortex and its anatomical organization in two perpendicular axes provided the foundations for many theories of cerebellar function. However, the functional organization does not always match the anatomical organization. Thus direct measurement of the functional organization is central to our understanding of cerebellar processing. Here we use voltage sensitive dye imaging in the isolated cerebellar preparation to characterize the spatio-temporal organization of the climbing and mossy fiber (MF) inputs to the cerebellar cortex. Spatial and temporal parameters were used to develop reliable criteria to distinguish climbing fiber (CF) responses from MF responses. CF activation excited postsynaptic neurons along a parasagittal cortical band. These responses were composed of slow (∼25 ms), monophasic depolarizing signals. Neither the duration nor the spatial distribution of CF responses were affected by inhibition. Activation of MF generated responses that were organized in radial patches, and were composed of a fast (∼5 ms) depolarizing phase followed by a prolonged (∼100 ms) negative wave. Application of a GABAA blocker eliminated the hyperpolarizing phase and prolonged the depolarizing phase, but did not affect the spatial distribution of the response, thus suggesting that it is not the inhibitory system that is responsible for the inability of the MF input to generate beams of activity that propagate along the parallel fiber system.
Highlights
Spatial patterns of activity in the nervous system are formed by the spatial organization of the incoming input and the structure of the local network
An area of 3 Â 3 mm was stained with the voltage sensitive dye RH-414
A concentric bipolar electrode was placed on the surface of the cerebellar cortex to stimulate the parallel fibers (PFs) system, and a second stimulating electrode was inserted into the white matter (WM) just underneath the stained area to stimulate climbing fibers (CF) and mossy fiber (MF)
Summary
Spatial patterns of activity in the nervous system are formed by the spatial organization of the incoming input and the structure of the local network. The two types of inputs, the climbing fibers (CF) and the mossy fibers (MFs), have been extensively studied and their effect on the principal cerebellar cortical neurons, the Purkinje cells, has been described in detail. These detailed studies stand in sharp contrast to the sporadic reports on the spatial organization of these two inputs. In a previous study Cohen and Yarom (1998) used voltage sensitive dye imaging to record presumptive MF responses, direct, careful measurement of synaptic activity elicited by both inputs has never been done
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