Glomerulus (cerebellum)

The cerebellar glomerulus is a small, intertwined mass of nerve fiber terminals in the granular layer of the cerebellar cortex. It consists of post-synaptic granule cell dendrites and pre-synaptic Golgi cell axon terminals surrounding the pre-synaptic terminals of mossy fibers.^[1]

Function

The cerebellar glomeruli are the first "processing station" for afferent nerve fibers entering the cerebellum. Input comes from the mossy fibers, which terminate here and synapse with the Golgi and granule cell fibers. The Golgi cells regulate the glomeruli with inhibitory signals, while information is passed on to the granule and Golgi cells from the mossy fiber.^[2]

Structure

The structure of the cerebellar glomeruli is about 2.5 um in diameter, and is enwrapped by glial sheathing. Glomeruli are centered on the large axonal terminals of glutamatergic afferent mossy fibers. Each of these terminals come into contact with dendrites from 50–60 different granule cells. The granule cells themselves each have a single or multiple dendrites, and each participate in a different glomerulus. Glomeruli also contain the GABAergic (inhibitory) synapses of Golgi cells onto granule cells, and the glutamatergic (excitatory) synapses from mossy fibers onto Golgi cells.^[3] Each glomerulus contains approximately 50 granule cell dendrites, 210 total dendritic digits, and 230 synaptic junctions.^[4]

Velate astrocytes

The glia that ensheath the glomeruli are called velate astrocytes. Velate astrocytes are protoplasmic astrocytes with extremely thin veil-like processes that spread out and overlap each other.^[5] Researchers Sanford Palay and Victoria Chan-Palay noted that the sheath does not penetrate into the deeper part of the glomeruli or come into contact with the mossy fiber. Instead it forms a sort of capsule, through which the neural processes of the granule and Golgi cells penetrate.^[6] The purpose of the glial sheath is still unknown, though multiple functions have been proposed, including supplying structural support, providing electrophysiological insulation, and maintaining chemical equilibrium in the interstitial fluid, as well as creating a chemical barrier to the further outgrowth of granule and Golgi cell fibers. Research conducted by David Eagleman suggests that the glial sheath limits the supply of extracellular calcium to regulate signaling.^[7]

References