SPECIALIZED MEMBRANE JUNCTIONS BETWEEN NEURONS IN THE VERTEBRATE CEREBELLAR CORTEX

doi:10.1083/jcb.53.2.271

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SPECIALIZED MEMBRANE JUNCTIONS BETWEEN NEURONS IN THE VERTEBRATE CEREBELLAR CORTEX

Constantino Sotelo ¹ and Rodolfo Llinás ¹

¹ From Laboratoire d'Histologie Normale et Pathologique du Système Nerveux de l'I.N.S.E.R.M., Hôpital de Port-Royal, Paris 14°, France, Laboratoire de Biologie Animale, Faculté des Sciences, Paris 5°, France, and the Division of Neurobiology, Department of Physiology and Biophysics, University of Iowa, Iowa City, Iowa

"Gap" junctions, the morphological correlate for low-resistancejunctions, are demonstrated between some mossy fiber terminalsand granule cell dendrites in some lower vertebrate cerebella(gymnotid and frog). Most of the gap junctions (GJs) seen inthe gymnotid-fish cerebellum exhibit an asymmetrical configuration,the electron-opaque cytoplasmic material underlying the junctionbeing more extensive in the dendritic than in the axonal side.In the frog cerebellum, the GJs have a symmetrical distributionof such electron-opaque material. In both species the GJs areencountered at the same synaptic interface as the conventionalsynaptic zone (CSZ), constituting "mixed synapses" in a morphologicalsense. The axonal surface covered by CSZs is larger than thatcovered by GJs. In mammalian cerebellum, GJs are observed onlyin the molecular layer, between perikarya, dendrites, or perikaryaand dendrites of the inhibitory interneurons. These GJs areintermixed with attachment plates and intermediary junctionsinterpreted as simply adhesive. In the mammalian cerebellum,a new type of junction which resembles the septate junctions(SJs) of invertebrate epithelia is observed between axonal branchesforming the tip of the brush of basket fibers around the initialsegment of the Purkinje cell axon. It is suggested that suchjunctions may be modified forms of septate junctions. The physiologicalimplications of the possible existence of high-resistance cross-bridgesbetween basket cell terminals, which may compartmentalize theextracellular space and thus regulate extracellular currentflow, must be considered.

Submitted on October 4, 1971
Revised on December 15, 1971

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