THE ULTRASTRUCTURE OF THE NEXUS: A Correlated Thin-Section and Freeze-Cleave Study

doi:10.1083/jcb.47.3.666

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BRIEF NOTES

THE ULTRASTRUCTURE OF THE NEXUS : A Correlated Thin-Section and Freeze-Cleave Study

N. Scott McNutt ¹ and Ronald S. Weinstein ¹

¹ From the Departments of Pathology, Harvard Medical School and the Massachusetts General Hospital; and the Mixter Laboratory for Electron Microscopy, Neurosurgical Service, Massachusetts General Hospital, Boston, Massachusetts 02114

A correlation is made between the appearances of the nexus("gap junction") as revealed by thin-section and by freeze-cleaveelectron microscopy techniques. These methods reveal differentaspects of a complex subunit assembly forming the nexus membranes.In thin sections, the nexus is formed by the very close appositionof two "unit" membranes. The electron-opaque tracer, colloidallanthanum hydroxide, outlines an aspect of electron-lucent subunitsthat project into the central region of the nexus. The freeze-cleavetechnique demonstrates novel membrane faces that are generatedfrom within the interior of plasma membranes by splitting theminto two lamellae (Lm): Lm 1 adjacent to the cytoplasm, andLm 2 adjacent to the extracellular space. Each of the two membranesforming the nexus can be split into these two lamellae. On thenew face of Lm 1, particles approximately 50 A in diameter areclosely packed in an array which is often hexagonal with a 90–100A center-to-center spacing. The two apposed lamellae (Lm 2-Lm2) of the nexus are constructed of sheets of subunits in a similararray. The Lm 1 particles appear to extend into the Lm 2 subunitsto form macromolecular complexes. The Lm 2 subunits extend tothe center of the nexus to form the contacts outlined by lanthanumin sections. It is postulated that central hydrophilic channelsmay extend through the subunit assembly to provide a directroute for intercellular communication.

Submitted on April 20, 1970
Revised on June 23, 1970

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