THE STRUCTURE OF THE ZONULA OCCLUDENS: A Single Fibril Model Based on Freeze-Fracture

doi:10.1083/jcb.60.1.168

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ARTICLE

THE STRUCTURE OF THE ZONULA OCCLUDENS

: A Single Fibril Model Based on Freeze-Fracture

James B. Wade ¹ and Morris J. Karnovsky ¹

¹ From the Department of Pathology, Harvard Medical School, Boston, Massachusetts 02115.

Dr. Wade's present address is the Renal Service, Department of Medicine, United States Public Health Service Hospital, Staten Island, New York 10304.

Replicas of freeze-fractured toad urinary bladder and gallbladderwere analysed in an attempt to determine the fracturing propertiesand structure of the zonula occludens (tight junction). Chalcroftand Bullivant have proposed that the junction has a double setof fibrils with one set associated with each of the adjacentcell membranes. However, the fracturing pattern that is observedmight also result from only a single set of fibrils which isshared by the adjacent membranes if fracturing occurred aroundeither side of the fibrils. These two models predict quite differentstructures at regions of the junction where tranl sitions aremade between face A and face B. The relative heights of faceA and face B and the shape of the transition from face A toface B do not agree with that expected according to the twofibril model but agree exactly with that expected if only asingle set of fibrils existed. Further evidence for the singlefibril model is derived from fractures of the mucosa membranewhich cross the junction to the membrane of the adjacent cellwithout deflection. Such fractures reveal a single ridge whichappears to be identical to the juxtaluminal fibril of the junction.In addition, small ridges are occasionally found in place ofthe grooves on face B which, although not consistent with thedouble fibril model, is expected if the single fibril modelwere correct. Although alternative explanations might accountfor these observations, we believe that the simplest and mostconsistent explanation is that the zonula occludens fracturesas would be expected of a single set of fibrils shared by adjacentcells.

Submitted on July 16, 1973
Revised on September 27, 1973

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