LUMENAL PLASMA MEMBRANE OF THE URINARY BLADDER: I. Three-Dimensional Reconstruction from Freeze-Etch Images

doi:10.1083/jcb.53.1.73

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LUMENAL PLASMA MEMBRANE OF THE URINARY BLADDER : I. Three-Dimensional Reconstruction from Freeze-Etch Images

L. Andrew Staehelin ¹, Francis J. Chlapowski ¹, and Mary A. Bonneville ¹

¹ From the Biological Laboratories, Harvard University, Cambridge, Massachusetts 02138; the Department of Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder, Colorado 80302; and the Department of Anatomy, University of Massachusetts Medical School, Worcester, Massachusetts 01604

To determine the three-dimensional structure of the lumenalmembrane of transitional epithelium, a study was made of sectioned,negatively stained, and freeze-etched specimens from intactepithelium and membrane fractions from rabbit urinary bladder.Particulate membrane components are confined to plaque regionswithin which the unit membrane is asymmetric, having a thickerouter leaflet. Transversely fractured freeze-etched plaquesdisplay a thick ( $sim$ 80 A), particulate lumenal leaflet and a thin( $sim$ 40 A) cytoplasmic one. Four different faces of the two leafletscan be distinguished: two complementary, split, inner membranefaces exposed by freeze-cleaving the bilayer and two external(lumenal and cytoplasmic) membrane surfaces revealed by deep-etching.On the split, inner face of the lumenal leaflet appear polygonalplaques of hexagonally arranged particles. These fit into holesobserved on the complementary, split, innerface of the cytoplasmicleaflet. The particles, which have a center-to-center spacingof $sim$ 160 A, also seem to protrude from the external surface ofthe lumenal leaflet, where their subunits ( $sim$ 50 A in diameter)are revealed by freeze-etching and negative staining. The plaquesare separated from each other by smooth-surfaced regions, whichcleave like simple lipid bilayers. Since the array of plaqueparticles covers only $sim$ 73% of the membrane surface area, whereas27% is taken up by particle-free interplaque regions, the presenceof particles cannot in itself entirely account for the permeabilitybarrier of the lumenal membrane. Although no particles are observedprotruding from the cytoplasmic surface of the membrane, cytoplasmicfilaments are attached to it by short, cross-bridge-like filamentsthat seem to contact the particles within the membrane. Theselong cytoplasmic filaments cross-link adjacent plaques. Therefore,we suggest that at least one function of the particles is toserve as anchoring sites for cytoplasmic filaments, which limitthe expansion of the lumenal membrane during distention of thebladder, thereby preventing it from rupturing. The particle-freeinterplaque regions probably function as hinge areas betweenthe stiff plaques, allowing the membrane to fold up when thebladder is contracted.

Submitted on June 25, 1971
Revised on December 17, 1971

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