Membrane alterations which accompany MuMTV maturation. I. Studies by freeze-cleave techniques

Structure of and alterations to defective murine sarcoma virus particles lacking envelope proteins and core polyprotein cleavage

HTG2 hamster cells produce a defective murine sarcoma virus lacking gp70 and, consequently, viral surface projections (knobs), but the lack of knobs appears to have no effect on intramembrane particle distribution. In addition, it has been noted that the core of the virus remains in the "immature" form as a result of the failure of the polyprotein precursor (p65) to undergo cleavage. However, incubation of HTG2 virus with avian myoblastosis virus was found to yield specific cleavage products of p65.

Membrane alterations during chick neural retina development: a freeze-fracture study

As part of a study of cell surface differentiation during chick retina development, a freeze-fracture study of neural retinas from 5 to 10 day embryonic chicks was undertaken. Three classes of changes have been detected. (1) As cells differentiate and become recognizable by their position within the tissue, they acquire characteristic numbers of intramembrane particles in the surfaces in each layer. (2) Small gap junctions appear between cells at the outer limiting membrane of the 5 day retina. At 6 days, they are larger, more numerous and are also found in deeper layers of the tissue. By the seventh day, the size and number of the junctions is greatly reduced; they are not visible after the tenth day. (3) The characteristic lack of particles in the outer limiting membrane of the mature retina appears at the ninth day of incubation, at the time that presumptive photoreceptors extend through the outer limiting membrane. Tight junctions between cells were not observed during this study.

Structural changes in the membrane of vero cells infected with a paramyxovirus

Vero cells productively infected with the Halle strain of measles virus have been studied by means of surface replication, freeze-fracturing, and surface labeling with horseradish peroxidase-measles antibody conjugate in order to examine changes in the structure of the cell membrane during viral maturation. Early in infection, the surfaces of infected cells are embossed by scattered groups of twisted strands, and diffuse patches of label for viral antigens cover regions marked by these strands. At later stages, when numerous nucleocapsids become aligned under the plasmalemmal strands, the strands increase in number and width and become more convoluted. At this stage, label for viral antigens on the surface of the cell membrane is organized into stripes lying on the crests of strands. Finally, regions of the membrane displaying twisted strands protrude to form ridges or bulges, and the freeze-fractured membrane surrounding these protrusions is characterized by an abundance of particles small than those found on the rest of the cell membrane. The fractured membranes of viral buds are continuous sheets of these small particles, and the spacing between both nucleocapsids and stripes of surface antigen in buds is less than in the surrounding cell membrane. Detached virus is covered with a continuous layer of viral antigen, has unusually large but no small particles on its membrane surfaces exposed by freeze-fracturing, and no longer has nucleocapsids aligned under its surface. Thus, surface antigens, membrane particles, and nucleocapsids attached to the cell membrane are mobile within the plane of the membrane during viral maturation. All three move simutaneously in preparation for viral budding.

Scanning microscopy of dissociated tissue cells

A method is described for studying by scanning electron microscopy (SEM) all the surfaces of fully differentiated cells from intact tissues. Thus, cell faces normally hidden from view are exposed and made available for SEM examination. This is achieved by fixing the tissue in OSO4 and then soaking it in a 1% solution (in water) of boric acid. After different periods of time, varied according to particular tissue, slight mechanical pressure will cause the fixed tissue to dissociate into its component cells. These are then made to adhere to a substrate and are taken through critical point drying, etc., for examination. Observations are reported on the topography of whole hepatocytes, adsorptive cells of the intestinal epithelium, proximal tubule cells of the rat kidney, mammary tumor cells of the mouse, and rat sarcoma cells. Several other tissues are reported to dissociate when similarly treated, but for each the procedure must be slightly modified.