Michael M. Atkinson

Modification of gap junctions in cells transformed by a temperature-sensitive mutant of Rous sarcoma virus

SummaryPrompted by our observation that a reduction in junctional permeance is one of the earlier events in the process of neoplastic transformation of a cell line by Rous sarcoma virus, we analyzed the gap junctions, from these cells to determine if the basis of the reduction is a loss of junctional channels. The cells (normal rat kidney, or NRK) are infected with a temperature-sensitive mutant of Rous sarcoma virus, allowing one easily to manipulate the cells into and out of the transformed state, and hence also to manipulate the junctional permeance. Using freeze-fracture electron microscopy, we found that the number and size of the junctions did not change in parallel with the permeance changes we had previously characterized. There is, however, a significant rearrangement of the junctional particles to a more random configuration when the cells are transformed and a reversal to the more ordered pattern when the cells are shifted back to the normal phenotype. These changes do parallel the changes in junctional permeance. We conclude that the permeance of existing junctional channels is modified and that the change in permeance may involve a change in the interaction of the junctional channels with each other and/or the surrounding lipid domain.

Permeance of Novikoff Hepatoma Gap Junctions: Quantitative Video Analysis of Dye Transfer

SummaryFluorescent dyes are commonly used to study permeable (gap) junctions, but only rarely have quantitative values for junctional dye permeability been determined. In the present study, junctional permeance (PA, i.e., the product of the junctional permeability coefficient,P, times the junctional area,A) to Lucifer Yellow CH (LY) has been obtained for pairs of Novikoff hepatoma cells. Dye was microinjected into one cell and the subsequent transfer monitored by a SIT camera and recorded on video tape. The intensities of fluorescence in the injected and “recipient” cell were measured using a Digisector (Microworks) digitizing board and an Apple II Plus computer to analyze the video records. These changes in intensity, along with an estimate of volume of the spherical cells, were used to calculate the junctional permeance (PA) of cell pairs according to Ficks diffusion equation. Junctional permeances show considerable variation ranging from 0.08×10−11 to 27.0×10−11 cm3/sec. Using the meanPA and a previous estimate of the mean number of junctional channels per interface in the Novikoff cultures, a value for diffusion coefficient of LY through gap junctions is calculated to be about 1.4×10−6 cm2/sec. There is a general proportionality between meanPA and cell volume for hepatoma cell pairs of a certain size range. Such a relationship between cell volume and junctional capacity suggests one source of variation ofPA. Other possible sources, e.g., related to position in the cell cycle, are discussed.

Measurement of gap junctional communication by fluorescence activated cell sorting.

SummaryCell-to-cell communication via gap junctions has played a fundamental role in the orderly development of multicellular organisms. Current methods for measuring this function apply mostly to homotypic cell populations. The newly introduced Fluorescence Activated Cell Sorting (FACS) method, albeit with some limitations, is simple, reliable, and quantitative in measuring the dye transfer via gap junctions in both homotypic and heterotypic cell populations. In the homotypic setting, the result in dye transfer from the FACS method is comparable to the scrape-loading and microinjection methods. Using this FACS method, we observed a decline of cell-to-cell communication in transformed and cancer cells. We also observed a differential degree of communication between two heterotypic cell populations depending on the direction of dye transfer.

Extracellular calcium and cadherins regulate the process of gap junction assembly between cells in culture

A number of previous observations have indicated that the cadherins play an important role in the regulation of gap junction communication. In the experiments reported here, the process of gap junction assembly was specifically monitored between Novikoff hepatoma cells in culture. In the presence of reduced levels of extracellular calcium, gap junction assembly was substantially inhibited, although not completely blocked. The mechanism of this inhibition was explored with an analysis of connexin43 phosphorylation, determinations of cytoplasmic calcium, and immunofluorescence methods for cadherins and connexins. Two models are considered - one for simple adhesion and one for signalling.