S.J. Singer

Vinculin: A cytoskeletal target of the transforming protein of rous sarcoma virus

Vinculin, a protein associated with the cytoplasmic face of the focal adhesion plaques which anchor actin-containing microfilaments to the plasma membrane and attach a cell to the substratum, contains 8-fold more phosphotyrosine in cells transformed by Rous sarcoma virus than in uninfected cells. Because the transforming protein of RSV, p60src, is a protein kinase that modifies cellular proteins through the phosphorylation of tyrosine and because phosphotyrosine is a very rare modified amino acid, this result is a very rare modified amino acid, this result suggests that vinculin is a primary substrate of p60src. Only trace amounts of phosphotyrosine were detected in myosin heavy chains, alpha-actinin, filamin, and the intermediate filament protein vimentin. The modification of vinculin by p60src may be responsible in part for the disruption of the microfilament organization and for the changes in cell shape and adhesiveness which accompany transformation by Rous sarcoma virus.

The antibody-induced clustering and endocytosis of HLA antigens on cultured human fibroblasts

It has previously been shown by immunofluorescence experiments that the cross-linking of HLA antigens into patches (by antibody reagents directed to human beta 2--microglobulin) on the surfaces of cultured human fibroblasts leads to the lining up of the patches over the actomyosin-containing stress fibers lying immediately under the surface membrane. These experiments have now been extended to the resolution of the electron microscope by the use of ferritin-conjugated antibody. The results show that a substantial part of the HLA surface clusters that form by 5 min after the addition of the antibody reagents is found in small uncoated surface invaginations which are subsequently endocytosed and ultimately fuse with lysosomal bodies. At no stage in this process is there any indication that coated pits or coated vesicles participate. These and other results suggest, therefore, that there are at least two distinct mechanisms for the ligand-induced endocytosis and lysosomal processing of membrane components, one involving coated pits and the other the noncoated invaginations described in this paper. Transmembrane associations of clusters with intracellular actomyosin-containing structures may have a role in the endocytosis of these noncoated invaginations.

The participation of α-actinin in the capping of cell membrane components

Abstract By means of double fluorescence staining experiments, intracellular α-actinin was found to accumulate under caps and patches induced in several cells by a variety of ligands. This phenomenon was demonstrated in lymphocytes and lymphoma cells treated with anti-H-2 sera; spleen lymphocytes treated with concanavalin A or anti-immunoglobulin antibodies, and VSV-infected mouse fibroblast line MC57 treated with antiserum against viral antigens. It occurred during both rapid and slow capping processes, and could be obtained by either direct or indirect ligand-induced redistribution. These observations were carried out on whole cells. For other cytoskeletal proteins such as filamin, tropomyosin and myosin, a similar accumulation under caps was not readily apparent using whole cell mounts, although earlier experiments with frozen-sectioned cells had shown such an enrichment of myosin (as well as actin). The enrichment of α-actinin under the clustered surface molecules was already apparent in early stages (patching) of the capping process, with or without 10 mM sodium azide present. Prolonged incubation of the cells with the different ligands resulted in endocytosis of the ligand-receptor complex. α-Actinin was not associated with the internalized complex, however, suggesting that it may dissociate from the patched or capped surface structures at some stage during endocytosis.

Molecular changes in the membranes of mouse erythroid cells accompanying differentiation

The development of the mouse erythroblast to a mature erythrocyte is accompanied by changes in the composition and properties of the plasma membranes of these cells. Using double fluorescence techniques, we have simultaneously determined the distribution of lectin receptors and spectrin on the membranes of these cells. The lateral mobility of the lectin receptors in the membranes decreases as differentiation proceeds, and this is accompanied by an increasing concentration of spectrin associated with the membranes. The most significant concentration of spectrin occurs, however, during the enucleation of the late erythroblast, where we observe a complete segregation of the spectrin to the incipient reticulocyte, as well as a previously observed enrichment of receptors for concanavalin A into the plasma membrane surrounding the extruding nucleus. On the basis of these and other observations, we explore the possible molecular mechanisms involved in erythroblast enucleation and the role of spectrin in the regulation of protein mobility in erythroid cell membranes.

Cytoskeletal organization, vinculin-phosphorylation, and fibronectin expression in transformed fibroblasts with different cell morphologies

Neoplastic transformation of fibroblasts results in widely different cell morphologies. We have attempted to correlate cell morphology with cytoskeletal organization and fibronectin expression in murine and avian fibroblasts transformed by a diverse group of viral and chemical agents. The distribution of vinculin, alpha-actinin, actin, and surface fibronectin was studied, and, where appropriate, also the extent of phosphotyrosine modification of vinculin. Irrespective of the transforming agent we found that increased cell rounding was generally correlated with a reduction in vinculin-containing focal adhesions, a dissolution of microfilament bundles, and a reduction of extracellular fibronectin. In contrast, spindle-shaped fibroblasts expressed relatively high levels of surface fibronectin. Reorganization of vinculin, actin, and alpha-actinin into rosette-like structures was observed in polygonal or rounded cells transformed by viruses encoding tyrosine kinases, but was not seen in fibroblasts transformed by agents without associated tyrosine kinase activity or in spindle-shaped cells. No correlation was found between the extent of phosphotyrosine modification of vinculin and the extent of cell rounding. Irrespective of cell morphology, the extent of tyrosine phosphorylation of vinculin was high in all cells transformed by viruses carrying the src gene, but low in those transformed by viruses expressing the fps gene. Our results indicate that the morphology of a transformed cell is determined by a combination of several factors which are affected to different extents by different transforming agents.