Faculty Bibliography

p21ras specific antiserum was used to immunoprecipitate p21ras polypeptides from human A431 cells. In addition to p21ras, this antiserum precipitated a series of polypeptides with relative molecular weights of 150,000, 120,000, 105,000, and 50,000. The precipitation of these polypeptides was prevented by preincubation of the antiserum with an excess of purified Ras protein. These polypeptides do not share an epitope with p21ras, and two of them (120 and 150 kDa) copurify with a fraction of p21ras. The co-precipitation of p21ras with these polypeptides was detected in a variety of cell types. The pattern of the immunoprecipitates was consistently different in normal and ras-transformed cells. The 120- and 150-kDa polypeptides are phosphorylated on serine and threonine in A431 cells. Serum treatment resulted in a 2-fold increase in the phosphoserine content of the 120-kDa polypeptides

Commonly, microinjection has been the method of choice for introducing proteins into living cells. Viable cells containing an introduced protein can be then identified providing that the protein is fluorochrome conjugated. This approach is applicable only for adherent cells, and the number of cells that can be analyzed is small. In this study, we have established that electroporation can be used to load proteins into large numbers of cells with high efficiency. Furthermore, we have developed a method for the isolation of protein-loaded cells using fluorescein isothiocyanate-dextran (dextran-FITC) as a molecular marker for protein uptake. The essential features of this method are that dextran-FITC is included in the electroporation medium and, thus, is cointroduced with the protein of interest. Purification of cells containing dextran-FITC using fluorescence-activated cell sorting yields a population which is composed almost entirely of cells containing the protein of interest

Cellular ras genes encode a family of membrane-associated proteins (p21ras) that bind guanine nucleotide and possess a low intrinsic GTPase activity. The p21ras proteins are ubiquitously expressed in mammalian cells and are thought to be involved in a growth-promoting signal transduction pathway; their mode of action, however, remains unknown. The ligand-induced movement of cell-surface receptors seems to be a primary event in the transduction of several extracellular signals that control cell growth and differentiation. In B lymphocytes, surface immunoglobulin receptors crosslinked by antibody or other multivalent ligands form aggregates called patches, which then collect into a single assembly, a cap, at one pole of the cell. This process constitutes the initial signal for the activation of a B cell. Here we show by immunofluorescence microscopy that p21ras co-caps with surface immunoglobulin molecules in mouse splenic B lymphocytes. In contrast, no apparent change in the distribution of p21ras occurs during the capping of concanavalin A receptors. The redistribution of p21ras is apparent at the early stages (patching) of immunoglobulin capping and is inhibited by metabolic inhibitors and the cytoskeleton-disrupting agents colchicine and cytochalasin D. The distribution of another membrane-associated guanine nucleotide-binding regulatory protein, the Gi alpha subunit, is not affected by surface immunoglobulin capping. These findings demonstrate that p21ras can migrate in a directed manner along the plasma membrane and suggest that p21ras may be a component of the signalling pathway initiated by the capping of surface immunoglobulin in B lymphocytes

The present study was undertaken to investigate whether purified ras proteins can affect the activity of polyphosphoinositide specific phospholipase C in a cell-free membrane system. For this purpose we used homogenous preparations of the proto-oncogenic (H-ras(gly 12)) and the oncogenic (H-ras(val 12)) forms of the human H-ras proteins and membranes prepared from the human leukemic HL60 cells. We demonstrate that both the proto-oncogenic and the oncogenic form of H-ras proteins stimulate phospholipase C activity only when coupled to non-hydrolysable analogues of GTP

Ras genes are an ubiquitous eukaryotic gene family. Since their discovery as the cellular homologues of the transforming genes of Harvey and Kirsten retroviruses, ras genes have been presumed to play a role in growth control, mainly because of their potential to induce uncontrolled cell proliferation. This notion is strongly supported by recent evidence indicating that ras mutations may be causative or closely linked to the onset of some types of human tumors. However, the mechanism of action of ras proteins in mammalian cells is poorly understood. Using the microinjection technique as a biological assay for ras proteins, it has been possible to address several important questions concerning cellular and biochemical aspects of ras function. When introduced into living cells by microinjection, purified ras proteins can induce cell proliferation, neuronal differentiation, oocyte maturation, and exocytotic degranulation. On the biochemical level, microinjection studies indicated that ras proteins can induce specific alterations in phospholipid metabolism

Muscarinic receptors of cardiac pacemaker and atrial cells are linked to a potassium channel (IK.ACh) by a pertussis toxin-sensitive GTP-binding protein. The dissociation of G-proteins leads to the generation of two potential transducing elements, alpha-GTP and beta gamma. IK.ACh is activated by G-protein alpha- and beta gamma-subunits applied to the intracellular surface of inside-out patches of membrane. beta gamma has been shown to activate the membrane-bound enzyme phospholipase A2 in retinal rods. Arachidonic acid, which is produced from the action of phospholipase A2 on phospholipids, is metabolized to compounds which may act as second messengers regulating ion channels in Aplysia. Muscarinic receptor activation leads to the generation of arachidonic acid in some cell lines. We therefore tested the hypothesis that beta gamma activates IK.ACh by stimulation of phospholipase A2. When patches were first incubated with antibody that blocks phospholipase A2 activity, or with the lipoxygenase inhibitor, nordihydroguaiaretic acid, beta gamma failed to activate IK.ACh. Arachidonic acid and several of its metabolites derived from the 5-lipoxygenase pathway, activated the channel. Blockade of the cyclooxygenase pathway did not inhibit arachidonic acid-induced channel activation. We conclude that the beta gamma-subunit of G-proteins activates IK.ACh by stimulating the production of lipoxygenase-derived second messengers

To investigate the possible role of ras proteins in the secretory process, we have microinjected the proto oncogenic and oncogenic forms of the human H-ras protein into rat peritoneal mast cells. Mast cells are secretory cells which, upon appropriate stimulus, liberate histamine and other mediators of the acute inflammatory reaction by exocytotic degranulation. We report here that microinjection of the ras oncogene protein into mast cells induces exocytotic degranulation. In contrast, microinjection of similar amounts of the proto-oncogenic protein has little apparent effect on mast cells. Degranulation induced by injection of the ras oncogene protein occurs in the absence of an external stimulus and requires the presence of external calcium. The ultrastructural features of exocytotic degranulation in mast cells injected with the ras oncogene protein are similar to those seen when mast cells are activated by soluble ligands. Our results suggest that ras proteins may be involved, possibly as regulatory elements, in cellular functions that control exocytosis

The cellular localization of phospholipase A2 (PLA2) was examined in normal and ras-transformed rat fibroblasts using immunohistochemical techniques. Polyclonal antibodies were generated against porcine pancreatic PLA2 and were affinity purified for use in this study. The antibodies detected a 16-kD band on immunoblots of total cellular proteins from fibroblasts. In cell-free assays of phospholipase A2 activity, the purified antibodies inhibited the bulk of the enzyme activity whereas control IgG preparations had no effect. Immunofluorescence microscopy indicated that PLA2 was diffusely distributed throughout the cell. Increased concentration of PLA2 was detected under membrane ruffles in normal and ras-transformed cells. Specific immunofluorescence staining was also detected on the outer surface of the normal cells. Immunoelectron microscopy demonstrated the increased accumulation of PLA2 in membrane ruffles and also revealed the presence of the enzyme in microvilli and its association with intracellular vesicles. Ultrastructural localization of PLA2 and the ras oncogene protein, using a double immunogold labeling technique, indicated a spatial proximity between PLA2 and ras proteins in the ruffles of ras-transformed cells. The possible role of PLA2 in the structural rearrangements that underlie membrane ruffling is discussed

Because ras oncogenes mediate abnormal cellular growth, ras proteins have been presumed to play a role primarily in growth control. The biological function of ras proteins may, however, prove to be much more diverse: ras proteins may be involved in cellular functions that control endocytosis and/or exocytosis