Faculty Bibliography

Fibroblasts transformed by ras oncogenes display enhanced cell surface ruffling and fluid-phase pinocytotic activities. Microinjection of antibodies that specifically bind the ras proteins into these cells results in the inhibition of these two surface activities. The possible underlying biochemical basis of the influence of the ras proteins on membrane ruffling and pinocytosis and the potential relationship of these two biological activities to membrane signal transduction are discussed

Expression of the ras oncogene is thought to be one of the contributing events in the initiation of certain types of human cancer. To determine the cellular activities that are directly triggered by ras proteins, the early consequences of microinjection of the human H-ras proteins into quiescent rat embryo fibroblasts were investigated. Within 30 minutes to 1 hour after injection, cells show a marked increase in surface ruffles and fluid-phase pinocytosis. The rapid enhancement of membrane ruffling and pinocytosis is induced by both the proto-oncogenic and the oncogenic forms of the H-ras protein. The effects produced by the oncogenic protein persist for more than 15 hours after injection, whereas the effects of the proto-oncogenic protein are short-lived, being restricted to a 3-hour interval after injection. The stimulatory effect of the ras oncogene protein on ruffling and pinocytosis is dependent on the amount of injected protein and is accompanied by an apparent stimulation of phospholipase A2 activity. These rapid changes in cell membrane activities induced by ras proteins may represent primary events in the mechanism of action of ras proteins

To investigate the possible role of ras proteins in the differentiation process signaled by nerve growth factor, we have microinjected the proto-oncogenic and oncogenic (T24) forms of the human H-ras protein into living rat pheochromocytoma cells (PC12). PC12 cells, which have the phenotype of replicating chromaffin-like cells under normal growth conditions, respond to nerve growth factor by differentiating into nonreplicating sympathetic neuron-like cells. Microinjection of the ras oncogene protein promoted the morphological differentiation of PC12 cells into neuron-like cells. In contrast, microinjection of similar amounts of the proto-oncogene form of the ras protein had no apparent effect on PC12 cells. The induction of morphological differentiation by the ras oncogene protein occurred in the absence of nerve growth factor, was dependent on protein synthesis, and was accompanied by cessation of cell division. Treatment of PC12 cells with nerve growth factor or cAMP analogue prior to injection did not alter the phenotypic changes induced by the ras oncogene protein

We have investigated the possibility that cellular control of membrane excitability involves feedback mechanisms in which the degree of activity of voltage-sensitive Na+ channels regulates the number of these channels. Using two independent assays, channel-mediated Na+ uptake and the specific binding of [3H] saxitoxin, we have studied the effects of pharmacological activation of Na+ channels with batrachotoxin (BTX) on the number and properties of these channels. Upon exposure of cultured muscle cells to BTX (1 microM), the number of surface Na+ channels decreases by approximately 75%, with a half-time of 3-6 h. This decrease is prevented by pharmacological blockade of these channels and does not reflect changes in the apparent affinities towards either BTX or saxitoxin. This reduction is reversible: a gradual increase in surface Na+ channels that is dependent on protein synthesis is observed upon removal of the activator. The BTX-induced decrease in Na+ channels is associated with an enhanced rate of disappearance of surface Na+ channels. These findings point to the existence of a down-regulation mechanism for the modulation of membrane excitability under conditions of elevated Na+ channel activity

We investigated the effect of trifluoperazine (TFP), a calmodulin antagonist, on the fusion of chick skeletal myoblasts in culture. TFP was found to inhibit myoblast fusion. This effect occurs at concentrations that have been reported to inhibit Ca2+-calmodulin in vitro, and is reversed upon removal of TFP. In addition, other calmodulin antagonists, including chlorpromazine, N-(6-aminohexyl)-5-chloro-1-naphthalene-sulfonamide (W7), and N-(6-aminohexyl)-1-naphthalene-sulfonamide (W5), inhibit fusion at doses that correspond closely to the antagonistic effects of these drugs on calmodulin. The expression of surface acetylcholine receptor, a characteristic aspect of muscle differentiation, is not impaired in TFP-arrested myoblasts. Myoblasts inhibited from fusion by 10 microM TFP display impaired alignment. In the presence of the Ca2+ ionophore A23187, the fusion block by 10 microM TFP is partially reversed and myoblast alignment is restored. The presence and distribution of calmodulin in both prefusional myoblasts and fused muscle cells was established by immunofluorescence. We observed an apparent redistribution of calmodulin staining that is temporally correlated with the onset of myoblast fusion. Our findings suggest a possible role for calmodulin in the regulation of myoblast fusion

The expression of Na+ channels during differentiation of cultured embryonic chick skeletal muscle cells was investigated using saxitoxin (STX) and batrachotoxin (BTX), which previously have been shown to interact with distinct, separate receptor sites of the voltage-sensitive Na+ channel of excitable cells. In the present study, parallel measurements of binding of [3H]-STX (STX) and of BTX-activated 22Na+ uptake (Na influx) were made in order to establish the temporal relationship of the appearance of these two Na+ channel activities during myogenesis. Na influx was clearly measurable in 2-d cells; from day 3 to day 7 the maximum Na influx approximately doubled when measured with saturating BTX concentrations potentiated by Leiurus scorpion toxin, while the apparent affinity of BTX, measured without scorpion toxin, also increased. Saturable STX binding did not appear consistently until day 3; from then until day 7 the STX binding capacity increased about threefold, whereas the equilibrium dissociation constant (KD) decreased about fourfold. Although Na influx in cells of all ages was totally inhibited by STX or tetrodotoxin (TTX) at 10 microM, lower concentrations (2-50 nM) blocked the influx in 7-d cells much more effectively than that in 3-d cells, where half the flux was resistant to STX at 20-50 nM. Similar but smaller differences characterized the block by TTX. In addition, when protein synthesis is inhibited by cycloheximide, both Na influx and STX binding activities disappear more rapidly in 3-d than in 7-d cells, which shows that these functions are less stable metabolically in the younger cells

We have studied the effect of tunicamycin (TM), an antibiotic which inhibits the glycosylation of nascent proteins, on the properties of the acetylcholine receptor (AChR) at the surface of embryonic chick skeletal muscle cells. The use of two separate assays, specific binding of 125I-alpha-bungarotoxin and carbamylcholine-activated 22Na+ uptake, has allowed us to monitor the effects of impaired glycosylation on the metabolic and functional properties of AChR. A significant decrease in the amounts of surface AChR elaborated in the presence of TM is detected by both measurements. This decrease has been found to reflect an enhanced proteolytic degradation of the underglycosylated AChR. The underglycosylated AChR, expressed on the cell surface in the presence of TM, retains the capability of mediating agonist-activated ionic permeability changes, but displays quantitatively altered interactions with receptor ligands. We conclude that the carbohydrate moiety on AChR may play a role in determining the folding of newly synthesized polypeptides to form a conformation compatible with the metabolic properties and ligand interactions characteristic of glycosylated AChR

We have investigated the effect of tunicamycin (TM), an inhibitor of protein glycosylation, on surface Na+ channels in cultured chick skeletal muscle cells. The expression of Na+ channels, estimated by the measurement of batrachotoxin (BTX)-activated 22Na+ uptake, was found to be significantly diminished after exposure of muscle cells to TM. This effect is partially reversed by the protease inhibitor leupeptin and is associated with a markedly enhanced rate of disappearance of Na+ channels from the surface of TM-treated cells. Our findings suggest that protein glycosylation contributes to the metabolic stability of voltage-sensitive Na+ channels