Phosphatidylcholine mobility in liver microsomal membranes

Analysis of the 35SO4-labelled macromolecules synthesized by cultures of normal )NIL8) and transformed (NIL8-HSV) hamster fibroblasts has revealed the following differences between the two cell lines: (1) The proportion of sulfate incorporated into cell-associated macromolecules is three times higher in normal than in transformed cells. In addition, normal fibroblasts incorporate more sulfate into extracellular, middle and low molecular weight species than do transformed cells. Transformed cells, however, incorporate more sulfate into extracellular, very high molecular weight species than do normal cells. (2) Normal fibroblasts, which synthesize much more extracellular dermatan sulfate than do transformed cells, produce a class of extracellular heterogeneous sulfated proteoglycans absent from transformed cultures. This macromolecular species consists largely of dermatan sulfate. The transformed cells instead release a lower molecular weight class of proteoglycans which consist of chondroitin sulfates A and C. (3) The large, external, transformation-sensitive glycoprotein is sulfated in NIL8 cultures. This macromolecular species is present on the surface membrane of normal cells, but absent from transformed cells. Sulfated large, external transformation-sensitive protein is also present in the conditioned medium from normal cultures. A similar species is present in the conditioned medium from transformed cultures, but has a slightly higher apparent molecular weight and differs in other properties from the large, external, transformation-sensitive protein of normal cells.     

Transformed BHK cells exhibiting normal or subnormal sugar uptake

The uptake of deoxyglucose was compared in BHK cells and in DMN4B cells, a conditionally transformed line of BHK cells which exhibits transformed behavior at 38.5° but not at 32°. At 32°, DMN4B cells took up deoxyglucose more slowly than BHK cells, reflecting a higher Km for uptake of this sugar. When both cell lines were grown at 38.5°, the Km for DMN4B cells was reduced to a level only slightly greater than for BHK cells, and deoxyglucose uptake became similar in the two cell lines. Growth in glucose-free medium for 22 hours stimulated deoxyglucose uptake in both BHK and DMN4B cells; under these conditions, uptake was equal in the two cells lines, both at 32° and 38.5°. Glycolysis, as measured by lactic acid production, was slower in DMN4B than BHK cells, but in contrast to deoxyglucose uptake, this difference was observed at 38.5° rather than 32°. The observation that the subnormal deoxyglucose uptake of DMN4B cells in the untransformed state (32°) can be normalized by growth at 38.5°, a temperature permissive for transformation, suggests that membrane changes facilitating sugar uptake, which have been found in other transformed cells, are associated with transformation in DMN4B cells as well. However, the failure of uptake to exceed normal in these cells indicates that their transformed behavior is not attributable to excessive sugar uptake per se.     

Polypeptide composition of cell membranes from chick embryo fibroblasts transformed by rous sarcoma virus.

Chick embryo fibroblasts were transformed by the Bryan high-titer strain of Rous sarcoma virus (RSV-BH), or a mutant (RSV-BH-Ta) inducing temperature-dependent transformation. Surface membranes from normal and transformed cells were isolated as membrane vesicles by differential centrifugation, and as cell ghosts after ZnCl2 treatment and separation in an aqueous two-phase system. These preparations were analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate or phenol/urea/acetic acid. In general a greater resolution of individual bands was found in gels containing phenol/urea/acetic acid, which separates polypeptides on the bases of size and charge. Electrophoresis of preparations from nontransformed cells showed that two polypeptides (molecular weights 200 000 and 250 000) found in cell ghosts were missing in membrane vesicles. In cell ghosts, transformation by RSV-BH resulted in a significant decrease of the 250 000 molecular weight complex. Also a polypeptide (molecular weight 73 000) prominent in membrane vesicles from nontransformed cells was decreased in transformed cells. Surfaces from cells transformed by RSV-BH-Ta at 37 degrees C presented patterns similar to those for RSV-BH infected cells. Shifting these cells to 41 degrees C resulted in an increase in the 250 000 molecular weight complex, although the amount of this protein(s) never reached that found in noninfected cells. Inhibitors of RNA and protein synthesis failed to block the morphological changes occurring in RSV-BH-Ta cells after temperature shifts from 41 degrees C to 37 degrees C or vice-versa. The same inhibitors caused a reduction in the levels of the 250 000 molecular weight complex at both temperatures. These data indicate that these large membrane-associated polypeptides play little or no role in the morphological changes associated with transformation and its reversal.     

Regulation of glucose uptake by stressed cells.

Lactate production by BHK cells is stimulated by arsenite, azide, or by infection with Semliki Forest virus (SFV). In the case of arsenite or SFV infection, the increase correlates approximately with the increase in glucose transport as measured by uptake of [3H] deoxy glucose (dGlc); in the case of azide, the increase in lactate production exceeds that of glucose transport. Hence glucose utilization by BHK cells and its stimulation by anaerobic and other types of cellular stress is controlled at least in part at the level of glucose transport. The glucose uptake by BHK cells is also stimulated by serum and by glucose deprivation. In these circumstances, as with arsenite, stimulation is reversible, with t1/2 of 1-2 hours; stimulation is compatible with a translocation of the glucose transporter protein between an intracellular site and the plasma membrane (shown here for serum and previously for arsenite). The surface binding and rate of internalization of [125I]-labelled transferrin and [125I] alpha 2-macroglobulin was studied to determine whether changes in glucose transport are accompanied by changes in the surface concentration or rate of internalization of membrane proteins. The findings indicate that changes in glucose transport do not reflect a consistent and general redistribution of membrane receptors. Taken together, the results are compatible with the proposal that BHK cells exposed to stimuli like insulin or serum, or to stresses like arsenite, azide, SFV infection, or deprivation of glucose, respond in the same manner: namely, by an increased capacity to transport glucose brought about by reversible and specific translocation of the transporter protein from an (inactive) intracellular site to the plasma membrane.     

Cellular stress induces a redistribution of the glucose transporter

The mechanism by which cells increase their rate of glucose uptake in response to stress is unclear. Using an immunofluorescence technique to localize the glucose transporter protein in BHK cells, we found that hyperthermia, treatment with arsenite, infection with vesicular stomatitis virus or Semliki Forest virus, and treatment with insulin cause the transporter to move from an intracellular site in the perinuclear region to the plasma membrane; the degree of translocation correlates approximately with the increase in glucose uptake. We conclude that stress induces an insulin-like distribution of certain membrane proteins.     

Regulation of the microfilament system in normal and polyoma virus transformed cultured (BHK) cells

The content and state of actin in baby hamster kidney (BHK) cells before and after transformation with polyoma virus were examined by deoxyribonuclease assay and gel electrophoresis followed by dye elution. The actin content of the transformed cells, relative to total cell protein, was lower than that of the normal cells by 30-50%. In both the normal and transformed cells the greater part of the total actin was found on lysis to be in the monomeric state. Cytoplasmic and membrane fractions of the two cell lines were, in qualitative terms, very similar in their protein compositions. The plasma membrane isolated from the transformed cells was richer in actin than that from the untransformed, and both membrane fractions contained proteins corresponding to myosin, filamin and alpha-actinin on SDS-polyacrylamide gels. The cell extract from both the normal and transformed lines formed an actin-based gel on incubation at 30 degrees C, although the amount of the cross-linked actin was much smaller in the latter. This was a consequence not only of the lower concentration of total actin in the cell, but also, presumably, of a gross relative deficiency in the concentration or activity of filament cross-linking protein(s) in the cytoplasm. Thus, small aliquots of cytoplasmic fractions from transformed cells, when added to an excess of exogenous F-actin, were able to cross-link the filaments to a much smaller extent than those from the normal cells. A similar range of proteins was found to be associated with the actin gels formed from both cell extracts. One conspicuous difference was that a species migrating in SDS-gel electrophoresis as a doublet with a subunit molecular weight of about 58,000, and tentatively identified as intermediate filament protein, was replaced in the transformed cells by a single band. Filament cross-linking activity of the cytoplasmic fractions was enhanced by addition of Triton extracts of crude membranes, although the latter were not capable of cross-linking exogenous F-actin on their own. The effect of Triton extracts was much greater in the case of membranes from the transformed cells. The cytoplasmic fractions of BHK cells contain capping protein(s) and/or complexes of such proteins with actin; these reveal themselves by the propensity of the extracts to nucleate polymerization of exogenous G-actin. This activity was more abundant in transformed cells, despite their lower actin content. Their membranes were also more effective in nucleating G-actin polymerization, indicating the presence of a greater number of filament ends.(ABSTRACT TRUNCATED AT 400 WORDS)     

Extracellular potassium can simulate the role of serum as an activator of uridine uptake by quiescent hamster cells in culture

Replacement of ~100 mM of sodium chloride in the extracellular medium of quiescent hamster fibroblasts (Nil 8 and BHK cells) by potassium chloride causes an increase in the rate of uridine uptake. This increase is identical with that achieved by addition of 10% serum to the same cultures. The effects of serum and KCl are not additive. The dependence of the rate of uridine uptake on extracellular KCl concentration is of a sigmoid nature. The time course of the activation process is similar to that of serum activation of uridine uptake in the same cells. The high rate of uridine uptake persists for at least 30 min after return to an extracellular medium containing a high concentration of sodium.     

Studies on the outer surface of normal and RSV-transformed BHK fibroblast plasma membrane

The probe trinitrobenzene sulphonate (TNBS) was used to selectively label the cell surface of normal and Rous sarcoma virus-transformed BHK fibroblasts. A five-fold increase in the number of TNBS-binding groups exposed on the outer membrane surface after neoplastic transformation was measured. The extra trinitrophenyl (TNP) groups bound by transformed cells were mostly removable by mild trypsinization and no differences were found between the amount of TNP bound by phospholipids in both normal and transformed cells. SDS-acrylamide patterns of TNP-labelled membrane proteins purified from normal and transformed cells showed only minor differences. This led to the conclusion that the increased exposure of TNBS-binding groups was due mainly to different binding properties of membrane proteins towards the probe rather than the appearance of new surface components in transformed cells.     

Stereospecific D-glucose transport in mixed membrane and plasma membrane vesicles derived from cultured chick embryo fibroblasts

Mixed membrane vesicles prepared from cultured chick embryo fibroblasts possess a stereospecific D-glucose transport system, the properties of which are identical to those of the system in intact cells. Uptake of D-glucose proceeds without chemical alteration. The rate of stereospecific uptake of D-glucose into the mixed vesicles is 70% greater than that of the homogenate and uptake is directly proportional to membrane protein concentration. Stereospecific D-glucose uptake appears linear for 0.3 min, reaches a maximum at 2--5 min, and declines to zero by 5 h as L-glucose enters the vesicles. Uptake is osmotically sensitive and inhibited by cytochalasin B (Ki = 0.13 microM) and the structural analogues of D-glucose : D-mannose, 2-deoxy-D-glucose, 3-O-methyl-D-glucose, D-galactose and maltose, but not by sucrose of L-glucose. Uphill counterflow can be demonstrated and the apparent activation energy displays a transition from 47.7 kcal/mol below 11 degrees C to 18.1 kcal/mol above 11 degrees C. Stereospecific uptake rates of mixed vesicles prepared from Rous sarcoma virus-transformed cells are increased 30% over control values, and are increased 66% in vesicles derived from cells incubated for 24 h in glucose-free medium. Plasma membrane vesicles prepared from these cells by a dextran cushion centrifugation procedure display a 9-fold increase in the specific activity of stereospecific D-glucose uptake relative to the homogenate. Extraction of these membranes with dimethylmaleic anhydride (5 mg/mg protein) results in substantial or complete removal of major polypeptides of molecular weight 40 000, 55 000, 75 000, 78 000 and 200 000 with no loss in total uptake activity. Following extraction, major polypeptides of molecular weight 28 000, 33 000 and 68 000 remain in the membrane residue.     

The uptake of actinomycin D by normal and virus transformed BHK21 hamster cells

The uptake of actinomycin-D (AMD) in the hamster cell line BHK21 clone 13, and its polyoma virus-transformed derivative, were compared. In the transformed cell the internal AMD concentration at equilibrium was lower and was reached more quickly. The AMD-binding capacities of nuclei from normal and transformed cells were similar, suggesting that some control of AMD uptake occurs at the plasma membrane. This may be a control on the efflux of AMD since this process has a higher rate constant in transformed cells.     

Degradation and regurgitation of extracellular proteins by cultured mouse peritoneal macrophages and baby hamster kidney fibroblasts. Kinetic evidence that the transfer of proteins to lysosomes is not irreversible

The uptake and degradation of bovine serum albumin (BSA), bovine liver catalase, and rabbit muscle enolase have been studied in cultured mouse peritoneal macrophages (MPM) and baby hamster kidney fibroblasts (BHK cells). Rates constant for the uptake of the three proteins by MPM were similar. In addition, BSA accumulation was independent of BSA concentration in the uptake medium and was not inhibited by a large excess of serum, suggesting that protein accumulation was by fluid phase pinocytosis. Following an overnight uptake, 20-30% of the accumulated protein was subsequently regurgitated into the medium in a trichloroacetic acid/phosphotungstic acid-precipitable form. This material co-migrated with the authentic protein during molecular sieve chromatography on Sephadex G-50. The rates of appearance of trichloroacetic acid/phosphotungstic acid-insoluble products were greater than expected for cell death and leakage. The observed first order rate constants, kobs, for the appearance of trichloroacetic acid/phosphotungstic acid-soluble and trichloroacetic acid/phosphotungstic acid-insoluble products in the culture medium were identical, indicating that both products were released in parallel from MPM and BHK cells. The kobs for intracellular BSA degradation and regurgitation were independent of the initial BSA concentration in the uptake medium, but were decreased about 35% when degradation was allowed to proceed in the presence of high concentrations of serum. Degradation was also inhibited by chloroquine and pepstatin. Inhibition of degradation was accompanied by an increase in the total amount of regurgitated protein appearing in the medium. Remarkably, however, these inhibitors also decreased kobs for regurgitation, thereby preserving the similarity in the observed rate constants for the appearance of trichloroacetic acid/phosphotungstic acid-soluble and trichloroacetic acid/phosphotungstic acid-insoluble products. These and other results were inconsistent with desorption of proteins from the surface of the culture dish or the surface of cells as the source of the trichloroacetic acid/phosphotungstic acid-insoluble label appearing in the medium.(ABSTRACT TRUNCATED AT 400 WORDS)     

THE DIFFERENTIAL EFFECT OF ACTINOMYCIN D IN NORMAL AND VIRUS-TRANSFORMED CELLS

Actinomycin D (AMD) at concentrations up to 0,25 µg/ml shows a differential effect on cell RNA synthesis and on the replication of an influenza virus in normal and virally transformed cells, both functions being more resistant to AMD in the transformed cell. A possible explanation for these differences in AMD sensitivity is provided by the observation that isotopically labeled AMD is maintained at a lower concentration in transformed BHK 21/13 (BHK) cells. There is evidence that the decreased sensitivity of the transformed cells to AMD is a result of maintenance of a lower internal concentration of the drug, since a correlation exists for a number of polyoma virus-transformed clones between sensitivity to and uptake of AMD.     

Hexose uptake and control of fibroblast proliferation

The role of glucose uptake in control of cell growth was studied by experimentally varying the rate of glucose uptake and examining the subsequent effect on initiation and cessation of cell proliferation. The rate of glucose uptake was varied by adjusting the concentration of glucose in the culture medium. This permitted analysis of two changes in rate of glucose uptake which are closely related to the regulation of cell growth: (1) the rapid increase in glucose uptake that can be detected within several minutes after mitogenic stimulation of quiescent fibroblasts and (2) the decrease in glucose uptake which accompanies growth to a quiescent state. Quiescent cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to fresh serum-containing medium with either the normal amount of glucose or a reduced level that lowered the rate of glucose uptake below the rate characteristic of quiescent control cells. The subsequent increases in cell number were equal in both media, demonstrating that the increase in glucose uptake, commonly observed after mitogenic stimulation, was not necessary for initiation of cell division. Measurements of intracellular D-glucose pools after serum stimulation of quiescent cells revealed that the increase in glucose uptake was not accompanied by a detectable change in the intracellular concentration of glucose. Nonconfluent growing cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to low glucose media, lowering the rate of glucose uptake below levels observed for quiescent cells. This did not affect rates of DNA synthesis or cell division over a several-day period. Thus, the decrease in glucose uptake, which usually occurs at about the same time as the decrease in DNA synthesis as cells grow to quiescence, does not cause the decline in cell proliferation. Experiments indicated that there was no set temporal relationship between the decline in glucose uptake and DNA synthesis as cells grew to quiescence. The sequence was variable and probably depended on the cell type as well as culture conditions. Measurements of intracellular D-glucose pools in secondary chick embryo cells demonstrated that the internal concentration of glucose in these cells did not significantly vary during growth to quiescence. Taken together, our results show that these fluctuations in the rate of glucose uptake do not lead to detectable changes in the intracellular concentration of glucose and that they do not control cell proliferation rates under usual culture conditions.     

Studies of a large transformation-increased membrane protein in the BHK21 cell system

We have recently described in BHK cells a plasma membrane protein of molecular weight 177 000, which is significantly increased in Hamster Sarcoma Virus-transformed cells (Lage-Davila, A. and Montagnier, L. (1977) Biochem. Biophys. Res. Commun. 79, 577–584). We present now a study of proteins from purified plasma membrane fractions in the same pair of clones. Solubilization conditions, cross-linking experiments, metabolic labelling and enzymatic radioiodination allow to characterize this 177 000 transformation-increased protein as an integral membrane glycoprotein partially exposed at the outer cell surface. Additional information on other membrane proteins in this system is also given.     

Release of the glucose‐regulated protein 94 by baby hamster kidney cells

Glucose‐regulated protein 94 (grp94) is a major component of the endoplasmic reticulum (ER) lumen of eukaryotic cells. We showed that grp94 is released from baby hamster kidney (BHK‐21) cells into a serum‐free medium. The exit of grp94 into the medium was not related to the protein discharge due to cell death and was independent of de novo protein synthesis. The treatment of cells with brefeldin A and monensin, the inhibitors of the classical pathway of protein secretion, did not decrease the extracellular level of grp94, indicating that the discharge of grp94 from cells does not occur through the ER/Golgi–dependent pathway. Exosomes, membrane vesicles secreted by several cell types, were not involved in the release of grp94 from cells. Methyl‐β‐cyclodextrin, a substance that disrupts the lipid raft organization, considerably reduced the extracellular level of grp94, indicating that lipid rafts are involved in the liberation of grp94 from BHK‐21 cells. The results suggest that BHK‐21 cells release grp94 into the serum‐free medium via the nonclassical secretory pathway in which lipid rafts play an important role. Copyright © 2012 John Wiley & Sons, Ltd.     

Hexose uptake enhancing factor released from rous sarcoma cells

Conditioned media from Rous sarcoma virus transformed chicken embryo fibroblasts stimulate the uptake of 2-deoxyglucose in normal chicken fibroblasts. The factor responsible for this effect, which is also shed in very low amount by non-transformed fibroblasts, is destroyed by trypsin and not linked to the protease and plasminogen activator activities present in the media. Its apparent molecular weight, determined by gel filtration, is about 20.000 daltons. The factor released by transformed cells might be related to the monomeric form of a family of glucose binding and transport proteins recently reported by Lee and Lipmann ('78) to be detached by detergents from normal and transformed cells.     

Metabolically labeled cell membrane proteins in spontaneously and in SV40 virus transformed mouse fibroblasts.

A family of mouse fibroblast cell lines in exponential phase of growth were compared in protein constitution of their cell membranes. In preparations from these cells enriched in cell-surface membrane we observed one protein component (apparent molecular weight about 250 000) consistently to be reduced or absent in an SV40 virus transformed cell line, when compared with the normal cell line. No such compositional difference was observed in a spontaneously transformed tumorigenic clonal derivative cell line, or in subclones of such a derivative cell line, with or without SV40 virus infection. However, in metabolic labeling experiments with 14C-labeled mixed amino acids, a consistent decrease also was demonstrated in the biosynthesis of the same protein in the SV40 virus infected subclone, as compared to an uninfected sister subclone, during exponential growth. This specific difference in biosynthesis is apparently related to the presence and functioning of the SV40 gene, and correlates with the ability of these cells to grow in viscous medium, but not with cellular tumorigenicity.     

Glycopeptides derived from individual membrane glycoproteins from control and Rous sarcoma virus-transformed hamster fibroblasts.

The membrane glycoproteins from control (BHK21/C13) and Rous sarcoma virus-transformed (C13/B4) baby hamster kidney cells grown in medium containing [14C]- or D-[3H]glucosamine have been separated into two distinct classes: a phenol-soluble fraction and an aqueous fraction. The membrane glycoproteins from both BHK21/C13 and C13/B4 partitioned similarly into these two fractions. The phenol and aquesous-soluble glycoproteins differed in their sodium dodecyl sulfate-polyacrylamide gel profiles, polyacrylamide isoelectric focusing profiles, and glycopeptide distribution on Sephadex G-50. A number of aqueous and phenol-soluble glycoproteins from BHK21/C13 and C13/B4 cells were purified to near homogeneity by means of polyacrylamide electrophoresis and gel electrofocusing. These glycoproteins range in molecular weight from 179,000 to 31,000 and have isoelectric points of 7.5 to 3.0. Our results show that the pronase glycopeptides of 20 out of 24 homologous membrane glycoproteins of equivalent molecular weight and isoelectric point from BHK21/C13 and C13/B4 cells are dissimilar as measured by Sephadex G-50 gel filtration.     

Collagen synthesis in normal BHK cells and temperature-sensitive chemically transformed BHK cells.

Collagen synthesis in normal BHK 21/cl 13 and chemically transformed temperature sensitive BHK 21/cl 13 cells (Me2N4) was assessed by examination of hydroxyproline formation and collagenase-susceptible protein. The Me2N4 cells lost their ability to synthesize collagen at both permissive and nonpermissive temperatures for transformation. These conclusions were confirmed by polyacrylamide-gel eletrophoresis and CM-cellulose chromatography. Prolyl hydroxylase activity was present in both normal and transformed cells even when no collagen could be demonstrated. The production of noncollagen protein, although decreased in the transformed cell, did not change as drastically as the collagen synthesis.     

Regulation of glucose transport by insulin and non-hormonal factors

Glucose uptake by nucleated cells is mediated by facilitated diffusion. In adipocytes, fibroblasts and muscle fibers uptake is regulated by a variety of hormones, environmental factors, and metabolic conditions. Glucose uptake by mammalian red cells also occurs by facilitated diffusion, but is not regulated by the same factors and conditions as in nucleated cells; yet the pharmacological and selectivity properties of this transport system resemble those of glucose uptake in regulated cells. The glucose transporter in the human red cell is a 55, 000 dalton protein, which has been purified to homogeneity and functionally reconstituted in artificial systems. Little is known about the molecular identity of the sugar carrier in other cell types. Glucose uptake is stimulated by insulin in muscle, fat and skin cells but not in bone, brain, placenta, erythrocytes nor probably lymphocytes. In responsive cells, stimulation occurs within seconds of exposure to the hormone; it requires cellular integrity but once elicited, it persists in isolated membranes; protein synthesis is not required for either the onset of the response or the return to basal conditions after hormone removal; on the other hand, intracellular energy is required for both steps; the cytoskeleton does not seem to be involved in the regulation of glucose uptake by insulin. In general, insulin increases V_t while K_t is unaffected. The hormone could affect the rate of turnover of the transporter in the membrane, and/or the number of transporters active at any time. An increase in the number of transport sites in the plasma membrane, due to incorporation of additional sites originating from intracellular membranes, has recently been proposed on the basis of both ³H-cytochalasin B binding and glucose transport determinations in isolated plasma and intracellular membranes. The feasibility and implications of a rapid and reversible translocation of glucose transport sites from specific intracellular pools to the plasma membrane are discussed.