p38: A novel protein that associates with the vesicular stomatitis virus glycoprotein

The vesicular stomatitis virus glycoprotein (VSV G) is a model transmembrane glycoprotein that has been extensively used to study the exocytotic pathway. The cytoplasmic domain of VSV G contains information for several intracellular sorting steps including efficient export from the ER, basolateral delivery, and endocytosis. In order to identify proteins that potentially interact with the polypeptide sorting motifs in the VSV G tail, the carboxy-terminal 27 amino acids of VSV G were used as bait in a yeast two-hybrid system. The protein identified most frequently in the screen is a novel protein of 38 kDa, p38. In the present work, the initial molecular and biochemical characterization of p38 is described. Preliminary evidence suggests that p38 may interact transiently with endoplasmic reticulum (ER) membranes, and thus may affect VSV G and other cargo movement at the step of ER to Golgi traffic.     

The biochemical and ultrastructural effects of tunicamycin and D-glucosamine in L1210 leukemic cells

Tunicamycin was found to specifically inhibit the incorporation of a number of sugars into L1210 leukemia cell glycoproteins. This inhibition of glyco-protein biosynthesis led to a cessation of cell growth which was reversible in a dose-dependent and time-dependent manner. After removal of the antibiotic from L1210 cell cultures resumption of sugar incorporation preceded that of thymidine incorporation and the recovery of cell growth. The treatment of cells with tunicamycin resulted in a significant increase in the intracellular pool of UDP-N-acetylglucosamine which occurred concurrently with alterations in cell ultrastructure including distentions of the endoplasmic reticulum and nuclear membranes. Similar ultrastructural changes and increases in the intracellular pools of UDP-sugars were observed in L1210 cells exposed to 5 mM D-glucosamine, which suggested that the antiproliferative effects of tunicamycin may be related to the accumulation in the endoplasmic reticulum of one or more nucleotide sugar precursors of asparagine-linked glycoprotein biosynthesis. However, the biological effects of tunicamycin could be distinguished from those caused by D-glucosamine. Exposure of L1210 cells to tunicamycin resulted in specific alterations in the biochemical composition of the plasma membrane and in the inhibition of cellular agglutination by wheat germ agglutinin which were not apparent following exposure to equitoxic concentrations of the aminosugar. These studies, together with those which demonstrated that recovery of the cellular capacity to synthesize glycoproteins was obligatory for the recovery of cellular proliferation in tunicamycin-treated cells, suggested that inhibition of the synthesis of glycoproteins was the major factor limiting L1210 leukemic cell proliferation.     

Direct visualization of protein transport and processing in the living cell by microinjection of specific antibodies

We have prepared polyclonal antibodies to the cytoplasmic portion of the envelope glycoprotein G of vesicular stomatitis virus (VSV) by using synthetic peptides corresponding to either the 22 or 11 ultimate carboxy-terminal residues of the G as immunogens. When antibodies to the 22 residue peptide are microinjected into monolayer baby hamster kidney cells before or shortly after infection with wild-type VSV, G protein accumulates in large intracellular patches and little G is observed in the Golgi complex or at the cell surface. In contrast, when antibodies to the 11 residue peptide are injected, no such patches are observed and G protein is seen colocalized with the injected antibody at the endoplasmic reticulum, in the Golgi complex, in transport vesicles, and at the plasma membrane. Microinjection of these antibodies does not disturb the pathway or kinetics of G-protein transport. In cells infected with a temperature-sensitive mutant of VSV, 045, the glycoprotein accumulates in the endoplasmic reticulum at 39.8 degrees C, but rapidly moves through the Golgi apparatus and then to the cell surface after a temperature shift-down to 32 degrees C. Using rhodamine-coupled antibodies to the 11 residue peptide, a microscope stage equipped for precise temperature control, and a silicon intensifier target video camera, we can visualize by video light microscopy the synchronized exocytotic transport of the G protein directly in the living cell.     

Subcellular localization of the env-related glycoproteins in Friend erythroleukemia cells.

A scheme was developed for the subcellular fractionation of murine erythroleukemia cells transformed by Friend leukemia virus. The subcellular localization of the env-related glycoproteins was determined by immune precipitation with antiserum against gp70, the envelope glycoprotein of the helper virus, followed by gel electrophoresis. In cells labeled for 2 h with [35S]methionine, the glycoprotein encoded by the defective spleen focus-forming virus, gp55SFFV, was found primarily in the nuclear fraction and in fractions containing dense cytoplasmic membranes such as endoplasmic reticulum. A similar distribution was noted for gp85env, the precursor to gp70. The concentration of viral glycoproteins in the nuclear fraction could not be accounted for by contamination with endoplasmic reticulum. In pulse-chase experiments, neither glycoprotein underwent major redistribution. However, labeled gp85env disappeared from intracellular membranes with a half-time of 30 min to 1 h, whereas labeled gp55SFFV was stable during a 2-h chase. In plasma membrane preparations with very low levels of contamination with endoplasmic reticulum, gp70 was the major viral env-related glycoprotein detected; a minor amount of gp55SFFV and no gp85env could be detected. The unexpected result of these experiments is the amount of viral glycoproteins found in the nuclear fraction. Presence of viral proteins in the nucleus could be relevant to the mechanism of viral leukemogenesis.     

Accumulation of a GPI-anchored protein at the cell surface requires sorting at multiple intracellular levels

Proteins modified by glycosylphosphatidylinositol membrane anchors have become popular for investigating the role of membrane lipid microdomains in cellular sorting processes. To this end, trypanosomatids offer the advantage that they express these molecules in high abundance. The parasitic protozoan Trypanosoma brucei is covered by a dense and nearly homogeneous coat composed of a glycosylphosphatidylinositol-anchored protein, the variant surface glycoprotein, which is essential for survival of the parasite in the mammalian blood. Therefore, T. brucei must possess mechanisms to selectively and efficiently deliver variant surface glycoprotein to the cell surface. In this study, we have quantified the steady-state distribution of variant surface glycoprotein by differential biotinylation, by fluorescence microscopy and by immunoelectron microscopy on high-pressure frozen and freeze-substituted samples. These three techniques provide very similar estimates of the fraction of variant surface glycoprotein located on the cell surface, on average 89.4%. The intracellular variant surface glycoprotein (10.6%) is predominantly located in the endosomal compartment (75%), while 25% are associated with the endoplasmic reticulum, Golgi apparatus and lysosomes. The density of variant surface glycoprotein in the plasma membrane including the membrane of the flagellar pocket, the only site for endo- and exocytosis in this organism, is 48-52 times higher than the density in endoplasmic reticulum membranes. The relative densities of the Golgi complex and of the endosomes are 2.7 and 10.8, respectively, compared to the endoplasmic reticulum. This data set provides the basis for an analysis of the dynamics of sorting. Depending on the intracellular itinerary of newly formed variant surface glycoprotein, the high surface density is achieved in two (endoplasmic reticulum --> Golgi complex --> cell surface) or three enrichment steps (endoplasmic reticulum --> Golgi complex --> endosomes --> cell surface), suggesting sorting between several membrane compartments.     

Intracellular maturation and secretion of acid phosphatase of Saccharomyces cerevisiae

To elucidate intracellular maturation and secretion of acid phosphatase of Saccharomyces cerevisiae we prepared a monoclonal antibody that recognizes specifically the protein moiety of this cell surface glycoprotein. With this antibody membranes and soluble fractions of wild-type cells, grown in low-phosphate medium in the presence and absence of tunicamycin, were examined by the immunoblot technique. Similarly, secretory mutants, blocked at distinct steps in the secretory pathway at the restrictive temperature as well as a strain harboring several copies of the structural gene PHO5 for repressible acid phosphatase, were analyzed. The data suggest the following sequence of events in acid phosphatase maturation and secretion: three unglycosylated precursors with molecular masses of 60 kDa, 58 kDa and 56 kDa are synthesized into membranes of the endoplasmic reticulum, where these are core glycosylated in a membrane-bound form. They appear on sodium dodecyl sulfate gels as bands with molecular masses of 76 kDa and 80 kDa. Owing to a rate-limiting maturation step, occurring after core glycosylation, they can accumulate in a membrane-bound form. At the Golgi apparatus outer carbohydrate chains are attached to the core and the enzyme appears in a soluble form, indicating a release of acid phosphatase from the membrane between the endoplasmic reticulum and the Golgi. Pulse-chase experiments suggest that the time for acid phosphatase synthesis and its transport to the Golgi is about 5 min.     

Post-translational glycosylation of coronavirus glycoprotein E1: inhibition by monensin.

The intracellular sites of biosynthesis of the structural proteins of murine hepatitis virus A59 have been analyzed using cell fractionation techniques. The nucleocapsid protein N is synthesized on free polysomes, whereas the envelope glycoproteins E1 and E2 are translated on the rough endoplasmic reticulum (RER). Glycoprotein E2 present in the RER contains N-glycosidically linked oligosaccharides of the mannose-rich type, supporting the concept that glycosylation of this protein is initiated at the co-translational level. In contrast, O-glycosylation of E1 occurs after transfer of the protein to smooth intracellular membranes. Monensin does not interfere with virus budding from the membranes of the endoplasmic reticulum, but it inhibits virus release and fusion of infected cells. The oligosaccharide side chains of E2 obtained under these conditions are resistant to endoglycosidase H and lack fucose suggesting that transport of this glycoprotein is inhibited between the trans Golgi cisternae and the cell surface. Glycoprotein E1 synthesized in the presence of monensin is completely carbohydrate-free. This observation suggests that the intracellular transport of this glycoprotein is also blocked by monensin.     

Replication of coronavirus MHV-A59 in sac- cells: determination of the first site of budding of progeny virions

During infection of sac- cells by murine coronavirus MHV A59 the intracellular sites at which progeny virions bud correlate with the distribution of the viral glycoprotein E1. Budding is first detectable by electron microscopy at 6 to 7 hours post infection in small, smooth, perinuclear vesicles and tubules in a region transitional between the rough endoplasmic reticulum and the Golgi apparatus. At later times the rough endoplasmic reticulum becomes the major site of budding and accumulation of progeny virus particles. Indirect immunofluorescence microscopy shows that E1 is confined at 6 hours post infection to the perinuclear region while at later times it also accumulates in the endoplasmic reticulum. At 6 hours post infection the second viral glycoprotein, E2, is distributed throughout the endoplasmic reticulum and is not restricted to the site at which budding begins. Core protein, the third protein in virions, can be detected 2 hours before E1 is detectable and budding begins, and at 6 hours post infection it is distributed throughout the cytosol. We conclude that the time and the site at which the maturation of progeny virions occurs is determined by the accumulation of glycoprotein E1 in intracellular membranes. Only rarely do progeny virions bud directly into the cisternae of the Golgi apparatus but at least some already budded virions are transported to the Golgi apparatus where they occur in structures some of which also contain TPPase, a trans Golgi marker.     

Analysis of the hemagglutinin glycoprotein from mutants of vaccinia virus that accumulates on the nuclear envelope

We isolated mutants whose vaccinia hemagglutinin (HA) accumulates on nuclear envelopes and the rough endoplasmic reticulum. Mutant HA must be blocked at a pre-Golgi step because it has high-mannose-type carbohydrates but no fucose. Neither N- nor O-glycosidically linked carbohydrates are involved in the transport defect of the mutant HA, because tunicamycin, an inhibitor of N-type glycosylation, has no effect, and O-type glycosylation takes place in the Golgi organelle. The unglycosylated form of the mutant HA synthesized in the presence of tunicamycin is 3000 daltons larger than the wild type. This higher molecular weight is related to the transport defect. HAs translated in vitro also show this difference, evidence that it reflects mutation in the HA structural gene. Portions of HAs that project into the cytoplasm seem to account for this weight difference. Thus the cytoplasmic tail of glycoprotein has an important function in transport out of the rough endoplasmic reticulum.     

The morphologic pathway of exocytosis of the vesicular stomatitis virus G protein in cultured fibroblasts

Cultured fibroblasts were infected with vesicular stomatitis virus (VSV) and the pathway of exocytosis of G protein, the transmembrane glycoprotein of VSV, was followed by immunofluorescence and electron microscopy. G protein was detected within the endoplasmic reticulum, within smooth vesicles and stacks in the Golgi region and on the cell surface. No G protein was detected in the coated regions of the Golgi. Our data are consistent with the hypothesis that coated regions of the Golgi are involved in transfer of lysosomal enzymes and other substances to lysosomes and not in exocytosis.     

Association of vesicular stomatitis virus proteins with HeLa cell membranes and released virus.

The association of vesicular stomatitis virus proteins with intracellular and plasma membranes was examined by pulse and pulse-chase labeling of virus-infected HeLa cells with [35S]methionine and separation of cell homogenates into three major membrane fractions in discontinuous sucrose gradients. The glycoprotein G was primarily associated with rough endoplasmic reticulum-like membranes after short radioactive pulses (2 to 4 min) but accumulated in the plasma membrane-enriched fraction and the smooth internal membrane fraction with longer pulse or chase periods. The nucleocapsid protein N and the matrix protein M accumulated in the rough endoplasmic reticulum and plasma membrane-like fractions but not in the smooth internal membrane fraction. Only a fraction (35 to 40%) of the viral protein synthesized during a short pulse in the mid-cycle of infection was apparently utilized in released virus. The newly synthesized virus proteins first appeared in released virus in the order: M, N and L, and G.     

Assembly of viral membranes: nature of the association of vesicular stomatitis virus proteins to membranes.

To explore the interaction of vesicular stomatitis virus (VSV) proteins with cellular membranes, we have isolated membranes from infected cells that have been radioactively pulse-labeled. We have found conditions of isolation that result in membrane preparation which contain primarily the VSV membrane protein (M) and glycoprotein (G). Both of these proteins are very firmly attached to membranes: conditions known to release peripherally associated membrane proteins from membranes (S. Razin, Biochim, Biophys. Acta 265:241-246, 1972; S. J. Singer, Annu. Rev. Biochem. 43:805-826, 1974; S. J. Singer and G. L. Nicholson, Science 175:720-731, 1972) are ineffective in detaching either the G or the M protein. The results of trypsin digestion of these membrane fractions suggest that the M protein resides primarily on one side, the cytoplasmic side of cellular membranes, whereas the glycoprotein has been transported to the lumen of the membrane vesicle. However, we present evidence that the glycoprotein is transmembranal and that approximately 3,000 daltons of one end of the molecule is on the cytoplasmic side of the membrane. We have also found that undenatured VSV M protein contains a trypsin-resistant core with a molecular weight of 22,000. This region of the M protein is trypsin-resistant regardless of its association with membranes.     

Biosynthesis of the erythrocyte anion transport protein

The biosynthesis of the erythrocyte anion transport protein (Band III) was studied in erythroid precursor cells obtained from the spleens of anemic mice. Newly synthesized Band III was inserted during or immediately after translation into rough endoplasmic reticulum membranes. The asymmetric orientation of Band III in these membranes resembled that of mature Band III in erythrocyte membranes, with the NH2-terminal portion of the molecule facing the cytoplasm. At this stage Band III contained a high mannose core oligosaccharide, which was susceptible to cleavage by endoglycosidase H. During the next 20 to 30 min, this oligosaccharide was processed to a form resistant to endoglycosidase H degradation, presumably in the Golgi complex. The processed Band III was subsequently expressed on the cell surface, at about 30 to 45 min after synthesis. In many respects, therefore, the biosynthesis of Band III resembles that of cotranslationally inserted proteins whose NH2-terminal portions are exposed on the exterior of the cell, like VSV glycoprotein, HLA-A antigens, and glycophorin.     

Maturation of the envelope glycoproteins of Newcastle disease virus on cellular membranes.

Based on subcellular fractionation data, the following maturation pathways were proposed for the Newcastle disease virus glycoproteins. During or shortly after synthesis in rough endoplasmic reticulum, hemagglutinin-neuraminidase (HN) and fusion (F0) glycoproteins underwent dolichol pyrophosphate-mediated glycosylation, and HN assumed a partially trypsin-resistant conformation. HN began to associate into disulfide-linked dimers in rough endoplasmic reticulum, and at least one of its oligosaccharide side chains was processed to a complex form en route to the cell surface. During migration in intracellular membranes, F0 was proteolytically cleaved to F1.2. Neither HN nor F1,2 required oligosaccharide side chains for migration to plasma membranes, and cleavage of F0 also occurred without glycosylation. Virion- and plasma membrane-associated HN contained both complex and high-mannose oligosaccharide chains on the same molecule, and F1,2 contained at least high-mannose forms. Several of the properties of HN were notable for a viral glycoprotein. The oligosaccharide side chains of HN were modified very slowly in chick cells, whereas those of the G glycoprotein of vesicular stomatitis virus were rapidly processed to a complex form. Therefore, their different rates of migration and carbohydrate processing were intrinsic properties of these glycoproteins. Consistent with its slow maturation, the HN glycopolypeptide accumulated to high levels in intracellular membranes as well as in plasma membranes. Intracellular HN contained immature oligosaccharide side chains, suggesting that it accumulated in the pre-Golgi/Golgi segment of the maturation pathway. The major site of accumulation of mature HN with neuraminidase activity was the plasma membrane.     

Effect of Inhibition of Glycosylation on the Appearance of a 60 kD Membrane Glycopolypeptide in Endomembrane Fractions of Soybean Root

Endomembrane (endoplasmic reticulum, Golgi apparatus, plasma membrane) proteins of soybean (Glycine max) root cells are highly glycosylated. We investigated whether N-linked oligosaccharide moieties are essential for the correct intracellular transport of plant endomembrane glycoproteins. Excised roots were incubated with tunicamycin, to block cotranslational glycosylation of proteins, and dual labeled with [³H]glucosamine and [³⁵S] (methionine, cysteine). In the presence of tunicamycin, the incorporation of glucosamine into membrane proteins was inhibited by 60 to 90% while amino acid incorporation was only slightly affected. Autoradiograms of two-dimensionally separated polypeptides from each endomembrane fraction revealed the presence of at least one new polypeptide in tunicamycin-treated tissue. The new polypeptide was of the same isoelectric point but lower molecular weight than a preexisting polypeptide. The new polypeptide was unreactive to concanavalin A, as opposed to the preexisting polypeptide, suggesting the absence of the glycan portion. Trifluoromethanesulfonic acid and N-glycanase were used to cleave the carbohydrate from the preexisting concanavalin A binding polypeptide. In each case a deglycosylated polypeptide of the same isoelectric point and molecular weight as the new polypeptide from tunicamycin-treated tissue resulted. Since the absence of carbohydrate from the new endomembrane polypeptide did not prevent its appearance on autoradiograms of Golgi and plasma membrane, intracellular transport and intercalation of newly synthesized glycoproteins into plant cell membranes may not require the presence of polysaccharide moieties.     

Studies of the mechanism of tunicamycin in hibition of IgA and IgE secretion by plasma cells.

Tunicamycin, an antibiotic which blocks the formation of N-acetylglucosamine-lipid intermediates, thereby preventing glycosylation of glycoproteins, inhibits the secretion of IgA and IgE by MOPC 315 mouse plasma cells and IR162 rat plasma cells, respectively. At 0.5 microng of tunicamycin per ml, D-[14C]glucosamine incorporation into newly synthesized immunoglobulin was inhibited greater than 90% while the overall rate of protein synthesized was much less inhibited (40% in the case of MOPC 315 cells and 13% in the case of IR162 cells). This dose of tunicamycin produced an 85% inhibition of IgA secretion by the MOPC 315 cells and a complete inhibition of intact IgE secretion by the IR162 plasma cells. In contrast, tunicamycin had little effect on the secretion of normally nonglycosylated lambda light chains or on cell-free protein synthesis, demonstrating that tunicamycin is not a general inhibitor of protein synthesis or a non-specific inhibitor of protein secretion. No enhancement of intracellular degradation of nonglycosylated immunoglobulin could be demonstrated. Electron microscopy of tunicamycin-treated MOPC 315 cells revealed marked dilatations of the rough endoplasmic reticulum, and direct immunofluorescence indicated that the dilated rought endoplasmic reticulum contained IgA. These data indicate that glycosylation of newly synthesized IgA and IgE may be necessary for normal secretion to occur.     

Cell-free synthesis and membrane insertion of mouse H-2Dd histocompatibility antigen and beta 2-microglobulin.

Messenger RNA from SL2 lymphoma cells was translated in a cell-free system in the presence of microsomal membranes. Mouse H-2Dd histocompatibility antigen was correctly assembled in the microsomal membranes, and transmembrane insertion of the nascent chain was accompanied by glycosylation and cleavage of the signal sequence H-2Kd antigens, synthesized in vivo, comprised a transmembrane glycoprotein and an unglycosylated protein in the cytoplasm. The glycosylated forms of the H-2Dd and H-2Kd antigens were modified during intracellular transport from the endoplasmic reticulum to the cell surface. beta 2-Microglobulin was also synthesized in vitro, and transfer of this protein into microsomal vesicles was accompanied by cleavage of its signal sequence. In the endoplasmic reticulum, beta-microglobulin can bind to newly synthesized H-2d glycoproteins. The mRNAs coding for beta 2-microglobulin and H-2Dd antigen could be separated on aqueous sucrose gradients.     

Glycosyltransferase activities in Golgi complex and endoplasmic reticulum fractions isolated from African trypanosomes

Highly enriched Golgi complex and endoplasmic reticulum fractions were isolated from total microsomes obtained from Trypanosoma brucei, Trypanosoma congolense, and Trypanosoma vivax, and tested for glycosyltransferase activity. Purity of the fractions was assessed by electron microscopy as well as by biochemical analysis. The relative distribution of all the glycosyltransferases was remarkably similar for the three species of African trypanosomes studied. The Golgi complex fraction contained most of the galactosyltransferase activity followed by the smooth and rough endoplasmic reticulum fractions. The dolichol- dependent mannosyltransferase activities were highest for the rough endoplasmic reticulum, lower for the smooth endoplasmic reticulum, and lowest for the Golgi complex. Although the dolichol-independent form of N-acetylglucosaminyltransferase was essentially similar in all the fractions, the dolichol-dependent form of this enzyme was much higher in the endoplasmic reticulum fractions than in the Golgi complex fraction. Inhibition of this latter activity in the smooth endoplasmic reticulum fraction by tunicamycin A1 suggests that core glycosylation of the variable surface glycoprotein may occur in this organelle and not in the rough endoplasmic reticulum as previously assumed.     

Assembly of viral membranes. I. Association of vesicular stomatitis virus membrane proteins and membranes in a cell-free system.

We report here an in vitro system designed to study the interactions of vesicular stomatitis virus (VSV) proteins with cellular membranes. We have synthesized the VSV nucleocapsid (N) protein, nonstructural (NS) protein, glycoprotein (G protein), and membrane (M) protein in a wheat germ, cell-free, protein-synthesizing system directed by VSV 12 to 18S RNA. When incubated at low salt concentrations with purified cytoplasmic membranes derived from Chinese hamster ovary cells, the VSV M andG proteins bind to membranes, whereas the VSV N and NS proteins do not. The VSV M protein binds to membranes in low or high divalent cation concentrations, whereas binding of significant amounts of G protein requires at least 5 mM magnesium acetate concentrations.