Requirements for the insertion of the Sindbis envelope glycoproteins into the endoplasmic reticulum membrane

Previous work has shown that the Sindbis structural proteins, core, the internal protein, and PE2 and E1, the integral membrane glycoproteins are synthesized as a polyprotein from a 26S mRNA; core PE2 and E1 are derived by proteolytic cleavage of a nascent chain. Newly synthesized core protein remains on the cytoplasmic side of the endoplasmic reticulum while newly synthesized PE2 and E1 are inserted into the lipid bilayer, presumably via their amino-termini. PE2 and E1 are glycosylated as nascent chains. Here, we examine a temperature-sensitive mutant of Sindbis virus which fails to cleave the structural proteins, resulting in the production of a polyprotein of 130,000 mol wt in which the amino-termini of PE2 and E1 are internal to the protein. Although the envelope sequences are present in this protein, it is not inserted into the endoplasmic reticulum bilayer, but remains on the cytoplasmic side as does the core protein in cells infected with wild-type Sindbis virus. We have also examined the fate of PE2 and E1 in cells treated with tunicamycin, an inhibitor of glycosylation. Unglycosylated PE2 and E1 are inserted normally into the lipid bilayer as are the glycosylated proteins. These results are consistent with the notion that a specific amino-terminal sequence is required for the proper insertion of membrane proteins into the endoplasmic reticulum bilayer, but that glycosylation is not required for this insertion.     

Role of the nuclear envelope in synthesis, processing, and transport of membrane glycoproteins

The outer nuclear membrane is morphologically similar to rough endoplasmic reticulum. The presence of ribosomes bound to its cytoplasmic surface suggests that it could be a site of synthesis of membrane glycoproteins. We have examined the biogenesis of the vesicular stomatitis virus G protein in the nuclear envelope as a model for the biogenesis of membrane glycoproteins. G protein was present in nuclear membranes of infected Friend erythroleukemia cells immediately following synthesis and was transported out of nuclear membranes to cytoplasmic membranes with a time course similar to transport from rough endoplasmic reticulum (t 1/2 = 5-7 min). Temperature-sensitive mutations in viral membrane proteins which block transport of G protein from endoplasmic reticulum also blocked transport of G protein from the nuclear envelope. Friend erythroleukemia cells and NIH 3T3 cells differed in the fraction of newly synthesized G protein found in nuclear membranes, apparently reflecting the relative amount of nuclear membrane compared to endoplasmic reticulum available for glycoprotein synthesis. Nuclear membranes from erythroleukemia cells appeared to have the enzymatic activities necessary for cleavage of the signal sequence and core glycosylation of newly synthesized G protein. Signal peptidase activity was detected by the ability of detergent-solubilized membranes of isolated nuclei to correctly remove the signal sequence of human preplacental lactogen. RNA isolated from the nuclear envelope was highly enriched for G protein mRNA, suggesting that G protein was synthesized on the outer nuclear membrane rather than redistributing to nuclear membranes from endoplasmic reticulum before or during cell fractionation. These results suggest a mechanism for incorporation of membrane glycoproteins into the nuclear envelope and suggest that in some cell types the nuclear envelope is a major source of newly synthesized membrane glycoproteins.     

THE SECRETORY PATHWAYS OF RAT SERUM GLYCOPROTEINS AND ALBUMIN : Localization of Newly Formed Proteins within the Endoplasmic Reticulum

These studies compare the secretory pathways of newly formed rat serum glycoproteins and albumin by studying their submicrosomal localization at early times after the beginning of their synthesis and also by determining the submicrosomal site of incorporation of N-acetylglucosamine, mannose, galactose, and leucine into protein. N-acetylglucosamine, mannose, and galactose were only incorporated in vitro into proteins from membrane-attached polysomes and not into proteins from free polysomes. Mannose incorporation occurred in the rough endoplasmic reticulum, was stimulated by puromycin but not by cycloheximide, and 90% of the mannose-labeled protein was bound to the membranes. Galactose incorporation, by contrast, occurred in the smooth microsome fraction and 89% of the radioactive protein was in the cisternae. Albumin was mostly recovered (98%) in the cisternae, with negligible amounts in the membranes. To determine whether the radio-active sugars were being incorporated into serum proteins or into membrane protein, the solubilized in vivo-labeled proteins were treated with specific antisera to rat serum proteins or to albumin. Immunoelectrophoresis of the ¹⁴C-labeled leucine membrane and cisternal proteins showed that the membranes contained radioactive serum glycoprotein but no albumin, while the cisternal fraction contained all of the radioactive albumin and some glycoproteins. The results indicate that newly formed serum glycoproteins remain attached to the membranes of the rough endoplasmic reticulum after they are released from the membrane-attached polysomes, while albumin passes directly into the cisternae.     

Synthesis and deposition of zein in protein bodies of maize endosperm

The origin of protein bodies in maize (Zea mays L.) endosperm was investigated to determine whether they are formed as highly differentiated organelles or as protein deposits within the rough endoplasmic reticulum. Electron microscopy of developing maize endosperm cells showed that membranes surrounding protein bodies were continuous with rough endoplasmic reticulum membranes. Membranes of protein bodies and rough endoplasmic reticulum both contained cytochrome c reductase activity indicating a similarity between these membranes. Furthermore, the proportion of alcohol-soluble protein synthesized by polyribosomes isolated from protein body or rough endoplasmic reticulum membranes was similar, and the alcohol-soluble or -insoluble proteins showed identical [¹⁴C]leucine labeling. These results demonstrated that protein bodies form simply as deposits within the rough endoplasmic reticulum.

Messenger RNA that directed synthesis of only the smaller molecular weight zein subunit was separated from mRNA that synthesized both subunits by sucrose gradient centrifugation. This result demonstrated that separate but similar sized mRNAs synthesize the major zein components. In vitro translation products of purified mRNAs or polyribosomes were approximately 2,000 daltons larger than native zein proteins, suggesting that the proteins are synthesized as zein precursors. When intact rough endoplasmic reticulum was placed in the in vitro protein synthesis system, proteins corresponding in molecular weight to the native zein proteins were obtained.

     

Role of glucocorticoids and progesterone in the development of rough endoplasmic reticulum involved in casein biosynthesis.

Hydrocortisone acetate injected into pseudopregnant rabbits induced casein synthesis and a parallel accumulation of casein mRNA. These effects were not accompanied by any enrichment of total RNA in the mammary cell. Hydrocortisone acetate did not favour the attachment of polysomes to endoplasmic reticulum. Casein mRNA concentration was enhanced in free and membrane-bound polysomes. After long treatments, the concentration of casein mRNA reached a plateau in membrane bound polysomes whereas it continued to be accumulated in free polysomes, suggesting that a substantial part of casein synthesis is then carried out by free polysomes. Progesterone injected with high doses of prolactin was unable to prevent the stimulatory action of prolactin on the synthesis of casein, the accumulation of casein mRNA and mammary gland growth, as judged by DNA content. By contrast, the increase in the total RNA content of mammary gland was still significantly reduced by progesterone. In addition, progesterone inhibited almost completely the formation of membrane-bound polysomes and the anchorage of casein mRNA to endoplasmic reticulum. From these data, it was concluded that the formation of the endoplasmic reticulum is not a prerequisite for the initiation of casein synthesis. Glucocorticoids do not play a major role in the formation of the endoplasmic reticulum and the Golai apparatus and in the binding of casein synthesizing polysomes to membranes. Progesteronne is capable of inhibiting preferentially and gradually the stimulation of cellular functions requiring the most potent prolactin stimulation.     

Identification of specific proteins and glycoproteins associated with membrane fractions isolated from Zea mays L. coleoptiles

The aim of this work was to identify proteins specific for plant cell membranes which could then be used as unique markers. A crude membrane fraction was isolated from corn coleoptiles and separated on non-linear sucrose density gradients. Separation of endoplasmic reticulum (NADH-cytochrome c reductase), mitochondria (cytochrome c oxidase), golgi (inosine diphosphatase), and plasma membranes (N-1-naphthylphthalamic acid-binding) was achieved. The membrane proteins from the gradient fractions were separated using sodium dodecyl sulphate-poly-acrylamide gel electrophoresis and the gels stained with coomassie blue or with concanavalin A/peroxidase to detect glycoproteins. Proteins specific for the various membranes were identified. Five proteins including two glycoproteins were plasma membrane markers. Protoplasts were isolated and iodinated using lactoperoxidase/glucose oxidase covalently attached to beads. Eleven iodinated proteins were found and three of these corresponded to proteins specifically associated with plasma membranes in the density gradients. Two methods for detecting Ca²⁺-binding proteins following sodium dodecylsulphate polyacrylamide gel electrophoresis were employed. The majority of such proteins were found in the endoplasmatic reticulum and one was specific for plasma membranes. In vitro and in vivo phosphorylation of membrane proteins was examined and the majority of proteins phosphorylated were glycoproteins. Two of the phosphorylated proteins (M_r=110,000 and 20,000) were also iodinated on protoplasts and may be part of the plasma membrane ATPases.Abbreviations ER endoplasmic reticulum - IDP inosine diphosphate - NPA N-1-naphthylphthalamic acid     

Segregation of specific classes of messenger RNA into free and membrane-bound polysomes

Analysis of mRNA populations from rat liver rough microsomes and free polysomes by homologous and heterologous cDNA . mRNA hybridization shows that the two mRNA populations are distinct, demonstrating that specific mRNA classes are efficiently segregated for translation in association with endoplasmic reticulum membranes. We estimate that approximately 90% of the mRNA in membrane-bound polysomes contains a diverse set of messengers with a minimum of 500--2000 different species although approximately 5--8 messengers may constitute 25--30% of the mRNA mass. The complexity of the mRNA population of free polysomes appears to be comparable to that estimated for total liver poly(A) + mRNA by other investigators, and is likely to be substantially greater than that of the bulk of bound mRNA. In addition, mRNA in free polysomes lacks the high abundance class characteristic of mRNA-bound polysomes. The substantial complexity of the bound mRNA population suggests that the segregation of polysomes in rough microsomes is not limited to a small class specialized in manufacturing secretory proteins, but extends to polysomes engaged in the synthesis of proteins for intracellular distribution. The segregation of specific messengers into the free and membrane-bound classes was abolished when polysome disassembly was induced by administration of ethionine. Thus, messenger RNA molecules themselves lacked the capacity for segregation, although they contain information for segregation which is expressed during translation. These findings are consistent with the presence of signal sequences in nascent polypeptides which determine the attachment of ribosomes to endoplasmic reticulum membranes.     

Studies on the Cell-Free Biosynthesis of CNS Membrane Proteins

Abstract: The biosynthesis of CNS membrane proteins was studied in cell-free systems containing membrane-bound polysomes (rough endoplasmic reticulum; RER) or free polysomes from rat forebrain. In previous studies of CNS membrane proteins using two-dimensional gel electrophoretic analysis, five proteins (mol. wt.-pI: 75K 5.4, 68K 5.6, 61K 5.1, 58K 5.1, and 36K 5.6) were found in ceil membrane fractions including preparations enriched in RER, smooth endoplasmic reticulum, and plasma membranes. One of these proteins, 68K 5.6, was also present in cytosol and comigrated with a microtubule-associated protein. In our present study, cell-free systems containing RER were found to synthesize the 75K 5.4, 61K 5.1, and 58K 5.1 proteins. A protein, 34K 5.65, similar (but not identical) to the 36K 5.6 protein was also synthesized. After cell-free synthesis, the 75K 5.4 and 58K 5.1 proteins could be purified by concanavalin A affinity chromatography. Of the five common membrane proteins previously identified, only the 68K 5.6 protein was synthesized by the free polysome population. The free polysomes were also found to synthesize cyclic AMP binding proteins at 48K and 54K, known from previous studies to be present in both cytosol and plasma membrane fractions in mammalian brain tissue. In conclusion, RER synthesized proteins found exclusively in CNS membrane fractions, whereas free polysomes synthesized those proteins found in both soluble and membrane compartments.     

Membrane-bound mRNAs are recruited from preinitiated ribonucleoprotein particles in injected Xenopus oocytes

Messenger RNA injected Xenopus oocytes exhibit a differential capacity for translation. mRNAs translated in the free cytoplasm are translated efficiently whereas mRNAs translated on the rough endoplasmic reticulum (RER) membrane are translated inefficiently. If mRNA injected oocytes are injected additionally with proteins isolated from the RER, enhanced translation of RER-bound mRNAs is observed. When examined by sucrose gradient centrifugation and RNA dot blots, most of the injected RER-bound mRNA sediments less than or equal to the 80 S monosome. The RER proteins recruit these preinitiated mRNAs onto polysomes as evidenced by a shift in sedimentation to the polysome region of a sucrose gradient. When examined by immunoblotting, the RER proteins are shown to contain a protein which reacts specifically with an antibody directed against docking protein (SRP-receptor protein). However, this putative docking protein does not appear to be the protein which actually recruits the preinitiated mRNAs onto polysomes.     

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.     

Assembly of the semliki forest virus membrane glycoproteins in the membrane of the endoplasmic reticulum in vitro

A cell-free system has been constructed to study the mechanism by which a single messenger RNA directs the synthesis of proteins destined for two different cellular locations. The Semliki Forest virus (SFV) 26 S mRNA codes for the viral capsid protein (C protein) and the membrane proteins p62 and E1. The three virus proteins are read in this order from the messenger RNA using one initiation site. The C protein is left on the cytoplasmic side and the p62 and the El proteins are inserted into the endoplasmic reticulum membrane. Translation of 26 S mRNA in a HeLa cell-free system in the presence of microsomes from dog pancreas reproduced the segregation, and proteolytic processing and glycosylation observed in infected cells. The signal for membrane binding was in the amino-terminal end of p62. The results indicate that the membrane proteins become inserted in the nascent state. The cleavage between p62 and El was coupled to membrane insertion. If the membranes were added after a period corresponding to the synthesis of about 100 amino acids of the p62 protein, segregation, glycosylation and cleavage between p62 and E1 failed to occur.     

Folding of viral envelope glycoproteins in the endoplasmic reticulum

Viral glycoproteins fold and oligomerize in the endoplasmic reticulum of the host cell. They employ the cellular machinery and receive assistance from cellular folding factors. During the folding process, they are retained in the compartment and their structural quality is checked by the quality control system of the endoplasmic reticulum. A special characteristic that distinguishes viral fusion proteins from most cellular proteins is the extensive conformational change they undergo during fusion of the viral and cellular membrane. Many viral proteins fold in conjunction with and dependent on a viral partner protein, sometimes even synthesized from the same mRNA. Relevant for folding is that viral glycoproteins from the same or related virus families may consist of overlapping sets of domain modules. The consequences of these features for viral protein folding are at the heart of this review.     

Analysis of the proteins in thymocyte plasma membrane and smooth endoplasmic reticulum by sodium dodecylsulfate-gel electrophoresis

We have purified the plasma membranes and membranes of endoplasmic reticulum from calf and rabbit thymocytes and from calf mediastinal lymph node lymphocytes. We disrupted the cells by the “nitrogen cavitation method” and prepared a microsomal isolate by differential centrifugation. We fractionated this by isopycnic ultracentrifugation in dextran gradients into membrane vesicles, PM₁ and PM₂, most likely derived from plasma membrane and a fraction, ER, most likely originating from endoplasmic reticulum. More than 80% of the microsomal 5′-nucleotidase and acid p-nitrophenylphosphatase concentrates in the PM₁ and PM₂ fractions; alkaline p-nitrophenylphosphatase, another presumptive PM marker, is concentrated in the PM₁ fraction. These data are confirmed by the lacroperoxidase radioiodination of intact rabbit thymocytes followed by subcellular fractionation. The specific content of phospholipids (822 nmoles/mg protein) and cholesterol (1032 nmoles/mg protein) is highest in PM₁ and PM₂ plasma membrane fractions. NADH-oxidoreductase, our endoplasmic reticulum marker, is clearly enriched in gradient pellet.The membrane proteins were separated by electrophoretic molecular sieving in sodium dodecylsulfate-polyacrylamide gel electrophoresis, containing dithiothreitol (sodium dodecylsulfate-polyacrylamide gel electrophoresis). We numbered the 10 major protein components of the “microsomal fraction” (apparent molecular weights between 280000 and 15000) from 1–10 according to their decreasing molecular weights. Of these proteins, those with higher molecular weight, predominantly glycoproteins, appear in the PM₁ fraction, while the endoplasmic reticulum fraction contains mainly low molecular weight components.     

Segregation of the polypeptide translocation apparatus to regions of the endoplasmic reticulum containing ribophorins and ribosomes. I. Functional tests on rat liver microsomal subfractions

A preparation of rat liver microsomes containing 70% of the total cellular endoplasmic reticulum (ER) membranes was subfractionated by isopycnic density centrifugation. Twelve subfractions of different ribosome content ranging in density from 1.06 to 1.29 were obtained and analyzed with respect to marker enzymes, RNA, and protein content, as well as the capacity of these membranes to bind 80S ribosomes in vitro. After removal of native polysomes from these microsomal subfractions by puromycin in a buffer of high ionic strength their capacity to rebind 80S ribosomes approached levels found in the corresponding native membranes before ribosome stripping. This indicates that in vitro rebinding of ribosomes occurs to the same sites occupied in the cell by membrane-bound polysomes. Microsomes in the microsomal subfractions were also tested for their capacity to effect the translocation of nascent secretory proteins into the microsomal lumen utilizing a rabbit reticulocyte translation system programmed with mRNA coding for the precursor of human placental lactogen. Membranes from microsomes with the higher isopycnic density and a high ribosome content showed the highest translocation activity, whereas membranes derived from smooth microsomes had only a very low translocation activity. These results indicate the membranes of the rough and smooth portions of the endoplasmic reticulum are functionally differentiated so that sites for ribosome binding and the translocation of nascent polypeptides are segregated to the rough domain of the organelle.     

Segregation of the polypeptide translocation apparatus to regions of the endoplasmic reticulum containing ribophorins and ribosomes. II. Rat liver microsomal subfractions contain equimolar amounts of ribophorins and ribosomes

Ribophorins I and II, two transmembrane glycoproteins characteristic of the rough endoplasmic reticulum (ER) are thought to be part of the translocation apparatus for proteins made on membrane bound polysomes. To study the stoichiometry between ribophorins and membrane-bound ribosomes we have determined the RNA and ribophorin content in rat liver microsomes or in microsomal subfractions of different density (i.e., ribosome content). The specificity of antibodies against the ribophorins was demonstrated by Western blot analysis of rat liver rough microsomes separated by 2-dimensional gel electrophoresis. The ribophorin content of microsomal subfractions was determined by indirect immunoprecipitation and for ribophorin I by a radioimmune assay. In the latter assay a molar ratio of ribophorin I/ribosomes approaching one was calculated for total microsomes as well as in the gradient subfractions. We therefore suggest that ribophorins mediate the binding of ribosomes to endoplasmic reticulum membranes or play a role in co-translational process which depend on this binding, such as the insertion of nascent polypeptides into the membrane or their transfer into the cisternal lumen.     

The characterization of free,cytoskeletal and membrane-bound polysomes in Krebs II ascites and 3T3 cells

Summary Polysomes from Krebs II ascites and 3T3 cells were separated into three populations by using a sequential extraction method. Free polysomes were released by using a combination of low salt (25 mM KCl) and NP-40 detergent in the lysis buffer. The cytoskeletal bound polysomes were subsequently released by raising the salt concentration to 130 mM and finally, polysomes bound to the membranes of the endoplasmic reticulum were extracted by the combined treatment with Triton X-100 and deoxycholate. The results presented here illustrate that the three polysome-containing fractions differ in many parameters such as polysome profiles, cytoskeletal components and phospholipid content. When polyA-containing mRNA was isolated from the three polysome fractions and translated in an in vitro system, some differences were observed in the patterns of proteins being synthesized.     

The signal recognition particle receptor alpha subunit assembles co-translationally on the endoplasmic reticulum membrane during an mRNA-encoded translation pause in vitro.

Many proteins, including the alpha subunit of the signal recognition particle receptor (SR alpha), are targeted within the cell by poorly defined mechanisms. A 140 residue N-terminal domain of SR alpha targets and anchors the polypeptide to the endoplasmic reticulum membrane by a mechanism independent of the pathway involving the signal recognition particle. To investigate the mechanism of membrane anchoring, translation pause sites on the SR alpha mRNA were used to examine the targeting of translation intermediates. A strong pause site at nucleotide 507 of the mRNA open reading frame corresponded with the shortest nascent SR alpha polypeptide able to assemble on membranes. An mRNA sequence at this pause site that resembles a class of viral -1 frameshift sequences caused translation pausing when transferred into another mRNA context. Site-directed mutagenesis of the mRNA greatly reduced translation pausing without altering the polypeptide sequence, demonstrating unambiguously a role for this mRNA sequence in translation pausing. SR alpha polypeptides synthesized from the non-pausing mRNA were impaired in co-translational membrane anchoring. Furthermore, co-translational membrane assembly of SR alpha appears to anchor polysomes translating SR alpha to membranes.     

The rough endoplasmic reticulum is the site of reserve-protein synthesis in developing Phaseolus vulgaris cotyledons

Cytyledons of the common bean, Phaseolus vulgaris L., were incubated with radioactive amino acids at different stages of seed development. The proteins were fractionated by ion-exchange chromatography, sucrose gradients, and sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis. From 16 to 28 d after flowering about 40% of the incorporated radioactivity was associated with the polypeptides of vicilin and 10% with those of phytohemagglutinin.Polysomes were isolated from developing cotyledons 20–25 d after flowering and free polysomes were separated from membrane-bound polysomes. Aurintricarboxylic acid, an inhibitor of initiation in cell-free translation systems, did not inhibit the incorporation of amino acids into in-vitro synthesized proteins, indicating that synthesis was limited to the completion of already initiated polypeptides. Autofluorography of SDS-polyacrylamide gels showed that the two classes of polysomes made two different sets of polypeptides and that there was little overlap between these two sets.Four polypeptides similar in size to the 4 polypeptides of vicilin were made by membrane-bound polysomes and not by free polysomes. Antibodies specific for vicilin bound to those 4 polypeptides. Free polysomes made only polypeptides which did not bind to antibodies specific for vicilin. Antibodies against phytohemagglutinin did not bind to any of the invitro synthesized polypeptides.The membranes to which the polysomes were bound were characterized on sucrose gradients and by electron microscopy. Polysomes recovered from membranes which banded on top of 35 and 50% sucrose synthesized the vicilin polypeptides most rapidly. These membrane fractions were rich in vesicles of rough endoplasmic reticulum (ER). The ER marker-enzyme NADH-cytochrome-c reductase banded with an average density of 1.18 g/cm³ (40% w/w sucrose) on continuous gradients. These experiments demonstrate that the ER is the site of vicilin synthesis in developing bean cotyledons. Quantitative determinations of several ER parameters (RNA and lipid-phosphate content, NADH-cytochrome-c-reductase activity) show that expansion of the cotyledons is accompanied by a 4-6-fold increase in ER.     

ER-to-Golgi transport: COP I and COP II function (Review)

COP I and COP II coat proteins direct protein and membrane trafficking in between early compartments of the secretory pathway in eukaryotic cells. These coat proteins perform the dual, essential tasks of selecting appropriate cargo proteins and deforming the lipid bilayer of appropriate donor membranes into buds and vesicles. COP II proteins are required for selective export of newly synthesized proteins from the endoplasmic reticulum (ER). COP I proteins mediate a retrograde transport pathway that selectively recycles proteins from the cis-Golgi complex to the ER. Additionally, COP I coat proteins have complex functions in intra-Golgi trafficking and in maintaining the normal structure of the mammalian interphase Golgi complex.