Membrane assembly of the triple spanning coronavirus M protein. Individual transmembrane domains show preferred orientation

The M protein of mouse hepatitis virus strain A59 is a triple-spanning membrane protein which assembles with an uncleaved internal signal sequence, adopting an NexoCcyt orientation. To study the insertion mechanism of this protein, domains potentially involved in topogenesis were deleted and the effects analyzed in topogenesis were deleted and the effects analyzed in several ways. Mutant proteins were synthesized in a cell-free translation system in the presence of microsomal membranes, and their integration and topology were determined by alkaline extraction and by protease-protection experiments. By expression in COS-1 and Madin-Darby canine kidney-II cells, the topology of the mutant proteins was also analyzed in vivo. Glycosylation was used as a biochemical marker to assess the disposition of the NH2 terminus. An indirect immunofluorescence assay on semi-intact Madin-Darby canine kidney-II cells using domain-specific antibodies served to identify the cytoplasmically exposed domains. The results show that each membrane-spanning domain acts independently as an insertion and anchor signal and adopts an intrinsic preferred orientation in the lipid bilayer which corresponds to the disposition of the transmembrane domain in the wild-type assembled protein. These observations provide further insight into the mechanism of membrane integration of multispanning proteins. A model for the insertion of the coronavirus M protein is proposed

O-glycosylation of the coronavirus M protein. Differential localization of sialyltransferases in N and O linked glycosylation

It has previously been shown that the M (E1) glycoprotein of mouse hepatitis virus strain A59 (MHV-A59) contains only O-linked oligosaccharides and localizes to the Golgi region when expressed independently. A detailed pulse-chase analysis was made of the addition of O-linked sugars to the M protein; upon sodium dodecyl sulfate- polyacrylamide gel electrophoresis, three different electrophoretic forms could be distinguished that corresponded to the sequential acquisition of N-acetylgalactosamine (GalNAc), galactose (Gal), and sialic acid (SA). A fourth and fifth form could also be detected which we were unable to identify. Following Brefeldin A treatment, the M protein still acquired GalNAc, Gal, and SA, but the fourth and fifth forms were absent, suggesting that these modifications occur in the trans-Golgi network (TGN). In contrast, in the presence of BFA, the G protein of vesicular stomatitis virus (VSV), which contains N-linked oligosaccharides, acquired Gal and fucose but not SA. These results are consistent with earlier published data showing that Golgi compartments proximal to the TGN, but not the TGN itself, relocate to the endoplasmatic reticulum/intermediate compartment. More importantly, our data argue that, whereas addition of SA to N-linked sugars occurs in the TGN the acquisition of both SA on O-linked sugars and the addition of fucose to N-linked oligosaccharides must occur in Golgi compartments proximal to the TGN. The glycosylation of the M protein moreover indicates that it is transported to trans-Golgi and TGN. This was confirmed by electron microscopy immunocytochemistry, showing that the protein is targeted to cisternae on the trans side of the Golgi and co- localizes, at least in part, with TGN 38, a marker of the TGN, as well as with a lectin specific for sialic acid

Oligomerization of a trans Golgi/trans Golgi network retained protein occurs in the Golgi complex and may be part of its retention

The mouse hepatitis virus M protein is a triple spanning membrane glycoprotein that, when expressed independently, localizes to trans-Golgi as well as to the trans-Golgi network (TGN). Passage of this protein from the endoplasmic reticulum through the intermediate compartment to the late Golgi and TGN can be conveniently followed by analyzing its O-linked sugars. Using pulse-chase analyses we studied the oligomerization of the M protein in sucrose gradients. The Golgi and TGN forms migrated as large heterogeneous complexes, whereas the endoplasmic reticulum and intermediate compartment forms of the protein appeared to migrate as monomer. Moreover, a mutant of the M protein lacking the 22 COOH-terminal amino acids, that is transported to the plasma membrane, gave rise to similar complexes, albeit smaller in size, that persisted at the plasma membrane. We propose that the trans-Golgi/TGN retention of the MHV-M protein is governed by two mechanisms: oligomerization possibly mediated by the transmembrane domains and binding of its cytoplasmic tail to cellular factors in trans Golgi/TGN

The cytoplasmic tail of mouse hepatitis virus M protein is essential but not sufficient for its retention in the Golgi complex

The M protein of mouse hepatitis virus (MHV) is a triple-spanning membrane glycoprotein that is exclusively O-glycosylated. When expressed independently, it accumulates in late Golgi and the trans- Golgi network (TGN) (Locker, J. K., Griffiths, G., Horzinek, M. C., and Rottier, P. J. M. (1992) (J. Biol. Chem. 267, 14094-14101). To analyze the domains of this protein responsible for its localization, we have generated deletion mutants by site-directed mutagenesis and analyzed their intracellular transport. The intracellular distribution of the mutant proteins was determined by following the extent of O- glycosylation in pulse-chase experiments, by electron microscopic immunocytochemistry, and by surface immunoprecipitation. Mutant proteins lacking the first or the first and second transmembrane domains were not efficiently retained in the Golgi complex or TGN. The latter mutant proteins also localized to endocytic compartments but were not subject to rapid lysosomal degradation. Deletion of the COOH- terminal 22 amino acids, including a tyrosine residue in the context of a potential internalization signal, resulted in plasma membrane exposure of the respective mutant protein. We show that the wild-type MHV-M protein does not recycle between the plasma membrane and the TGN, but rather behaves as a late Golgi/TGN resident in our assays. We propose that the MHV-M protein is retained in the Golgi by two signals, one contained in the cytoplasmic tail and the other determined by the transmembrane domains

Chikungunya virus replication in salivary glands of the mosquito aedes albopictus

10.3390/v7112917Viruses7115902-590

Characterization of the coronavirus mouse hepatitis virus strain A59 small membrane protein E

The small envelope (E) protein has recently been shown to play an essential role in the assembly of coronaviruses. Expression studies revealed that for formation of the viral envelope, actually only the E protein and the membrane (M) protein are required. Since little is known about this generally low-abundance virion component, we have characterized the E protein of mouse hepatitis virus strain A59 (MHV-A59), an 83-residue polypeptide. Using an antiserum to the hydrophilic carboxy terminus of this otherwise hydrophobic protein, we found that the E protein was synthesized in infected cells with similar kinetics as the other viral structural proteins. The protein appeared to be quite stable both during infection and when expressed individually using a vaccinia virus expression system. Consistent with the lack of a predicted cleavage site, the protein was found to become integrated in membranes without involvement of a cleaved signal peptide, nor were any other modifications of the polypeptide observed. Immunofluorescence analysis of cells expressing the E protein demonstrated that the hydrophilic tail is exposed on the cytoplasmic side. Accordingly, this domain of the protein could not be detected on the outside of virions but appeared to be inside, where it was protected from proteolytic degradation. The results lead to a topological model in which the polypeptide is buried within the membrane, spanning the lipid bilayer once, possibly twice, and exposing only its carboxy-terminal domain. Finally, electron microscopic studies demonstrated that expression of the E protein in cells induced the formation of characteristic membrane structures also observed in MHV-A59-infected cells, apparently consisting of masses of tubular, smooth, convoluted membranes. As judged by their colabeling with antibodies to E and to Rab-1, a marker for the intermediate compartment and endoplasmic reticulum, the E protein accumulates in and induces curvature into these pre-Golgi membranes where coronaviruses have been shown earlier to assemble by budding

Characterization of the coronavirus mouse hepatitis virus strain A59 small membrane protein E

The small envelope (E) protein has recently been shown to play an essential role in the assembly of coronaviruses. Expression studies revealed that for formation of the viral envelope, actually only the E protein and the membrane (M) protein are required. Since little is known about this generally low-abundance virion component, we have characterized the E protein of mouse hepatitis virus strain A59 (MHV-A59), an 83-residue polypeptide. Using an antiserum to the hydrophilic carboxy terminus of this otherwise hydrophobic protein, we found that the E protein was synthesized in infected cells with similar kinetics as the other viral structural proteins. The protein appeared to be quite stable both during infection and when expressed individually using a vaccinia virus expression system. Consistent with the lack of a predicted cleavage site, the protein was found to become integrated in membranes without involvement of a cleaved signal peptide, nor were any other modifications of the polypeptide observed. Immunofluorescence analysis of cells expressing the E protein demonstrated that the hydrophilic tail is exposed on the cytoplasmic side. Accordingly, this domain of the protein could not be detected on the outside of virions but appeared to be inside, where it was protected from proteolytic degradation. The results lead to a topological model in which the polypeptide is buried within the membrane, spanning the lipid bilayer once, possibly twice, and exposing only its carboxy-terminal domain. Finally, electron microscopic studies demonstrated that expression of the E protein in cells induced the formation of characteristic membrane structures also observed in MHV-A59-infected cells, apparently consisting of masses of tubular, smooth, convoluted membranes. As judged by their colabeling with antibodies to E and to Rab-1, a marker for the intermediate compartment and endoplasmic reticulum, the E protein accumulates in and induces curvature into these pre-Golgi membranes where coronaviruses have been shown earlier to assemble by budding