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Query: UMLS:C0038362 (
stomatitis
)
8,852
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The fusion of lipid enveloped viruses with cellular membranes is thought to be mediated by the insertion into the target membrane of the N-terminal polypeptides of viral spike glycoproteins. Since membrane destabilization is a necessary step in membrane fusion, we investigated whether synthetic peptides with amino acid sequences corresponding to the N-termini of influenza virus hemagglutinin (HA2), vesicular
stomatitis
virus G-protein and Sendai virus F-protein, induce the destabilization and fusion of phospholipid vesicles. Membrane destabilization by the peptides was monitored by the release of aqueous contents of large unilamellar phospholipid vesicles. Aggregation was detected by a resonance energy transfer assay. Membrane fusion was followed by means of assays for the intermixing of phospholipids and of aqueous contents. The 17-amino acid HA2 peptide (HA2.17) destabilized phosphatidylcholine (PC) vesicles even at neutral pH, but the rate and extent of destabilization increased at lower pH. This peptide did not mediate appreciable release of contents from phosphatidylserine (PS) vesicles. HA2.17 induced neither aggregation nor fusion of PC or PS vesicles. In contrast, the 7-amino acid
N-terminal peptide
of G-protein (G.7) destabilized PS-containing membranes and not pure PC vesicles. Although G.7 caused aggregation of and lipid mixing between PS vesicles, it did not mediate any detectable intermixing of aqueous contents. The presence of cholesterol in PC membranes did not affect the destabilization caused by the
N-terminal peptide
of Sendai virus F-protein (F1.7), suggesting that cholesterol is not necessary for the effective interaction of this peptide with membranes, contrary to earlier proposals. Our results support the hypothesis that the hydrophobic N-terminal region of certain viral envelope proteins insert into and destabilize target membranes.
...
PMID:Membrane destabilization by N-terminal peptides of viral envelope proteins. 132 86
The cysteine residue in the cytoplasmic domain at position 489 of the sequence of the glycoprotein (G protein) isolated from vesicular-
stomatitis
virions is completely blocked for carboxymethylation. After release of covalently bound fatty acids by hydroxylamine at pH 6.8, this cysteine residue could be specifically labelled by iodo[14C]acetic acid. Reaction products were analysed after specific cleavage of labelled G protein at asparagine-glycine bonds by hydroxylamine at pH 9.3, which generated a
C-terminal peptide
of Mr 15,300 containing only the single cysteine residue. Bromelain digestion of [3H]palmitic acid-labelled membrane fractions of vesicular-
stomatitis
-virus-infected baby-hamster kidney cells removed almost completely the 3H radioactivity from the cytoplasmic domain of the G protein, whereas the ectodomain was completely protected by the microsomal membrane. This result indicates that the acylation site of the G protein is exposed on the cytoplasmic side of intracellular membranes. Taken together, both biochemical techniques strongly suggest that the single cysteine-489 residue, which is located six amino acid residues distal to the putative transmembrane domain, is the acylation site. The thioester bond between palmitic acid and the G protein is quite resistant to hydroxylamine treatment (0.32 M at pH 6.8 for 1 h at 37 degrees C) compared with the reactivity of the thioester linkage in palmitoyl-CoA, which is cleaved at relatively low concentrations of hydroxylamine (0.05 M).
...
PMID:Fatty acid acylation at the single cysteine residue in the cytoplasmic domain of the glycoprotein of vesicular-stomatitis virus. 285
Infection of BHK 21 cells by vesicular
stomatitis
virus (VSV) results in the intracellular synthesis of the five viral proteins which are easily detectable in polyacrylamide gels after short labeling periods with [35S]methionine. In addition, a 6th prominent radioactive protein band appears intracellularly in VSV-infected BHK cells. This additional polypeptide is also coded by the viral genome, because it is immunoprecipitated by antibodies against viral particles and more specifically by antibodies against purified G-protein. We propose to call this derivative of the G-protein Gsi-protein (short intracellular G-protein). It is associated with intracellular membranes and has an apparent mol. wt. of 58 000. Both G- and Gsi-protein have the same kinetics of appearance in the cell. The ratio of G-:Gsi-protein in BHK 21 cells is approximately 85:15. The mol. wt. difference of approximately 6000 daltons between G- and Gsi-protein is not due to variations in the degree of glycosylation because trypsin digestions of both [3H]mannose-labeled glycoproteins gave rise to identical glycopeptide patterns. Incubation of microsomes with trypsin demonstrates that Gsi-protein is protected in its full length by intracellular membranes. Gsi-protein is lacking an extended carboxy-terminal region of the viral G-protein sequence because it is not modified by palmitic acid and is not immunprecipitated by specific antibodies against a
C-terminal peptide
of the G-protein. Limited proteolysis by endoproteinase arg C indicates that the structure of Gsi-protein is very similar to the shedded form of the G-protein which has been previously described in the literature.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Intracellular appearance of a glycoprotein in VSV-infected BHK cells lacking the membrane-anchoring oligopeptide of the viral G-protein. 608 25
The biosynthesis of the erythrocyte anion transport glycoprotein, Band III (Mr 100,000), is of interest, as its N-terminal half is hydrophilic and faces the cytoplasmic surface; the C-terminal half spans the phospholipid bilayer several times. Band III is synthesized by erythroid precursor cells obtained from the spleens of anaemic mice. Newly synthesized Band III was inserted into rough endoplasmic reticulum membranes with an asymmetric orientation which resembled that of mature Band III in erythrocyte membranes: the N-terminal portion of the molecule facing the cytoplasm. Newly made Band III contained a high-mannose asparagine-linked oligosaccharide, which was susceptible to cleavage by endoglycosidase H. During the next 20-30 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 30-45 min after synthesis. To study the mechanism of insertion of Band III into microsomes, we used erythroid precursor cells from the spleens of anaemic mice as a source of messenger RNA for studies in vitro in the wheat germ and reticulocyte lysate cell-free system containing dog pancreatic microsomes. Immediately after synthesis, Band III was found to be inserted into microsomal membranes in its mature configuration, with the N-terminal portion exposed to the cytoplasm and its hydrophobic C-terminal portion spanning the lipid bilayer. The newly-synthesized Band III was also provided with a high-mannose asparagine-linked oligosaccharide. Band III was found to be inserted into dog pancreatic microsomes in a co-translational manner; in synchronized translation studies microsomes could be added as late as the time when the hydrophilic N-terminal half of the protein had been synthesized and still allow normal trans-membrane insertion and glycosylation. There is no cleavage of any
N-terminal peptide
during membrane insertion. In many respects, therefore, the biosynthesis of Band III resembles that of co-translationally-inserted proteins whose N-terminal portions are exposed on the exterior of the cell, like vesicular
stomatitis
virus glycoprotein, HLA-A antigens, and glycophorin. However, our results suggest that Band III contains a sequence near the middle of the protein which directs its insertion into endoplasmic reticulum membranes.
...
PMID:Synthesis and maturation of the erythrocyte anion transport protein--an internal sequence for membrane insertion. 682 84
We have previously shown that murine interferon gamma (IFN gamma) and its
C-terminal peptide
, muIFN gamma (95-133), bind to a region on the cytoplasmic domain of the IFN gamma receptor contained in the synthetic peptide, MIR(253-287). This region of the murine receptor bears considerable homology (approximately 80%) to its human counterpart. Here we report that not only do human IFN gamma and the human IFN gamma
C-terminal peptide
, huIFN gamma(95-134), bind to the cytoplasmic domain of the human IFN gamma receptor, but also that this interaction is species non-specific. MuIFN gamma(95-133) binds to human IFN gamma receptor cytoplasmic peptide HIR(252-291), and huIFN gamma(95-133) binds to MIR(253-287). Furthermore, treatment of murine macrophage cell lines with C-terminal peptides of either murine or human IFN gamma results in 10-fold upregulation of MHC class II molecule expression and increased resistance to infection with vesicular
stomatitis
virus (VSV) (10(6)-10(9)-fold reduction in yield). These data suggest a direct role for the C-terminus of IFN gamma in the initiation of intracellular signalling processes and may be indicative of a more general mechanism of action for extracellular signalling molecules.
...
PMID:The C-terminus of IFN gamma is sufficient for intracellular function. 794 13
The molecular interactions between the CD8 co-receptor dependent N15 and N26 T cell receptors (TCRs) and their common ligand, the vesicular
stomatitis
virus octapeptide (VSV8) bound to H-2Kb, were studied to define the docking orientation(s) of MHC class I restricted TCRs during immune recognition. Guided by the molecular surfaces of the crystallographically defined peptide/MHC and modeled TCRs, a series of mutations in exposed residues likely contacting the TCR ligand were analyzed for their ability to alter peptide-triggered IL-2 production in T cell transfectants. Critical residues which diminished antigen recognition by 1000 to 10,000-fold in molar terms were identified in both N15 Valpha (alphaE94A or alphaE94R, Y98A and K99) and Vbeta (betaR96A, betaW97A and betaD99A) CDR3 loops. Mutational analysis indicated that the Rp1 residue of VSV8 is critical for antigen recognition of N15 TCR, but R62 of H-2Kb is less critical. More importantly, the alphaE94R mutant could be fully complemented by a reciprocal charge reversal at Kb R62 (R62E). This result suggests a direct interaction between N15 TCR Valpha E94R and Kb R62E residues. As Rp1 of VSV8 is adjacent to R62 in the VSV8/Kb complex and essential for T cell activation, this orientation implies that the N15 Valpha CDR3 loop interacts with the N-terminal residues of VSV8 with the Valpha domain docking to the Kb alpha2 helix while the N15 Vbeta CDR3 loop interacts with the more
C-terminal peptide
residues and the Vbeta domain overlies the Kb alpha1 helix. An equivalent orientation is suggested for N26, a second VSV8/Kb specific TCR. Given that genetic analysis of two different class II MHC-restricted TCRs and two crystallographic studies of class I restricted TCRs offers a similar overall orientation of V domains relative to alpha-helices, these data raise the possibility of a common docking mode between TCRs and their ligands regardless of MHC restriction.
...
PMID:Topology of T cell receptor-peptide/class I MHC interaction defined by charge reversal complementation and functional analysis. 926 59
The vesicular
stomatitis
virus (VSV) matrix protein (M) interacts with cellular membranes, self-associates and plays a major role in virus assembly and budding. We present the crystallographic structure, determined at 1.96 A resolution, of a soluble thermolysin resistant core of VSV M. The fold is a new fold shared by the other vesiculovirus matrix proteins. The structure accounts for the loss of stability of M temperature-sensitive mutants deficient in budding, and reveals a flexible loop protruding from the globular core that is important for self-assembly. Membrane floatation shows that, together with the M lysine-rich
N-terminal peptide
, a second domain of the protein is involved in membrane binding. Indeed, the structure reveals a hydrophobic surface located close to the hydrophobic loop and surrounded by conserved basic residues that may constitute this domain. Lastly, comparison of the negative-stranded virus matrix proteins with retrovirus Gag proteins suggests that the flexible link between their major membrane binding domain and the rest of the structure is a common feature shared by these proteins involved in budding and virus assembly.
...
PMID:Crystal structure of vesicular stomatitis virus matrix protein. 1206 2
