Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0038362 (stomatitis)
 8,852 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mobility of the lipids in the bilayer of the envelope of vesicular stomatitis virus has been probed over its complete space by the biosynthetic incorporation of [N-13CH3]- choline as a probe for the polar head groups and [3-13C]- and [11-13C] oleic acid and [16-13C]- palmitic acid for the hydrophobic region of the bilayer. These precursors were effectively incorporated as established by the concomitant administration of the same precursors in radioactive form. Spin lattice relaxation time measurements (T1) of the 13C enriched segments in complete virus envelope allowed estimation of their mobility. The mobility of the polar head groups is restricted, probably due to ionic interactions with neighbouring acidic phospholipids (phosphatidylserine) and/or acidic side chains of the glycoprotein (G-protein). The rigidity of the hydrophobic part of the bilayer is due to the high cholesterol content and interaction with the immersing polypeptide chains of the G- and possibly M-protein. The rigidity is limited to a depth of about 15 A ranging from the inner and outer surface, whereas the inner core of the bilayer is fluid. Tryptic cleavage of the hydrophilic part of the G-protein allows the lipophilic immersing polypeptide fragment to enter further the bilayer which then reduces the fluidity of the hydrocarbon chains in the core region by lipid-protein interactions.
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PMID:13C-NMR studies of the membrane structure of enveloped virions (vesicular stomatitis virus). 18 76

To delineate the proximity and spatial arrangement of the major structural proteins of intact vesicular stomatitis (VS) virions, protein complexes formed by oxidation or by bivalent cross-linkers were analyzed by two-dimensional electrophoresis on polyacrylamide slab gels. H2O2 oxidation of VS virions produced an N-polypeptide dimer (molecular weight, approximately equal to 110,000) on a first dimension gel that could be reduced to N monomers (molecular weight, approximately equal to 50,000). Proteins extracted from unreduced and unoxidized VS virions contained dimeric and trimeric forms of M-protein complexes as well as a heterodimer of M and N protein. Qualitatively similar VS viral protein complexes were generated by exposing VS virions to the reversible protein cross-linkers methyl-4-mercaptobutyrimidate (MMB), tartryl diazide (TDA), and dithiobis(succinimidyl proprionate) (DTBSP); cross-linked complexes on first-dimension gels were cleaved by reduction with 2-mercaptoethanol (MMB or DTBSP cross-linked) or by periodate oxidation (TDA cross-linked). In addition to covalently linked homodiamers of M and N proteins and a protein M-N heterodimer, the protein cross-linkers also generated homo-oligomers of G protein and a G-M heterodimer. These data suggest that the glycoprotein spike of VS virus is composed of more than one G protein. The existence of N-M and G-M heterodimers is consistent with the hypothesis that the matrix (M) protein may serve as a bridge between the G and N proteins in assembly of the VS virion.
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PMID:Spatial relationships of the proteins of vesicular stomatitis virus: induction of reversible oligomers by cleavable protein cross-linkers and oxidation. 19 63

The peripheral membrane M protein of vesicular stomatitis virus purified by detergent extraction of virions and ion-exchange chromatography was determined to be a monomer in the absence of detergent at high salt concentrations. Reduction of the ionic strength below 0.2 M resulted in a rapid aggregation of M protein. This self-association was reversible by the detergent Triton X-100 even in low salt. However, aggregation was not reversible by high salt concentration alone. M protein is initially synthesized as a soluble protein in the cytosol of infected cells, thus raising the question of how the solubility of M protein is maintained at physiological ionic strength. Addition of radiolabeled M protein purified from virions to unlabeled cytosol from either infected or uninfected cells inhibited the self-association reaction. Cytosolic fractions from infected or uninfected cells were equally effective at preventing the self-association of M protein. Self-association could also be prevented by an irrelevant protein such as bovine serum albumin. Sedimentation velocity analysis indicated that most of the newly synthesized M protein is monomeric, suggesting that the solubility of M protein in the cytosol is maintained by either low-affinity interaction with macromolecules in the cytosol or interaction of a small population of M-protein molecules with cytosolic components.
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PMID:Solubility of vesicular stomatitis virus M protein in the cytosol of infected cells or isolated from virions. 215 51

The ability of the matrix (M) protein of wild-type vesicular stomatitis virus (VSV) to regulate viral transcription was studied with monoclonal antibodies and temperature-sensitive (ts) mutants in complementation group III, the M proteins of which are restricted in transcription inhibition. The marked inhibition of transcription by VSV ribonucleoprotein (RNP) cores complexed with M protein (RNP/M) was reversed by antibody to epitope 1. Antibodies to epitopes 2 and 3 not only failed to reverse the transcription-inhibitory activity of isolated M protein but actually increased M-protein inhibition of transcription in a reconstituted system. Monoclonal antibodies to epitopes 2 and 3 strongly bound to M proteins from all wild-type and ts-mutant virions, but monoclonal antibody to epitope 1 completely failed to bind to the M protein of ts023(III) even though it reacted strongly with M proteins of mutants tsG31(III) and tsG33(III). The M protein of a tsO23 revertant (R11) completely recovered its capacity to inhibit transcription and to bind monoclonal antibody to epitope 1, whereas the M proteins of three other revertants remained restricted in their capacity to inhibit transcription and to bind monoclonal antibody to epitope 1. These studies indicate that exposure of epitope 1 on the surface of M protein is essential for inhibiting transcription by VSV RNP cores.
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PMID:Regulation of viral transcription by the matrix protein of vesicular stomatitis virus probed by monoclonal antibodies and temperature-sensitive mutants. 241 64

Of 33 hybridomas raised by immunization of BALB/c mice with the matrix (M) protein of the New Jersey serotype of vesicular stomatitis virus (VSV), 17 secreted monoclonal antibodies (mAb) of the IgG isotype and, unexpectedly, 16 of the IgM isotype. All these monoclonal antibodies bound strongly to VSV-New Jersey M protein by ELISA, immunoprecipitation, and immunoblotting assays, but exhibited only slight or no cross-reactivity with the M protein of VSV-Indiana. Four antigenic determinants of VSV-New Jersey M protein could be identified by competitive binding of 125I-labeled monoclonal antibodies but three of these epitopes exhibited partial overlap. Monoclonal antibodies to two epitopes reversed the inhibitory effect of M protein on in vitro transcription of VSV-New Jersey ribonucleoprotein. However, monoclonal antibodies to the other two epitopes had little effect on M-protein transcription inhibition but actually increased significantly the transcriptional inhibitory effect of M protein under certain experimental conditions. Monoclonal antibodies to all four epitopes reacted strongly with the M protein of the tsC1 mutant of VSV-New Jersey which is restricted in transcription inhibition.
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PMID:Monoclonal antibodies to the matrix protein of vesicular stomatitis virus (New Jersey serotype) and their effects on viral transcription. 241 13

Natural killer (NK) cells have the capability of lysing virus-infected, transformed, and embryonal cells, yet the nature of the target structure(s) recognized remains unclear. The availability of well-characterized temperature-sensitive (ts) mutants of vesicular stomatitis virus, defective in expression of individual viral-encoded polypeptides at the nonpermissive temperature (39 degrees C), offered an approach to elucidating NK-cell recognition of virus-infected cells. Target cells were infected with ts mutants in three functions: the viral surface glycoprotein (G protein; ts 045); the matrix (M) protein (ts G31, ts G33), and the polymerase (ts G11). Cells infected with wild-type virus and all ts mutants at the permissive temperature (31 degrees C) were killed by murine spleen cells. Similar to results on cytotoxic T lymphocytes, target cells infected by ts 045 defective in expression of G protein at 39 degrees C were not killed by NK cells. Unexpectedly, cells infected at 39 degrees C with the M-protein mutants also were not killed, although G protein was expressed at the cell surface. Target binding studies indicated that conjugates were not formed by cells infected with the ts mutants at the nonpermissive temperature. That expression of G protein was not sufficient for NK cell-mediated cytotoxicity was established in experiments in which a plasmid (pSVGL) containing the gene for vesicular stomatitis virus G protein was transfected into COS cells. Although G antigen was expressed on the plasma membrane, the cells were not lysed. These results suggest either that recognition of virus-infected cells depends on an appropriate conformation imparted to the viral G protein by association with the M protein or that NK cells can recognize alterations in the structure of the cell membrane induced by insertion of viral M and G molecules.
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PMID:Natural killer cell recognition of target cells expressing different antigens of vesicular stomatitis virus. 298 17

Sequences were determined of the coding regions of the M-protein genes of the Glasgow and Orsay strains of vesicular stomatitis virus (Indiana serotype) and of two group III (M-protein) mutants derived from each wild type. Synthetic primers were annealed with viral genomic RNA and extended with reverse transcriptase. The resulting high-molecular-weight cDNA was sequenced directly. Both Glasgow and Orsay wild types differed in 13 bases from a clone of the San Juan strain sequenced by J. K. Rose and C. J. Gallione (J. Virol. 39:519-528, 1981). Six of these base changes caused amino acid changes in each wild type, whereas seven were degenerate. The Orsay and Glasgow sequences resembled each other more closely than either resembled that of Rose and Gallione, differing in eight nucleotides and four amino acids. Each of the four mutants, however, differed from its parent wild type in only one or two point mutations. Every mutation caused a change either from or to a charged amino acid; the change for tsG31 was Lys (position 215) to Glu, the change for tsO23 was Gly (position 21) to Glu, the change for tsO89 was Ala (position 133) to Asp, the changes for tsG33 were Lys (position 204) to Thr and Glu (position 214) to Lys. The charge differences predicted from these amino acid changes was confirmed by nonequilibrium pH gradient electrophoresis for tsG31, tsG33, tsO23, and the two wild types. These mutations affect residues spanning nearly 85% of the linear sequence, although the mutants possess nearly identical phenotypic properties.
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PMID:Sequence alterations in temperature-sensitive M-protein mutants (complementation group III) of vesicular stomatitis virus. 299 21

A series of psoralen-derivatized oligodeoxyribonucleoside methylphosphonates were examined for their abilities to cross-link to DNA and RNA oligonucleotide targets. These targets were designed to have either a random coil or a hairpin structure in solution. The methylphosphonate oligomers cross-linked with approximately the same rates to the random coil DNA and RNA targets, although the extent of cross-linking to the DNA target was higher than that to the RNA target. For a given methylphosphonate sequence, cross-linking decreased as the temperature increased, and this behavior paralleled the interaction of the oligomer with the target as determined by ultraviolet melting experiments. The oligomers also cross-linked efficiently with the DNA hairpin target, but little or no cross-linking was observed with the RNA hairpin. In the case of these hairpin targets, the extent of cross-linking was dependent upon the location of the oligomer binding site relative to the stem and loop regions of the hairpin. The lack of reactivity with the RNA hairpin may be due to the high stability of the stem of this target versus that in the DNA target and the relatively lower efficiency of binding of the methylphosphonates to RNA versus DNA targets. The sequences of the oligomers are complementary to vesicular stomatitis virus M-protein mRNA. One of the oligomers was tested, and was found to cross-link at 20 degrees C to VSV N-mRNA to approximately the same extent as observed for cross-linking with the random coil RNA target, suggesting that the mRNA binding site for the oligomer most likely is in a somewhat open conformation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of target structure on cross-linking by psoralen-derivatized oligonucleoside methylphosphonates. 751 41

Transfection of mammalian CV1 cells with a recombinant M-gene pTM1 plasmid, driven by vaccinia virus-expressed phage T7 polymerase, resulted in the expression of matrix (M) protein, which is progressively released from the exterior surface of the transfected-cell plasma membrane. Exocytosis of M protein begins 2 to 4 h posttransfection and reaches a peak by 10 to 16 h posttransfection; dye uptake studies reveal that > 97% of cells are alive and have intact membranes at 16 h posttransfection. Density gradient centrifugation and labeling with radioactive palmitic acid revealed that the M protein is released from cells in association with lipid vesicles. Expression of M-gene deletion mutants suggests that exocytosis of M protein requires the presence of a membrane-binding site at N-terminal amino acids 1 to 50. Cells transfected with the pTM1 plasmid containing the M gene of the temperature-sensitive mutant tsO23 expressed ample quantities of the mutant M protein at permissive (31 degrees C) and restrictive (39 degrees C) temperatures, but the exocytosis of the mutant M protein occurred only at the permissive temperature. The tsO23 M gene has three site-specific mutations resulting in amino acid substitutions at residues 21, 111, and 227. Expression of wild-type and mutant M genes with mutations or revertants at each of these sites resulted in exocytosis of M protein at the nonpermissive temperature only when wild-type leucine was present at residue 111, but M-protein exocytosis was restricted (to some extent even at the permissive temperature) when mutant phenylalanine was present at residue 111. Past and present data indicate that a specific structural conformation of the M protein is responsible for the formation and budding of vesicles, a property of the M protein which probably also promotes vesicular stomatitis virus assembly and budding of virions from host cells.
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PMID:Membrane vesiculation function and exocytosis of wild-type and mutant matrix proteins of vesicular stomatitis virus. 770 43

We have prepared oligodeoxyribonucleotides that are modified at the 3'-terminal with N4-(4-aminobutyl)deoxycytidine and derivatized at the 5'-end with a 4'-([N-(aminoethyl)amino]methyl)-4,5',8-trimethylpsoralen, (ae)AMT, and whose sequences are complementary to vesicular stomatitis virus (VSV), N-protein mRNA, (ae)AMT-II, or VSV M-protein mRNA, (ae)AMT-III. (ae)AMT-II cross-links exclusively to VSV N-mRNA when a mixture of the oligomer and poly(A+) RNA from VSV-infected cells is irradiated in vitro with long wavelength UV light at either 20 degrees or 37 degrees C. N4-(4-Aminobutyl)deoxycytidine at the 3'-end of (ae)AMT-II does not appear to affect the binding or cross-linking of the oligomer to its target RNA. Oligomer (ae)AMT-II is completely resistant to hydrolysis by the 3'-5'-exonuclease activity found in fetal calf serum whereas a similar oligomer, (ae)AMT-I, which contains a 3'-terminal deoxycytidine, is hydrolyzed within 30 min when incubated at 37 degrees C. Intact (ae)AMT-II was found in both the cell lysate and cell culture medium after 12 hr of incubation with mouse L-cells along with d-(ae)AMTpT, which appears to result from endonuclease degradation of the oligomer. In contrast no intact (ae)AMT-I was found in either the cell lysate or the culture medium after 1 hr incubation. Although 10 microM (ae)AMT-II had no effect on VSV-protein synthesis in either unirradiated or UV-irradiated VSV-infected mouse L-cells, 10 microM (ae)AMT-III inhibited VSV protein synthesis 30% in irradiated cells. These results show that introduction of a N4-(4-aminobutyl)deoxycytidine at the 3'-end of an oligodeoxyribonucleotide significantly increases the resistance of the oligomer to degradation by 3'-5'-exonucleases but does not interfere with its ability to bind selectively to complementary RNA. Further derivatization with psoralen creates an oligomer that can be triggered to cross-link with RNA in a sequence-specific manner, is taken up intact by mammalian cells in culture, and exhibits biological activity. In combination, these two modifications endow the oligodeoxyribonucleotide with novel properties that could be exploited in the design of antisense or antigene reagents for use in controlling gene expression in mammalian cells.
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PMID:Properties of exonuclease-resistant, psoralen-conjugated oligodeoxyribonucleotides in vitro and in cell culture. 773 38


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