UMLS:C0038362 - FACTA Search

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Query: UMLS:C0038362 (stomatitis)
8,852 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Previously, we reported that expression of the murine beta 2-microglobulinb (beta 2mb) antigenic epitopes defined by the mAb S19.8 and 23 (SJL [beta 2ma] anti-B10.S beta 2mb]) was dependent upon association of beta 2m with MHC class I heavy chains. We have further explored the antigenic properties of beta 2m under circumstances requiring the induction of MHC class I surface expression with heavy chain-specific peptide-ligand. For the RMA-S cell line, which is class I surface null due to a defect in the TAP-2 peptide transporter, treatment with the H-2Kb-specific vesicular stomatitis virus-derived N p52-59 peptide resulted in the cell surface expression of the epitopes defined by the anti-H-2Kb mAb Y-3, as well as equally strong expression of the epitopes defined by the anti-beta 2mb mAb S19.8 and 23. Similarly, the FLU-NP p366-374 peptide induced H-2Db on the surface of RMA-S cells as determined by cytofluorometry with the mAb MKQ8; however, expression of the epitope defined by S19.8 was only partially recovered and no reactivity was observed for mAb 23. That the H-2Db heavy chain was assembled with beta 2mb on the cell surface was established from immunoprecipitation experiments with 125I-surface-radiolabeled RMA-S cells treated with FLU-NP p366-374; MKQ8 immunoprecipitated prominent heavy chain and beta 2m bands, whereas S19.8 and 23 isolated a weak beta 2m band (12-15% of that co-immunoprecipitated with MKQ8). These results are consistent with the observation that human beta 2m-deficient cells (designated FO-1) transfected with the B2mb allele were induced, in combination with the endogenous HLA class I heavy chains, to express the epitope defined by S19.8, but not mAb 23, whereas both were expressed when contransfection was performed with the H-2Kb gene. That the determinants recognized by S19.8 and 23 were formed by a discontinuous cluster of amino acids within beta 2m was established from experiments demonstrating that H-2Kb heavy chain assembled with a chimeric beta 2m molecule (comprising human beta 2m from 1-69 and mouse beta 2m from amino acid 70-99, including the polymorphic residue Ala 85) did not lead to expression of the S19.8 and 23 epitopes. The results of this study provide evidence that heavy chain polymorphism can affect the antigenic properties of beta 2m and offer insight into the basis by which CTL may react against beta 2mb when assembled with the H-2Kb molecule.
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PMID:MHC class I heavy chain-dependent expression of discontinuous antigenic epitopes on beta 2-microglobulinb is inducible with peptide-ligand. 753 Aug 67

The phosphorylation of the P protein of vesicular stomatitis virus by cellular casein kinase II (CKII) is essential for its activity in viral transcription. Recent in vitro studies have demonstrated that CKII converts the inactive unphosphorylated form of P (P0) to an active phosphorylated form P1, after phosphorylation at two serine residues, Ser-59 and Ser-61. To gain insight into the role of CKII-mediated phosphorylation in the structure and function of the P protein, we have carried out circular dichroism (CD) and biochemical analyses of both P0 and P1. The results of CD analyses reveal that phosphorylation of P0 to P1 significantly increases the predicted alpha-helical structure of the P1 protein from 27 to 48%. The phosphorylation defective double serine mutant (P59/61), which is transcriptionally inactive, possesses a secondary structure similar to that of P0. P1, at a protein concentration of 50 micrograms/ml, elutes from a gel filtration column apparently as a dimer, whereas both P0 and the double serine mutant elute as a monomer at the same concentration. Interestingly, unlike wild-type P1 protein, the P mutants in which either Ser-59 or Ser-61 is altered to alanine required a high concentration of CKII for optimal phosphorylation. We demonstrate here that phosphorylation of either Ser-59 or Ser-61 is necessary and sufficient to transactivate L polymerase although alteration of one serine residue significantly decreases its affinity for CKII. We have also shown that P1 binds to the N-RNA template more efficiently than P0 and the formation of P1 is a prerequisite for the subsequent phosphorylation by L protein-associated kinase. In addition, mutant P59/61 acts as a transdominant negative mutant when used in a transcription reconstitution assay in the presence of wild-type P protein.
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PMID:Role of cellular casein kinase II in the function of the phosphoprotein (P) subunit of RNA polymerase of vesicular stomatitis virus. 759 11

The matrix (M) protein of vesicular stomatitis virus (VSV) plays a central role in virus assembly by binding the nucleocapsid core to the viral envelope during the budding process. A small percentage of M protein molecules are phosphorylated in vivo, but the role of phosphorylation in M protein function is unknown. Using limited proteolysis, we previously determined the sites of in vivo phosphorylation for VSV M protein to be Thr 31 (and possibly Ser 32) and a site N-terminal to position 19 (Ser 2, Ser 3, or Ser 17) (P. E. Kaptur et al., J. Virol. 66, 5384-5392, 1992). M protein mutants were constructed using site-directed mutagenesis by substituting Ala for Ser or Thr at these sites in the M gene of the San Juan strain of VSV. One mutant had substitutions at the major in vivo phosphorylation site(s) at positions 31 and 32 (M31.32) while two others had additional substitutions at positions 2 and 3 (M2.3.31.32) or at position 17 (M17.31.32). Mutant M proteins were expressed in BHK cells using the vaccinia/T7 system, radiolabeled with 32Pi, and then analyzed for 32P content by PAGE and autoradiography. The data show that the site of phosphorylation near the N-terminus is at Ser 2 or 3 and not Ser 17. Further, Ser 38 was not phosphorylated. Mutation of the major phosphorylation site enhanced phosphorylation at alternative sites in the M protein C-terminal to amino acid 43 and at Ser residues 2 and 3. Mutant M proteins were tested for their ability to complement growth of the temperature-sensitive M protein mutant virus tsO23 at the nonpermissive temperature. Mutant M2.3.31.32 was further tested for its ability to assemble into VSV-defective interfering (DI) particles, using a replication system in which the DI genome and all five VSV proteins were expressed from plasmid DNA. Assembly of tsO23 virions or DI particles in the presence of mutant M proteins was similar to that observed for wild-type M proteins. These data indicate that phosphorylation of M protein at the major in vivo sites is not essential for virus assembly.
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PMID:Assembly functions of vesicular stomatitis virus matrix protein are not disrupted by mutations at major sites of phosphorylation. 785 2

A class of integral membrane glycoproteins specific to lysosomes has been identified, and they are classified into two separate groups depending on whether or not their cytoplasmic sequence contains a tyrosine residue. Lamp-1 and lamp-2 have a tyrosine-containing motif in their cytoplasmic segments, and this motif was found to direct the glycoproteins to lysosomes. Limp II glycoprotein, on the other hand, lacks a tyrosine in its cytoplasmic segment and it must be directed to lysosomes by a different signal (Fukuda, M. (1991) J. Biol. Chem. 266, 21327-21330). In order to elucidate the targeting signal of Limp II, a cDNA encoding its cytoplasmic segment was fused with a reporter molecule, a chimeric protein of human gonadotropin alpha chain-vesicular stomatitis G-protein transmembrane. After various mutations its expression was examined by immunofluorescence. First it was shown that a chimeric protein with a Limp II wild-type tail is transported to lysosomes. Deletion of the three amino acids of the cytoplasmic tail at the carboxyl terminus abolished this sorting to lysosomes. Substitution of individual amino acids revealed that the Leu-Ile motif in the Leu-Ile-Arg-Thr sequence at the carboxyl terminus is crucial to the sorting signal. When this motif was brought closer to the transmembrane domain by deletion of nine amino acids next to the transmembrane domain, this sorting function was abolished. In addition, substitution of alanine for the serine, which is at 5 residues from the transmembrane also abolished the sorting capacity, although there was no evidence that the phosphorylation of serine is involved in sorting. Altered proteins that were not transported to lysosomes were found to accumulate at the cell surface and, unlike proteins with a wild-type cytoplasmic tail, were unable to undergo endocytosis. These results indicate that the carboxyl-terminal amino acid sequence, including the Leu-Ile motif and the sequence that connects the motif to the transmembrane domain, is critical for the sorting of Limp II to lysosomes.
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PMID:Lysosomal targeting of Limp II membrane glycoprotein requires a novel Leu-Ile motif at a particular position in its cytoplasmic tail. 810 3

Investigations in newborns, children and young adults have revealed an inverse proportion between aminoaciduria and plasma hemoglobin (Hb) levels. Values above normal were recorded for alanine, leucine, valine, phenylalanine and glutamic acid, correlating proportionally with their increased blood levels, and preceding or being concomitant with the decrease of plasma Hb, both during the first 20 months of life and in young adults. The return to near normal values of aminoaciduria occurred generally only after an early treatment with minerals, vitamins and trace elements (Supradyn), activators of the enzymes involved in the amino acid metabolism. After treatment, the Hb levels also became almost normal. An early re-equilibration of the amino acid metabolism can prevent the risk of developing, at the adult age, certain anemias and other diseases (rachitism, mental handicap, urinary infections, conjunctivitis, stomatitis, a.o.). The correlation factor was r = 0.964 and the differences between the data recorded in patients and in controls were statistically significant (p < 0.01).
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PMID:The relationship between aminoaciduria and plasma hemoglobin levels. 813 Jul 61

The envelope glycoprotein G of vesicular stomatitis virus induces membrane fusion at low pH. Site-directed mutagenesis of specific amino acids within a segment spanning amino acids 123 to 137 of G protein, which is highly conserved in vesiculoviruses and was previously shown by us to be involved in fusogenic activity (Y. Li, C. Drone, E. Sat, and H. P. Ghosh, J. Virol. 67:4070-4077, 1993), was used to determine the role of this region in low-pH-induced membrane fusion. The mutant glycoproteins expressed in COS cells were assayed for acid-pH-induced cell-cell fusion. Substitution of the variant Pro-123 with Leu had no effect on the fusogenic activity, while substitution of conserved Phe-125 and Asp-137 with Tyr and Asn, respectively, shifted the pH optimum of membrane fusion to a more acidic pH value and decreased the fusion efficiency. The deletion of amino acid residues 124 to 127, 131 to 137, or 124 to 137 produced mutants defective in transport. Mutation of the conserved residues Gly-124 and Pro-127 to Ala and to Gly or Leu, respectively, inhibited cell-cell fusion activity by about 90% without affecting transport of the mutant proteins to the cell surface, suggesting that these two residues may be present within the fusion peptide and thus may be directly involved in fusion. This highly conserved domain containing neutral amino acids of G protein may therefore represent the putative fusion domain of vesicular stomatitis virus G protein.
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PMID:Characterization of the putative fusogenic domain in vesicular stomatitis virus glycoprotein G. 813 3

As a subunit of both the P-L polymerase complex and the P-N assembly complex, the vesicular stomatitis virus (VSV) P protein plays a pivotal role in transcription and replication of the viral genome. Constitutive phosphorylation of this protein is currently thought to be essential for formation of the P-L complex. We recently identified the three relevant phosphate acceptor sites in the VSV Indiana serotype P protein (R. L. Jackson, D. Spadafora, and J. Perrault, Virology 214:189-197, 1995). We now report the effects of substituting Ala at these acceptor sites on transcription reconstitution in vitro and replication of defective interfering virus (DI) templates in vivo. The singly substituted S60A, T62A, and S64A mutants and the doubly substituted S60A/T62A and T62A/S64A mutants, all of which retain some constitutive phosphorylation, were nearly as active as the wild type in both assays. Surprisingly, the nonphosphorylated S60A/S64A protein was also active in transcription (> or = 28%)) and replication (> or = 50%) under optimal conditions. However, this mutant was much less active in in vitro transcription (< or = 5% of wild type) at low P concentrations (<27 nM). In addition, S60A/S64A required higher concentrations of L protein than did the wild type for optimal DI replication in vivo. DI replication efficiency and intracellular accumulation of L, P, and N proteins in the transfected system were very similar to those in VSV-infected cells. We conclude that P protein constitutive phosphorylation is not essential for VSV RNA synthesis per se but likely plays an important role in vivo in facilitating P multimerization and possibly P-L complex formation.
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PMID:Constitutive phosphorylation of the vesicular stomatitis virus P protein modulates polymerase complex formation but is not essential for transcription or replication. 867 80

Human MxA protein is an interferon-induced 76-kDa GTPase that exhibits antiviral activity against several RNA viruses. Wild-type MxA accumulates in the cytoplasm of cells. TMxA, a modified form of wild-type MxA carrying a foreign nuclear localization signal, accumulates in the cell nucleus. Here we show that MxA protein is translocated into the nucleus together with TMxA when both proteins are expressed simultaneously in the same cell, demonstrating that MxA molecules form tight complexes in living cells. To define domains important for MxA-MxA interaction and antiviral function in vivo, we expressed mutant forms of MxA together with wild-type MxA or TMxA in appropriate cells and analyzed subcellular localization and interfering effects. An MxA deletion mutant, MxA(359-572), formed heterooligomers with TMxA and was translocated to the nucleus, indicating that the region between amino acid positions 359 and 572 contains an interaction domain which is critical for oligomerization of MxA proteins. Mutant T103A with threonine at position 103 replaced by alanine had lost both GTPase and antiviral activities. T103A exhibited a dominant-interfering effect on the antiviral activity of wild-type MxA rendering MxA-expressing cells susceptible to infection with influenza A virus, Thogoto virus, and vesicular stomatitis virus. To determine which sequences are critical for the dominant-negative effect of T103A, we expressed truncated forms of T103A together with wild-type protein. A C-terminal deletion mutant lacking the last 90 amino acids had lost interfering capacity, indicating that an intact C terminus was required. Surprisingly, a truncated version of MxA representing only the C-terminal half of the molecule exerted also a dominant-negative effect on wild-type function, demonstrating that sequences in the C-terminal moiety of MxA are necessary and sufficient for interference. However, all MxA mutants formed hetero-oligomers with TMxA and were translocated to the nucleus, indicating that physical interaction alone is not sufficient for disturbing wild-type function. We propose that dominant-negative mutants directly influence wild-type activity within hetero-oligomers or else compete with wild-type MxA for a cellular or viral target.
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PMID:Dominant-negative mutants of human MxA protein: domains in the carboxy-terminal moiety are important for oligomerization and antiviral activity. 906 Jun 10

Members of the Bunyaviridae family mature by a budding process in the Golgi complex. The site of maturation is thought to be largely determined by the accumulation of the two spike glycoproteins, G1 and G2, in this organelle. Here we show that the signal for localizing the Uukuniemi virus (a phlebovirus) spike protein complex to the Golgi complex resides in the cytoplasmic tail of G1. We constructed chimeric proteins in which the ectodomain, transmembrane domain (TMD), and cytoplasmic tail (CT) of Uukuniemi virus G1 were exchanged with the corresponding domains of either vesicular stomatitis virus G protein (VSV G), chicken lysozyme, or CD4, all proteins readily transported to the plasma membrane. The chimeras were expressed in HeLa or BHK-21 cells by using either the T7 RNA polymerase-driven vaccinia virus system or the Semliki Forest virus system. The fate of the chimeric proteins was monitored by indirect immunofluorescence, and their localizations were compared by double labeling with markers specific for the Golgi complex. The results showed that the ectodomain and TMD (including the 10 flanking residues on either side of the membrane) of G1 played no apparent role in targeting chimeric proteins to the Golgi complex. Instead, all chimeras containing the CT of G1 were efficiently targeted to the Golgi complex and colocalized with mannosidase II, a Golgi-specific enzyme. Conversely, replacing the CT of G1 with that from VSV G resulted in the efficient transport of the chimeric protein to the cell surface. Progressive deletions of the G1 tail suggested that the Golgi retention signal maps to a region encompassing approximately residues 10 to 50, counting from the proposed border between the TMD and the tail. Both G1 and G2 were found to be acylated, as shown by incorporation of [3H]palmitate into the viral proteins. By mutational analyses of CD4-G1 chimeras, the sites for palmitylation were mapped to two closely spaced cysteine residues in the G1 tail. Changing either or both of these cysteines to alanine had no effect on the targeting of the chimeric protein to the Golgi complex.
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PMID:A retention signal necessary and sufficient for Golgi localization maps to the cytoplasmic tail of a Bunyaviridae (Uukuniemi virus) membrane glycoprotein. 915 65

Phosphorylation by casein kinase II at three specific residues (S-60, T-62, and S-64) within the acidic domain I of the P protein of Indiana serotype vesicular stomatitis virus has been shown to be critical for in vitro transcription activity of the viral RNA polymerase (P-L) complex. To examine the role of phosphorylation of P protein in transcription as well as replication in vivo, we used a panel of mutant P proteins in which the phosphate acceptor sites in domain I were substituted with alanines or other amino acids. Analyses of the alanine-substituted mutant P proteins for the ability to support defective interfering RNA replication in vivo suggest that phosphorylation of these residues does not play a significant role in the replicative function of the P protein since these mutant P proteins supported replication at levels > or = 70% of the wild-type P-protein level. However, the transcription function of most of the mutant proteins in vivo was severely impaired (2 to 10% of the wild-type P-protein level). The level of transcription supported by the mutant P protein (P(60/62/64)) in which all phosphate acceptor sites have been mutated to alanines was at best 2 to 3% of that of the wild-type P protein. Increasing the amount of P(60/62/64) expression in transfected cells did not rescue significant levels of transcription. Substitution with other amino acids at these sites had various effects on replication and transcription. While substitution with threonine residues (P(TTT)) had no apparent effect on transcription (113% of the wild-type level) or replication (81% of the wild-type level), substitution with phenylalanine (P(FFF)) rendered the protein much less active in transcription (< 5%). Substitution with arginine residues led to significantly reduced activity in replication (6%), whereas glutamic acid substituted P protein (P(EEE)) supported replication (42%) and transcription (86%) well. In addition, the mutant P proteins that were defective in replication (P(RRR)) or transcription (P(60/62/64)) did not behave as transdominant repressors of replication or transcription when coexpressed with wild-type P protein. From these results, we conclude that phosphorylation of domain I residues plays a major role in in vivo transcription activity of the P protein, whereas in vivo replicative function of the protein does not require phosphorylation. These findings support the contention that different phosphorylated states of the P protein regulate the transcriptase and replicase functions of the polymerase protein, L.
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PMID:Phosphorylation within the amino-terminal acidic domain I of the phosphoprotein of vesicular stomatitis virus is required for transcription but not for replication. 934 67

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