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Disease
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Drug
Enzyme
Compound
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Target Concepts:
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Query: UMLS:C0149514 (
bronchitis
)
6,902
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have found six major polypeptides in virions of the avian coronavirus infectious
bronchitis
virus grown in tissue culture: four glycoproteins, GP84, GP36, GP31, and GP28, and two non-glycosylated proteins, P51 and
P23
. In addition, we detected three minor species: two glycoproteins, GP90 and GP59, and one non-glycosylated protein, P14. Two-dimensional tryptic peptide mapping showed that GP36, GP31, GP28, and
P23
comprise a group of closely related proteins which we have designated the "P23 family," but that the other proteins are distinct. Analysis by partial proteolytic digestion of
P23
family, but that the other proteins are distinct. Analysis by partial proteolytic digestion of the
P23
family labeled biosynthetically with [35S] methionine, and
P23
, labeled with [35S] formyl-methionine by in vitro translation of RNA from infected cells, revealed that the proteins of the
P23
family differ in their amino-terminal domains. Similar analysis of GP31 and Gp36 labeled with [3H] mannose showed that the partial proteolytic fragments unique to these proteins were glycosylated. This suggests that differences in glycosylation in the amino-terminal domains contributes to the marked polymorphism os the
P23
family. The results are discussed with respect to possible models for synthesis of the virion proteins.
...
PMID:Structural analysis of virion proteins of the avian coronavirus infectious bronchitis virus. 628 41
We examined the synthesis of viral structural proteins in cultured cells infected with the avian coronavirus infectious
bronchitis
virus. Tryptic peptide mapping was used to determine the structural relationships of the intracellular proteins to the virion polypeptides. Pulse-chase experiments were performed to identify precursors to the virus-specific proteins. We found that the nucleocapsid protein, P51, and the small viral membrane proteins GP31, GP28, and
P23
do not undergo post-translational proteolytic processing. In contrast, GP90 and GP84, the two large virion membrane proteins, were found to be produced by cleavage of a single precursor, GP155. This demonstrated that at least one coronavirus mRNA specifies two virion proteins.
...
PMID:Coronavirus proteins: biogenesis of avian infectious bronchitis virus virion proteins. 629 29
The recent finding that the E1 glycoproteins of murine coronaviruses contain only O-linked oligosaccharides suggested that this unusual modification might be a distinguishing feature of coronaviruses and might play an essential role in the life cycle of this family of viruses. To examine these possibilities, we analyzed the oligosaccharide moieties of the membrane proteins of the avian coronavirus infectious
bronchitis
virus. In addition, we determined the effect of inhibiting the glycosylation of these proteins on viral maturation and infectivity. Infectious
bronchitis
virus virions contain nine proteins. Four of these proteins, GP36, GP31, GP28, and
P23
, are closely related structurally and appear to be homologous to the E1 proteins of murine coronaviruses. We found that the oligosaccharides of GP31 and GP28 could be removed with endoglycosidase H and that neither of these glycoproteins was detectable in tunicamycin-treated cells. These two results indicated that GP31 and GP28 contain N-linked oligosaccharides. Therefore, O-linked oligosaccharides are not a universal feature of the small coronavirus membrane glycoproteins. Tunicamycin inhibited glycosylation of all of the viral glycoproteins but did not inhibit production of virions by infectious
bronchitis
virus-infected cells. The virions released by these cells contained only the three non-glycosylated viral proteins P51,
P23
, and P14. These particles were not infectious. Therefore, it appears that glycosylated infectious
bronchitis
virus polypeptides are not required for particle formation. However, the viral glycoproteins are apparently indispensible for viral infectivity.
...
PMID:Coronavirus proteins: structure and function of the oligosaccharides of the avian infectious bronchitis virus glycoproteins. 629 30
Six overlapping viral RNAs are synthesized in cells infected with the avian coronavirus infectious
bronchitis
virus (IBV). These RNAs contain a 3'-coterminal nested sequence set and were assumed to be viral mRNAs. The seven major IBV virion proteins are all produced by processing of three polypeptides of ca. 23, 51, and 115 kilodaltons. These are the core polypeptides of the small membrane proteins, the nucleocapsid protein, and the 155-kilodalton precursor to the large membrane proteins GP90 and GP84, respectively. To determine which mRNAs specify these polypeptides, we isolated RNA from infected cells and translated it in a messenger-dependent rabbit reticulocyte lysate. Proteins of 23, 51, and 110 kilodaltons were produced. Two-dimensional tryptic peptide mapping demonstrated that these proteins were closely related to the major virion proteins. Fractionation of the RNA before cell-free translation permitted the correlation of messenger activities for synthesis of the proteins with the presence of specific mRNAs. We found that the smallest RNA, RNA A, directs the synthesis of P51, the nucleocapsid protein. RNA C, which contains the sequences of RNA A, directs the synthesis of the small membrane protein
P23
. RNA E directs the synthesis of the large virion glycoproteins. These results supported a model in which only the unique 5'-terminal domain of each IBV mRNA is active in translation and enabled us to localize genes for virion proteins on the IBV genome.
...
PMID:Coronavirus multiplication: locations of genes for virion proteins on the avian infectious bronchitis virus genome. 632 90
