Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0019158 (hepatitis)
 30,205 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cellular receptor for the murine coronavirus mouse hepatitis virus (MHV) has been identified as a member of the murine carcinoembryonic antigen (CEA) family (R. K. Williams, G. S. Jiang, and K. V. Holmes, Proc. Natl. Acad. Sci. USA 88:5533-5536, 1991). However, the receptor protein was not detected in some of the susceptible mouse tissues. We therefore examined whether other types of MHV receptor might exist. By polymerase chain reaction with the conserved sequences of murine CEA gene family members (mmCGM) as primers, we detected two CEA-encoding RNAs in the mouse liver. One of them (1.3 kb) encodes mmCGM1, which has previously been identified as the receptor for MHV, and the other one (0.8 kb) was shown to encode another member of mouse CGM, mmCGM2. The sequence analysis showed that mmCGM2 lacks 564 nucleotides in the middle of the gene compared with mmCGM1. These two CEA transcripts are probably derived from the same gene by an alternative splicing mechanism. Expression of either of these cDNA clones in COS-7 cells rendered these cells susceptible to MHV infection, suggesting that not only mmCGM1 but also mmCGM2 serves as a receptor for MHV. The mmCGM2 was the major CEA species in the mouse brain, which is a main target organ for the neurotropic strains of MHV. Very little mmCGM1 was detected in the mouse brain or in cells of the susceptible mouse astrocytoma cell line DBT. This result indicates that MHV may utilize different CEA molecules as the major receptor in the mouse brain and in the liver. This is a first identification of multiple receptors for a single virus. The presence of different receptors in different tissues may explain the target cell specificity of certain MHVs.
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PMID:Mouse hepatitis virus utilizes two carcinoembryonic antigens as alternative receptors. 132 65

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.
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PMID:Membrane assembly of the triple-spanning coronavirus M protein. Individual transmembrane domains show preferred orientation. 140 May 1

Hepatocyte growth factor (HGF) is a most potent factor for mature parenchymal hepatocytes in primary culture and may act as a trigger for liver regeneration. We purified HGF from rat platelets to homogeneity and cloned both human and rat HGF cDNA. HGF is a heterodimer molecule composed of the 69 kDa alpha-subunit and the 34 kDa beta-subunit. HGF has no amino acid sequence homology with other known peptide growth factors and possesses the highest potential among known growth factors to stimulate proliferation of hepatocytes in primary culture. HGF is derived from a single chain precursor of 728 amino acid residues and the precursor is proteolytically processed to form a two-chain mature HGF. The alpha-subunit of HGF contains 4 kringle structures and HGF has a homology (38%) with plasmin. Biologically active recombinant human HGF could be expressed from COS-1 cells and CHO cells transfected with cloned cDNA. HGF activity and the HGF mRNA level are markedly increased in the liver following insult such as hepatitis, by the administration of hepatotoxins, ischaemia, physical damage and partial hepatectomy. Moreover, HGF mRNA is induced in the lung and kidney, in the presence of liver injury. In situ hybridization revealed that HGF-producing cells in liver are non-parenchymal liver cells, presumably Kupffer and sinusoidal endothelial cells. Therefore, HGF from neighbouring cells (Kupffer and sinsuoidal endothelial cells) and distal organs (lung and kidney) may function as a trigger for liver regeneration by both a paracrine mechanism and an endocrine mechanism. HGF has mitogenic activity for renal tubular epithelial cells, epidermal melanocytes and keratinocytes as well as mature hepatocytes, and has the potential to promote cell migration for some epithelial cells, including normal human keratinocytes. Since cell growth and cell motility are relevant to tissue repair and embryogenesis, HGF may well have important roles in tissue repair and embryogenesis as well as in liver regeneration.
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PMID:Hepatocyte growth factor: molecular structure and implications for a central role in liver regeneration. 183 43

Cloned cDNA encoding the membrane glycoprotein E1 of the coronavirus mouse hepatitis virus strain A59 was expressed transiently in a monkey fibroblast cell line (COS) by using a simian virus 40-based vector. As determined by indirect immunofluorescence microscopy, the E1 protein accumulated intracellularly in a perinuclear region coincident with a Golgi marker. The same three species of E1 that occur in virus-infected cells were also found in transfected cells. These are one unglycosylated form and two apparently O-glycosylated forms that could be labeled in a tunicamycin-resistant fashion with [3H]glucosamine. Because O glycosylation occurs posttranslationally in the Golgi apparatus, we could show, by monitoring the rate of acquisition of oligosaccharides, that the transport of E1 from the rough endoplasmic reticulum to the Golgi apparatus had a half time of between 15 and 30 min.
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PMID:Coronavirus E1 glycoprotein expressed from cloned cDNA localizes in the Golgi region. 303 31

The genetic origin, structure, and biochemical properties of the delta antigen (HDAg) of a human hepatitis delta virus (HDV) were investigated. A cDNA fragment containing the open reading frame encoding the HDAg was transcribed into RNA and used for in vitro translation in rabbit reticulocyte lysates. The HDAg open reading frame was also inserted into an expression vector containing a simian virus 40 T-antigen promoter and expressed into COS 7 cells. In both systems, a protein species of 26 kilodaltons was synthesized from this open reading frame and could be specifically immunoprecipitated with antisera obtained from patients with delta hepatitis. A similar protein was also synthesized from antigenomic-sense monomeric HDV RNA in both systems, although the efficiency of translation was lower than that of the isolated open reading frame. This protein was found to be phosphorylated at the serine residues. Immunoperoxidase studies with anti-HDV sera demonstrated that the HDAg was expressed mainly in the nuclei of the transfected COS 7 cells. Moreover, the HDAg was shown to bind the genomic RNA of HDV. These studies indicate that HDAg is encoded by the antigenomic-sense RNA of HDV and is a nuclear phosphoprotein associated with an RNA-binding activity.
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PMID:Human hepatitis delta antigen is a nuclear phosphoprotein with RNA-binding activity. 337 72

By using a new host-vector system, expression of the gene coding for hepatitis B surface antigen has been studied. A subgenomic fragment of cloned hepatitis B viral DNA was inserted into the plasmid vector pSV010. Transfection of COS cells with the recombinant plasmid vector containing hepatitis sequences leads to the synthesis of hepatitis B surface antigen, which is released in the culture medium in the form of 22-nm particles similar to those found in the sera of hepatitis carriers.
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PMID:Expression of hepatitis B virus surface antigen gene in cultured cells by using recombinant plasmid vectors. 629 4

Hepatitis delta virus is a satellite of the hepatitis B virus which provides the surface antigen for the viral coat. The genome of the hepatitis delta virus consists of a single-stranded, circular RNA of 1679 nucleotides which forms a rod structure due to a high extent of self homology and which replicates via synthesis of an antigenomic RNA in a rolling circle mechanism similar to plant viroids. The antigenomic RNA contains the open reading frame for the delta-antigen which exists in two isoforms, p24 and p27. The formation of these two isoforms is explained by RNA editing at nucleotide 1012 which changes the stop translation codon UAG at amino acid residue 196 into the codon UGG for tryptophan and extends the open reading frame for the synthesis of p27. In order to investigate whether the editing occurs cotranscriptionally during RNA replication or is a posttranscriptional base modification in the genomic or antigenomic RNA, replication defective deletion mutants of the HDV genome were constructed and expressed in COS-7 cells. Editing was demonstrated in non-replicating fragments of genomic HDV RNA but not in antigenomic HDV RNA fragments. The sequences from nucleotide position 337-1200 of the genomic RNA were sufficient to enable low levels of editing. Editing at position 1012 required the opposite strand of the RNA rod from nucleotide position 337-783. Replicating circular HDV RNA was much more efficiently edited than non-replicating full length genomic HDV RNA. Expression of delta-antigen in trans did not complement the low editing efficiency of replication defective genomic HDV RNA. These results demonstrate posttranscriptional U to C editing in the genomic HDV RNA and exclude misincorporation during HDV RNA replication as the editing mechanism. The minimal structural requirements for HDV RNA editing reside between nucleotide position 337-1200.
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PMID:Requirements for editing in the genomic RNA of hepatitis delta virus. 774 56

The termini of viral genomic RNA and its complementary strand are important in the initiation of viral RNA replication, which probably involves both viral and cellular proteins. To detect the possible cellular proteins involved in the replication of mouse hepatitis virus RNA, we performed RNA-protein binding studies with RNAs representing both the 5' and 3' ends of the viral genomic RNA and the 3' end of the negative-strand complementary RNA. Gel-retardation assays showed that both the 5'-end-positive- and 3'-end-negative-strand RNA formed an RNA-protein complex with cellular proteins from the uninfected cells. UV cross-linking experiments further identified a 55-kDa protein bound to the 5' end of the positive-strand viral genomic RNA and two proteins 35 and 38 kDa in size bound to the 3' end of the negative-strand cRNA. The results of the competition assay confirmed the specificity of this RNA-protein binding. No proteins were found to bind to the 3' end of the viral genomic RNA under the same conditions. The binding site of the 55-kDa protein was mapped within the 56-nucleotide region from nucleotides 56 to 112 from the 5' end of the positive-strand RNA, and the 35- and 38-kDa proteins bound to the complementary region on the negative-strand RNA. The 38-kDa protein was detected only in DBT cells but was not detected in HeLa or COS cells, while the 35-kDa protein was found in all three cell types. The juxtaposition of the different cellular proteins on the complementary sites near the ends of the positive- and negative-strand RNAs suggests that these proteins may interact with each other and play a role in mouse hepatitis virus RNA replication.
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PMID:Three different cellular proteins bind to complementary sites on the 5'-end-positive and 3'-end-negative strands of mouse hepatitis virus RNA. 823 Apr 43

We have previously reported that certain murine cell lines are susceptible to mouse hepatitis virus (MHV) A59 strain infection but resistant to JHM strain, despite the expression of the viral receptor for both strains. This restriction on viral infection has been shown to occur at the virus entry level (Yokomori et al., Virology 196, 45-56, 1993). To study whether JHM resistance of these cell lines is due to a defective cellular factor necessary for JHM virus entry, or due to the presence of an inhibitor, hybrid cells were obtained by polyethylene glycol (PEG)-mediated fusion between two resistant cell lines, i.e., a Balb/c mouse-derived cell line, BC10 cells, which are resistant to JHM infection but express a viral receptor, and the simian cell line COS cells, which are resistant to JHM because of the absence of the viral receptor. JHM could replicate in the hybrid BC10-COS cells, indicating that the restriction of viral infection in BC10 cells could be complemented by COS cells. This result indicates that the resistance of BC10 cells to JHM infection is due to the defectiveness of a cellular factor rather than the presence of an inhibitor. JHM virus-binding and penetration into BC10 cells appeared to be normal. However, JHM internalization into BC10 cells by PEG-induced virus-cell fusion did not lead to viral replication, suggesting that the restriction of JHM infection in BC10 cells is at the level of viral uncoating. This restriction could be complemented by PEG-mediated fusion with other murine cell lines which have the virion-uncoating activity, but not by cell lines which lack this activity. Furthermore, the viral resistance of most of other murine cell lines, which express MHV receptors, could not be overcome by fusion with COS cells, suggesting that different murine cell lines are defective in different viral entry functions. Therefore, we conclude that JHM viral entry process requires multiple cellular factors secondary to the viral receptor.
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PMID:Cell fusion studies identified multiple cellular factors involved in mouse hepatitis virus entry. 824 96

Previous studies have shown that some mouse strains are resistant to mouse hepatitis virus (MHV) infection despite the presence of functional viral receptors (K. Yokomori and M. M. C. Lai, J. Virol. 66, 6931-6938, 1992). To determine the molecular requirement for MHV infection, several cell lines derived from both susceptible and resistant mouse strains were tested for their ability to support infection by two different MHV strains, JHM and A59. Most of the cell lines tested, including ones from susceptible mouse strains, exhibited selective resistance to JHM, but were susceptible to A59, suggesting that there is an additional cellular factor(s) discriminating JHM from A59 infection. Both RNA and protein syntheses of JHM were inhibited in the resistant cells; however, transfection of JHM genomic RNA into these cells led to the production of infectious virus, suggesting that the restriction step(s) is during an early stage of viral replication cycle. The mRNA for the MHV receptor (the murine homolog of the carcinoembryonic antigen) is expressed in all cell lines, and expression in COS cells of the receptor isolated from the resistant murine cell lines rendered the COS cells susceptible to both A59 and JHM infections. Furthermore, the transfection of additional MHV receptors into the resistant cells did not overcome the resistance to JHM virus infection. These results suggested that the viral receptor is functional; nevertheless, the JHM infection is restricted at an early step of infection in these cells. The study of the growth properties of the various recombinant viruses between A59 and JHM revealed that one of the viral genes determining viral replication in these cell lines is the S protein gene; thus, the second factor required for viral infection may interact directly or indirectly with the S protein at an early step of infection. Taken together, these studies suggest that expression of a functional viral receptor is not sufficient to establish MHV infection, and that an additional factor(s) is required for an early step of viral infection, possibly during virus entry.
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PMID:A spike protein-dependent cellular factor other than the viral receptor is required for mouse hepatitis virus entry. 839 26


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