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Query: UMLS:C0019158 (
hepatitis
)
30,205
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Infection with coronavirus results in the accumulation of genomic-sized mRNA and six to eight subgenomic mRNAs that make up a 3' coterminal nested-set structure. Genome-length negative-strand RNA and subgenomic-length negative-strand RNAs, each of which corresponds to each of the subgenomic mRNAs, also accumulate in infected cells. The present study examined whether the genome-length negative-strand RNA serves as a template for subgenomic mRNA synthesis. Genome-length replicative intermediate (RI) RNA was purified by two-dimensional gel electrophoresis of intracellular RNAs from cells infected with mouse
hepatitis
virus.
RNase A
treatment of the purified genome-length RI resulted in the production of the genome-length replicative form RNA, indicating that the genome-length RI included genome-length template RNA.
RNase
protection assays using the purified genome-length RI and two probes, which corresponded to the 5' 300-nt region of mRNA 6 and to the same region of mRNA 7, showed the presence of nascent leader sequence-containing subgenomic mRNAs in the genome-length RI. These data demonstrated that the genome-length negative-strand RNA serves as a template for subgenomic mRNA synthesis.
...
PMID:Nascent synthesis of leader sequence-containing subgenomic mRNAs in coronavirus genome-length replicative intermediate RNA. 1099 22
In addition to the RI (replicative intermediate RNA) and native RF (replicative form RNA), mouse
hepatitis
virus-infected cells contained six species of RNA intermediates active in transcribing subgenomic mRNA. We have named these transcriptive intermediates (TIs) and native transcriptive forms (TFs) because they are not replicating genome-sized RNA. Based on solubility in high salt solutions, approximately 70% of the replicating and transcribing structures that accumulated in infected cells by 5-6 h post-infection were multi-stranded intermediates, the RI/TIs. The other 30% were in double-stranded structures, the native RF/TFs. These replicating and transcribing structures were separated by velocity sedimentation on sucrose gradients or by gel filtration chromatography on Sepharose 2B and Sephacryl S-1000, and migrated on agarose gels during electrophoresis, according to their size. Digestion with RNase T1 at 1-10 units/microgram RNA resolved RI/TIs into RF/TF cores and left native RF/TFs intact, whereas
RNase A
at concentrations of 0.02 microgram/microgram RNA or higher degraded both native RF/TFs and RI/TIs. Viral RI/TIs and native RF/TFs bound to magnetic beads containing oligo(dT)(25), suggesting that the poly(A) sequence on the 3' end of the positive strands was longer than any poly(U) on the negative strands. Kinetics of incorporation of [(3)H]uridine showed that both the RI and TIs were transcriptionally active and the labelling of RI/TIs was not the dead-end product of aberrant negative-strand synthesis. Failure originally to find TIs and TF cores was probably due to overdigestion with
RNase A
.
...
PMID:The RNA structures engaged in replication and transcription of the A59 strain of mouse hepatitis virus. 1116 Dec 78
An inducible in vitro cell culture system was developed to assay HCV replication by direct biochemical means. A transcription plasmid containing a T7 promoter at the 5' end, full-length cDNA of the HCV genome, a ribozyme sequence from the antigenomic strand of
hepatitis
delta virus and a T7 terminator was prepared. To facilitate high-level transcription of HCV RNA, HepG2 cells were infected with replication deficient adenovirus containing the T7 RNA polymerase gene and later transfected with the transcription plasmid containing the full-length HCV genome. This transfection-based cell culture system expressed high levels of HCV structural (core, El and E2) and non-structural proteins (NS3 and NS5B) detectable by Western blot and immunofluorescence assays. Production of HCV RNA transcripts and presence of replicative negative strand of HCV was confirmed by
ribonuclease
protection assay indicating replication of HCV in the transfected HepG2 cell. The transfected HepG2 cells assembled 50-60 nm virus-like particles, which could be aggregated by anti-E2 antibodies. This model can be utilized for studying mechanisms of HCV replication, assembly of HCV particles and to test potential anti-HCV compounds.
...
PMID:Inducible model to study negative strand RNA synthesis and assembly of hepatitis C virus from a full-length cDNA clone. 1133 40
Previously, we characterized two host protein binding elements located within the 3'-terminal 166 nucleotides of the mouse
hepatitis
virus (MHV) genome and assessed their functions in defective-interfering (DI) RNA replication. To determine the role of RNA secondary structures within these two host protein binding elements in viral replication, we explored the secondary structure of the 3'-terminal 166 nucleotides of the MHV strain JHM genome using limited
RNase
digestion assays. Our data indicate that multiple stem-loop and hairpin-loop structures exist within this region. Mutant and wild-type DIssEs were employed to test the function of secondary structure elements in DI RNA replication. Three stem structures were chosen as targets for the introduction of transversion mutations designed to destroy base pairing structures. Mutations predicted to destroy the base pairing of nucleotides 142 to 136 with nucleotides 68 to 74 exhibited a deleterious effect on DIssE replication. Destruction of base pairing between positions 96 to 99 and 116 to 113 also decreased DI RNA replication. Mutations interfering with the pairing of nucleotides 67 to 63 with nucleotides 52 to 56 had only minor effects on DIssE replication. The introduction of second complementary mutations which restored the predicted base pairing of positions 142 to 136 with 68 to 74 and nucleotides 96 to 99 with 116 to 113 largely ameliorated defects in replication ability, restoring DI RNA replication to levels comparable to that of wild-type DIssE RNA, suggesting that these secondary structures are important for efficient MHV replication. We also identified a conserved 23-nucleotide stem-loop structure involving nucleotides 142 to 132 and nucleotides 68 to 79. The upstream side of this conserved stem-loop is contained within a host protein binding element (nucleotides 166 to 129).
...
PMID:Secondary structural elements within the 3' untranslated region of mouse hepatitis virus strain JHM genomic RNA. 1171 1
Flock house virus (FHV) is a small icosahedral insect virus of the family Nodaviridae. Its genome consists of two positive-sense RNA molecules, RNA1 (replicase gene) and RNA2 (coat protein gene), which are encapsidated into a single virion. Expression of coat protein in Sf21 cells using a baculovirus vector results in formation of virus-like particles (VLPs) whose capsids are structurally indistinguishable from native virions. However, RNA packaging is not specific for RNA2, the coat protein message. Using
ribonuclease
protection assays, we showed that the fraction of RNA2 in VLPs is 19% relative to the amount present in a population of native virions. To investigate possible reasons for the reduced level of RNA2, we generated two new baculovirus vectors, AcR1delta and AcR2delta, expressing the replicase gene and the coat protein gene, respectively. The inserted genes carried the self-cleaving
hepatitis
delta ribozyme sequence at the 3' end to allow for synthesis of RNA1 and RNA2 transcripts with authentic 3' ends. Infection of Sf21 cells with AcR2delta yielded VLPs that contained 66% RNA2 relative to native virions. Coinfection of Sf21 cells with AcR1delta and AcR2delta launched self-directed FHV replication and resulted in formation of particles most of which contained RNA1 and RNA2. However, a small fraction of particles containing cellular RNA was detected as well. The latter particles could be eliminated by infecting Sf21 cells with AcR1delta followed by transfection with in vitro synthesized transcripts of RNA2. We have further utilized this system to show that two coat protein deletion mutants with distinct RNA packaging defects form mosaic virus capsids but do not complement each other to rescue specific packaging of FHV RNAs.
...
PMID:Analysis of RNA packaging in wild-type and mosaic protein capsids of flock house virus using recombinant baculovirus vectors. 1250 36
Most RNA viruses encode their own RNA polymerases for genome replication, and increasing numbers of them appear to be capable of undergoing RNA recombination. Here, we provide the first report of intergenotypic recombination in
hepatitis
delta virus (HDV), the only animal RNA virus that requires host RNA polymerase(s) for viral replication. In vivo, we analyzed RNA species derived from the serum of a patient with mixed genotype I and genotype IIb HDV infection by using multiple restriction fragment length polymorphism (RFLP) assays and sequence analysis of cloned reverse transcription (RT)-PCR products. Six HDV recombinants were isolated from 101 tested clones, and HDV recombination in this patient was further confirmed by RT-PCR with genotype-specific primer pairs. Analysis of the recombination junctions suggested that the HDV genome rearrangement occurred through faithful homologous recombination. We then used an RNA cotransfection cell culture system to investigate HDV RNA recombination in vitro. We found that HDV recombinants could indeed be detected in the transfected cells; some of these possessed recombination junctions identical to those identified in vivo. Furthermore, using a PCR-independent
RNase
protection assay, we were able to readily identify the recombined HDV RNA species in cultured cells. Taken together, our results demonstrate that HDV RNA recombination occurs in both natural HDV infections and cultured cells, thereby presenting a novel mechanism for HDV evolution.
...
PMID:RNA recombination of hepatitis delta virus in natural mixed-genotype infection and transfected cultured cells. 1568 24
The woodchuck together with the woodchuck
hepatitis
virus (WHV) is an excellent model to study the pathogenesis of hepadnaviral infections. Chronic WHV infection causes severe liver disease and hepatocellular carcinoma in woodchucks. The mechanism of viral clearance is not fully understood, interferons seem to play a major role in down-regulating viral replication prior to elimination of infected hepatocytes. We investigated on the pattern of cytokine and T-cell-marker expression in livers of woodchucks chronically infected with WHV.
RNase
-protection-assay (RPA) was used to determine mRNA of woodchuck specific genes (TNF-alpha, IFN-gamma, IL-15, CD3, CD4, CD8). Serial liver biopsies were performed daily or weekly in eight chronic WHV-carrier woodchucks. Cytokine/T-cell-marker expression differed significantly between the time points up to +/-50% within each woodchuck. The different expression patterns of cytokines or T-cell-markers did not correlate to the (weak) fluctuations in the viremia but may explain the observed fluctuations in the WHV/HBV-load in chronically infected individuals. Furthermore, we observed associations between cytokine and T-cell-marker expression. The marginal fluctuations in viremia during the chronic infection may indicate, that, once the chronic hepadnaviral infection is established, cytokines/interferons expressed endogenously (i.e. not vector-borne or injected) play only a minor role.
...
PMID:Fluctuation of the cytokine expression in the liver during the chronic woodchuck hepatitis virus (WHV) infection is not related to viral load. 1604 39
[Structure: see text]. Five naturally occurring nucleolytic ribozymes have been identified: the hammerhead, hairpin, glmS,
hepatitis
delta virus (HDV), and Varkud satellite (VS) ribozymes. All of these RNA enzymes catalyze self-scission of the RNA backbone using a chemical mechanism equivalent to that of
RNase A
.
RNase A
uses four basic strategies to promote this reaction: geometric constraints, activation of the nucleophile, transition-state stabilization, and leaving group protonation. In this Account, we discuss the current thinking on how nucleolytic ribozymes harness
RNase A
's four sources of catalytic power. The geometry of the phosphodiester cleavage reaction constrains the nucleotides flanking the scissile phosphate so that they are unstacked from a canonical A-form helix and thus require alternative stabilization. Crystal structures and mutational analysis reveal that cross-strand base pairing, along with unconventional stacking and tertiary hydrogen-bonding interactions, work to stabilize the splayed conformation in nucleolytic ribozymes. Deprotonation of the 2'-OH nucleophile greatly increases its nucleophilicity in the strand scission reaction. Crystal structures of the hammerhead, hairpin, and glmS ribozymes reveal the N1 of a G residue within hydrogen-bonding distance of the 2'-OH. In each case, this residue has also been shown to be important for catalysis. In the HDV ribozyme, a hydrated magnesium has been implicated as the general base. Catalysis by the VS ribozyme requires both an A and a G, but the precise role of either has not been elucidated. Enzymes can lower the energy of a chemical reaction by binding more tightly to the transition state than to the ground states. Comparison of the hairpin ground- and transition-state mimic structures reveal greater hydrogen bonding to the transition-state mimic structure, suggesting transition-state stabilization as a possible catalytic strategy. However, the hydrogen-bonding pattern in the glmS ribozyme transition-state mimic structure and the ground-state structures are equivalent. Protonation of the 5'-O leaving group by a variety of functional groups can promote the cleavage reaction. In the HDV ribozyme, the general acid is a conserved C residue. In the hairpin ribozyme, a G residue has been implicated in protonation of the leaving group. An A in the hammerhead ribozyme probably plays a similar role. In the glmS ribozyme, an exogenous cofactor may provide the general acid. This diversity is in contrast to the relatively small number of functional groups that serve as a general base, where at least three of the nucleolytic ribozymes may use the N1 of a G.
...
PMID:Catalytic strategies of self-cleaving ribozymes. 1865 94
Since the 1980s, several small RNA motifs capable of chemical catalysis have been discovered. These small ribozymes, composed of between approximately 40 and 200 nucleotides, have been found to play vital roles in the replication of subviral and viral pathogens, as well as in gene regulation in prokaryotes, and have recently been discovered in noncoding eukaryotic RNAs. All of the known natural small ribozymes - the hairpin, hammerhead,
hepatitis
delta virus, Varkud satellite, and glmS ribozymes--catalyze the same self-cleavage reaction as
RNase A
, resulting in two products, one bearing a 2'-3' cyclic phosphate and the other a 5'-hydroxyl group. Although originally thought to be obligate metalloenzymes like the group I and II self-splicing introns, the small ribozymes are now known to support catalysis in a wide variety of cations that appear to be only indirectly involved in catalysis. Nevertheless, under physiologic conditions, metal ions are essential for the proper folding and function of the small ribozymes, the most effective of these being magnesium. Metal ions contribute to catalysis in the small ribozymes primarily by stabilizing the catalytically active conformation, but in some cases also by activating RNA functional groups for catalysis, directly participating in catalytic acid-base chemistry, and perhaps by neutralizing the developing negative charge of the transition state. Although interactions between the small ribozymes and cations are relatively nonspecific, ribozyme activity is quite sensitive to the types and concentrations of metal ions present in solution, suggesting a close evolutionary relationship between cellular metal ion homeostasis and cation requirements of catalytic RNAs, and perhaps RNA in general.
...
PMID:Metal ions: supporting actors in the playbook of small ribozymes. 2201 Feb 72
Background. In situ hybridization (ISH) with high sensitivity has been requested to demonstrate hepatitis C virus (HCV) RNA in formalin-fixed, paraffin-embedded (FFPE) sections of the liver. Methods. ISH employing a locked-nucleic-acid- (LNA-)modified oligonucleotide probe and biotin-free catalyzed signal amplification system (CSAII) was applied to HCV-RNA detection in the liver tissue. Nested reverse-transcription polymerase chain reaction (RT-PCR) was performed for HCV genotyping using total RNA extracted from FFPE sections. The target tissues included FFPE tissue sections of humanized livers in HCV-infected chimeric mice (HCV genotypes 1a, 1b, and 2a and noninfected) and of needle-biopsied livers from HCV-infected patients. Results. HCV-RNA was demonstrated with the ISH technique in HCV-infected liver tissues from both chimeric mice and 9 (82%) of 11 patients with HCV infection. The HCV signals were sensitive to
RNase
. Nested RT-PCR confirmed the genotype in 8 (73%) of 11 livers (type 1b: 6 lesions and type 2a: 2 lesions). HCV-RNA was not identified in chronic hepatitis B lesions, fatty liver, autoimmune
hepatitis
, and hepatocellular carcinoma. Conclusion. ISH using the LNA-modified oligonucleotide probe and CSAII was applicable to detecting HCV-RNA in routinely prepared FFPE liver specimens.
...
PMID:Demonstration of hepatitis C virus RNA with in situ hybridization employing a locked nucleic Acid probe in humanized liver of infected chimeric mice and in needle-biopsied human liver. 2385 23
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