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Query: UMLS:C0019158 (
hepatitis
)
30,205
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Both genomic and subgenomic replicative intermediates (RIs) and replicative-form (RF) structures were found in 17CL1 mouse cells that had been infected with the A59 strain of mouse
hepatitis
virus (MHV), a prototypic coronavirus. Seven species of RNase-resistant RF RNAs, whose sizes were consistent with the fact that each was derived from an RI that was engaged in the synthesis of one of the seven MHV positive-strand RNAs, were produced by treatment with
RNase A
. Because the radiolabeling of the seven RF RNAs was proportional to that of the corresponding seven positive-strand RNAs, the relative rate of synthesis of each of the MHV positive-strand RNAs may be controlled by the relative number of each of the size classes of RIs that are produced. In contrast to alphavirus, which produced its subgenome-length RF RNAs from genome-length RIs, MHV RF RNAs were derived from genome- and subgenome-length RIs. Only the three largest MHV RF RNAs (RFI, RFII, and RFIII) were derived from the RIs that migrated slowest on agarose gels. The four smallest RF RNAs (RFIV, RFV, RFVI, and RFVII) were derived from RIs that migrated in a broad region of the gel that extended from the position of 28S rRNA to the position of the viral single-stranded MHV mRNA-3. Because all seven RIs were labeled during very short pulses with [3H]uridine, we concluded that the subgenome-length RIs are transcriptionally active. These findings, with the recent report of the presence of subgenome-length negative-strand RNAs in cells infected with porcine transmissible gastroenteritis virus (P. B. Sethna, S.-L. Hung, and D. A. Brian, Proc. Natl. Acad. Sci. USA 86: 5626-5630, 1989), strongly suggest that coronaviruses utilize a novel replication strategy that employs the synthesis of subgenomic negative strands to produce subgenomic mRNAs.
...
PMID:Coronavirus transcription: subgenomic mouse hepatitis virus replicative intermediates function in RNA synthesis. 215 91
The
hepatitis
delta virus can be found in the serum and liver of some hepatitis B virus patients. We now report that the RNA genome of serum-derived delta virus is single-stranded and circular. Livers of infected chimpanzees or woodchucks contained as many as 300,000 copies of genomic strand RNA per average cell, and at least some of this RNA had a circular conformation. Also present in the livers were RNA species complementary to the virion RNA. The genomic RNA was 5-22 times more abundant than this antigenomic strand. Some of the antigenomic RNA was complexed with genomic RNA, as evidenced by the fact that at least 34% of the antigenomic RNA was resistant to digestion with either
RNase A
in 0.3 M NaCl or S1 nuclease. Some of the antigenomic RNA was in a circular conformation. These and other findings showed that the structure and replication of
hepatitis
delta virus are in many ways similar to those of the previously described plant viroids, virusoids, and satellite RNAs.
...
PMID:Structure and replication of the genome of the hepatitis delta virus. 243 Feb 99
Physico-chemical and biological properties of an interferon inducer, a natural double-stranded RNA (dsRNA) obtained from RNA-genome bacteriophage-infected E. coli are described. Three independent methods i.e. sedimentation analysis, gel chromatography, and direct measurement of electronograms, were used to determine an average length of dsRNA molecules which was found to correspond to about 432 nucleotide pairs. dsRNA melting temperature in 0.15 M NaCl is 103 degrees C, and the resistance to
RNase A
is above 85%. Additional purification of the preparation by the methods eliminating bacterial endotoxin and other possible admixtures does not decrease acute toxicity of dsRNA. The influence of dsRNA on the cytolytic activity of natural killers (NK) in normal subjects and patients with viral diseases of the liver was demonstrated. dsRNA enhances the activity of NK in normal subjects as well as in patients with acute virus hepatitis B in the abatement stage of the disease and in patients with chronic persisting
hepatitis
. At the peak of acute virus hepatitis B NK stimulation was detected in only 40 +/- 16% of the patients. In patients with chronic active liver diseases dsRNA enhanced NK activity in 50 +/- 22% of cases. A similar effect on NK cell activity is exerted by human leukocyte interferon.
...
PMID:[Physicochemical and biological properties of double-stranded RNA--an interferon inducer]. 620 91
Mouse hepatitis virus A59 codes for seven mRNAs in infected cells. These mRNAs are transcribed from a minus (-) strand template of genome length and contain a leader RNA at their 5' ends. To further elucidate the mechanism of coronavirus transcription, we examined the structure of mouse
hepatitis
virus replicative intermediates (RIs) isolated by 2 M NaCl precipitation and Sepharose 2-B column chromatography. Purified RIs migrated as a single species on agarose gels and sedimented between 12 and 38S on 10 to 25% sucrose gradients. The complexes were readily heat denatured into a heterogeneous population of smaller RNA molecules which probably represent nascent plus (+) strands.
RNase A
digestion of RIs produced a single replicative form which sedimented between 30 and 32S. These data suggest that the RI is composed of a single genome-sized (-) strand hydrogen bonded to an average of 4 to 6.5 nascent (+) strands. In contrast, a column-purified replicative form was extremely resistant to
RNase A
digestion and heat denaturation and migrated as a single RNA species on agarose gels and sucrose gradients. Oligonucleotide fingerprinting of an RI revealed the presence of the 5' leader RNA on the nascent (+) strands. In addition, an average of 6.2 cap structures were present in each RI, which agrees with the average number of nascent (+) strands per RI. These data suggest that the leader RNA is utilized as a primer for mouse
hepatitis
virus RNA transcription and is not added to mRNA post-transcriptionally.
...
PMID:Characterization of replicative intermediate RNA of mouse hepatitis virus: presence of leader RNA sequences on nascent chains. 631 63
Antibodies (Abs) hydrolyzing proteins, DNA, and RNA are detected in the blood of patients with various autoimmune diseases. In the present work, homogeneous preparations of IgG Abs from the blood of the healthy donors as well as patients with A, B, C, and delta types of viral hepatitis, influenza, pneumonia, tuberculosis, tonsillitis, duodenal ulcer, and some types of cancer were purified. For the first time, the fraction of IgG and its Fab fragments of patients with viral hepatitis were shown to have high DNA- and RNA-hydrolyzing activity. In case of Abs from the healthy donors and patients with other diseases, high activity of Abs was not detected. The data obtained by various methods indicate that the activity of
hepatitis
Abs is an intrinsic property of the immunoglobulins. The relative rates of hydrolysis of cCMP, poly(U), poly(A), poly(C), and tRNA(Phe) by
hepatitis
Abs were compared with those of
RNase A
and other RNases from human blood. Significant differences in activities of Abs and nucleases in hydrolysis of model substrates were demonstrated. Thus, catalytically active Abs can appear in the blood of patients not only with autoimmune disorders, but with viral diseases as well.
...
PMID:DNA- and RNA-hydrolyzing antibodies from the blood of patients with various forms of viral hepatitis. 948 69
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
[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
RNA catalysis is of fundamental importance to biology and yet remains ill-understood due to its complex nature. The multidimensional "problem space" of RNA catalysis includes both local and global conformational rearrangements, changes in the ion atmosphere around nucleic acids and metal ion binding, dependence on potentially correlated protonation states of key residues, and bond breaking/forming in the chemical steps of the reaction. The goal of this chapter is to summarize and apply multiscale modeling methods in an effort to target the different parts of the RNA catalysis problem space while also addressing the limitations and pitfalls of these methods. Classical molecular dynamics simulations, reference interaction site model calculations, constant pH molecular dynamics (CpHMD) simulations, Hamiltonian replica exchange molecular dynamics, and quantum mechanical/molecular mechanical simulations will be discussed in the context of the study of RNA backbone cleavage transesterification. This reaction is catalyzed by both RNA and protein enzymes, and here we examine the different mechanistic strategies taken by the
hepatitis
delta virus ribozyme and
RNase A
.
...
PMID:Multiscale methods for computational RNA enzymology. 2572 72
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