Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
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Target Concepts:
Gene/Protein
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Query: EC:2.7.7.48 (
transcriptase
)
9,479
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The double-stranded RNA (dsRNA) viruses of Saccharomyces cerevisiae consist of 4.5-kilobase-pair (kb) L species and 1.7- to 2.1-kb M species, both found in cytoplasmic viruslike particles (VLPs). The L species encode their own capsid protein, and one (LA) has been shown to encode a putative capsid-polymerase fusion protein (cap-pol) that presumably provides VLPs with their
transcriptase
and replicase functions. The M1 and M2 dsRNAs encode the K1 and K2 toxins and specific immunity mechanisms. Maintenance of M1 and M2 is dependent on the presence of LA, which provides capsid and cap-pol for M dsRNA maintenance. Although a number of different S. cerevisiae killers have been described, only K1 and K2 have been studied in any detail. Their secreted polypeptide toxins disrupt cytoplasmic membrane functions in sensitive yeast cells.
K28
, named for the wine S. cerevisiae strain 28, appears to be unique; its toxin is unusually stable and disrupts DNA synthesis in sensitive cells. We have now demonstrated that 4.5-kb L28 and 2.1-kb M28 dsRNAs can be isolated from strain 28 in typical VLPs, that these VLPs are sufficient to confer
K28
toxin and immunity phenotypes on transfected spheroplasts, and that the immunity of the transfectants is distinct from that of either M1 or M2. In vitro transcripts from the M28 VLPs show no cross-hybridization to denatured M1 or M2 dsRNAs, while L28 is an LA species competent for maintenance of M1.
K28
, encoded by M28, is thus the third unique killer system in S. cerevisiae to be clearly defined. It is now amenable to genetic analysis in standard laboratory strains.
...
PMID:K28, a unique double-stranded RNA killer virus of Saccharomyces cerevisiae. 220 3
Killer strains of the yeast Hanseniaspora uvarum contain cytoplasmic double-stranded RNAs (dsRNAs) of 4.7-kbp L and 1.0-kbp M species, which were shown to be separately packaged into icosahedral virus-like particles exhibiting
RNA-dependent RNA polymerase
activity. The L genome of the H. uvarum L-dsRNA virion HuV-L was shown to encode a 77-kDa major capsid protein. Peptide maps of the purified HuV coat protein and the 81-kDa major capsid protein from K1 killer viruses of Saccharomyces cerevisiae revealed distinctly different peptide patterns, suggesting significant sequence divergence at the level of the capsid-coding L-dsRNAs. In vitro transcripts from purified HuV-L particles showed no cross-hybridization to denatured L(A), L(B), or L(C), indicating that L from H. uvarum represents a unique L-dsRNA species. Weak, but clearly detectable cross-hybridization of the 1.0-kb dsRNA of HuV-M, encoding the secreted 18-kDa anti-Candida toxin, to the toxin-coding M genomes of S. cerevisiae K1, K2, and
K28
killers indicated partial sequence homology among all of the M-dsRNAs tested.
...
PMID:Unique double-stranded RNAs responsible for the anti-Candida activity of the yeast Hanseniaspora uvarum. 934 46
Yeast killer viruses are widely distributed in nature. Several toxins encoded in double-stranded RNA (dsRNA) satellites of the L-A totivirus have been described, including K1, K2,
K28
, and Klus. The 4.6-kb L-A genome encodes the Gag major structural protein that forms a 39-nm icosahedral virion and Gag-Pol, a minor fusion protein. Gag-Pol has
transcriptase
and replicase activities responsible for maintenance of L-A (or its satellite RNAs). Recently we reported a new killer toxin, Klus. The L-A virus in Klus strains showed poor hybridization to known L-A probes, suggesting substantial differences in their sequences. Here we report the characterization of this new L-A variant named L-A-lus. At the nucleotide level, L-A and L-A-lus showed only 73% identity, a value that increases to 86% in the amino acid composition of Gag or Gag-Pol. Two regions in their genomes, however, the frameshifting region between Gag and Pol and the encapsidation signal, are 100% identical, implying the importance of these two cis signals in the virus life cycle. L-A-lus shows higher resistance than L-A to growth at high temperature or to in vivo expression of endo- or exonucleases. L-A-lus also has wider helper activity, being able to maintain not only Mlus but also M1 or a satellite RNA of L-A called X. In a screening of 31 wine strains, we found that none of them had L-A; they carried either L-A-lus or a different L-A variant in K2 strains. Our data show that distinct M killer viruses are specifically associated with L-As with different nucleotide compositions, suggesting coevolution.
...
PMID:L-A-lus, a new variant of the L-A totivirus found in wine yeasts with Klus killer toxin-encoding Mlus double-stranded RNA: possible role of killer toxin-encoding satellite RNAs in the evolution of their helper viruses. 2372 12
Zika virus (ZIKV), a member of the Flaviviridae family, has emerged as a major public health threat, since ZIKV infection has been connected to microcephaly and other neurological disorders. Flavivirus genome replication is driven by NS5, an
RNA-dependent RNA polymerase
(RdRP) that also contains a N-terminal methyltransferase domain essential for viral mRNA capping. Given its crucial roles, ZIKV NS5 has become an attractive antiviral target. Here, we have used integrated structural biology approaches to characterize the supramolecular arrangement of the full-length ZIKV NS5, highlighting the assembly and interfaces between NS5 monomers within a dimeric structure, as well as the dimer-dimer interactions to form higher order fibril-like structures. The relative orientation of each monomer within the dimer provides a model to explain the coordination between MTase and RdRP domains across neighboring NS5 molecules and mutational studies underscore the crucial role of the MTase residues Y25,
K28
and K29 in NS5 dimerization. The basic residue
K28
also participates in GTP binding and competition experiments indicate that NS5 dimerization is disrupted at high GTP concentrations. This competition represents a first glimpse at a molecular level explaining how dimerization might regulate the capping process.
...
PMID:Supramolecular arrangement of the full-length Zika virus NS5. 3095 55
