Showing papers on "RNA-dependent RNA polymerase published in 1989"

Transcription-based amplification system and detection of amplified human immunodeficiency virus type 1 with a bead-based sandwich hybridization format

Abstract: The in vitro amplification of biologically important nucleic acids has proceeded principally by a strategy of DNA replication. Polymerase chain reaction was the first such protocol to achieve this goal. In this report, a transcription-based amplification system (TAS) is described. Each cycle of the TAS is composed of two steps. The first is a cDNA synthesis step that produces one copy of a double-stranded DNA template for each copy of RNA or DNA target nucleic acid. During the course of this cDNA synthesis step, a sequence recognized by a DNA-dependent RNA polymerase is inserted into the cDNA copy of the target sequence to be amplified. The second step is the amplification of the target sequence by the transcription of the cDNA template into multiple copies of RNA. This procedure has been applied to the detection of human immunodeficiency virus type 1 (HIV-1)-infected cells. After four cycles of TAS, the amplification of the vif region of the HIV-1 RNA genome was measured to be, on the average, 38- to 47-fold per cycle, resulting in a 2-5 x 10(6)-fold increase in the copy number of the original target sequence. This amplification by the TAS protocol allows the detection of fewer than one HIV-1-infected CEM cell in a population of 10(6) uninfected CEM cells. Detection of the TAS-generated RNA from HIV-1-infected cells can easily be accomplished by means of a bead-based sandwich hybridization protocol, which provides additional specificity for the identification of the amplified HIV-1-specific sequence.

Temporal aspects of DNA and RNA synthesis during human immunodeficiency virus infection: evidence for differential gene expression.

Abstract: The kinetics of retroviral DNA and RNA synthesis are parameters vital to understanding viral growth, especially for human immunodeficiency virus (HIV), which encodes several of its own regulatory genes. We have established a single-cycle growth condition for HIV in H9 cells, a human CD4+ lymphocyte line. The full-length viral linear DNA is first detectable by 4 h postinfection. During a one-step growth of HIV, amounts of viral DNA gradually increase until 8 to 12 h postinfection and then decrease. The copy number of unintegrated viral DNA is not extraordinarily high even at its peak. Most strikingly, there is a temporal program of RNA accumulation: the earliest RNA is greatly enriched in the 2-kilobase subgenomic mRNA species, while the level of 9.2-kilobase RNA which is both genomic RNA and mRNA remains low until after 24 h of infection. Virus production begins at about 24 h postinfection. Thus, viral DNA synthesis is as rapid as for other retroviruses, but viral RNA synthesis involves temporal alteration in the species that accumulate, presumably as a consequence of viral regulatory genes.

A double-stranded RNA unwinding activity introduces structural alterations by means of adenosine to inosine conversions in mammalian cells and Xenopus eggs.

Abstract: Amphibian eggs and embryos as well as mammalian cells have been reported to contain an activity that unwinds double-stranded RNA. We have now found that adenosine residues have been modified in the RNA products of this unwinding activity. Although the modified RNA remains double-stranded, the modification causes the RNA to be susceptible to single-strand-specific RNase and to migrate as a retarded smear on a native polyacrylamide electrophoresis gel. The modification is specific for double-stranded RNA. At least 40% of the adenosine residues can be modified in vitro in a given random sequence RNA molecule. By using standard two-dimensional TLC and HPLC analyses, the modified base has been identified as inosine. Mismatched base-pairing between inosine and uridine appears to be responsible for the observed characteristics of the unwound RNA. The biological significance of this modifying activity and also of the modified double-stranded RNA is discussed.

Coronavirus genome: prediction of putative functional domains in the non-structural polyprotein by comparative amino acid sequence analysis

Abstract: Amino acid sequences of 2 giant non-structural polyproteins (F1 and F2) of infectious bronchitis virus (IBV), a member of Coronaviridae, were compared, by computer-assisted methods, to sequences of a number of other positive strand RNA viral and cellular proteins. By this approach, juxtaposed putative RNA-dependent RNA polymerase, nucleic acid binding ("finger"-like) and RNA helicase domains were identified in F2. Together, these domains might constitute the core of the protein complex involved in the primer-dependent transcription, replication and recombination of coronaviruses. In F1, two cysteine protease-like domains and a growth factor-like one were revealed. One of the putative proteases of IBV is similar to 3C proteases of picornaviruses and related enzymes of como- nepo- and potyviruses. Search of IBV F1 and F2 sequences for sites similar to those cleaved by the latter proteases and intercomparison of the surrounding sequence stretches revealed 13 dipeptides Q/S(G) which are probably cleaved by the coronavirus 3C-like protease. Based on these observations, a partial tentative scheme for the functional organization and expression strategy of the non-structural polyproteins of IBV was proposed. It implies that, despite the general similarity to other positive strand RNA viruses, and particularly to potyviruses, coronaviruses possess a number of unique structural and functional features.

Human hepatitis delta virus RNA subfragments contain an autocleavage activity.

Abstract: Hepatitis delta virus (HDV) contains a single-stranded circular RNA genome of 1.7 kilobases. In this report we demonstrate that subfragments of HDV RNA can undergo autocatalytic cleavage. This cleavage requires at least 500 microM of Mg2+ or Ca2+, is not affected by varying the pH from 5.0 to 9.1, and occurs with RNA fragments as small as 133 nucleotides. The larger RNA fragments containing additional HDV sequences have a lower efficiency of cleavage. Deletion analysis at both ends of RNA subfragments suggested that the catalytic ability of HDV RNA resides in a stretch of no more than 117 nucleotides around the cleavage site. The cleavage occurs at the phosphodiester bond between nucleotides 688 and 689 on the HDV genomic map, generating a 5' fragment with a terminal uridyl 2',3'-cyclic monophosphate residue and a 3' fragment with a guanosyl residue with a 5'-hydroxyl group. The smallest autocleaving RNA does not contain the "hammerhead" sequence required for the autocleavage of other known self-cleaving RNA. The cleavage of HDV RNA occurs at a much faster rate, even at a very low Mg2+ concentration, than that of other "ribozymes." Thus, HDV RNA represents a distinct class of ribozyme.

RNA chain initiation by Escherichia coli RNA polymerase: structural transitions of the enzyme in early ternary complexes

Abstract: We have studied the properties and structures of a series of Escherichia coli RNA polymerase ternary complexes formed during the initial steps of RNA chain initiation and elongation. Five different templates were used that contained the bacteriophage T7 A1 promoter or the E. coli Tac or the lac UV5 promoter, as well as variant templates with alterations in the initial transcribed regions. The majority of ternary complexes bearing short transcripts (from two to nine nucleotides) are highly unstable and cannot be easily studied. This includes transcripts from the phage T7 A1 promoter, for which the stability of complexes bearing transcripts as short as four nucleotides has previously been postulated. However, with one Tac promoter template, RNA polymerase forms ternary complexes with transcripts as short as five nucleotides that are stable enough for biochemical study. We describe several approaches to identifying and isolating such stable complexes and show that stringent criteria are needed in carrying out such experiments if the results are to be meaningful. Deoxyribonuclease I (DNase I) footprinting has been used to probe the general structure of the stable ternary complexes formed as the polymerase begins transcription and moves away from the start site. The enzyme undergoes a sequence of structural changes during initiation and transition to an elongating complex. Complexes with five to eight nucleotide transcripts, designated initial transcribing complexes (ITC), have identical footprints; they all retain the sigma factor and have a slightly extended DNase I footprint (-57 to +24) as compared to the open promoter complex (-57 to +20). ITC complexes all show a region of marked DNase I hypersensitivity in the -25 region that may reflect bending or distortion of the DNA template. Complexes with 10 or 11 nucleotide transcripts, designated initial elongating complexes (IEC), have lost the sigma factor and have a slightly reduced and shifted DNase I footprint (-32 to +30). However, these IEC have not yet achieved the much smaller footprint (approximately 30 bp) reported as characteristic of elongating ternary complexes bearing longer RNA chains. During the initial phase of transcription, the RNA polymerase does not move monotonically along the DNA template as RNA chains are extended, but instead, the upstream and downstream contacts remain more or less fixed as the nascent transcript is elongated up to about eight nucleotides in length. Only after incorporation of 10 nucleotides is there significant movement of the enzyme away from the promoter region and a commitment to elongation.

The RNA binding protein La influences both the accuracy and the efficiency of RNA polymerase III transcription in vitro.

Abstract: The autoantigen La binds the U-rich 3' ends of all nascent RNA polymerase III transcripts Here, we demonstrate that this abundant nuclear phosphoprotein not only binds these RNAs but appears to be required for their synthesis HeLa cell extracts immunochemically depleted of La by either patient or mouse monoclonal antibodies lose greater than 99% of their transcription activity on class III genes The few transcripts synthesized in the absence of La have fewer uridylate residues at their 3' ends than those made in its presence Reconstitution of La-depleted extracts with biochemically purified HeLa La protein stimulates transcription levels and completely restores transcript length A model coupling transcription levels to the action of La at the RNA polymerase III termination signal is presented

Evidence for specificity in the encapsidation of Sindbis virus RNAs.

Abstract: We investigated the interaction of the capsid protein of Sindbis virus with Sindbis viral RNAs and defined a region of the genome that is required for binding in vitro and for packaging in vivo. The binding studies were performed with purified capsid protein immobilized on nitrocellulose and 32P-labeled RNAs transcribed in vitro from viral and nonspecific cDNAs. Genomic and defective interfering (DI) RNAs bound capsid protein significantly better than either the subgenomic (26S) RNA or nonspecific RNAs. Transcripts prepared from either truncated or deleted cDNAs were used to define the segment required for binding. This segment, which is represented twice in DI RNA, lies between nucleotides 746 and 1226 of the genomic RNA and is within the coding region of the nonstructural protein nsP1. Insertion of a domain covering these sequences into a nonviral RNA was able to convert it from a background level of binding to an activity that was 80% that of the Sindbis virus DI RNA. We analyzed DI RNA transcripts in detail because they could be studied not only for the ability to bind capsid protein in vitro but also for the ability to be replicated and packaged in vivo in the presence of helper virion RNA. The results obtained with three DI RNAs are reported. One (CTS14), which has one copy of the binding domain, bound efficiently to capsid protein in vitro and was packaged in vivo as measured by amplification on passaging. In contrast, a DI RNA (CTS1) which lacked this region did not bind to capsid protein and was not detected on passaging. By using lipofectin (P. L. Felgner, T. R. Gadek, M. Holm, R. Roman, H. W. Chan, M. Wenz, J.P. Northrop, G. M. Ringold, and M. Danielson, Proc. Natl. Acad. Sci. USA 84:7413-7417, 1987) to enhance RNA uptake, we were able to demonstrate that CTS1 RNA was replicated in the transfected cells. It was replicated to the same level as another DI RNA (CTS253) which has only the 3' 279 nucleotides of the binding domain and these are located near the 3' terminus of the RNA. CTS253 bound capsid protein to an intermediate level but was amplified on passaging. The binding studies and the in vivo packaging data, taken together, provide strong support for the conclusion that there is a specific capsid recognition domain in Sindbis virus RNA that plays a role in nucleocapsid assembly.

Promoter analysis of influenza virus RNA polymerase.

Abstract: Influenza virus polymerase, which was prepared depleted of viral RNA, was used to copy small RNA templates prepared from plasmid-encoded sequences. Template constructions containing only the 3' end of genomic RNA were shown to be efficiently copied, indicating that the promoter lay solely within the 15-nucleotide 3' terminus. Sequences not specific for the influenza virus termini were not copied, and, surprisingly, RNAs containing termini identical to those from plus-sense cRNA were copied at low levels. The specificity for recognition of the virus sense promoter was further defined by site-specific mutagenesis. It was also found that increased levels of viral protein were required in order to catalyze both the cap endonuclease-primed and primer-free RNA synthesis from these model templates, as well as from genomic-length RNAs. This finding indicates that the reconstituted system has catalytic properties very similar to those of native viral ribonucleoprotein complexes.

Analysis of the gene encoding the largest subunit of RNA polymerase II in Drosophila.

Abstract: We have characterized RpII215, the gene encoding the largest subunit of RNA polymerase II in Drosophila melanogaster. DNA sequencing and nuclease S1 analyses provided the primary structure of this gene, its 7 kb RNA and 215 kDa protein products. The amino-terminal 80% of the subunit harbors regions with strong homology to the β′ subunit of Escherichia coli RNA polymerase and to the largest subunits of other eukaryotic RNA polymerases. The carboxyl-terminal 20% of the subunit is composed of multiple repeats of a seven amino acid consensus sequence, Tyr-Ser-Pro-Thr-Ser-Pro-Ser. The homology domains, as well as the unique carboxyl-terminal structure, are considered in the light of current knowledge of RNA polymerase II and the properties of its largest subunit. Additionally, germline transformation demonstrated that a 9.4 kb genomic DNA segment containing the α-amanitinresistant allele, RpII215 C4 , includes all sequences required to produce amanitin-resistant transformants.

Mapping of RNA- temperature-sensitive mutants of Sindbis virus: assignment of complementation groups A, B, and G to nonstructural proteins.

Abstract: Four complementation groups of temperature-sensitive (ts) mutants of Sindbis virus that fail to make RNA at the nonpermissive temperature are known, and we have previously shown that group F mutants have defects in nsP4. Here we map representatives of groups A, B, and G. Restriction fragments from a full-length clone of Sindbis virus, Toto1101, were replaced with the corresponding fragments from the various mutants. These hybrid plasmids were transcribed in vitro by SP6 RNA polymerase to produce infectious RNA transcripts, and the virus recovered was tested for temperature sensitivity. After each lesion was mapped to a specific region, cDNA clones of both mutants and revertants were sequenced in order to determine the precise nucleotide change responsible for each mutation. Synthesis of viral RNA and complementation by rescued mutants were also examined in order to study the phenotype of each mutation in a uniform genetic background. The single mutant of group B, ts11, had a defect in nsP1 (Ala-348 to Thr). All of the group A and group G mutants examined had lesions in nsP2 (Ala-517 to Thr in ts17, Cys-304 to Tyr in ts21, and Gly-736 to Ser in ts24 for three group A mutants, and Phe-509 to Leu in ts18 and Asp-522 to Asn in ts7 for two group G mutants). In addition, ts7 had a change in nsP3 (Phe-312 to Ser) which also rendered the virus temperature sensitive and RNA-. Thus, changes in any of the four nonstructural proteins can lead to failure to synthesize RNA at a nonpermissive temperature, indicating that all four are involved in RNA synthesis. From the results presented here and from previous results, several of the activities of the nonstructural proteins can be deduced. It appears that nsP1 may be involved in the initiation of minus-strand RNA synthesis. nsP2 appears to be involved in the initiation of 26S RNA synthesis, and in addition it appears to be a protease that cleaves the nonstructural polyprotein precursors. It may also be involved in shutoff of minus-strand RNA synthesis. nsP4 appears to function as the viral polymerase or elongation factor. The functions of nsP3 are as yet unresolved.

RNA polymerase II subunit RPB4 is essential for high- and low-temperature yeast cell growth.

Abstract: RPB4 encodes the fourth-largest RNA polymerase II subunit in Saccharomyces cerevisiae. The RPB4 gene was cloned and sequenced, and its identity was confirmed by amino acid sequence analysis of tryptic peptides from the purified subunit. The RPB4 DNA sequence predicted a protein of 221 amino acids with a molecular mass of 25,414 daltons. The central 100 amino acids of the RPB4 protein were found to be similar to a segment of the major sigma subunit in Escherichia coli RNA polymerase. Deletion of RPB4 produced cells that were heat and cold sensitive but could grow, albeit slowly, at intermediate temperatures. RNA polymerase II lacking the RPB4 subunit exhibited markedly reduced activity in crude extracts in vitro. The RPB4 subunit, although not essential for mRNA synthesis or enzyme assembly, was essential for normal levels of RNA polymerase II activity and indispensable for cell viability over a wide temperature range.

Gamma-monomethyl phosphate: a cap structure in spliceosomal U6 small nuclear RNA.

Abstract: U6 small nuclear RNA (snRNA), a component of eukaryotic spliceosomes, is required for splicing of nuclear pre-mRNAs. Whereas trimethylguanosine cap-containing U sn-RNAs are transcribed by RNA polymerase II, the U6 RNA is transcribed by RNA polymerase III and contains a nonnucleotide cap structure on its 5' end. We characterized the cap structure of human U6 snRNA and show that the gamma phosphate of the 5' guanosine triphosphate is methylated. The mobilities of in vivo-modified gamma phosphate from the 5' end of HeLa U6 RNA were identical to the synthetic monomethyl phosphate (CH3-O-P) in two-dimensional chromatography and two-dimensional electrophoresis. The cap structure of U6 RNA is distinct from all other cap structures characterized thus far.

Role of 3'-end sequences in infectivity of poliovirus transcripts made in vitro.

Abstract: It has been shown by van der Werf et al. (S. van der Werf, J. Bradley, E. Wimmer, F. W. Studier, and J. Dunn, Proc. Natl. Acad. Sci. USA 83:2330-2334, 1986) that in vitro synthesis of poliovirus RNA by T7 RNA polymerase gives rise to infectious RNA molecules; however, these molecules are only 5% as infectious as RNA isolated from virions. A plasmid, T7D-polio, was constructed that allows the in vitro synthesis of full-length RNA molecules with two additional guanine residues at the 5' end. However, T7D-polio differed from the construct of van der Werf et al. in that RNA transcribed from T7D-polio has an authentic 3' end, ending with only a polyadenine nucleotide sequence. Transfection of these RNA molecules into mammalian cells produced wild-type poliovirus with an efficiency similar to that of virion RNA. The use of this vector in the characterization of viral mutants in vivo and in vitro is discussed.

Quantitative assays based on the use of replicatable hybridization probes.

Abstract: Amplifiable hybridization probes--molecules with a probe sequence embedded within the sequence of a replicatable RNA--will promote the development of sensitive clinical assays. To demonstrate their utility, we prepared a recombinant RNA that contained a 30-nucleotide-long probe complementary to a conserved region of the pol gene in human immunodeficiency virus type 1 (HIV-1) mRNA. Test samples were prepared, each containing a different number of HIV-1 transcripts that served as simulated HIV-1 mRNA targets. Hybridizations were carried out in a solution containing the chaotropic salt, guanidine thiocyanate. Probe-target hybrids were isolated by reversible target capture on paramagnetic particles. The probes were then released from their targets and amplified by incubation with the RNA-directed RNA polymerase, Q beta replicase (EC 2.7.7.48). The replicase copied the probes in an exponential manner: after each round of copying, the number of RNA molecules doubled. The amount of RNA synthesized in each reaction (approximately 50 ng) was sufficient to measure without using radioisotopes. Kinetic analysis of the reactions demonstrated that the number of HIV-1 targets originally present in each sample could be determined by measuring the time it took to synthesize a particular amount of RNA (the longer the synthesis took, the fewer the number of targets originally present). The results suggest that clinical assays involving replicatable hybridization probes will be simple, accurate, sensitive, and automatable.

Characterization of the Escherichia coli transcription factor sigma 70: localization of a region involved in the interaction with core RNA polymerase.

Abstract: A set of internal deletions and frame-shift mutations was made in the structural gene for the major sigma factor of Escherichia coli RNA polymerase (sigma 70). The truncated proteins from these various mutants were examined to determine if they retained the ability to bind core RNA polymerase. Two assays were used to determine core-binding activity. Gel filtration was used to separate free sigma 70 from sigma 70 bound to core polymerase. Immunoprecipitation of polymerase using an anti-alpha-subunit monoclonal antibody was also used to determine if the various truncated proteins were bound to core. Results from these experiments indicate core-binding activity is retained when large portions of the sigma 70 protein are deleted. Deletion of a region in the central portion of the protein caused a large decrease in core-binding activity. The results suggest that the region spanning amino acids 361-390 is important for efficient core-binding activity. Sequence comparison of various sigma factors shows highly conserved amino acids in this region. A synthetic peptide having the sequence of amino acids 361-390 was synthesized and examined for the ability to bind core RNA polymerase.

Protection against tobacco mosaic virus in transgenic plants that express tobacco mosaic virus antisense RNA.

Abstract: Transgenic tobacco plants that express RNA sequences complementary to the tobacco mosaic virus (TMV) coat protein (CP) coding sequence with or without the tRNA-like structure at the 3' end of the TMV RNA were produced. Progeny of self-pollinated plants were challenged with TMV to determine their resistance to infection. Plants that expressed RNA sequences complementary to the CP coding region and the 3' untranslated region, including the tRNA-like sequences, were protected from infection by TMV at low levels of inoculum. However, plants that expressed RNA complementary to the CP coding sequence alone were not protected from infection. These results indicate that sequences complementary to the terminal 117 nucleotides of TMV, which include a putative replicase binding site, are responsible for the protection. However, the level of protection in these plants was considerably less than in transgenic plants that expressed the TMV CP gene and accumulated CP. Since the mechanisms of protection in the two systems are different, it may be possible to increase protection by introducing both sequences into transgenic plants.

Activation of interferon-regulated, dsRNA-dependent enzymes by human immunodeficiency virus-1 leader RNA.

Abstract: Human immunodeficiency virus-1 (HIV-1) leader RNA, which contains double-stranded regions due to inverted repeats, was shown to activate the dsRNA-dependent enzymes associated with the interferon system. HIV-1 leader RNA produced in vitro using SP6 RNA polymerase was characterized using probes for antisense and sense-strand RNA. The RNA preparation was free from significant levels of antisense RNA. HIV-1 leader RNA was shown to activate dsRNA-dependent protein kinase in a cell-free system from interferon-treated HeLa cells. Affinity resins, consisting of HIV-1 leader RNA covalently attached to cellulose, immobilized and activated dsRNA-dependent protein kinase and 2-5A-synthetase. HIV-1 leader RNA, therefore, may be a contributing factor in the mechanism by which interferon inhibits HIV replication.