Showing papers on "RNA-dependent RNA polymerase published in 1990"

Selection in vitro of an RNA enzyme that specifically cleaves single-stranded DNA

Abstract: The discovery of RNA enzymes has, for the first time, provided a single molecule that has both genetic and catalytic properties. We have devised techniques for the mutation, selection and amplification of catalytic RNA, all of which can be performed rapidly in vitro. Here we describe how these techniques can be integrated and performed repeatedly within a single reaction vessel. This allows evolution experiments to be carried out in response to artificially imposed selection constraints. We worked with the Tetrahymena ribozyme, a self-splicing group I intron derived from the large ribosomal RNA precursor of Tetrahymena thermophila that catalyses sequence-specific phosphoester transfer reactions involving RNA substrates. It consists of 413 nucleotides, and assumes a well-defined secondary and tertiary structure responsible for its catalytic activity. We selected for variant forms of the enzyme that could best react with a DNA substrate. This led to the recovery of a mutant form of the enzyme that cleaves DNA more efficiently than the wild-type enzyme. The selected molecule represents the discovery of the first RNA enzyme known to cleave single-stranded DNA specifically.

Rna ribozyme restriction endoribonucleases and methods

Abstract: New RNA endoribonuclease ribozymes are found with new conditions to prevent mismatch cleavage and able to cleave RNA after 6 different sets of ribonucleotide 4 base sequences.

Functional evidence for an RNA template in telomerase.

Abstract: The RNA moiety of the ribonucleoprotein enzyme telomerase from the ciliate Euplotes crassus was identified and its gene was sequenced. Functional analysis, in which oligonucleotides complementary to portions of the telomerase RNA were tested for their ability to prime telomerase in vitro, showed that the sequence 5' CAAAACCCCAAA 3' in this RNA is the template for synthesis of telomeric TTTTGGGG repeats by the Euplotes telomerase. The data provide a direct demonstration of a template function for a telomerase RNA and demarcate the outer boundaries of the telomeric template. Telomerase can now be defined as a specialized reverse transcriptase.

External guide sequences for an RNA enzyme.

Abstract: Ribonuclease P (RNase P) from Escherichia coli or its catalytic RNA subunit can efficiently cleave small RNA substrates that lack the conserved features of natural substrates of RNase P if an additional small RNA is also present. This additional RNA must contain a sequence complementary to the substrate [external guide sequence (EGS)] and a 3'-proximal CCA sequence to ensure cleavage. The aminoacyl acceptor stem and some additional 5'- and 3'-terminal sequences of a precursor transfer RNA are sufficient to allow efficient cleavage by RNAase P, and the 2'-hydroxyl group at the cleavage site is not absolutely necessary for cleavage. In principle, any RNA could be targeted by a custom-designed EGS RNA for specific cleavage by RNase P in vitro or in vivo.

Polymerase gene products of hepatitis B viruses are required for genomic RNA packaging as well as for reverse transcription

Abstract: All reactions involving reverse transcription of RNA are segregated from the cytosol within a subviral particle or capsid composed of the major capsid protein, the polymerase and the RNA template. A key step in the formation of these particles is the selective encapsidation of the RNA template. Although an important general feature of the reverse transcription pathway, encapsidation has been carefully studied only for retroviruses. We have now examined the encapsidation reaction in a family of enveloped DNA viruses that replicate by reverse transcription--the hepatitis B viruses (hepadnaviruses). Our results indicate that the hepadnaviral polymerase (P) gene product is required for RNA packaging, and that the encapsidation function of the enzyme can be separated from its DNA polymerase activity. To our knowledge, this is the first description of a role for polymerase gene products in this step of the reverse transcription pathway.

Plants transformed with a tobacco mosaic virus nonstructural gene sequence are resistant to the virus.

Abstract: Nicotiana tabacum cv. Xanthi nn plants were transformed with nucleotides 3472-4916 of tobacco mosaic virus (TMV) strain U1. This sequence contains all but the three 3 terminal nucleotides of the TMV 54-kDa gene, which encodes a putative component of the replicase complex. These plants were resistant to infection when challenged with either TMV U1 virions or TMV U1 RNA at concentrations of up to 500 micrograms/ml or 300 micrograms/ml, respectively, the highest concentrations tested. Resistance was also exhibited when plants were inoculated at 100 micrograms/ml with the closely related TMV mutant YSI/1 but was not shown in plants challenged at the same concentrations with the more distantly related TMV strains U2 or L or cucumber mosaic virus. Although the copy number of the 54-kDa gene sequence varied in individual transformants from 1 to approximately 5, the level of resistance in plants was not dependent on the number of copies of the 54-kDa gene sequence integrated. The transformed plants accumulated a 54-kDa gene sequence-specific RNA transcript of the expected size, but no protein product was detected.

An E. coli Ribonucleoprotein Containing 4.5S RNA Resembles Mammalian Signal Recognition Particle

Abstract: The signal recognition particle (SRP) plays a central role in directing the export of nascent proteins from the cytoplasm of mammalian cells. An SRP-dependent translocation machinery in bacteria has not been demonstrated in previous genetic and biochemical studies. Sequence comparisons, however, have identified (i) a gene in Escherichia coli (ffh) whose product is homologous to the 54-kilodalton subunit (SRP54) of SRP, and (ii) an RNA encoded by the ffs gene (4.5S RNA) that shares a conserved domain with the 7SL RNA of SRP. An antiserum to Ffh precipitated 4.5S RNA from E. coli extracts, implying that the two molecules reside in a complex. The 4.5S RNA can also bind to SRP54 and can replace 7SL RNA in an enzymatic assay. The product of a dominant mutation in the ffs gene (4.5S RNAdl1) is also coprecipitated by the antiserum to Ffh protein and is lethal when expressed from an inducible promoter. After induction of 4.5S RNAdl1, the earliest observed phenotype was a permanent induction of the heat shock response, suggesting that there was an accumulation of aberrant proteins in the cytoplasm. Late after induction, translocation of beta-lactamase was impaired; this may be an indirect effect of heat shock, however, because translocation of ribose binding protein or of the porin, OmpA, was unaffected. An unusual separation of the inner and outer membranes, suggestive of a defect in cell envelope, was also observed. Protein synthesis did not cease until very late, an indication that 4.5S RNA probably does not have a direct role in this process.

Expression using the T7 RNA polymerase/promoter system.

Abstract: This unit describes the expression of genes by placing them under the control of the bacteriophage T7 RNA polymerase T7 RNA polymerase is a very active enzyme: it synthesizes RNA at a rate several times that of E coli RNA polymerase and it terminates transcription less frequently; in fact, its transcription can circumnavigate a plasmid, resulting in RNA several times the plasmid length in size T7 RNA polymerase is also highly selective for initiation at its own promoter sequences and is resistant to antibiotics such as rifampicin that inhibit E coli RNA polymerase Consequently, the addition of rifampicin to cells that are producing T7 RNA polymerase results in the exclusive expression of genes under the control of a T7 RNA polymerase promoter (p(T7)) In the Basic Protocol, two plasmids are maintained within the same E coli cell One (the expression vector) contains p(T7) upstream of the gene to be expressed The second contains the T7 RNA polymerase gene under the control of a heat-inducible E coli promoter Upon heat induction, the T7 RNA polymerase is produced and initiates transcription on the expression vector, resulting in turn in the expression of the gene(s) under the control of p(T7) If desired, the gene products can be uniquely labeled by carrying out the procedure in minimal medium, adding rifampicin to inhibit the E coli RNA polymerase, and then labeling the proteins with [35S]methionine

Cytoplasmic expression system based on constitutive synthesis of bacteriophage T7 RNA polymerase in mammalian cells.

Abstract: A mouse cell line that constitutively synthesizes the bacteriophage T7 RNA polymerase was constructed. Fluorescence microscopy indicated that the T7 RNA polymerase was present in the cytoplasmic compartment. The system provided, therefore, a unique opportunity to study structural elements of mRNA that affect stability and translation. The in vivo activity of the bacteriophage polymerase was demonstrated by transfection of a plasmid containing the chloramphenicol acetyltransferase (CAT) gene flanked by T7 promoter and termination signals. Synthesis of CAT was dependent on the presence of a cDNA copy of the untranslated region of encephalomyocarditis virus (ECMV) RNA downstream of the T7 promoter, consistent with the absence of RNA-capping activity in the cytoplasm. CAT expression from a plasmid, pT7EMCAT, containing the T7 and EMCV regulatory elements was detected within 4 hr after transfection and increased during the next 20 hr, exceeding that obtained by transfection of a plasmid with the CAT gene attached to a retrovirus promoter and enhancer. Nevertheless, the presumably cap-independent transient expression of CAT from pT7EMCAT was increased more than 500-fold when the transfected cells also were infected with wild-type vaccinia virus. A protocol for high-level expression involved the infection of the T7 RNA polymerase cell line with a single recombinant vaccinia virus containing the target gene regulated by a T7 promoter and EMCV untranslated region.

Structural organization of poliovirus RNA replication is mediated by viral proteins of the P2 genomic region.

Abstract: Transcriptionally active replication complexes bound to smooth membrane vesicles were isolated from poliovirus-infected cells. In electron microscopic, negatively stained preparations, the replication complex appeared as an irregularly shaped, oblong structure attached to several virus-induced vesicles of a rosettelike arrangement. Electron microscopic immunocytochemistry of such preparations demonstrated that the poliovirus replication complex contains the proteins coded by the P2 genomic region (P2 proteins) in a membrane-associated form. In addition, the P2 proteins are also associated with viral RNA, and they can be cross-linked to viral RNA by UV irradiation. Guanidine hydrochloride prevented the P2 proteins from becoming membrane bound but did not change their association with viral RNA. The findings allow the conclusion that the protein 2C or 2C-containing precursor(s) is responsible for the attachment of the viral RNA to the vesicular membrane and for the spatial organization of the replication complex necessary for its proper functioning in viral transcription. A model for the structure of the viral replication complex and for the function of the 2C-containing P2 protein(s) and the vesicular membranes is proposed.

RNA helicase: a novel activity associated with a protein encoded by a positive strand RNA virus

Abstract: Most positive strand RNA viruses infecting plants and animals encode proteins containing the so-called nucleotide binding motif (NTBM) (1) in their amino acid sequences (2). As suggested from the high level of sequence similarity of these viral proteins with the recently described superfamilies of helicase-like proteins (3-5), the NTBM-containing cylindrical inclusion (CI) protein from plum pox virus (PPV), which belongs to the potyvirus group of positive strand RNA viruses, is shown to be able to unwind RNA duplexes. This activity was found to be dependent on the hydrolysis of NTP to NDP and Pi, and thus it can be considered as an RNA helicase activity. In the in vitro assay used, the PPV CI protein was only able to unwind double strand RNA substrates with 3' single strand overhangs. This result indicates that the helicase activity of the PPV CI protein functions in the 3' to 5' direction (6). To our knowledge, this is the first report on a helicase activity associated with a protein encoded by an RNA virus.

Substrate sequence effects on "hammerhead" RNA catalytic efficiency.

Abstract: The "hammerhead" RNA self-cleaving domain can be assembled from two RNA molecules: a large (approximately 34 nucleotide) ribozyme RNA containing most of the catalytically essential nucleotides and a small (approximately 13 nucleotide) substrate RNA containing the cleavage site Four such hammerheads that contained identical catalytic core sequences but differed in the base composition of the helices that are involved in substrate binding had been reported to vary in cleavage rates by more than 70-fold under similar reaction conditions Steady-state kinetic analyses reveal that kcat values are nearly the same for these hammerheads but Km values vary nearly 60-fold The substrates for reactions having high Km values form aggregates that are virtually nonreactive These observations demonstrate that the secondary structure of substrate RNA can be a major determinant of hammerhead catalytic efficiency

Promoter for Sindbis virus RNA-dependent subgenomic RNA transcription.

Abstract: Sindbis virus is a positive-strand RNA enveloped virus, a member of the Alphavirus genus of the Togaviridae family. Two species of mRNA are synthesized in cells infected with Sindbis virus; one, the 49S RNA, is the genomic RNA; the other, the 26S RNA, is a subgenomic RNA that is identical in sequence to the 3' one-third of the genomic RNA. Ou et al. (J.-H. Ou, C. M. Rice, L. Dalgarno, E. G. Strauss, and J. H. Strauss, Proc. Natl. Acad. Sci. USA 79:5235-5239, 1982) identified a highly conserved region 19 nucleotides upstream and 2 nucleotides downstream from the start of the 26S RNA and proposed that in the negative-strand template, these nucleotides compose the promoter for directing the synthesis of the subgenomic RNA. Defective interfering (DI) RNAs of Sindbis virus were used to test this proposal. A 227-nucleotide sequence encompassing 98 nucleotides upstream and 117 nucleotides downstream from the start site of the Sindbis virus subgenomic RNA was inserted into a DI genome. The DI RNA containing the insert was replicated and packaged in the presence of helper virus, and cells infected with these DI particles produced a subgenomic RNA of the size and sequence expected if the promoter was functional. The initiating nucleotide was identical to that used for Sindbis virus subgenomic mRNA synthesis. Deletion analysis showed that the minimal region required to detect transcription of a subgenomic RNA from the negative-strand template of a DI RNA was 18 or 19 nucleotides upstream and 5 nucleotides downstream from the start of the subgenomic RNA.

cis elements and trans-acting factors involved in dimer formation of murine leukemia virus RNA.

Abstract: The genetic material of all retroviruses examined so far consists of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Since the precise location of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analyzed the dimerization process of Moloney murine leukemia virus (MoMuLV) genomic RNA. For this purpose we derived an in vitro model for RNA dimerization. By using this model, murine leukemia virus RNA was shown to form dimeric molecules. Deletion mutagenesis in the 620-nucleotide leader of MoMuLV RNA showed that the dimer promoting sequences are located within the encapsidation element Psi between positions 215 and 420. Furthermore, hybridization assays in which DNA oligomers were used to probe monomer and dimer forms of MoMuLV RNA indicated that the DLS probably maps between positions 280 and 330 from the RNA 5' end. Also, retroviral nucleocapsid protein was shown to catalyze dimerization of MoMuLV RNA and to be tightly bound to genomic dimer RNA in virions. These results suggest that MoMuLV RNA dimerization and encapsidation are probably controlled by the same cis element, Psi, and trans-acting factor, nucleocapsid protein, and thus might be linked during virion formation.

Identifying the RNA polymerases that synthesize specific transcripts of the Autographa californica nuclear polyhedrosis virus.

Abstract: Nuclear run-on assays carried out in the presence and absence of the RNA polymerase II inhibitor, α-amanitin, were used to determine the exact timing of the switch from inhibitor-sensitive transcription catalysed by host RNA polymerase II, to inhibitor-resistant transcription catalysed by the baculovirus-induced RNA polymerase. These studies revealed that the onset of α-amanitin-resistant transcription is just after 6 h post-infection, simultaneous with the beginning of the late phase of infection. They also showed that transcripts from the p26 gene in the HindIII Q/P region and the p35 gene in the HindIII K/Q region of the viral genome are synthesized by the host RNA polymerase II both early and late in infection. On the other hand, transcripts of the p10 gene in the HindIII Q/P region and the γ transcripts in the HindIII K region are synthesized by the α-amanitin-resistant, virus-induced RNA polymerase late in infection.

Structure and transcription of a human gene for H1 RNA, the RNA component of human RNase P

Abstract: The gene coding for H1 RNA, the RNA component of human RNase P, has been isolated and characterized from a human genomic DNA library. The sequence corresponding to the mature H1 RNA is almost identical to that previously identified using H1 RNA and a cDNA clone corresponding to it. The nucleotide sequence of the genomic clone contains an array of potential transcriptional control elements, some characteristic of transcription by RNA polymerase III and some characteristic of RNA polymerase II, as is also the case for U6 and certain other small stable RNAs. The transcription in vitro of the genomic clone shows that the gene is functional and is transcribed by RNA polymerase III. Southern hybridization analysis indicates that there is very likely only one copy of the gene for H1 RNA in the human genome.

Subunits shared by eukaryotic nuclear RNA polymerases.

Abstract: RNA polymerases I, II, and III share three subunits that are immunologically and biochemically indistinguishable. The Saccharomyces cerevisiae genes that encode these subunits (RPBS, RPB6, and RPBS) were isolated and sequenced, and their transcriptional start sites were deduced. RPB5 encodes a 25-kD protein, RPB6, an 18-kD protein, and RPB8, a 16-kD protein. These genes are single copy, reside on different chromosomes, and are essential for viability. The fact that the genes are single copy, corroborates previous evidence suggesting that each of the common subunits is identical in RNA polymerases I, II, and III. Furthermore, immunoprecipitation of RPB6 coprecipitates proteins whose sizes are consistent with RNA polymerase I, II, and III subunits. Sequence similarity between the yeast RPB5 protein and a previously characterized human RNA polymerase subunit demonstrates that the common subunits of the nuclear RNA polymerases are well conserved among eukaryotes. The presence of these conserved and essential subunits in all three nuclear RNA polymerases and the absence of recognizable sequence motifs for DNA and nucleoside triphosphate-binding indicate that the common subunits do not have a catalytic role but are important for a function shared by the RNA polymerases such as transcriptional efficiency, nuclear localization, enzyme stability, or coordinate regulation of rRNA, mRNA, and tRNA synthesis. .,

The 54-kD protein of signal recognition particle contains a methionine-rich RNA binding domain.

Abstract: Signal recognition particle (SRP) plays the key role in targeting secretory proteins to the membrane of the endoplasmic reticulum (Walter, P., and V. R. Lingappa. 1986. Annu. Rev. Cell Biol. 2:499-516). It consists of SRP7S RNA and six proteins. The 54-kD protein of SRP (SRP54) recognizes the signal sequence of nascent polypeptides. The 19-kD protein of SRP (SRP19) binds to SRP7S RNA directly and is required for the binding of SRP54 to the particle. We used deletion mutants of SRP19 and SRP54 and an in vitro assembly assay in the presence of SRP7S RNA to define the regions in both proteins which are required to form a ribonucleoprotein particle. Deletion of the 21 COOH-terminal amino acids of SRP19 does not interfere with its binding to SRP7S RNA. Further deletions abolish SRP19 binding to SRP7S RNA. The COOH-terminal 207 amino acids of SRP54 (M domain) were found to be necessary and sufficient for binding to the SRP19/7S RNA complex in vitro. Limited protease digestion of purified SRP confirmed our results for SRP54 from the in vitro binding assay. The SRP54M domain could also bind to Escherichia coli 4.5S RNA that is homologous to part of SRP7S RNA. We suggest that the methionine-rich COOH terminus of SRP54 is a RNA binding domain and that SRP19 serves to establish a binding site for SRP54 on the SRP7S RNA.

A study of the dimer formation of Rous sarcoma virus RNA and of its effect on viral protein synthesis in vitro

Abstract: The genetic material of all retroviruses examined so far is an RNA dimer where two identical RNA subunits are joined at their 5' ends by a structure named dimer linkage structure (DLS). Since the precise location and structure of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analysed the dimerization process of Rous sarcoma virus (RSV) RNA. For this purpose we set up an in vitro model for RSV RNA dimerization. Using this model RSV RNA was shown to form dimeric molecules and this dimerization process was greatly activated by nucleocapsid protein (NCp12) of RSV. Furthermore, RSV RNA dimerization was performed in the presence of complementary 5'32P-DNA oligomers in order to probe the monomer and dimer forms of RSV RNA. Data indicated that the DLS of RSV RNA probably maps between positions 544-564 from the 5' end. In an attempt to define sequences needed for the dimerization of RSV RNA, deletion mutageneses were generated in the 5' 600 nt. The results showed that the dimer promoting sequences probably are located within positions 208-270 and 400-600 from the 5' end and hence possibly encompassing the cis-acting elements needed for the specific encapsidation of RSV genomic RNA. Also it is reported that synthesis of the polyprotein precursor Pr76gag is inhibited upon dimerization of RSV RNA. These results suggest that dimerization and encapsidation of genome length RSV RNA might be linked in the course of virion formation since they appear to be under the control of the same cis elements, E and DLS, and the trans-acting factor nucleocapsid protein NCp12.

Host cell proteins required for measles virus reproduction.

Abstract: We have developed a cell-free system derived from measles virus-infected cells that supported the transcription and replication of measles virus RNA in vitro. The data suggest that tubulin may be required for these reactions, since an anti-β-tubulin monoclonal antibody inhibited viral RNA synthesis and the addition of purified tubulin stimulated measles virus RNA synthesis in vitro. Tubulin may be a subunit of the viral RNA polymerase, since two different anti-tubulin antibodies, one specific for the β- and another specific for the α-subunit of tubulin, coimmunoprecipitated the measles virus L protein as well as tubulin from extracts of measles virus-infected cells. Other experiments further implicated actin in the budding process during virus maturation, as there appeared to be a specific association of actin in vitro only with nucleocapsids that have terminated RNA synthesis, which is presumably a prerequisite to budding.

Identification of barley stripe mosaic virus genes involved in viral RNA replication and systemic movement.

Abstract: Barley stripe mosaic hordeivirus (BSMV) has a tripartite positive-sense RNA genome which encodes seven major polypeptides. Infectious in vitro transcripts derived from full-length wild-type and mutant cDNA clones have been used to investigate the contribution made by various BSMV gene products to viral RNA replication and systemic movement. We show that whereas all three of the BSMV RNA components are required for plant infection, RNAs alpha and gamma can replicate together in barley protoplasts, and therefore RNA beta must encode functions required for systemic invasion of plants. The alpha a and gamma a proteins, which contain helicase and RNA polymerase sequence motifs, together comprise the essential virus-encoded components of BSMV RNA replicase. A second BSMV protein (beta b) which contains a helicase motif is not required for RNA replication. A small cysteine-rich protein (gamma b) is dispensable for infection of plants, but in its absence the accumulation of viral coat (beta a) and beta b proteins is significantly reduced. In addition, mutations in both the gamma b and gamma a (replicase) proteins can affect the systemic movement phenotype.

Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs.

Abstract: Replication and amplification of RNA genomes of defective interfering (DI) particles of vesicular stomatitis virus (VSV) depend on the expression of viral proteins and have until now been attained only in cells coinfected with helper VSV. In the work described in this report, we used a recombinant vaccinia virus-T7 RNA polymerase expression system to synthesize individual VSV proteins in cells transfected with plasmid DNAs that contain cDNA copies of the VSV genes downstream of the T7 RNA polymerase promoter. In this way, we were able to examine the ability of VSV proteins, individually and in combination, to support DI particle RNA replication. VSV proteins were synthesized soon after transfection in amounts that depended on the amount of input plasmid DNA and at rates that remained constant for at least 16 h after transfection. When cells expressing the nucleocapsid protein (N), the phosphoprotein (NS), and the large polymerase protein (L) of VSV were superinfected with the DI particles, rapid and efficient replication and amplification of DI particle RNA was observed. Omission of any one of the three viral proteins abrogated the replication. The maximum levels of DI particle RNA replication that were achieved in the system exceeded those seen with wild-type helper VSV by 8- to 10-fold and were observed at molar L:NS:N protein ratios of approximately 1:200:200. This replication system can be used for analysis of structure-function relationships of VSV proteins that are involved in RNA replication and has potential for use in the identification of RNA sequences in the viral genome that control transcription and replication of VSV RNA.