Showing papers on "RNA-dependent RNA polymerase published in 1991"

The phylogeny of RNA-dependent RNA polymerases of positive-strand RNA viruses.

Abstract: Representative amino acid sequences of the RNA-dependent RNA polymerases of all groups of positive-strand RNA viruses were aligned hierarchically, starting with the most closely related ones. This resulted in delineation of three large supergroups. Within each of the supergroups, the sequences of segments of approximately 300 amino acid residues originating from the central and/or C-terminal portions of the polymerases could be aligned with statistically significant scores. Specific consensus patterns of conserved amino acid residues were derived for each of the supergroups. The composition of the polymerase supergroups was as follows. I. Picorna-, noda-, como-, nepo-, poty-, bymo-, sobemoviruses, and a subset of luteoviruses (beet western yellows virus and potato leafroll virus). II. Carmo-, tombus-, dianthoviruses, another subset of luteoviruses (barley yellow dwarf virus), pestiviruses, hepatitis C virus (HCV), flaviviruses and, unexpectedly, single-stranded RNA bacteriophages. III. Tobamo-, tobra-, hordei-, tricornaviruses, beet yellows virus, alpha-, rubi-, furoviruses, hepatitis E virus (HEV), potex-, carla-, tymoviruses, and apple chlorotic leaf spot virus. An unusual organization was shown for corona- and torovirus polymerases whose N-terminal regions were found to be related to the respective domains of supergroup I, and the C-terminal regions to those of the supergroup III polymerases. The alignments of the three polymerase supergroups were superimposed to produce a comprehensive final alignment encompassing eight distinct conserved motifs. Phylogenetic analysis using three independent methods of tree construction confirmed the separation of the positive-strand RNA viral polymerases into three supergroups and revealed some unexpected clusters within the supergroups. These included the grouping of HCV and the pestiviruses with carmoviruses and related plant viruses in supergroup II, and the grouping of HEV and rubiviruses with furoviruses in supergroup III.

Transcription by single molecules of RNA polymerase observed by light microscopy.

Abstract: The kinetics of transcription by Escherichia coli RNA polymerase relate directly to the regulation of transcription and to the properties of processive enzymes in general, but analysis of RNA polymerase movement along the DNA template has so far been limited to the study of populations of enzyme molecules. The ability to view nanometre-sized particles with the light microscope suggested a method of monitoring transcription by individual RNA polymerase molecules. We describe here the behaviour of 40-nm-diameter particles of colloidal gold attached to the ends of DNA molecules being transcribed by RNA polymerase immobilized on a glass surface. The tethered gold particles are released from the surface at times after addition of nucleoside triphosphates that are consistent with the kinetics of transcription by RNA polymerase in solution. Analysis of the brownian motion of the gold particles enabled us to measure the movement along the template DNA of individual polymerase molecules.

Tomato spotted wilt virus L RNA encodes a putative RNA polymerase.

Abstract: The complete nucleotide sequence of the large (L) genome segment of tomato spotted wilt virus (TSWV) has been determined. The RNA is 8897 nucleotides long and contains complementary 3' and 5' ends, comprising 62 nucleotides at the 5' end and 66 nucleotides at the 3' end. The RNA is of negative polarity, with one large open reading frame (ORF) located on the viral complementary strand. This ORF corresponds to a primary translation product of 2875 amino acids in length, with a predicted Mr of 331,500. Comparison with the polymerase proteins of other negative-strand viruses indicates that this protein most likely represents the viral polymerase. The genetic organization of TSWV L RNA is similar to that of the L RNA segments of Bunyamwera and Hantaan viruses, animal-infecting representatives of the Bunyaviridae.

Transcription on nucleosomal templates by RNA polymerase II in vitro: inhibition of elongation with enhancement of sequence-specific pausing.

Abstract: The process by which RNA polymerase II elongates RNA chains in vivo, where the template is at least partially in a nucleosomal configuration, remains poorly understood. To approach this question we have partially purified RNA polymerase II transcription complexes paused early in elongation. These complexes were then used as substrates for chromatin reconstitution. Elongation of the nascent RNA chains on these nucleosomal templates is severely inhibited relative to elongation on naked DNA templates. Elongation on the nucleosomal templates results in a reproducible template-specific pattern of transcripts generated by RNA polymerase pausing. The RNA polymerases are not terminated because the large majority will resume elongation upon the addition of Sarkosyl or 400 mM KCl. The effectiveness of RNA polymerase II pause/termination sites is enhanced by the presence of nucleosomes. For example, a pause site similar in sequence to the c-myc gene exon 1 terminator is used four to seven times more effectively in reconstituted templates. A comparison of elongation on templates bearing phased nucleosomes and on reconstituted templates that show no predominant phasing pattern indicates that the locations of pause sites are not related to the positions of the nucleosomes. Rather, the major determinant of RNA polymerase pausing on the nucleosomal templates appears to be the underlying DNA sequence.

Relationships among the positive strand and double-strand RNA viruses as viewed through their RNA-dependent RNA polymerases

Abstract: The sequences of 50 RNA-dependent RNA polymerases (RDRPs) from 43 positive strand and 7 double strand RNA (dsRNA) viruses have been compared. The alignment permitted calculation of distances among the 50 viruses and a resultant dendrogram based on every amino acid, rather than just those amino acids in the conserved motifs. Remarkably, a large subgroup of these viruses, including vertebrate, plant, and insect viruses, forms a single cluster whose only common characteristic is exploitation of insect hosts or vectors. This similarity may be due to molecular constraints associated with a present and/or past ability to infect insects and/or to common descent from insect viruses. If common descent is important, as it appears to be, all the positive strand RNA viruses of eucaryotes except for the picornaviruses may have evolved from an ancestral dsRNA virus. Viral RDRPs appear to be inherited as modules rather than as portions of single RNA segments, implying that RNA recombination has played an important role in their dissemination.

The polyadenylation signal of influenza virus RNA involves a stretch of uridines followed by the RNA duplex of the panhandle structure.

Abstract: Appropriate RNAs are transcribed and amplified and proteins are expressed after transfection into cells of in vitro-reconstituted RNA-protein complexes and infection with influenza virus as the helper. This system permits us to study the signals involved in transcription of influenza virus RNAs. For the analysis we used a plasmid-derived RNA containing the reporter gene for chloramphenicol acetyltransferase (CAT) flanked by the noncoding sequences of the NS RNA segment of influenza A/WSN/33 virus. Mutations were then introduced into both the 5' and 3' ends, and the resulting RNAs were studied to determine their transcription in vitro and their CAT expression activity in the RNA-protein transfection system. The results reveal that a stretch of uninterrupted uridines at the 5' end of the negative-strand RNA is essential for mRNA synthesis. Also, a double-stranded RNA "panhandle" structure generated by the 5'- and 3'-terminal nucleotides appears to be required for polyadenylation, since opening up of these base pairs diminished mRNA synthesis and eliminated expression of CAT activity by the mutant RNAs. Finally, it was shown that this double-stranded RNA structural requirement is not sequence specific, since a synthetic GC clamp can replace the virus-coded RNA duplex. The data suggest that the viral RNA polymerase adds poly(A) by a slippage (stuttering) mechanism which occurs when it hits the double-stranded RNA barrier next to the stretch of uridines.

Dimerization of human immunodeficiency virus (type 1) RNA: stimulation by cations and possible mechanism

Abstract: The retroviral genome consists of two identical RNA molecules joined close to their 5' ends by the dimer linkage structure Recent findings indicated that retroviral RNA dimerization and encapsidation are probably related events during virion assembly We studied the cation-induced dimerization of HIV-1 RNA and results indicate that all in vitro generated HIV-1 RNAs containing a 100 nucleotide domain downstream from the 5' splice site are able to dimerize RNA dimerization depends on the concentration of RNA, mono- and multivalent cations, the size of the monovalent cation, temperature, and pH Up to 75% of HIV-1 RNA is dimeric in the presence of spermidine HIV-1 RNA dimer is fairly resistant to denaturing agents and unaffected by intercalating drugs Antisense HIV-1 RNA does not dimerize but heterodimers can be formed between HIV-1 RNA and either MoMuLV or RSV RNA Therefore retroviral RNA dimerization probably does not simply proceed through mechanisms involving Watson-Crick base-pairing Neither adenine and cytosine protonation, nor quartets containing only guanines appear to determine the stability of the HIV-1 RNA dimer, while quartets involving both adenine(s) and guanine(s) could account for our results A consensus sequence PuGGAPuA found in the putative dimerization-encapsidation region of all retroviral genomes examined may participate in the dimerization process

Specific Interaction between RNA Phage Coat Proteins and RNA

Abstract: Publisher Summary This chapter describes the biochemistry of the interaction of phage coat protein with RNA and attempt to provide a molecular understanding of its high specificity. Coat protein binding is believed to serve two functions in the life cycle of the phage: 1) it acts as a translational repressor of the replicase gene early in infection, and 2) as an initiation site of phage assembly late in infection. This interaction has been extensively a prototype of sequence specific RNA-protein interactions. It is now clear that the phage coat proteins can be considered an example of a class of RNA hairpin binding proteins that are quite common in prokaryotes and eukaryotes. In case of bacteriophage coat protein, the coat protein assembles into phage-like capsids that can be purified by differential centrifugation and ion-exchange chromatography. Most coat proteins can be successfully renatured by the transfer from storage buffer directly into a variety of neutral buffers of moderate ionic strength. In many cases, these renatured proteins are fully active in both RNA binding and capsid assembly.

Binding of Epstein-Barr virus small RNA EBER-1 to the double-stranded RNA-activated protein kinase DAI

Abstract: Epstein-Barr virus encodes two small RNAs, EBER-1 and -2, that are abundantly expressed in latently infected cells. Recent evidence suggests a role for EBER-1 in regulation of translation since this RNA is able to prevent the inhibition of protein synthesis by double-stranded RNA in rabbit reticulocyte lysates. We show here that EBER-1 that has been synthesized in vitro forms a complex with the dsRNA-activated inhibitor of protein synthesis DAI, a protein kinase that specifically phosphorylates polypeptide chain initiation factor eIF-2. Gel retardation assays and UV crosslinking experiments indicate that complex formation is specific for EBER-1 and requires the presence of some secondary structure in the molecule. RNA competition studies show that EBER-1-DAI complex formation is not inhibited in the presence of other small RNA species, heparin or the synthetic double-stranded RNA, poly(I).poly(C). SDS gel analysis reveals the existence of two forms of the crosslinked complex, of 64-68kDa and 46-53kDa, both of which are recognized by anti-DAI antibodies in immunoprecipitation experiments. These data suggest that EBER-1 regulates protein synthesis through its ability to interact with DAI.

RNA editing by cytidine insertion in mitochondria of Physarum polycephalum.

Abstract: A corollary of the central dogma of molecular biology is that genetic information passes from DNA to RNA by the continuous synthesis of RNA on a DNA template. The demonstration of RNA editing (the specific insertion, deletion or substitution of residues in RNA to create an RNA with a sequence different from its own template) raised the possibility that in some cases not all of the genetic information for a trait residues in the DNA template. Two different types of RNA editing have been identified in mitochondria: insertional editing represented by the extensive insertion (and occasional deletion) of uridine residues in mitochondrial RNAs of the kinetoplastid protozoa and the substitutional editing represented by the cytidine to uridine substitutions in some plant mitochondria. These editing types have not been shown to be present in the same organism and may have very different mechanisms. RNA editing of both types has been observed in nonmitochondrial systems but is not as extensive and may involve still different mechanisms. Here we report the discovery of extensive insertional RNA editing in mitochondria from an organism other than a kinetoplastid protozoan. The mitochondrial RNA apparently encoding the alpha subunit of ATP synthetase in the acellular slime mould, Physarum polycephalum, is edited at 54 sites by cytidine insertion.

Spontaneous cleavage of RNA in ternary complexes of Escherichia coli RNA polymerase and its significance for the mechanism of transcription.

Abstract: Ternary complexes of RNA polymerase, bearing the nascent RNA transcript, are intermediates in the synthesis of all RNAs and are regulatory targets of factors that control RNA chain elongation and termination. To study the catalytic and regulatory properties of RNA polymerases during elongation, we have developed methods for the preparation of these intermediates halted at defined positions along a DNA template. To our surprise, some of these halted complexes undergo a reaction in which the RNA transcript is cleaved up to 10 nucleotides from its 3'-terminal growing point. The 5'-terminal fragment, bearing a free 3'-OH residue, remains bound to the RNA polymerase-DNA complex and can resume elongation, whereas the 3'-terminal oligonucleotide of 2-10 nucleotides, bearing a 5'-phosphate, is released. RNA cleavage occurs only in the ternary complex and requires a divalent metal ion such as Mg2+. Since RNA polymerases are believed to have a single catalytic site for nucleotide addition, this reaction is unlikely to be due to hydrolysis catalyzed by this site comparable to the 3'----5' exonuclease activity associated with the catalytic center found for some DNA polymerases. Nor is this reaction easily explained by models for transcription elongation that postulate a 12-base-pair DNA.RNA hybrid as intermediate. Instead, we suggest that this is an unusual kind of protein-facilitated reaction in which tight binding of the RNA product to the enzyme strains the RNA phosphodiester linkage, resulting in cleavage of the RNA well away from the catalytic center. By this model, the nascent RNA enters a product binding site beginning 3 or 4 nucleotides from the growing point at the 3' terminus. This RNA binding site extends for up to 16 nucleotides along the protein surface. The stress brought about by this binding appears to vary considerably for different ternary complexes and may play a role in driving the translocation of the RNA polymerase along the DNA.

Rescue of a foreign gene by Sendai virus.

Abstract: A simple protocol for the rescue of a synthetic genome into a paramyxovirus has been developed. First, a synthetic Sendai virus-like RNA, containing the antisense coding region of the chloramphenicol acetyltransferase gene replacing the coding region of the Sendai virus genome, was transcribed from a cDNA. When introduced into cells that are infected with Sendai virus, this RNA construct was transcribed, replicated, and packaged into infectious virions. The addition of infected cell extract to the RNA prior to transfection markedly enhanced levels of chloramphenicol acetyltransferase expression and rescue. However, this enhancement is not due to encapsidation of the RNA into nucleocapsids as the RNA remains nuclease-sensitive. Uninfected cell extract also enhances expression and rescue efficiency, implying involvement of a cellular factor(s) with the synthetic viral-like RNA construct that allows for enhanced polymerase recognition. This system should allow for the dissection of the various cis-acting RNA signals within the paramyxovirus genome.

An analysis of the sequence of an infectious clone of rice tungro bacilliform virus, a plant pararetrovirus.

Abstract: The nucleotide sequence of an infectious clone of rice tungro bacilliform virus (RTBV) DNA has been determined. The circular genome has 8002 bp and one strand contains four open reading frames (ORFs). One ORF is potentially capable of encoding a protein of 24 kD (P24) and has no initiation (ATG) codon. The other three ORFs potentially encode proteins of 12 kD, 194 kD and 46 kD (P12, P194, P46) respectively. The functions of P24, P12 and P46 are unknown. Comparative analyses with retroviruses and Commelina yellow mottle virus suggest that the 194 kD putative product is a polyprotein that is proteolytically cleaved to yield the virion coat protein, a protease and replicase (reverse transcriptase and RNase H) characteristic of retroelements. The DNA sequence reveals other features which strongly support our belief that RTBV is a pararetrovirus. These include sequences at the mapped positions of two discontinuities in the virion DNA which are complementary to tRNA metinit and purine-rich, and may be the priming sites for minus- and plus-strand DNA synthesis respectively. As the positions of likely transcriptional signals suggest, a full-length viral transcript is observed by northern analysis. The predicted folding of the 645 bp 5'-region of this RNA resembles that of caulimoviruses. Comparisons with other reverse transcribing elements are discussed.

Recombination between Sindbis virus RNAs.

Abstract: The Sindbis virus RNA genome is divided into two modules - one coding for the nonstructural protein genes and the other coding for the structural protein genes. In our studies of recombination, the two parental RNAs were defective in different modules. Analysis of the recombinant RNAs demonstrated that the parental RNAs each contributed its intact module and that the crossovers occurred within the defective modules. The recombinational events giving rise to infectious virion RNAs could create deletions, rearrangements or insertions as long as they occurred outside of the functional module. These crossovers produced RNA genomes that contained two functional subgenomic RNA promoters.

Promoter ligation activated transcription amplification of nucleic acid sequences

Abstract: This invention discloses a scheme for producing nucleic acid end products that are functionally or exactly identical to the starting products, thereby resulting in exponential amplification of a desired nucleic acide sequence. Specifically, sequences are cycled between RNA and DNA forms using the following basic steps: (1) a T7 RNA polymerase promoter is ligated onto a single-stranded DNA template; (2) T7 RNA polymerase makes many copies of RNA: (3) a complementary DNA is made from the RNA by extension of a primer by reverse transcriptase; and (4) the RNA template is removed by ribonuclease H. This amplification method is useful for purposes such as genetic research and diagnostic assays.

The cloned RNA polymerase II transcription factor IID selects RNA polymerase III to transcribe the human U6 gene in vitro.

Abstract: Although the human U2 and U6 snRNA genes are transcribed by different RNA polymerases (i.e., RNA polymerases II and III, respectively), their promoters are very similar in structure. Both contain a proximal sequence element (PSE) and an octamer motif-containing enhancer, and these elements are interchangeable between the two promoters. The RNA polymerase III specificity of the U6 promoter is conferred by a single A/T-rich element located around position -25. Mutation of the A/T-rich region converts the U6 promoter into an RNA polymerase II promoter, whereas insertion of the A/T-rich region into the U2 promoter converts that promoter into an RNA polymerase III promoter. We show that this A/T-rich element can be replaced by a number of TATA boxes derived from mRNA promoters transcribed by RNA polymerase II with little effect on RNA polymerase III transcription. Furthermore, the cloned RNA polymerase II transcription factor TFIID both binds to the U6 A/T-rich region and directs accurate RNA polymerase III transcription in vitro. Mutations in the U6 A/T-rich region that convert the U6 promoter into an RNA polymerase II promoter also abolish TFIID binding. Together, these observations suggest that in the human snRNA promoters, unlike in mRNA promoters, binding of TFIID directs the assembly of RNA polymerase III transcription complexes, whereas the lack of TFIID binding results in the assembly of RNA polymerase II snRNA transcription complexes.

Deletion analysis of brome mosaic virus 2a protein: effects on RNA replication and systemic spread.

Abstract: Brome mosaic virus (BMV) genomic RNA2 encodes the 94-kDa 2a protein, which is one of two BMV nonstructural proteins required for RNA replication and subgenomic mRNA transcription. 2a contains a central polymeraselike region, which has extensive sequence similarity with the Sindbis virus nsP4 and tobacco mosaic virus (TMV) 183-kDa replication proteins, and also contains N- and C-terminal flanking segments without counterparts in the Sindbis virus and TMV nonstructural proteins. To further investigate the roles of the central and flanking segments in 2a, we have constructed a series of deletion and frameshift mutants in a biologically active BMV RNA2 cDNA clone and tested their ability to support viral RNA replication in barley protoplasts and systemic infection in whole barley plants. The entire 125-amino-acid C-terminal segment following the polymeraselike region was dispensable for RNA replication and transcription. Within the 200-amino-acid N-terminal flanking segment, deletion of the first 50 residues dramatically reduced genomic and subgenomic RNA accumulation, and deletion of 100 or more residues abolished detectable RNA synthesis. All mutations removing residues from the central polymeraselike domain also blocked RNA replication in trans. Sequences required in cis for RNA2 replication or stability were found to occur within the first 300 nucleotides of the 2a coding region. In whole barley plants, systemic infection was inhibited even by 2a deletions that supported strong RNA replication in protoplasts. Some replication-competent 2a variants failed to spread to uninoculated leaves, while other showed 10- to 500-fold-reduced virus yield in both inoculated and uninoculated leaves. These reductions were not due to any defects in RNA2 encapsidation.

RNA polymerase II pauses at the 5' end of the transcriptionally induced Drosophila hsp70 gene.

Abstract: An RNA polymerase II molecule is associated with the 5' end of the Drosophila melanogaster hsp70 gene under non-heat shock conditions. This polymerase is engaged in transcription but has paused, or arrested, after synthesizing about 25 nucleotides (A. E. Rougvie and J. T. Lis, Cell 54:795-804, 1988). Resumption of elongation by this paused polymerase appears to be the rate-limiting step in hsp70 transcription in uninduced cells. Here we report results of nuclear run-on assays that measure the distribution of elongating and paused RNA polymerase molecules on the hsp70 gene in induced cells. Pausing of polymerase was detected at the 5' end of hsp70 in cells exposed to the intermediate heat shock temperatures of 27 and 30 degrees C. At 30 degrees C, each copy of hsp70 was transcribed approximately five times during the 25-min heat shock that we used. Therefore, once the hsp70 gene is induced to an intermediate level, initiation of transcription by RNA polymerase II remains more rapid than the resumption of elongation by a paused polymerase molecule.

Binding of human immunodeficiency virus type 1 (HIV-1) RNA to recombinant HIV-1 gag polyprotein.

Abstract: We have expressed the human immunodeficiency virus type 1 (HIV-1) gag polyprotein (Pr55gag) in bacteria under the control of the T7 phage gene 10 promoter. When the gene encoding the viral protease is included in cis, in the -1 reading frame, the expected proteolytic cleavage products MA and CA are produced. Disruption of the protease-coding sequence prevents proteolytic processing, and full-length polyprotein is produced. Pr55gag, separated from bacterial proteins by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) and immobilized on nitrocellulose membranes, binds RNA containing sequences from the 5' end of the HIV-1 genome. This binding is tolerant of a wide range of pH and temperature but has distinct salt preferences. Conditions were identified which prevented nonspecific binding of RNA to bacterial proteins but still allowed binding to Pr55gag. Under these conditions, irrelevant RNA probes lacking HIV-1 sequences bound Pr55gag less efficiently. Quantitation of binding to Pr55gag by HIV-1 RNA probes with deletions mutations demonstrated that there are two regions lying within the HIV-1 gag gene which independently promote binding of RNA to Pr55gag.

RNA-mediated ligation of self-cleavage products of a Neurospora mitochondrial plasmid transcript.

Abstract: Neurospora VS RNA is a mitochondrial single-stranded RNA that combines certain features of catalytic RNAs and group I introns. We report here that monomeric VS RNA synthesized in vitro by self-cleavage of a multimeric transcript can perform an RNA-mediated self-ligation reaction producing circular RNAs indistinguishable from those isolated from mitochondria. We conclude that the active site for the ligation reaction is present in the RNA itself. Also, the mechanism for aligning the termini to be ligated may be different from mechanisms previously described. The lack of sequence similarity between VS RNA and previously characterized catalytic RNAs suggests that VS RNA is an independently evolved ribozyme capable of both cleavage and ligation.