Showing papers on "RNA-dependent RNA polymerase published in 1978"

Inhibition of Rous sarcoma viral RNA translation by a specific oligodeoxyribonucleotide

Abstract: A tridecamer oligodeoxynucleotide, d(A-A-T-G-G-T-A-A-A-A-T-G-G), which is complementary to reiterated 3'- and 5'-terminal nucleotides of Rous sarcoma virus 35S RNA, is an efficient inhibitor of the translation of proteins specified by the viral RNA in the wheat embryo cell-free system. The inhibition specificity for oncornavirus RNA is greater than for rabbit reticulocyte mRNA or brome mosaic virus RNA. Other oligodeoxynucleotides of similar size have little or no specific effect on the RNA-directed translation. The tridecamer acts as a primer for the avian myeloblastosis virus DNA polymerase when Rous sarcoma virus heated 70S RNA is used as a template, offering evidence that it can hybridize to the RNA. The possible use of such an oligodeoxynucleotide hybridization competitor to inhibit Rous sarcoma virus replication is described in the preceding paper [Zamecnik, P. C. & Stephenson, M. L. (1978) Proc. Natl. Acad. Sci. USA. 75, 280--284].

3'-terminal labelling of RNA with T4 RNA ligase.

Abstract: T4 RNA LIGASE catalyses the formation of an internucleotide phosphodiester bond between an oligonucleotide donor molecule with a 5′-terminal phosphate and an oligonucleotide acceptor molecule with a 3′-terminal hydroxyl1–3. Although the minimal acceptor must be a trinucleoside diphosphate, dinucleoside pyrophosphates and mononucleoside 3′,5′-bisphosphates (pNps) are effective donors in the intermolecular reaction4–6. We demonstrate here that various high molecular weight RNA molecules are acceptors in the RNA ligase reaction even when present in very low concentrations in the reaction mixture. One immediate consequence of this observation is that a convenient method for labelling the 3′ end of RNA molecules in vitro becomes available. By using a [5′-32P]pNp as a donor and RNA as an acceptor, the product of the reaction is an RNA molecule one nucleotide longer, with a 3′-terminal phosphate and a 32P-phosphate in the last internucleotide linkage. This reaction is therefore analogous to the in vitro labelling of the 5′ termini of RNA chains with polynucleotide kinase and [γ-32P]ATP and can be used in situations where 5′ labelling is not possible. In addition, the ability to add various donors to an RNA molecule should allow the function of the 3′ terminus of the molecule to be investigated.

Globin mRNAs are primers for the transcription of influenza viral RNA in vitro

Abstract: Because influenza viral RNA transcription in vitro is greatly enhanced by the addition of a primer dinucleotide, ApG or GpG, we have proposed that viral RNA transcription in vivo requires initiation by primer RNAs synthesized by the host cell, specifically by RNA polymerase II, thereby explaining the α-amanitin sensitivity of viral RNA transcription in vivo. Here, we identify such primer RNAs, initially in reticulocyte extracts, where they are shown to be globin mRNAs. Purified globin mRNAs very effectively stimulated viral RNA transcription in vitro, and the resulting transcripts directed the synthesis of all the nonglycosylated virus-specific proteins in micrococcal nuclease-treated L cell extracts. The viral RNA transcripts synthesized in vitro primed by ApG also directed the synthesis of the nonglycosylated virus-specific proteins, but the globin mRNA-primed transcripts were translated about 3 times more efficiently. The translation of the globin mRNA-primed, but not the ApG-primed, viral RNA transcripts was inhibited by 7-methylguanosine 5′-phosphate in the presence of S-adenosylhomocysteine, suggesting that the globin mRNA-primed transcripts contained a 5′-terminal methylated cap structure. We propose that this cap was transferred from the globin mRNA primer to the newly synthesized viral RNA transcripts, because no detectable de novo synthesis of a methylated cap occurred during globin mRNA-primed viral RNA transcription. Preliminary experiments indicate that other purified eukaryotic mRNAs also stimulate influenza viral RNA transcription in vitro.

3'-terminal nucleotide sequence of encephalomyocarditis virus RNA determined by reverse transcriptase and chain-terminating inhibitors

Abstract: We have adapted the chain-termination method for determining the nucleotide sequence of DNA of Sanger, Nicklen, and Coulson [(1977) Proc. Natl. Acad. Sci. USA 74, 5463--5467] for use with reverse transcriptase (RNA-directed DNA nucleotidyltransferase) on RNA templates. With this method and using a primer (the octanucleotide pdT7rC) directed at the 3'-terminal poly(A), we have determined a sequence of 166 residues in the genomic RNA of the picornavirus encephalomyocarditis virus.

RNA of mouse hepatitis virus.

Abstract: The RNA of mouse hepatitis virus, a coronavirus, was isolated from the virus released early in the infection and analyzed by sucrose gradient sedimentation and electrophoresis. It was found to consist of a piece of single-stranded RNA of about 60S. Its molecular weight was estimated to be 5.4 X 10(6) by electrophoresis in methylmercury-agarose gels. At least one third of the RNA contained polyadenylated sequences. It is, therefore, probably positive stranded. The virus harvested late in the infection contained, in addition to 60S, some 30 to 50S RNA that are possibly degradation products of the 60S RNA. No difference in the electrophoretic behavior could be detected between the RNA isolated from a pathogenic (JHM) and a nonpathogenic (A59) strain.

Nonspecific interactions of Escherichia coli RNA polymerase with native and denatured DNA: differences in the binding behavior of core and holoenzyme

Abstract: We have investigated the nonspecific interactions of Escherichia coli RNA polymerase core and holoenzyme with double-stranded (ds) and single-stranded (ss) DNA. Binding constants for these interactions as functions of such solution variables as monovalent and/or divalent cation concentration, temperature, or pH were determined by the method of deHaseth et a. [deHaseth, P.L., Gross, C.A., Burgess, R.R. and Record, M.T. (1977), Biochemistry 16, 4777--4783] from analysis of the elution of the proteins from small columns containing immobilized DNA. This technique, although as yet empirical, has been demonstrated to yield accurate binding constants fot the nonspecific interation of lac repressor with ds DNA. We find that observed binding constants (Kobsd) are extraordinarily sensitive functions of the monovalent cation concentration for the interactions of both core and holoenzyme with ds DNA. In the absence of divalent cations, the derivatives --(d log Kobsd/d log [Na+]) are 11 +/- 2 for the holo--ds DNA interaction and 21 +/- 3 for the core--ds DNA interaction. Consequently, approximately 11 and 21 low-molecular-weight ions are released, iin the thermodynamic sense, in the formation of the holo--ds and core--ds complexes, respectively (Record, M.T., Jr., Lohman, T.M., and deHaseth, P.L. (1976), J. Mol. Biol. 107, 145--158; Record, M.T., Jr., Anderson, C.F., and Lohman, T.M. (1978), Q. Rev. Biophys., in press). Ion release is a thermodynamic driving force for these nonspecific interactions and causes the stability of the complexes to increase very substantially with a reduction in monovalent ion concnetration. Possible molecular models which account for the different salt sensitivities of the holo--ds and core--ds complexes are discussed. Effects of the competitive ligand Mg2+ on these interactions are also examined. Substantial ion release (approximately 18 monovalent ions) also accompanies the interaction of either holo or core polymerase with ss DNA. Over the range of ion concentrations investigated the holo--ss interaction is substantially stronger than the core--ss interaction; furthermore, we conclude that the interactions of polymerase with ss DNA are, in general, stronger than the nonspecific interations of the enzyme with ds DNA. It is likely that the nonspecific interactions of RNA polymerase with DNA have physiological relevance. Not only is it plausible to assume that the same regions of the protein are involved in both specific and nonspecific interactions, but in addition nonspecific interactions of RNA polymerase and DNA may play role in determining the availability of this protein, in both the thermodynamic and the kinetic sense, for promoter binding and RNA chain initiation [von Hippel. P.H., Revzin, A., Gross, C.A., and Wang, A.C. (1974), Proc. Natl. Acad. Sci U.S.A. 71, 4808--4812]. Consequently, the strong dependences of the nonspecific interactions of RNA polymerase on ionic conditions suggest the possibility of a modulating role of ion concentrations in the control of transcription.

Specific RNA sequences and gene products of MC29 avian acute leukemia virus.

Abstract: The 28S RNA of the defective avian acute leukemia virus MC29 contains two sets of sequences: 60% are hybridized by DNA complementary to other avian tumor virus RNAs (group-specific cDNA) and 40% are hybridized only by MC29-specific cDNA. Specific and group-specific sequences of viral RNA, defined in terms of their large RNase T1-resistant oligonucleotides, were located on a map of all large T1 oligonucleotides of viral RNA. Oligonucleotides representing MC29-specific sequences of viral RNA mapped between 0.4 and 0.7 unit from the 3′-poly(A) end. Oligonucleotides of group-specific sequences mapped between 0 and 0.4 and between 0.7 and 1 map unit. Cell-free translation of viral RNA yielded three proteins with approximate molecular weights of 120,000, 56,000, and 37,000, termed P120mc, P56mc, and P37mc. P120mc contained both MC29-specific peptides and serological determinants and peptides of the conserved, internal group-specific antigens of avian tumor viruses. P120mc is translated only from full-length 28S RNA. Furthermore, MC29 RNA contains sequences related to the group-specific antigen gene (gag), near the 5′ end, which are followed by MC29-specific sequences. We conclude that this protein is translated from the 5′ 60% of the RNA, and that it includes a segment translated from the specific sequences. It is suggested that the transforming (onc) gene of MC29 may consists of the specific and some group-specific RNA sequences and that P120mc, which is also found in transformed cells, may be the onc gene product.

Small Stable RNAs from Escherichia coli: Evidence for the Existence of New Molecules and for a New Ribonucleoprotein Particle Containing 6S RNA

Abstract: Small stable RNA molecules of Escherichia coli other than 5S (rRNA) and 4S (tRNA) were studied. Two of the molecules corresponded to 4.5S and 6S RNA, which have been reported previously. The third stable RNA molecule, 10S RNA, has not been described before. RNA labeled with (32)P(i) or [(14)C]uracil for a relatively long time, when separated in 5%/12% tandem polyacrylamide gels, displayed three bands corresponding to 10S, 6S, and 4.5S RNA in addition to rRNA and tRNA bands. These RNAs were stable in pulse-chase-labeling experiments. The amount of these RNAs was small, comprising only 0.2 to 0.5% of the total (32)P incorporation. However, this amount represented a large number of molecules; for 6S and 4.5S, it was about 1,000/DNA molecule. These three RNAs were found in the postribosomal supernatant fraction. None of them was found in purified nucleoid fractions in which the tightly coiled DNA molecules were contained. Of these three RNAs, 6S RNA was unique in that it seemed to exist in a ribonucleoprotein particle. All these RNAs, as well as tRNA, were very stable in the cell under various physiological conditions. 5S RNA was less stable. On the other hand, purified 6S RNA was more susceptible than tRNA to cell nucleases when incubated with cell extracts, suggesting that, being in a particle, it is protected from cell nucleases.

Adenovirus DNA-directed transcription of 5.5S RNA in vitro

Abstract: A cell-free system developed from human KB cells was used to transcribe 5.5S RNA from deproteinized adenovirus DNA in vitro. The cell-free RNA synthesis is dependent upon exogenous templates, ribonucleoside triphosphates, and cell-free postmitochondrial supernatant of human KB cells. The synthesis of 5.5S RNA is inhibited only by high levels of alpha-amanitin; therefore it is carried out by RNA polymerase III. The rate of synthesis was linear for at least 2 hr, indicating reinitiation. The 5.5S RNA synthesized in vitro is similar to the corresponding in vivo RNA in size, sequence, and coding region on adenovirus type 2 DNA. In this report is demonstrated in vitro synthesis of a facsimile of an in vivo transcript directed by deproteinized DNA in a mammalian cell-free postmitochondrial supernatant system.

Contacts between Escherichia coli RNA polymerase and a lac operon promoter

Abstract: The chemical alkylating agent dimethyl sulfate can probe the interaction between Escherichia coli RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) and the purine bases of a promoter. This agent methylates the N7 position on guanine or the N3 position on adenine; the bound protein can either protect these positions or affect the reactivity to produce an enhanced methylation. The pattern of DNA residues in the lactose promoter protected from, or enhanced to, methylation by a specifically bound polymerase shows that the enzyme covers a region of at least 38 base pairs, stretching upstream from the origin of transcription. These protein-DNA contacts occur predominantly in the major groove of the DNA helix. Furthermore, this pattern of methylation shows that the polymerase unwinds the helix at the origin of transcription. The relationship between polymerase-DNA contacts defined by dimethyl sulfate and known features of promoter structure is discussed. To facilitate these experiments I have constructed a plasmid that permits a unique 5'-end labeling of each strand of a 95-base-pair fragment containing a lac operon promoter. This plasmid contains two copies of the lac promoter-operator region.

Transcription pattern of in vivo-labeled late simian virus 40 RNA: equimolar transcription beyond the mRNA 3' terminus.

Abstract: We have examined the pattern of RNA transcription on the L (late) DNA strand late in the simian virus 40 virus infectious cycle by separating pulse-labeled RNA chains according to size and hybridizing to an ordered series of DNA fragments obtained by restriction enzyme digestion. From this analysis, the 5' end of the nascent transcript occurs a short distance counterclockwise from 0.735. Transcription proceeds in a clockwise direction. There is equimolar transcription for at least 1,000 nucleotides beyond the 3' end of the mRNA (0.175). The 3' terminus for the largest molecules is in 0.43--0.655. Molecules which represent more than one circuit of the genome are not more than 1% of the total population of nascent molecules. Implications of these findings for models of the biogenesis of mRNA are discussed.

Identification of a protein linked to nascent poliovirus RNA and to the polyuridylic acid of negative-strand RNA.

Abstract: A protein similar to that previously demonstrated on poliovirus RNA and replicative intermediate RNA (VPg) was found on all sizes of nascent viral RNA molecules and on the polyuridylic acid isolated from negative-strand RNA. ^(32)P-labeled nascent chains were released from their template RNA and fractionated by exclusion chromatography on agarose. Fingerprint analysis using two-dimensional polyacrylamide gels of RNase T1 oligonucleotides derived from nascent chains of different lengths showed that a size fractionation of nascent chains was achieved. VPg was recovered from nascent chains varying in length from 7,500 nucleotides (full-sized RNA) to about 500 nucleotides. No other type of 5' terminus could be demonstrated on nascent RNA, and the yield of VPg was consistent with one molecule of the protein on each nascent chain. These results are consistent with the concept that the protein is added to the 5' end of the growing RNA chains at a very early stage, possibly as a primer of RNA synthesis. Analysis of the polyuridylic acid tract isolated from the replicative intermediate and double-stranded RNAs indicated that a protein of the same size as that found on the nascent chains and virion RNA is also linked to the negative-strand RNAs. It is likely that a similar mechanism is responsible for initiation of synthesis of both plus- and minus-strand RNAs.

Sequence complexity and relative abundance of vaccinia virus mRNA's synthesized in vivo and in vitro.

Abstract: The sequence complexity and relative abundance of vaccinia virus mRNA's, synthesized in vivo and in vitro, have been measured by DNA-RNA hybridization. Up to 42% of [3H]thymidine-labeled virus DNA can be protected from digestion with nuclease S1, a single-strand specific nuclease, after annealing to excess polyadenylylated mRNA obtained at 7 h after infection. In contrast, only 26% of vaccinia virus DNA is protected when hybridized to polyadenylylated RNA obtained at 2 h after infection in the presence of an inhibitor of DNA synthesis. That the 94 kilobases transcribed early are a subset of the 152 kilobases present late was suggested by hybridization of DNA with a mixture of early and late RNAs. Some control of transcription is lost when virus purified by procedures that include sonic treatment is used for infection since under these conditions similar proportions of DNA are protected by either excess early or late RNA. Excess RNA, synthesized in vitro by enzymes within purified vaccinia virus particles, hybridized to approximately the same fraction of the DNA as did RNA present at late times in vivo. A second type of transcriptional control was demonstrated by kinetic analysis of the hybridization of polyadenylylated RNA to labeled DNA. With virion DNA used as the probe, a single abundance class for early RNA, two classes differing 11-fold in abundance for late RNA, and two classes differing 43-fold in abundance for in vitro RNA were found. To be able to detect high-abundance RNAs of very low sequence complexity, labeled complementary DNA probes to early, late, and in vitro polyadenylylated RNA were used. Evidence that, at late times, RNAs totaling 9 kilobases of sequence complexity are present 40 to 500 times more frequently than the bulk of the virus-specific RNA was obtained. In contrast, the highest abundance class of RNA present at 2 h after infection corresponded to 7 kilobases present in only a 13-fold molar excess over the majority of virus-specific sequences. RNA synthesized in vitro was found to contain a small amount of sequence information, approximately 2 kilobases, which occurred 150 times more frequently than the majority of viral sequences. Studies using hybridization of viral DNA to labeled complementary DNA probes also suggested that 52 to 59% of the polyadenylylated RNA present at 2 h after infection and 82 to 92% of that at 7 h are virus specific.

A protein linked to the 5' termini of both RNA components of the cowpea mosaic virus genome

Abstract: Evidence is presented for the presence of a protein covalently bound to the 5' termini of both M and B RNA components of CPMV. The protein is found to be linked in both cases to the 5' phosphate of the dinucleotide pUpAp, derived by ribonuclease digestion of the RNA. The intact protein is not required for infectivity or for in vitro translation of the RNA in cell-free extracts.

DNA-dependent RNA polymerase from Halobacterium halobium

Abstract: DNA-dependent RNA polymerase core enzyme was isolated from Halobacterium halobium. The purification is based on the finding that the enzyme is stable in 40% (v/v) glycerol, in the presence of 0.05 M MgCl2 and involves adsorption of contaminants to DEAE-cellulose, precipitation of the complex of polymerase with DNA by streptomycin sulfate, chromatography over Biogel and affinity chromatography over heparin-Sepharose or heparin-cellulose. The enzyme consists of four or five different subunits. The composition formula was estimated as (150000) (86000)2 (72000)2 (49000)3 or 2; there may be one or two different 49000-Mr subunits. RNA synthesis requires a template. Denatured DNA is more efficient than native DNA. The transcription of native DNA is specifically stimulated by the addition of a possibly sigma-like factor eluted from DEAE-cellulose. The fidelity of transcription is indicated by the absolute requirement for UTP besides ATP with poly[d(A-T)] as the template.

Identification of a 30S RNA with properties of a defective type C virus in murine cells.

Abstract: A novel species of 30S RNA has been detected in a variety of mouse cell lines The 30S RNA is specifically packaged by helper-independent type C viruses propagated in such cells Nucleic acid hybridization detects no homology between the 30SRNA and the genomic RNA of helper-independent mouse type C viruses The properties of the 30S RNA suggest that it is a defective endogenous mouse type C virus and that it is analogous to a previously described class of defective endogenous rat type C virus, which has been shown previously to be the progenitor of Kirsten and Harvey murine sarcoma viruses

Coat protein binds to the 3'-terminal part of RNA 4 of alfalfa mosaic virus.

Abstract: All four RNAs of alfalfa mosaic virus contain a limited number of sites with a high affinity for coat protein [Van Boxsel, J. A. M. (1976), Ph.D. Thesis, University of Leiden]. In order to localize these sites in the viral RNAs, RNA 4 Tthe subgenomic messenger for coat protein) was subjected to a very mild digestion with ribonucleast T1. The ten major fragments, apparently resulting from five preferential hits, were separated and tested for messenger activity in a wheat germ cell-free system, as well as for the capacity to withdraw coat protein from intact particles. Fragments which stimulated amino acid incorporation were assumed to contain the 5 terminus. Strong evidence was obtained for the location of sites with a high affinity for coat protein near the 3' terminus. The smallest fragment which has the 3'-terminal cytosine comprises only 10% of the length of intact RNA 4 but still possesses these sites. Evidence is presented that the complete coat protein cistron is in the complementing 90% fragment. Possibly, the high-affinity sites are entirely located in the 3'-terminal extracistronic part of RNA 4. They will have the same position in RNA 3 and, possibly, also in the other parts of the genome of alfalfa mosaic virus. The need of this genome for coat protein in order to become infectious may therefore find its explanation in the fact that a conformational change at the 3' ends of the genome parts brought about by the coat protein is required for recognition by the viral replicase.

Analysis of terminal structures of RNA from potato virus X.

Abstract: The 5'-end structure of potato virus X RNA was determined following enzymatic methylation in vitro. A single 3H-methyl group was introduced into the 2'-position of the 5'-penultimate residue and the end structure was determined as m7GpppG(m)pAp(Xp)3G. This part of the RNA apparently is involved in binding to ribosomes since it can be partially protected against RNase digestion by wheat germ 40S ribosomes. PVX RNA was not retained by poly(U)-sepharose, indicating that it does not contain a 3'-terminal poly(A) tract.