Transcription of DNA from the 70S RNA of Rous sarcoma virus. II. Structure of a 4S RNA primer

The Host RNAs in Retroviral Particles

As they assemble, retroviruses encapsidate both their genomic RNAs and several types of host RNA. Whereas limited amounts of messenger RNA (mRNA) are detectable within virion populations, the predominant classes of encapsidated host RNAs do not encode proteins, but instead include endogenous retroelements and several classes of non-coding RNA (ncRNA), some of which are packaged in significant molar excess to the viral genome. Surprisingly, although the most abundant host RNAs in retroviruses are also abundant in cells, unusual forms of these RNAs are packaged preferentially, suggesting that these RNAs are recruited early in their biogenesis: before associating with their cognate protein partners, and/or from transient or rare RNA populations. These RNAs' packaging determinants differ from the viral genome's, and several of the abundantly packaged host ncRNAs serve cells as the scaffolds of ribonucleoprotein particles. Because virion assembly is equally efficient whether or not genomic RNA is available, yet RNA appears critical to the structural integrity of retroviral particles, it seems possible that the selectively encapsidated host ncRNAs might play roles in assembly. Indeed, some host ncRNAs appear to act during replication, as some transfer RNA (tRNA) species may contribute to nuclear import of human immunodeficiency virus 1 (HIV-1) reverse transcription complexes, and other tRNA interactions with the viral Gag protein aid correct trafficking to plasma membrane assembly sites. However, despite high conservation of packaging for certain host RNAs, replication roles for most of these selectively encapsidated RNAs-if any-have remained elusive.

Analysis of the human immunodeficiency virus-1 RNA packageome

All retroviruses package cellular RNAs into virions. Studies of murine leukemia virus (MLV) revealed that the major host cell RNAs encapsidated by this simple retrovirus were LTR retrotransposons and noncoding RNAs (ncRNAs). Several classes of ncRNAs appeared to be packaged by MLV shortly after synthesis, as precursors to tRNAs, small nuclear RNAs, and small nucleolar RNAs were all enriched in virions. To determine the extent to which the human immunodeficiency virus (HIV-1) packages similar RNAs, we used high-throughput sequencing to characterize the RNAs within infectious HIV-1 virions produced in CEM-SS T lymphoblastoid cells. We report that the most abundant cellular RNAs in HIV-1 virions are 7SL RNA and transcripts from numerous divergent and truncated members of the long interspersed element (LINE) and short interspersed element (SINE) families of retrotransposons. We also detected precursors to several tRNAs and small nuclear RNAs as well as transcripts derived from the ribosomal DNA (rDNA) intergenic spacers. We show that packaging of a pre-tRNA requires the nuclear export receptor Exportin 5, indicating that HIV-1 recruits at least some newly made ncRNAs in the cytoplasm. Together, our work identifies the set of RNAs packaged by HIV-1 and reveals that early steps in HIV-1 assembly intersect with host cell ncRNA biogenesis pathways.

Packaging and reverse transcription of snRNAs by retroviruses may generate pseudogenes

Retroviruses specifically package two copies of their RNA genome in each viral particle, along with some small cellular RNAs, including tRNAs and 7S L RNA. We show here that Rous sarcoma virus (RSV) also packages U6 snRNA at approximately one copy per virion. In addition, trace amounts of U1 and U2 snRNAs were detected in purified virus by Northern blotting. U6 snRNA comigrated with the RSV 70S genomic RNA dimer on sucrose gradients. We observed reverse transcription of U6 snRNA in an endogenous reaction in which RSV particles were the source of both reverse transcriptase and RNA substrates. This finding led us to examine mammalian genomic sequences for the presence of snRNA pseudogenes. A survey of the human, mouse, and rat genomes revealed a high number of spliceosomal snRNA pseudogenes. U6 pseudogenes were the most abundant, with approximately 200 copies in each genome. In the human genome, 67% of U6 snRNA pseudogenes, and a significant number of the other snRNA pseudogenes, were associated with LINE, SINE, or retroviral LTR repeat sequences. We propose that the packaging of snRNAs in retroviral particles leads to their reverse transcription in an infected cell and the integration of snRNA/viral recombinants into the host genome.

Isolation of three kinds of human endogenous retrovirus-like sequences using tRNA(Pro) as a probe

Three kinds of human endogenous retrovirus-like sequences (HuERS-P1, 2 and 3) were isolated from a HeLa cell genomic library using the 3'-half fragment of proline tRNA as a hybridization probe. These elements contained putative primer binding sites complementary to the 3'-terminus of proline tRNA and long terminal repeats (LTRs) characteristic of retrovirus provirus. The LTR sequence of HuERS-P1 consisted of about 690 nucleotides and contained a CAT box, a TATA box and a polyadenylation signal. A complete unit of an Alu family sequence was inserted into the 5'-LTR of one of the clones. HuERS-P2 also contained a TATA box and a polyadenylation signal in its LTR (about 840 nucleotides long), but the LTR sequence of this element was quite different from that of HuERS-P1. Although clone HuERS-P3 contained only the 5'-LTR region, this LTR sequence contained a CAT box, a TATA box and a poly-adenylation signal and was quite similar to the LTR sequence of the recently isolated human retrovirus-related sequence HuRRS-P (Kröger, B. and Horak, I. (1987) J. Virol., 61, 2071-2075). Human and simian DNAs contain 10 to 40 copies of these elements, but mouse DNA does not contain these elements.

The pathophysiology of murine retrovirus-induced leukemias

Murine leukemia viruses (MuLVs) are retroviruses which induce a broad spectrum of hematopoietic malignancies. In contrast to the acutely transforming retroviruses, MuLVs do not contain transduced cellular genes, or oncogenes. Nonetheless, MuLVs can cause leukemias quickly (4 to 6 weeks) and efficiently (up to 100% incidence) in susceptible strains of mice. The molecular basis of MuLV-induced leukemia is not clear. However, the contribution of individual viral genes to leukemogenesis can be assayed by creating novel viruses in vitro using recombinant DNA techniques. These genetically engineered viruses are tested in vivo for their ability to cause leukemia. Leukemogenic MuLVs possess genetic sequences which are not found in nonleukemogenic viruses. These sequences control the histologic type, incidence, and latency of disease induced by individual MuL Vs.

Structural features required for the binding of tRNATrp to avian myeloblastosis virus reverse transcriptase

The basis of the specific binding of tRNATrp by avian myeloblastosis virus reverse transcriptase was studied by chemical and enzymatic modification of the RNA. Binding does not depend on recognition of the tryptophan anticodon since molecules cleaved in the anticodon are stably bound by the enzyme. Modification of pseudouridine residues in the tRNA destroys binding to reverse transcriptase. These results are consistent with a model in which reverse transcriptase-tRNATrp interaction occurs not at the anticodon, but at regions in the tRNA which contain or are stabilized by pseudouridine residues.

Synthesis of murine leukemia viral DNA in vitro: evidence for plus-strand DNA synthesis at both ends of the genome

We studied the synthesis of B-tropic murine leukemia viral DNA in vitro by detergent-disrupted virions. The reaction products (detected by the Southern transfer technique) included full-length, infectious, double-stranded DNA and several subgenomic fragments. Restriction endonuclease analysis and hybridization and specific probes revealed two classes of subgenomic fragments: some were derived from the right end of the genome, and some were derived from the left end. Most of the fragments harbored one long terminal repeat copy at their ends, suggesting that they were initiated correctly. S1 nuclease and restriction endonuclease treatments of these fragments indicated that a single-stranded gap was present near the first initiation site of plus strong-stop DNA. The treatments also suggested the presence of a second initiation site flanked by a single-stranded gap 0.9 kilobase pairs from the right end of the genome. Our data clearly show that plus-strand DNA is synthesized at both ends of the genome, by using plus strong stop as the first initiation site and additional initiation sites.

tRNA's and priming of RNA-directed DNA synthesis in mouse mammary tumor virus

The low-molecular-weight RNAs of mouse mammary tumor virus (MuMTV) were examined by two-dimensional acrylamide gel electrophoresis. Unlike other retroviruses, MuMTV was found to contain only two major fractions of tRNA. These have been fully characterized and shown to correspond to the published sequences for tRNA1+2Lys and tRNA3Lys. By determining which of these tRNA's was most tightly associated with the MuMTV genome and which of them acquired label from [alpha-32P]deoxynucleoside triphosphates in limited DNA synthesis reactions, we identified tRNA3Lys as the primer for MuMTV reverse transcription in vitro. tRNA3Lys does not share any unusual sequence feature with the other previously characterized retrovirus primers, tRNATrp and tRNAPro.

Differential association of transfer RNAs with the genomes of murine, feline and primate retroviruses

The tRNAs that are bound to the genomic RNAs of several murine, feline, and primate retroviruses have been identified. Transfer RNAs were divided into those loosely bound and those tightly bound by stepwise thermal dissociation of the 70 S RNA. They were then identified and semiquantitated by aminoacylation. Proline tRNA is the most tenaciously bound tRNA in several strains of murine leukemia virus, two strains of feline leukemia virus, and the primate viruses simian sarcoma, baboon endogenous, and gibbon ape lymphoma. In the feline xenotropic virus, RD-114, tRNAGly is enriched in the most tightly bound fraction. In Mason-Pfizer monkey virus, as in the murine mammary tumor virus, tRNALys is the tRNA most tenaciously bound to its genomic RNA. Besides the most tightly associated tRNA, one or more different tRNAs are found in relatively large amounts in association with the 70 S RNA. (For convenience, we refer to the largest RNA ccomplex (50-70 S) isolated from any of the retroviruses studies as '70 S' RNA.) These tRNAs can be distinguished from the most tightly bound tRNA by the fact that they can be dissociated at lower temperatures. However, they occur in the same relative abundance as the tightly bound tRNA.

Enzymatic synthesis of deoxyribonucleic acid by the avian retrovirus reverse transcriptase in vitro: optimum conditions required for transcription of large ribonucleic acid templates

In this communication, we present data which describe optimum conditions for reverse transcription of large ribonucleic acid (RNA) templates into deoxyribonucleic acid (DNA) transcripts by the avian retrovirus reverse transcriptase in vitro. In contrast to previous studies, we have optimized all of the reaction components with respect to their influence on the size of DNA transcripts rather than the incorporation of radio-labeled deoxynucleoside triphosphates into acid-insoluble DNA product. The most dramatic effect on uninterrupted reverse transcription is the presence of physiological concentrations (i.e., 148 mM) of monovalent cation in the reaction mixture, although all of the components of the reaction influence the size of the DNA transcripts synthesized to some extent. The enzymatic conditions described herein for the uninterrupted reverse transcription of large RNA templates (greater than 1000--2000 nucleotides) are superior to those described previously because they are reproducible, do not require the presence of ribonuclease inhibitors, and do not result in the precipitation of components of the reaction mixture during incubation.

Low-molecular-weight RNAs and initiation of RNA-directed DNA synthesis in avian reticuloendotheliosis virus

The small RNAs of avian reticuloendotheliosis virus (REV) were analyzed by two-dimensional polyacrylamide gel electrophoresis and compared with those of murine leukemia virus and avian sarcoma virus. Although there were some similarities among the three virus types, the patterns of small RNAs were distinct. By characterizing the small RNA which is most tightly associated with REV genome RNA and which can be labeled in limited DNA synthesis reactions, the primer for REV reverse transcription was identified as tRNAPro. This is consistent with previous reports that REV is more closely related to retroviruses of mammalian origin than to other avian viruses. In contrast, REV strong-stop complementary DNA is longer than any previously characterized strong-stop products of avian or mammalian retroviruses. The REV group may, therefore, have been derived from an as yet unidentified mammalian type C virus.

Partial purification and characterization of a ribonucleic acid N2-guanine methyltransferase associated with avian myeloblastosis virus

A nucleic acid methylase, N2-guanine ribonucleic acid (RNA) methyltransferase, which is associated with type C RNA tumor viruses, has been purified from avian myeloblastosis virions by gel filtration on Sephadex G-200, followed by chromatography on hydroxylapatite. The molecular weight estimated by gel filtration is 220 000, and the methylase activity has a pH optimum of 7.6--7.9. Magnesium and ammonium ions both stimulate activity 1.5-fold at 9.5 mM and 0.36 M, respectively, but apparently neither is essential for activity. Both daunomycin and adriamycin, antineoplastic drugs, also increase activity 1.5-fold at 1 mM. The enzyme was purified 120-fold from the virions and the activity is partially stabilized by dithiothretiol, but large losses were sustained during 24-h dialysis. The purified enzyme retains 75% of its activity on storage at -25 degrees C for 2 months in buffer containing 50% glycerol. Escherichia coli tRNAPhe and tRNAVal are preferred substrates with methylation occurring at position 10 of E. coli tRNAPhe.

Circular forms of DNA synthesized by Rous sarcoma virus in vitro

Electron microscopic analysis of the DNA product synthesized by detergent-disrupted preparations of Rous sarcoma virus in vitro revealed the presence of several interesting molecular forms including covalently closed circular DNA. The identification of such circular DNA indicates that virions of retroviruses contain all the components necessary to facilitate the complete synthesis of mature forms of viral DNA and therefore provide a useful system to delineate the molecular mechanisms involved in their synthesis.

A new series of RNAs associated with the genome of spleen focus forming virus (SFFV) and poly(A)-containing RNA from SFFV-infected cells

A series of low molecular weight RNAs (4.5 to 5.5S) as well as other 4 to 7S RNAs were dissociated from genomic RNA of spleen focus forming virus (SFFV) by heating. On two dimensional polyacrylamide gel electrophoresis, this series of RNAs gave a series of more than thirty spots. RNase T1 fingerprints of these spots were identical except for differences in 3'-terminal oligonucleotides, which were mainly due to different numbers of uridylic acid residues, larger RNA-molecules containing poly(U)sequences at their 3'-termini. This series of RNAs is also associated with poly(A)-containing nuclear and cytoplasmic RNAs from SFFV-infected cells.

RNA-directed DNA synthesis in Moloney murine leukemia virus: interaction between the primer tRNA and the genome RNA

Initiation of RNA-directed DNA synthesis in virions of Moloney murine leukemia virus requires a cellular tRNAPro as primer. The site(s) on the Moloney murine leukemia virus genome RNA at which functional primer molecules are bound and at which purified tRNAPro hybridizes has been located near (within 20%) the 5' end of the genome. A relatively stable duplex (temperature at which 50% dissociation has occurred, 76 degrees C) is formed between the amino acid acceptor stem of the tRNAPro and a complementary sequence in the Moloney murine leukemia virus 35S RNA. The interaction involves 19 base pairs, extending from the penultimate nucleotide at the 3' end of the tRNAPro but apparently not including the 3'-terminal adenosine residue. In most respects, the interaction between primer and template in Moloney murine leukemia virus parallels the situation in the avian leukosis-sarcoma viruses.

Initiation of DNA synthesis by the avian retrovirus reverse transcriptase in vitro: nature and location of the oligodeoxycytidylic acid primer binding site

We have investigated the use of oligodeoxycytidylic acid [oligo(dC)] as a primer for the initiation of DNA synthesis by the avian retrovirus reverse transcriptase in vitro, employing the viral RNA genome as template. The addition of oligo(dC)(12-18) to viral 35S RNA results in a stimulation of DNA synthesis by the viral RNA-directed DNA polymerase comparable to that observed when oligo(dT) is employed as a primer. Under similar conditions neither oligo(dA)(12-18) nor oligo(dG)(12-18) was active as primer for transcription of the avian retrovirus genome. Several different approaches have been employed to localize the oligo(dC)(12-18) binding site on the viral genome, including isolation of poly(A)-containing fragments, competition hybridization, and RNase H hydrolysis. These analyses indicate that oligo(dC)(12-18) binds to a site approximately 2,000 to 3,000 nucleotides from the 3' terminus of the genome of transforming strains of avian sarcoma viruses and approximately 700 to 1,000 nucleotides from the 3' terminus of nontransforming avian retroviruses. Therefore, the major site of initiation of DNA synthesis by oligo(dC)(12-18) appears to be in the vicinity of the 3' end of the env gene and the 5' end of the src gene, although the presence of minor initiation sites located elsewhere on the viral genome cannot be excluded by these data. Characterization of oligonucleotides after pancreatic RNase hydrolysis and poly(C)-Sepharose chromatography of viral RNA directly demonstrates the presence of oligoguanylic acid residues in the avian sarcoma virus genome. DNA sequences transcribed from the oligo(dC) primer appear to be conserved in all of the avian leukosis-sarcoma viruses tested. The use of oligo(dC) as a tool for the production of specific complementary DNA probes is discussed.

Comparison of the small RNAs of polymerase-deficient and polymerase-positive Rous sarcoma virus and another species of avian retrovirus

The small RNAs contained in virions of avian leukosis and sarcoma viruses are a virus-specific subset of the total small RNA population of the host cell. The reverse transcriptase protein must be present in the budding virion for this selection to take place. Virions of the alpha form of the Bryan strain of Rous sarcoma virus, which lack detectable reverse transcriptase, incorporated an unselected population of small RNAs identical to total chicken cell small RNA. Virions of reticuloendotheliosis virus, which contain a reverse transcriptase unrelated to that of the avian leukosis and sarcoma viruses, contained a distinctly different population of small RNAs although both the avian leukosis and sarcoma and the reticuloendotheliosis viruses were grown in chicken cells. Because the primer for avian leukosis and sarcoma virus RNA-dependent DNA synthesis is a host cell tRNA, the differences in reverse transcriptase small RNA selection may help explain the failure of different species of retrovirus to complement for the reverse transcriptase.

Unwinding-like activity associated with avian retrovirus RNA-directed DNA polymerase

The avian retrovirus RNA-directed DNA polymerase contains an activity that is capable of removing hydrogen bonds from duplex nucleic acid molecules. This "unwinding-like" activity appears to be specific in its action, affecting RNA.DNA and DNA.DNA duplex molecules but not RNA.RNA duplexes. Studies with defined RNA.DNA hybrid molecules (e.g., Rous sarcoma virus RNA and complementary DNAs representing specific regions of the Rous sarcoma virus genome) and DNA.DNA duplexes indicate that, although this activity can remove a portion of the hydrogen bonds from these double-stranded structures, complete separation of complementary strands is not accomplished. The unwinding-like activity exhibits sensitivities to temperature and monovalent and divalent cation concentrations. It can also remove a specific large oligonucleotide from the 5' end of the viral genome subsequent to RNase H hydrolysis of viral RNA complexed to DNA present at that terminus. This reverse transcriptase-associated unwinding-like activity is discussed with respect to recently proposed models of retrovirus proviral DNA synthesis.

Reverse transcriptase of RNA tumor viruses. V. In vitro proteolysis of reverse transcriptase from avian myeloblastosis virus and isolation of a polypeptide manifesting only RNase H activity

Purified avian myeloblastosis virus reverse transcriptase contains two subunits that are structurally related. The large subunit, beta (molecular weight, 95,000), was converted in vitro by chymotrypsin into a polypeptide of molecular weight 63,000. This polypeptide was indistinguishable from the small subunit, alpha (molecular weight, 65,000), in its chromatographic behavior on the phosphocellulose column and its tryptic peptide composition. During this proteolytic conversion, a polypeptide of molecular weight 32,000 (fragment B) was obtained. It was composed of tryptic peptides unique to beta and appeared to be derived from the portion of the beta subunit that was cleaved off during the conversion of beta into alpha. Upon continued proteolysis, a smaller polypeptide of molecular weight 24,000 (fragment A) was generated. This polypeptide manifested only RNase H activity and shared common amino acid sequences with beta and alpha subunits. Fragment A did not share any amino acid sequence homology with fragment B.

Sequence of an oligonucleotide derived from the 3' end of each of the four brome mosaic viral RNAs

A 3'-terminal oligonucleotide fragment, 161 bases long, can be obtained from each of the four brome mosaic virus RNAs by means of nuclease digestion. Like the four intact brome mosaic virus RNAs, each fragment accepts tyrosine in a reaction catalyzed by wheat germ aminoacyl-tRNA synthetase. The complete nucleotide sequence of the RNA 4 fragment has been determined by use of standard radiochemical methods. Comparative data for the fragments from RNAs 1, 2, and 3 show that they have nearly the same sequence as the RNA 4 fragment. The eight bases adjacent to the 3' terminus of the RNA 4 fragment are identical in sequence to the eight terminal bases of tyrosine tRNA from Torula utilis and eleven interior bases are identical in sequence to eleven bases encompassing the anticodon region of tyrosine tRNA from Saccharomyces cerevisiae, T. utilis, and Escherichia coli. Nevertheless, reasonable base-pairing schemes yield, at best, a distorted cloverleaf secondary structure.

In vitro transcription of the avian retrovirus genome by the alpha form of the viral RNA-directed DNA polymerase

The nature of transcription of the avian retrovirus RNA genome by the alpha form of the viral RNA-directed DNA polymerase has been investigated. Transcription was most efficient when Mn2+ was provided as the divalent metal ion. The patterns of DNA transcription using 70S RNA, 35S RNA-tRNAtrp, or 35S RNA-oligo(dT)12-18 template-primer complexes by the alpha DNA polymerase were essentially identical to those obtained using the alphabeta form. The alpha DNA polymerase appears to be deficient in the synthesis of true duplex DNA but is able to synthesize hairpin-structured DNA initiated at the 5' terminus of the viral genome on the tRNAtrp primer molecule.

Characterization of RNA from equine infectious anemia virus

The genome of equine infectious anemia virus, a nononcogenic retrovirus, has been characterized by velocity sedimentation, electrophoresis in polyacrylamide gels, buoyant density in CS2SO4, and susceptibility to nuclease digestion. The nucleic acid of purified virus was resolved by sedimentation analysis into a fast-sedimenting genome component, which comprises about two-thirds of the virion RNA, and a slow-sedimenting RNA, which is probably comprised of host-derived tRNA and a trace amount of 5S RNA. The fast-sedimenting RNA had a sedimentation coefficient of 62S and a molecular weight of 5.4 X 10(6) to 5.6 X 10(6), as determined by sedimentation velocity and electrophoretic mobility. Upon heat denaturation, [3H]uridine-labeled 62S RNA dissociated into material comprised of 90 to 95% single-stranded species, sedimenting predominantly at 34S, with a molecular weight of 2.7 X 10(6) to 2.9 X 10(6) and 5 to 10% 4S RNA. The 62S RNA was predominantly single-stranded but contained double-stranded regions, as indicated by partial resistance to RNase IA and SI nuclease and by a lower buoyant density in CS2SO4 than that of the single-stranded 34S RNA derived by heat denaturation. These data indicated that the viral genome consisted of two 34S subunits of single-stranded RNA held in a high-molecular-weight complex with 4S RNA by a mechanism involving a small degree of base pairing. Thus, the structure of equine infectious anemia virus RNA is similar to that of other retroviruses.

Regulation of the intracellular concentration of T4 induced tRNA

We have studied the biosynthesis of T4 induced tRNA's upon infection of E. coli BE cells in low phosphate (l.p.) medium (10(-4) M PO---4). Under out experimental conditions the onset of phage DNA synthesis occurs about 15 min after infection, while the first intracellular phage appears one hour later. Amounts of newly synthesized DNA and phage burst size are equivalent to the values obtained in standard (M9) medium (10(-1) M PO---4). We present evidence that the synthesis of mature tRNA's and of at least one dimeric precursor drastically declines 20 min after infection. In addition we show that T4 induced tRNA molecules are stable and that the triphosphate nucleoside precursor pool does not change significantly during infection. Therefore we conclude that T4 induce tRNA molecules behave similarly to other early gene products.

Role of ribothymidine in mammalian tRNAPhe

We have previously reported that mammalian tRNAsPhe from variation tissues contain different amounts of ribothymidine and that a uridine methylase from Escherichia coli can quantitatively convert these tRNAs to species that contain their full complement ofribothymidine at position 23 from the 3' terminus. The role of ribothymidine in mammalian tRNAs has now been investigated by studying the ability of several highly purified mammalian tRNAsPhe, differing only in their ribothymidine content, to support poly(U)-directed poly(Phe) synthesis under various conditions. Our results indicate that the ribothymidine content of mammalian tRNAPhe can be correlated with the ability of these tRNAs to functionin vitro in a low-magnesium (6 mM), ribosome wash factor-dependent, poly(U)-directed poly(Phe) synthesis system from rat liver. Specifically, the effect of increasing the ribothymidine content in a class C mammalian tRNA becomes manifest in an increased apparent maximum velocity for the overall synthesis of poly(Phe), while the apparent Michaelis constant (Km) remains essentially unchanged. It is postulated that the modifiednucleoside ribothymidine might be involved in the regulation of protein synthesis at the level of translation in mammalian liver.

Terminally repeated sequences in the avian sarcoma virus RNA genome

The initiation of DNA synthesis in vitro by RNA-directed DNA polymerase (deoxynucleosidetriphosphate: DNA deoxynucleotidyltransferase, EC 2.7.7.7) of avian oncornaviruses requires a tRNAtrp primer molecule located close to the 5' end of the viral RNA genome. DNA transcripts, 100 nucleotides in length, initiated on the tRNAtrp primer molecule contain nucleotide sequences complementary to a large (25 nucleotides) RNase T1 oligonucleotide, T-13, located at the 5' terminus of the avian sarcoma virus RNA genome. tRNAtrp-initiated DNA transcripts with a length of about 70 nucleotides contain substantially fewer nucleotide sequences complementary to this 5'-terminal oligonucleotide, suggesting that the tRNAtrp primer associated with the avian sarcoma virus RNA is located approximately 100 nucleotides from the 5' end of the RNA. In addition, we present evidence to demonstrate that DNA transcribed from avian sarcoma virus RNA sequences located at the 3' end, immediately adjacent to the poly(A), contains nucleotide sequences that are complementary to the 5'-terminal T1 oligonucleotide T-13. These data indicate that the 5' end of the viral genome contains nucleotide sequences that are repeated at the 3' end of the genome. We conclude that the avian oncornavirus RNA genome is terminally redundant.

In vitro transcription of theavian oncornavirus genome by the RNA-directed DNA polymerase: analysis of DNA transcripts synthesized in reconstructed enzymatic reactions

We have analyzed the DNA products synthesized in vitro in reconstructed reactions containing purified avian oncornavirus genome RNA and RNA-directed DNA polymerase. The results of these studies indicate that: (i) the initial DNA product synthesized on either 70S RNA or reconstituted 35S RNA-tRNAtrp template - primer complexes in the presence of low concentrations of deoxynucleoside triphosphates consists of several discrete size classes, none of which exceed 200 nucleotides in length; (ii) large DNA transcripts (about 2,000 nucleotides) can be synthesized on both 70S RNA and the 35S RNA - tRNAtrp complex by increasing the deoxynucleoside triphosphate concentration; and (iii) DNA synthesized by detergent-disrupted virus is considerably longer than DNA synthesized in reconstructed reactions.

Primer recognition by avian myeloblastosis virus RNA-directed DNA polymerase

Tryptophanyl-tRNA was specifically labeled at the 3' end with [3H]tryptophan and cleaved in half with RNase under denaturing conditions, and the 3' half was shown to hybridize exclusively at the 5' end of avian myeloblastosis virus RNA. The RNA-dependent DNA polymerase of avian myeloblastosis virus is capable of efficiently binding the 3' half of the primer molecule.

Low-molecular-weight RNAs of Moloney murine leukemia virus: identification of the primer for RNA-directed DNA synthesis

The small RNAs of Moloney murine leukemia virus (M-MuLV) were fractionated into at least 15 species by two-dimensional polyacrylamide gel electrophoresis. The pattern of small RNAs is significantly different from that of Rous sarcoma virus. A subset of the virion small RNAs is associated with the genome RNA in the 70S complex. One of the associated molecules, a cellular tRNA, is tightly bound to the genome RNA and serves as the major primer for M-MuLV RNA-directed DNA synthesis in vitro.

Rous sarcoma virus genome is terminally redundant: the 3' sequence

A sequence of 20 nucleotide residues immediately adjacent to the 3'-terminal poly(A) in Rous sarcoma virus (Prague strain, subgroup C) 35S RNA has been determined by extension of a riboguanylic acid-terminated oligothymidylic acid primer hybridized at the 5' end of the 3'-terminal poly(A) with purified reverse transcriptase (RNA-directed DNA polymerase; deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) from avian myeloblastosis virus. The sequence is 5'GCCAUUUUACCAUUCACCACpoly(A)3'. This same nucleotide sequence, excluding the poly(A) segment, has also been found at the 5' terminus of Rous sarcoma virus RNA (W. A. Haseltine, A. Maxam, and W. Gilbert, this issue pp. 989-993), and therefore the RNA genome of this virus is terminally redundant. Possible mechanisms for endogenous in vitro copying of the complete RNA genome by reverse transcriptase which involve terminally repeated nucleotide sequences are discussed.