RNA primer used in synthesis of anticomplementary DNA by reverse transcriptase of avian myeloblastosis virus

PCR inhibition by reverse transcriptase leads to an overestimation of amplification efficiency

This study addresses the problem of PCR inhibition by reverse transcriptase. It has been shown that the inhibition occurs mostly when a small amount of RNA is taken for RT reaction, and it is more visible for rarely expressed transcripts. We show here that the inhibition takes place regardless of what amount of template is utilized for RT. The inhibition possesses a global nature, i.e. the amplification of any given transcript may be compromised with different levels of inhibition. The process of inhibition also explains wrongfully derived PCR amplification efficiencies, sometimes more than 100%, when the sequential dilutions of unpurified RT sample are utilized to build the calibration curve. The RT influences PCR not only by inhibiting it. When microgram(s) of RNA are taken for RT reaction, reverse transcriptase may cause overamplification of some transcripts under certain PCR conditions. The possible mechanism of RT influence on PCR is presented, and a purification method is implemented to remove the effects of RT on PCR.

Specificities involved in the initiation of retroviral plus-strand DNA

Reverse transcription of the retroviral RNA genome begins with tRNA-primed synthesis of a minus-strand DNA, which subsequently acts as the template for the synthesis of plus-strand DNA. This plus-strand DNA is initiated at a unique location and makes use of a purine-rich RNA oligonucleotide derived by RNase H action on the viral RNA. To determine the variables that are relevant to successful specific initiation of plus-strand DNA synthesis, we have used nucleic acid sequences from the genome of Rous sarcoma virus along with three different sources of RNase H: avian myeloblastosis virus DNA polymerase, murine leukemia virus DNA polymerase, and the RNase H of Escherichia coli. Our findings include evidence that specificity is controlled not only by the nucleic acid sequences but also by the RNase H. For example, while the avian reverse transcriptase efficiently and specifically initiates on the sequences of the avian retrovirus, the murine reverse transcriptase initiates specifically but at a location 4 bases upstream of the correct site.

Molecular cloning of the common acute lymphoblastic leukemia antigen (CALLA) identifies a type II integral membrane protein

Common acute lymphoblastic leukemia antigen (CALLA) is a 100-kDa cell-surface glycoprotein expressed on most acute lymphoblastic leukemias and certain other immature lymphoid malignancies and on normal lymphoid progenitors. The latter are either uncommitted to B- or T-cell lineage or committed to only the earliest stages of B- or T-lymphocyte maturation. To elucidate to homogeneity, obtained the NH2-terminal sequence from both the intact protein and derived tryptic and V8 protease peptides and isolated CALLA cDNAs from a Nalm-6 cell line lambda gt10 library using redundant oligonucleotide probes. The CALLA cDNA sequence predicts a 750-amino acid integral membrane protein with a single 24-amino acid hydrophobic segment that could function as both a transmembrane region and a signal peptide. The COOH-terminal 700 amino acids, including six potential N-linked glycosylation sites compose the extracellular protein segment, whereas the 25 NH2-terminal amino acids remaining after cleavage of the initiation methionine form the cytoplasmic tail. CALLA+ cells contain CALLA transcripts of 2.7 to 5.7 kilobases with the major 5.7- and 3.7-kilobase mRNAs being preferentially expressed in specific cell types.

Involvement of retrovirus reverse transcriptase-associated RNase H in the initiation of strong-stop (+) DNA synthesis and the generation of the long terminal repeat

Reconstructed enzymatic reactions containing purified reverse transcriptase and defined analog substrates which mimic those purported to be natural substances for reverse transcription in vivo were employed to delineate the mechanism of strong-stop (+) DNA synthesis. Our analysis of this system has indicated that strong-stop (+) DNA synthesis is initiated after the introduction of a nick in the viral RNA genome between a polypurine sequence and an inverted repeat that represents the end of the long terminal repeat. Since inhibitors of the reverse transcriptase-associated RNase H activity prevent the introduction of the nick and the synthesis of strong-stop (+) DNA synthesis, it appears that this particular reverse transcriptase-associated enzymatic activity is responsible for the initiation of strong-stop (+) DNA. Our data also indicated that the RNase H activity creates a second nick in the viral RNA genome 11 nucleotides upstream from the strong-stop (+) DNA initiation site since the strong-stop (+) DNA synthesized in these reactions is covalently linked to an oligoribonucleotide 11 residues in length. Nucleotide sequence analysis of the oligoribonucleotide primer molecule indicated that a single homogenous oligomer was associated with strong-stop (+) DNA exhibiting the sequence rArGrGrGrArGrGrGrGrGrA. The oligoribonucleotide primer can be removed from strong-stop (+) DNA by the purified reverse transcriptase, which creates a nick at the junction between the primer and strong-stop (+) DNA. These data demonstrate that the initiation of strong-stop (+) DNA synthesis is mediated by RNase H and that the site of initiation is exactly at the end of the long terminal repeat, providing evidence for yet another function of this reverse transcriptase-associated enzymatic activity in the synthesis of retrovirus DNA.

RNA-primed initiation of Moloney murine leukemia virus plus strands by reverse transcriptase in vitro

A 190-base-pair DNA-RNA hybrid containing the Moloney murine leukemia virus origin of plus-strand DNA synthesis was constructed and used as a source of template-primer for the reverse transcriptase in vitro. Synthesis was shown to initiate precisely at the known plus-strand origin. The observation that some of the origin fragments retained ribonucleotide residues on their 5' ends suggests that the primer for chain initiation is an RNA molecule left behind by RNase H during the degradation of the RNA moiety of the DNA-RNA hybrid. If the RNase H is responsible for creating the correct primer terminus, then it must possess a specific endonucleolytic activity capable of recognizing the sequence in the RNA where plus strands are initiated. The 16-base RNase A-resistant fragment which spans the plus-strand origin can also serve as a source of the specific plus-strand primer RNA. Evidence is presented that some of the plus-strand origin fragments synthesized in the endogenous reaction contain 5' ribonucleotides, suggesting that specific RNA primers for plus-strand initiation may be generated during reverse transcription in vivo as well.

Evidence for involvement of an RNA primer in initiation of strong-stop plus DNA synthesis during reverse transcription in vitro

Employing enzymatic reactions in vitro, we have identified the presence of oligoribonucleotides at the 5' end of strong-stop plus [(+)] DNA. Similar results were obtained whether the strong-stop (+) DNA was synthesized by preparations of detergent-disrupted avian sarcoma virus or reconstructed reactions containing purified reverse transcriptase and a template that mimics the purported natural template for strong-stop (+) DNA synthesis. The latter reactions provide a system to delineate more precisely the discrete requirements necessary for the initiation and synthesis of this species of (+) DNA.

Mechanism of RNA primer removal by the RNase H activity of avian myeloblastosis virus reverse transcriptase

The single-stranded DNA containing the Moloney murine leukemia virus origin for plus-strand synthesis was cloned in M13mp2 and used as a template for avian myeloblastosis virus reverse transcriptase in the presence of Moloney RNA which had been treated with pancreatic RNase A. The RNA pieces containing the polypurine stretch near the plus-strand origin were processed, presumably by RNase H, to generate primers for DNA synthesis which initiated both at the correct origin site and at one nucleotide downstream from the correct site. Approximately 50% of the labeled DNA fragments synthesized under these conditions retained the priming RNA on their 5' ends. When the isolated fragments were hybridized back to the template DNA and again treated with the reverse transcriptase, all of the RNA was removed from the labeled DNA. By using 5'-end-labeled pancreatic RNase A-resistant fragments, it was possible to show that the RNA primers were removed intact. It appears from these results that the RNase H activity associated with the enzyme shows a preference for cutting at the junction between the RNA and DNA moieties of such complexes and therefore is ideally suited for removing RNA primers.

Reverse transcriptase and its associated ribonuclease H: interplay of two enzyme activities controls the yield of single-stranded complementary deoxyribonucleic acid

The synthesis of single-stranded globin cDNA by the RNA-directed DNA polymerase activity of reverse transcriptase in the presence of oligothymidylate primers was investigated in order to determine the limitations to higher yields. The results indicated that the associated ribonuclease H activity, an integral part of reverse transcriptase, plays a large role in the synthesis of the first strand of cDNA and that the interplay of the two enzyme activities for any specific set of conditions determines the yield of single-stranded products. In both the presence and the absence of polymerization, the associated ribonuclease H catalyzed the deadenylation of mRNA, producing molecules that were somewhat shorter, highly homogeneous in size, and fully translatable into globin protein. They were also entirely lacking in the ability to serve as templates for cDNA synthesis. The reaction was completely dependent on oligothymidylate and completely independent of deoxyribonucleoside triphosphates. The initial rate of deadenylation was one-fourth the initial rate of initiation of polymerization when saturating levels of deoxyribonucleoside triphosphates were used in the polymerase reaction. In the presence of ribonuclease H activity, the DNA polymerase catalyzed the synthesis of an array of cDNAs including some that were full length. The initiation of polymerization was rate limiting: once synthesis had begun, it required 1-1.5 min to transcribe globin mRNA. However, most primers that were elongated were aborted prematurely. Maximum synthesis of full-length cDNA required stoichiometric levels of enzyme and high triphosphate levels, but regardless of conditions, the sum of completed cDNA and deadenylated mRNA accounted for only 50% of the input mRNA. The data fit a model in which synthesis of full-length cDNA molecules depends on the arrangement of primers and transcription initiation complexes on the poly(A) "tail" of mRNA.

Improved yield of full-length phaseolin cDNA clones by controlling premature anticomplementary DNA synthesis

The manner in which the known enzymatic properties of reverse transcriptase may limit the length of double stranded cDNAs to be used in cloning was studied. Results here suggest that the well-documented ability of reverse transcriptase to synthesize anticomplementary DNA can, if unrecognized, seriously limit the final yield of full-length cDNA clones. Under conditions which permitted anticomplementary DNA synthesis during the synthesis of the first cDNA strand, no full-length cDNA clones for phaseolin, the principal storage proteins ofPhaseolus vulgaris, were detected among 19 phaseolin-positive cDNA clones. When anticomplementary DNA synthesis was inhibited with 4 mM sodium pyrophosphate, 5 full-length cDNA clones were identified among 45 phaseolin-positive clones. In both cases, the products of the first strand synthesis were C-tailed and the second strand synthesized by reverse transcriptase using oligo(dG) as a primer. The implications of anticomplementary synthesis in cloning methods involving the use of S1 nuclease are discussed. In addition, a rapid, one-step procedure for obtaining partial clones which equally represent the 5' and 3' ends of the RNA is presented.

Molecular cloning of double-stranded RNA virus genomes

Genome double-stranded RNAs isolated from purified human reovirus (serotype 3) and rotavirus (Wa strain) were modified at the 3' termini by addition of oligo(C) approximately 15 with T4 RNA ligase. These RNAs were transcribed into cDNA by oligo(dG)-primed reverse transcriptase and cloned after insertion into pBR322 at the Pst I site. Hybridization of plasmid-transformed Escherichia coli RR1 colonies with 32P-labeled viral genome RNAs demonstrated the presence of DNA clones representative of each of the 10 reovirus RNAs and 10 of the 11 constituent segments of the rotavirus genome. Analyses of the size and terminal nucleotide sequences of insert DNAs indicated that some clones contained a full-length copy of the virus genome segment. The complete nucleotide sequence of rotavirus genome segment 11 double-stranded RNA was obtained by using this procedure. It provides a general method for cloning double-stranded RNAs and also nonpolyadenylylated single-stranded RNAs.

Products of reverse transcription in avian retrovirus analyzed by electron microscopy

DNA products synthesized in avian retroviral particles permeabilized with melittin have been analyzed in an electron microscope. These studies have provided further insight and subsequent refinement in the melittin activation techniques. Our electron microscope analyses verify the existence of the plus-strand single-stranded DNA branches, presumed to originate by strand-displacement synthesis (L. R. Boone and A. M. Skalka, J. Virol. 37:117-126, 1981). The branches occur at many locations along the DNA molecules and are observed at very early times, even before the minus-strand copies of the RNA genome are completed. Circular forms of different derivations are observed at early and at late times, which are possible intermediates in viral replication. Novel forms termed H structures are also described. In addition to the identification of possible intermediates, these analyses have provided further information on the sequence of events in retroviral reverse transcription. These new data are combined with previous results to generate a model of reverse transcription which incorporates strand-displacement synthesis as an essential feature.

Cloning of four DNA fragments complementary to human thyroglobulin messenger RNA

Human thyroglobulin mRNA was isolated from Graves' goitres by size selection of total poly(A)-rich RNA in a sucrose gradient. It sedimented at 33 S, as in other mammalian species, and showed a single component of approximately 8500 bases by gel electrophoresis. cDNA was synthesized from the 33-S RNA by using reverse transcriptase in the presence of human placenta ribonuclease inhibitor and in conditions allowing the formation of long transcripts. The latter was made double-stranded using reverse transcriptase and blunt-ended with nuclease S1. After tailing with dCTP and terminal transferase, the double-stranded cDNA was annealed to pBR322 DNA that had been cleaved at the endonuclease PstI site and tailed with dGTP. The resulting plasmids were used to transform Escherichia coli C600 cells and four cloned recombinants were selected. Each plasmid DNA was shown to contain a sequence complementary to human thyroglobulin mRNA by hybridization with a labeled 33-S mRNA, visualization of cDNA . mRNA hybrids by electron microscopy and filter hybridization selection of mRNA directing the synthesis of immunologically related thyroglobulin peptides in the reticulocyte lysate. The four inserted DNA sequences were 1400 - 1800 base pairs long, two of them showing an homologous sequence of 1100 base pairs. Together, the four cloned DNA fragments represented 63% of the 8500 bases of human thyroglobulin mRNA.

Viral DNA synthesized in vitro by avian retrovirus particles permeabilized with melittin. II. Evidence for a strand displacement mechanism in plus-strand synthesis

Analyses of the native DNA product of mellitin-activated avian retrovirus reverse transcription have revealed a unique structure. The vast majority of the molecules were linear, either 7.7 (genome) or 8.0 (extended genome) kilobases in length, and contained single-stranded DNA branches distributed throughout. These conclusions are based on electrophoretic properties of intact and restriction endonuclease-treated molecules before and after treatment with single-strand-specific nuclease S1. Preliminary data from linear viral DNA extracted from infected cells suggest that these molecules have a similar structure. The findings summarized in this report and those in the preceding paper indicated that the single-stranded branches are of positive polarity and are generated by a strand displacement mechanism. The existence of these branches suggests a role for strand displacement in replication and recombination.

Viral DNA synthesized in vitro by avian retrovirus particles permeabilized with melittin. I. Kinetics of synthesis and size of minus- and plus-strand transcripts

We have examined the kinetics of synthesis of minus [(-)]- and plus [(+)]-strand viral DNA in melittin-permeabilized avian retrovirus particles. The reaction was biphasic. There was a very rapid initial rate, followed, after approximately 1 h, by a lower rate. Many discrete bands of subgenomic-length (-) strands were produced after 10 and 20 min of synthesis; genome-length (7.7-kilobase [kb]) (-) strands were detected within 30 min. Extension to an 8.0-kb (-)-strand species was evident by 60 min. This extension was inhibited by actinomycin D. Synthesis of (+) strands (which is also inhibited by actinomycin D) began early, before any (-) strands were completed, and continued for more than 4 h beyond the time when synthesis of full-length DNA had terminated. Two distinct species of (+)-strand DNA, 0.27 and 0.35 kb, could be observed at the earliest times. Their presence was quickly obscured by subsequent formation of (+)-strand molecules of molecular length between 0.2 and 2.0 kb.

Synthesis of plus strands of retroviral DNA in cells infected with avian sarcoma virus and mouse mammary tumor virus

The vast majority of plus strands synthesized in quail cells acutely infected with avian sarcoma virus were subgenomic in size, generally less than 3 kilobases (kb). A series of discrete species could be identified after agarose gel electrophoresis by annealing with various complementary DNAs, indicating specificity in the initiation and termination of plus strands. The first plus strand to appear (within 2 h postinfection) was similar in length to the long redundancy at the ends of linear DNA (0.35 kb), and it annealed with complementary DNAs specific for the 3' and 5' termini of viral RNA (Varmus et al., J. Mol. Biol. 120:50-82, 1978). Several subgenomic plus-strand fragments (0.94, 1.38, 2.3, and 3.4 kb) annealed with these reagents. At least the 0.94- and 1.38-kb strands were located at the same end of linear DNA as the 0.35-kb strand, indicating that multiple specific sites for initiation were employed to generate strands which overlapped on the structural map. We were unable to detect RNA liked to plus strands isolated as early as 2.5 h postinfection; thus, the primers must be short (fewer than 50 to 100 nucleotides), rapidly removed, or not composed of RNA. To determine whether multiple priming events are a general property of retroviral DNA synthesis in vivo, we also examined plus strands of mouse mammary tumor virus DNA in chronically infected rat cells after induction of RNA and subsequent DNA synthesis with dexamethasone. In this case, multiple, discrete subgenomic DNA plus strands were not found when the same methods applied to avian sarcoma virus DNA were used; instead, the plus strands present in the linear DNA of mouse mammary tumor virus fell mainly into two classes: (i) strands of ca. 1.3 kb which appeared early in synthesis and were similar in size and genetic content to the terminally repeated sequence in linear DNA; and (ii) plus strands of the same length as linear DNA. A heterogeneous population of other strands diminished with time, was not found in completed molecules, and was probably composed of strands undergoing elongation. These two retroviruses thus appear to differ with respect to both the number of priming sites used for the synthesis of plus strands and the abundance of full-length plus strands. On the other hand the major subgenomic plus strand of mouse mammary tumor virus DNA (1.3 kb) is probably the functional homolog of a major subgenomic plus strand of avian sarcoma virus DNA (0.35 kb). The significance of this plus strand species is discussed in the context of current models which hold that it is used as a template for the completion of the minus strand, thereby generating the long terminal redundancy.