Initiation Of Minus-strand DNA Synthesis Research Articles

Diminished RNA primer usage associated with the L74V and M184V mutations in the reverse transcriptase of human immunodeficiency virus type 1 provides a possible mechanism for diminished viral replication capacity.

The emergence of drug resistance-conferring mutations can severely compromise the success of chemotherapy directed against human immunodeficiency virus type 1 (HIV-1). The M184V and/or L74V mutation in the reverse transcriptase (RT) gene are frequently found in viral isolates from patients treated with the nucleoside RT inhibitors lamivudine (3TC), abacavir (ABC), and didanosine (ddI). However, the effectiveness of combination therapy with regimens containing these compounds is often not abolished in the presence of these mutations; it has been conjectured that diminished fitness of HIV-1 variants containing L74V and M184V may contribute to sustained antiviral effects in such cases. We have determined that viruses containing both L74V and M184V are more impaired in replication capacity than viruses containing either mutation alone. To understand the biochemical mechanisms responsible for this diminished fitness, we generated a series of recombinant mutated enzymes containing either or both of the L74V and M184V substitutions. These enzymes were tested for their abilities to bypass important rate-limiting steps during the complex process of reverse transcription. We studied both the initiation of minus-strand DNA synthesis with the cognate replication primer human tRNA(3)(Lys) and the initiation of plus-strand DNA synthesis, using a short RNA primer derived from the viral polypurine tract. We observed that the efficiencies of both reactions were diminished with enzymes containing either L74V or M184V and that these effects were significantly amplified with the double mutant. We also show that release from intrinsic pausing sites during reverse transcription appears to be a major obstacle that cannot be efficiently bypassed. Our data suggest that the efficiency of RNA-primed DNA synthesis represents an important consideration that can affect viral replication kinetics.

Initiation of minus-strand DNA synthesis by human immunodeficiency virus type 1 reverse transcriptase.

The initiation of (-) strand DNA synthesis by HIV-1 reverse transcriptase was examined using a transient kinetic approach and a physiologically relevant RNA 18-mer/RNA 36-mer primer-template substrate. HIV-1 reverse transcriptase (RT) was found to bind with reasonably high affinity to the RNA/RNA substrate (K(d) = 90 nM), although the affinity for DNA/RNA and DNA/DNA substrates is higher (K(d) approximately 5 nM). A pre-steady-state burst of deoxynucleotide incorporation (k(obsd) = 1.0 s(-)(1)) into the RNA duplex was observed followed by a slower steady-state release of the elongated primer-template product (k(ss) = 0.58 s(-)(1)). The observation of a burst provides evidence that the release of the product is most likely the rate-limiting step in the overall kinetic pathway for the enzymatic reaction during a single deoxynucleotide incorporation event. Furthermore, the release of this product was 5-fold faster than that for elongated DNA/RNA and DNA/DNA products. Single-turnover experiments showed that there is a hyperbolic dependence of the rate of deoxynucleotide incorporation on the concentration of dCTP and demonstrated that the maximum rate of dCTP incorporation (k(pol) = 1.4 s(-)(1)) is 33- and 12-fold slower than the values for DNA/RNA and DNA/DNA primer-template substrates, respectively, while the affinity of dCTP (K(d) = 780 microM) for the HIV-1 RT.RNA/RNA complex is 56- and 71-fold weaker than the affinities for HIV-1 RT.DNA/RNA and HIV-1 RT.DNA/DNA complexes, respectively. Consequently, the overall efficiency of dCTP incorporation (k(pol)/K(d)) into the RNA/RNA substrate is approximately 1800- and 800-fold less than that for DNA/RNA and DNA/DNA substrates, respectively. These findings provide evidence which suggests that the HIV-1 RT.RNA/RNA.dCTP ternary complex exists in a significantly different conformation compared to ternary complexes involving DNA/RNA and DNA/DNA substrates. A model summarizing these results is presented, and implications for the molecular mechanism of initiation of (-) strand DNA synthesis by RT are discussed.

The fidelity of reverse transcription differs in reactions primed with RNA versus DNA primers.

Reverse transcriptase enzymes (RT) convert single-stranded retroviral RNA genomes into double-stranded DNA. The RT enzyme can use both RNA and DNA primers, the former being used exclusively during initiation of minus- and plus-strand synthesis. Initiation of minus-strand DNA synthesis occurs by extension of a tRNA primer that is associated with the viral genome, and plus-strand DNA synthesis is initiated from an RNase H- resistant polypurine tract of the genomic RNA that remains bound to the newly synthesized minus-strand DNA. All other phases of reverse transcription represent elongation of a DNA primer. We demonstrate that the polymerase fidelity of RT enzymes is significantly higher in tRNA-primed reverse transcription compared with DNA-primed reactions. Two mechanistic explanations can be proposed. First, the type of template-primer (T- P) duplex (RNA-RNA versus RNA-DNA) may affect the RT enzyme conformation such that the discrimination against incorrect nucleotides is affected. Second, the tRNA primer may act as a fidelity co-factor through specific association with the RT enzyme. According to the latter hypothesis, the increased fidelity observed for an RNA-RNA T-P should persist at a distance from the initiation site, where the enzyme-bound nucleic acid duplex will consist of RNA-cDNA. However, we measured that the effect of tRNA on the fidelity is detectable only at a short distance from the initiation site. These results indicate that the type of T-P duplex influences the fidelity of reverse transcription, suggesting that two small segments of the viral genome downstream of the initiation sites for minus- and plus-strand DNA synthesis are copied with a fidelity that is greater than average.

Human immunodeficiency virus Type 1 nucleocapsid protein (NCp7) directs specific initiation of minus-strand DNA synthesis primed by human tRNA(Lys3) in vitro: studies of viral RNA molecules mutated in regions that flank the primer binding site.

Retroviral reverse transcription starts near the 5' end of unspliced viral RNA at a sequence called the primer binding site (PBS), where the tRNA primer anneals to the RNA template for initiation of DNA synthesis. We have investigated the roles of NCp7 in annealing of primer tRNA(Lys3) to the PBS and in reverse transcriptase (RT) activity, using a cell-free reverse transcription reaction mixture consisting of various 5' viral RNA templates, natural primer tRNA(Lys3) or synthetic primer, human immunodeficiency virus type I (HIV-1) nucleocapsid protein (NCp7), and HIV-1 RT. In the presence of tRNA(Lys3), NCp7 was found to stimulate synthesis of minus-strand strong-stop DNA [(-)ssDNA], consistent with previous reports. However, specific DNA synthesis was observed only at a NCp7/RNA ratio similar to that predicted to be present in virions. Moreover, at these concentrations, NCp7 inhibited the synthesis of nonspecific reverse-transcribed DNA products, which are initiated because of self-priming by RNA templates. In contrast to results obtained with tRNA(Lys3) as primer, NCp7 inhibited the synthesis of (-)ssDNA products primed by an 18-nucleotide (nt) ribonucleotide (rPR), complementary to the PBS, even though rPR can initiate synthesis of such material in the absence of preannealing with NCp7. Primer placement band shift assays showed that NCp7 was necessary for efficient formation of the tRNA-RNA complex. In contrast, NCp7 was found to prevent formation of the rPR-RNA complex. Since NCp7 appears to exert opposite effects (annealing versus dissociation) on tRNA(Lys3) and rPR substrates, the non-PBS binding regions of the tRNA(Lys3) molecule may play a role in the annealing of tRNA to the template. We also investigated the roles of an A-rich loop upstream of the PBS, a 7-nt region immediately downstream of the PBS, and a 54-nt deletion further downstream of the PBS in interactions with tRNA(Lys3). We found that deletions in the 54-nt region that may prevent formation of the U5-leader stem prevented tRNA(Lys3) placement and priming, while deletions in the A-rich loop or the 7-nt sequence had relatively minor effects in this regard.

Role of RNA primers in initiation of minus-strand and plus-strand DNA synthesis of the yeast retrotransposon Ty1

The Ty1 retrotransposon of the yeast Saccharomyces cerevisiae is a long terminal repeat mobile genetic element that transposes through an RNA intermediate. Initiation of minus-strand and plus-strand DNA synthesis are two critical steps during reverse transcription of the retrotransposon genome. Initiation of minus-strand DNA synthesis of the Ty1 element is primed by the cytoplasmic initiator methionine tRNA base paired to the primer binding site near the 5′ end of the genomic RNA. A structural probing study of the primer tRNA-Ty1 RNA binary complex reveals that besides interactions between the primer binding site and the last 10 nucleotides at the 3′ end of the primer tRNA, three short regions of Ty1 RNA named box 0, box 1 and box 2.1 interact with the T and D stems and loops of the primer tRNA. Some in vivo results underline the functional importance of the nucleotide sequence of the boxes and suggest that extended interactions between genomic Ty1 RNA and the primer tRNA play a role in the reverse transcription pathway. Plus-strand DNA synthesis is initiated from an RNase H resistant oligoribonucleotide spanning a purine-rich sequence, the polypurine tract (PPT). Two sites of initiation located at the 5′ boundary of the 3′ long terminal repeat (PPT1) and near the middle of the TyB ( pol) gene in the integrase coding sequence (PPT2) have been identified in the genome of Ty1. The two PPTs have an identical sequence, TGGGTGGTA. Mutations replacing purines by pyrimidines in this sequence significantly diminish or abolish initiation of plus-strand DNA synthesis. Ty1 elements bearing a mutated PPT2 sequence are not defective for transposition whereas mutations in PPT1 abolish transposition.

SOS induction in Escherichia coli by single-stranded DNA of mutant filamentous phage: monitoring by cleavage of LexA repressor.

Infection of Escherichia coli in the presence of chloramphenicol with mutant filamentous phage that are defective in the initiation of minus-strand DNA synthesis induces the SOS response as monitored by cellular LexA levels. This observation demonstrates that single-stranded DNA serves as a primary signal for SOS induction in vivo.

Mutations in the epsilon sequences of human hepatitis B virus affect both RNA encapsidation and reverse transcription

Hepadnaviruses replicate by reverse transcription of an RNA intermediate within subviral core particles in the cytoplasm of infected hepatocytes. Recognition of the epsilon encapsidation signal located on the 5' end of the pregenomic RNA by the viral polymerase occurs early in core particle assembly. The epsilon sequences contain a set of nested inverted repeats which form a stable stem-loop structure shown to play a role in RNA packaging and recently implicated as the site of initiation of minus-strand DNA synthesis. We have introduced a variety of site-directed mutations into the epsilon sequences of human hepatitis B virus to study their effects on viral replication in transfected HuH7 cells. We have identified two classes of mutations: those which adversely affect packaging and those which package RNA but adversely affect DNA synthesis. Analysis of these mutants has allowed us to identify separate features of the epsilon cis-acting signal which function in the processes of RNA packaging and reverse transcription.

Human immunodeficiency virus reverse transcriptase ribonuclease H: specificity of tRNALys3-primer excision

Two model substrates were prepared to examine the mechanism of tRNA-primer excision catalyzed by reverse transcriptase associated ribonuclease H (RT-RNase H). The first model substrate contained sequences from the HIV genome and was designed to be structurally similar to the DNA-extended tRNA created by initiation of minus-strand DNA synthesis during retroviral replication. The DNA-extended RNA was a template and was annealed to a DNA oligonucleotide that primed reverse transcription of the RNA in the template. The second model substrate was structurally similar the first substrate but contained sequences unrelated to the HIV viral genome. The RT-RNase H catalyzed excision of the RNA from the template of the two model substrates was examined. Human immunodeficiency virus (HIV) and Moloney murine leukemia virus RT-RNase H hydrolyzed the substrates to leave a single ribonucleotide 5'-phosphate at the 5'-terminus of the model DNA genome. In contrast, avian myeloblastosis virus RT-RNase H hydrolyzed the phosphodiester bond at the DNA-RNA junction. These hydrolytic specificities were not highly dependent on substrate sequence. The importance of these specificities to retroviral integration is discussed. Additional data indicated that the HIV polymerase and RNase H active sites are separated by a distance equivalent to the length of a 15-nucleotide RNA-DNA heteroduplex.