Role of the "helix clamp" in HIV-1 reverse transcriptase catalytic cycling as revealed by alanine-scanning mutagenesis

The Determination of HIV-1 RT Mutation Rate, Its Possible Allosteric Effects, and Its Implications on Drug Resistance

The high mutation rate of the human immunodeficiency virus type 1 (HIV-1) plays a major role in treatment resistance, from the development of vaccines to therapeutic drugs. In addressing the crux of the issue, various attempts to estimate the mutation rate of HIV-1 resulted in a large range of 10⁻⁵–10⁻³ errors/bp/cycle due to the use of different types of investigation methods. In this review, we discuss the different assay methods, their findings on the mutation rates of HIV-1 and how the locations of mutations can be further analyzed for their allosteric effects to allow for new inhibitor designs. Given that HIV is one of the fastest mutating viruses, it serves as a good model for the comprehensive study of viral mutations that can give rise to a more horizontal understanding towards overall viral drug resistance as well as emerging viral diseases.

Identification of a premature termination of DNA polymerization in vitro by Klenow fragment mutants

DNA polymerization products by Klenow fragment (KF) are blunt-ended. In the present study, we found that the Klenow fragment mutants with partial deletions of thumb subdomain were unable to extend primers to the 5' terminal of templates, thus creating 5' overhanging sticky ends 2 nt long. We termed this phenomenon as PmTP (premature termination of polymerization). The KF mutants produced homogenous sticky-ended products only under mild reaction conditions, whereas under vigorous reaction conditions, the sticky ends were prone to be blunt-ended. It was also identified that deletions of more than four residues of KF thumb subdomain could induce PmTP, and tworesidue deletion of KF thumb subdomain only induced PmTP in a lower-concentration situation. Structure modelling analysis suggested that shortening or destruction of alpha helix H1 at the tip of the thumb subdomain was crucial to PmTP, while the conserved residues in front of alpha helix was less important. PmTP might be caused by the reduced DNAbinding affinity of the mutants. The sticky ends made by PmTP have potential applications in gene splicing and molecular cloning techniques.

Inhibition of HIV-1 reverse transcriptase-catalyzed synthesis by intercalated DNA Benzo[a]Pyrene 7,8-Dihydrodiol-9,10-Epoxide adducts

To aid in the characterization of the relationship of structure and function for human immunodeficiency virus type-1 reverse transcriptase (HIV-1 RT), this investigation utilized DNAs containing benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE)-modified primers and templates as a probe of the architecture of this complex. BPDE lesions that differed in their stereochemistry around the C₁₀ position were covalently linked to N⁶-adenine and positioned in either the primer or template strand of a duplex template-primer. HIV-1 RT exhibited a stereoisomer-specific and strand-specific difference in replication when the BPDE-lesion was placed in the template versus the primer strand. When the C₁₀R-BPDE adduct was positioned in the primer strand in duplex DNA, 5 nucleotides from the 3΄ end of the primer terminus, HIV-1 RT could not fully replicate the template, producing truncated products; this block to further synthesis did not affect rates of dissociation or DNA binding affinity. Additionally, when the adducts were in the same relative position, but located in the template strand, similar truncated products were observed with both the C₁₀R and C₁₀S BPDE adducts. These data suggest that the presence of covalently-linked intercalative DNA adducts distant from the active site can lead to termination of DNA synthesis catalyzed by HIV-1 RT.

Prediction of mutational tolerance in HIV-1 protease and reverse transcriptase using flexible backbone protein design

Predicting which mutations proteins tolerate while maintaining their structure and function has important applications for modeling fundamental properties of proteins and their evolution; it also drives progress in protein design. Here we develop a computational model to predict the tolerated sequence space of HIV-1 protease reachable by single mutations. We assess the model by comparison to the observed variability in more than 50,000 HIV-1 protease sequences, one of the most comprehensive datasets on tolerated sequence space. We then extend the model to a second protein, reverse transcriptase. The model integrates multiple structural and functional constraints acting on a protein and uses ensembles of protein conformations. We find the model correctly captures a considerable fraction of protease and reverse-transcriptase mutational tolerance and shows comparable accuracy using either experimentally determined or computationally generated structural ensembles. Predictions of tolerated sequence space afforded by the model provide insights into stability-function tradeoffs in the emergence of resistance mutations and into strengths and limitations of the computational model.

Many related protein sequences can be consistent with the structure and function of a given protein, suggesting that proteins may be quite robust to mutations. This tolerance to mutations is frequently exploited by pathogens. In particular, pathogens can rapidly evolve mutated proteins that have a new function - resistance against a therapeutic inhibitor - without abandoning other functions essential for the pathogen. This principle may also hold more generally: Proteins tolerant to mutational changes can more easily acquire new functions while maintaining their existing properties. The ability to predict the tolerance of proteins to mutation could thus help both to analyze the emergence of resistance mutations in pathogens and to engineer proteins with new functions. Here we develop a computational model to predict protein mutational tolerance towards point mutations accessible by single nucleotide changes, and validate it using two important pathogenic proteins and therapeutic targets: the protease and reverse transcriptase from HIV-1. The model provides insights into how resistance emerges and makes testable predictions on mutations that have not been seen yet. Similar models of mutational tolerance should be useful for characterizing and reengineering the functions of other proteins for which a three-dimensional structure is available.

HIV-1 RT Inhibitors with a Novel Mechanism of Action: NNRTIs that Compete with the Nucleotide Substrate

HIV-1 reverse transcriptase (RT) inhibitors currently used in antiretroviral therapy can be divided into two classes: (i) nucleoside analog RT inhibitors (NRTIs), which compete with natural nucleoside substrates and act as terminators of proviral DNA synthesis, and (ii) non-nucleoside RT inhibitors (NNRTIs), which bind to a hydrophobic pocket close to the RT active site. In spite of the efficiency of NRTIs and NNRTIs, the rapid emergence of multidrug-resistant mutations requires the development of new RT inhibitors with an alternative mechanism of action. Recently, several studies reported the discovery of novel non-nucleoside inhibitors with a distinct mechanism of action. Unlike classical NNRTIs, they compete with the nucleotide substrate, thus forming a new class of RT inhibitors: nucleotide-competing RT inhibitors (NcRTIs). In this review, we discuss current progress in the understanding of the peculiar behavior of these compounds.

Mutation rates and intrinsic fidelity of retroviral reverse transcriptases

Retroviruses are RNA viruses that replicate through a DNA intermediate, in a process catalyzed by the viral reverse transcriptase (RT). Although cellular polymerases and host factors contribute to retroviral mutagenesis, the RT errors play a major role in retroviral mutation. RT mutations that affect the accuracy of the viral polymerase have been identified by in vitro analysis of the fidelity of DNA synthesis, by using enzymological (gel-based) and genetic assays (e.g., M13mp2 lacZ forward mutation assays). For several amino acid substitutions, these observations have been confirmed in cell culture using viral vectors. This review provides an update on studies leading to the identification of the major components of the fidelity center in retroviral RTs.

The y271 and i274 amino acids in reverse transcriptase of human immunodeficiency virus-1 are critical to protein stability

Reverse transcriptase (RT) of human immunodeficiency virus (HIV)-1 plays a key role in initiating viral replication and is an important target for developing anti-HIV drugs. Our previous study showed that two mutations (Y271A and I274A) in the turn RT (Gln(269)-Arg(277)) abrogated viral replication, but the replication capacity and RT activity was discordant. In this study, we further investigated why alanine substitutions at these two sites would affect viral replication. We found that both RT activity and RT protein were almost undetectable in viral particles of these two mutants, although the Pr160(gag-pol) mutants were properly expressed, transported and incorporated. Using protease inhibition assay, we demonstrated a correlation between the degradation of the RT mutants and the activity of viral protease. Our native gel analysis indicated that the mutations at 271 and 274 amino acids might cause conformational changes, leading to the formation of higher order oligomers instead of dimers, resulting in increased protein instability and susceptibility to viral protease. Thus, residues 271 and 274 are critical to RT stability and resistance to viral protease. The conservation of the two amino acid residues among different strains of HIV-1 lent further support to this conclusion. The knowledge gained here may prove useful in drug design.

Autoimmunogenicity of the helix-loop-helix DNA-binding domain

Nonimmunogenic character of native DNA, and its high immunogenicity when presented in complex with the DNA-binding proteins indicate that the latter might contain molecular triggers of anti-DNA response. To find if this is the case, we have evaluated the autoimmunogenic potential of the main DNA-binding domain of HIV-1 reverse transcriptase that belongs to the canonical helix-loop-helix type. BALB/c mice were immunized with a peptide representing the domain, alone or in complex with the fragmented human DNA in the presence of an adjuvant. Mice were assessed for specific antibodies, autoantibodies against a panel of self-antigens; glomerular immunoglobulin deposition; and for the signs of autoimmune disease, such as proteinuria, and changes in the blood components. Immunization with the adjuvanted peptide-DNA complex induced autoantibodies against double-stranded DNA, histones, heterochromatin, and kidney proteins; glomerular IgG and IgA deposition; proteinuria; thrombocytopenia, and anemia. Altogether, this identifies the helix-loop-helix DNA-binding domain as one of the molecular triggers of autoimmunity to DNA and DNA-associated proteins. The experiments cast new light on the role of the DNA-binding retroviral proteins in the induction of autoimmunity, and on the origins of autoimmune complications in the microbial infections in general. It also implies that choosing the DNA-binding proteins as vaccine candidates should be done with precaution.

Mutational analysis of the "turn" of helix clamp motif of HIV-1 reverse transcriptase

Helix clamp motifs of polymerases possessing the helix-turn-helix secondary structure are crucial for their polymerase activity by binding to the nucleic acid template/primer via the alpha helices. To study the functions of turn in helix clamp motif of human immunodeficiency virus (HIV)-1 RT, clones with turn mutants at rt271-274 of HIV-1 RT were generated and studied by one cycle infection assay. Mutants rtY271A and rtI274A almost lost their replication competency, while mutants rtA272P, rtA272S, and rtG273A retained comparable replication competency relative to wild type pseudotyped HIV-1. To study the mechanisms involved, RT proteins from rt271 to rt274 mutants were expressed and assayed for their RNA dependent DNA polymerase activity, DNA binding activity and processivity. Discordance between RT activity and viral replication efficiency of some turn mutants was observed, indicating that aside from RT, other steps in HIV replication could be affected by substitutions at the turn of helix clamp motif.

A putative new domain target for anti-hepatitis B virus: residues flanking hepatitis B virus reverse transcriptase residue 306 (rtP306)

Previous work showed that conservation of proline at residue 306 (rtP306) of hepatitis B virus (HBV) reverse transcriptase (RT) is crucial for virus replication and encapsidation of pregenomic RNA (pgRNA). In this study, the functions of residues flanking rtP306 in HBV RT (rtG304, rtY305, rtA307, rtL308 and rtL311) are presented. Alanine or phenylalanine was used to substitute these residues by constructing site-directed mutants which were used to transfect Huh-7 cells. Replication competencies and encapsidation efficiencies were compared between the mutants and the parental viral strain. Substitutions at these residues resulted in marked decrease of replication competency, which was confirmed by Southern blot hybridization of HBV DNA isolated from intracytoplasmic core particles, and trans-complementation between a non-replicative defective mutant and corresponding RT mutants. Impaired pgRNA encapsidation efficiency of these mutants was shown as the major mechanism for decreased replication efficiency. Since residues from rt304 to rt311 are highly conserved among genotypes A-H HBV strains, results suggest that rt304 to rt311 in HBV RT may serve as a putative anti-HBV new target domain.

Biochemical properties of a plastidial DNA polymerase of rice

Plastids are organelles unique to plant cells and are responsible for photosynthesis and other metabolic functions. Despite their important cellular roles, relatively little is known about the mechanism of plastidial DNA replication and repair. Recently, we identified a novel DNA polymerase in Oryza Sativa L. (OsPOLP1, formerly termed OsPolI-like) that is homologous to prokaryotic DNA polymerase Is (PolIs), and suggested that this polymerase might be involved in plastidial DNA replication and repair. Here, we propose to rename the plant PolI homologs as DNA polymerase pi (POLP), and investigate the biochemical properties of full-length OsPOLP1. The purified OsPOLP1 elongated both DNA and RNA primer hybridized to a DNA template, and possessed a 3' exonuclease activity. Moreover, OsPOLP1 displayed high processivity and fidelity, indicating that this polymerase has the biochemical characteristics appropriate for DNA replication. We found that POLPs have two extra sequences in the polymerase domain that are absent in prokaryotic PolIs. Deletion of either insert from OsPOLP1 caused a decrease in DNA synthetic activity, processivity, and DNA binding activity. In addition, OsPOLP1 efficiently catalyzed strand displacement on nicked DNA with a 5'-deoxyribose phosphate, suggesting that this enzyme might be involved in a repair pathway similar to long-patch base excision repair. These results provide insights into the possible role of POLPs in plastidial DNA replication and repair.

Structural determinants of slippage-mediated mutations by human immunodeficiency virus type 1 reverse transcriptase

Single-base deletions at nucleotide runs or -1 frameshifting by human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) result from template slippage during polymerization. In crystal structures of HIV-1 RT complexed with DNA-DNA template-primer, the palm subdomain in the template cleft contacts the template backbone near the proposed site of slippage via the Glu(89) side chain. We investigated the role of Glu(89) in frameshifting by perturbing this interaction. Substitutions with Asp, Gly, Ala, Val, Ser, Thr, Asn, or Lys were created in recombinant HIV RT, and frameshift frequencies of the resulting mutant RTs were measured. All substitutions led to reduced -1 frameshifting by HIV-1 RT (2-40-fold). Interestingly, the suppression of -1 frameshifting frequently coincided with an enhancement of +1 frameshifting (3-47-fold) suggesting that Glu(89) can influence the slippage of both strands. Glu(89) substitutions also led to reduced rates of dNTP misincorporation that paralleled reductions in -1 frameshifting, suggesting a common structural mechanism for both classes of RT error. Our results reveal a major influence of Glu(89) on slippage-mediated errors and dNTP incorporation fidelity. The crystal structure of HIV-1 RT reveals a salt bridge between Glu(89) and Lys(154), which may facilitate -1 frameshifting; this concept is supported by the observed reduction in -1 frameshifting for K154A and K154R mutants.

High sequence conservation of human immunodeficiency virus type 1 reverse transcriptase under drug pressure despite the continuous appearance of mutations

To define the extent of sequence conservation in human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) in vivo, the first 320 amino acids of RT obtained from 2,236 plasma-derived samples from a well-defined cohort of 1,704 HIV-1-infected individuals (457 drug naïve and 1,247 drug treated) were analyzed and examined in structural terms. In naïve patients, 233 out of these 320 residues (73%) were conserved (<1% variability). The majority of invariant amino acids clustered into defined regions comprising between 5 and 29 consecutive residues. Of the nine longest invariant regions identified, some contained residues and domains critical for enzyme stability and function. In patients treated with RT inhibitors, despite profound drug pressure and the appearance of mutations primarily associated with resistance, 202 amino acids (63%) remained highly conserved and appeared mostly distributed in regions of variable length. This finding suggests that participation of consecutive residues in structural domains is strictly required for cooperative functions and sustainability of HIV-1 RT activity. Besides confirming the conservation of amino acids that are already known to be important for catalytic activity, stability of the heterodimer interface, and/or primer/template binding, the other 62 new invariable residues are now identified and mapped onto the three-dimensional structure of the enzyme. This new knowledge could be of help in the structure-based design of novel resistance-evading drugs.

High-efficiency bypass of DNA damage by human DNA polymerase Q

Endogenous DNA damage arises frequently, particularly apurinic (AP) sites. These must be dealt with by cells in order to avoid genotoxic effects. DNA polymerase theta; is a newly identified enzyme encoded by the human POLQ gene. We find that POLQ has an exceptional ability to bypass an AP site, inserting A with 22% of the efficiency of a normal template, and continuing extension as avidly as with a normally paired base. POLQ preferentially incorporates A opposite an AP site and strongly disfavors C. On nondamaged templates, POLQ makes frequent errors, incorporating G or T opposite T about 1% of the time. This very low fidelity distinguishes POLQ from other A-family polymerases. POLQ has three sequence insertions between conserved motifs in its catalytic site. One insert of approximately 22 residues into the tip of the polymerase thumb subdomain is predicted to confer considerable flexibility and additional DNA contacts to affect enzyme fidelity. POLQ is the only known enzyme that efficiently carries out both the insertion and extension steps for bypass of AP sites, commonly formed as endogenous genomic lesions.

High-level expression and purification of untagged and histidine-tagged HIV-1 reverse transcriptase

We have devised simplified protocols to purify large quantities of histidine-tagged (His-tagged) and untagged heterodimeric forms of human immunodeficiency virus type-1 reverse transcriptase (HIV-1 RT). Here, we report the optimization of overexpression and purification of heterodimeric RT expressed in Escherichia coli. The coding sequences of p66 and p51 subunits of RT were amplified using PCR from HXB2 HIV-1 and cloned into a bacterial expression system. The resulting expression plasmids for the RT subunits, pET-RT66 and pET-RT51, were under a strong T7/lac promoter that is induced by isopropyl-beta-d-thiogalactopyranoside. Purification of heterodimeric forms of RT was facilitated by high-level expression of these subunits that represented approximately 30-40% of total cell protein. For purification of the His-tagged heterodimeric RT, cell pellet from cells expressing the untagged p66 subunit was mixed in excess with a cell pellet expressing tagged p51. For untagged heterodimeric RT, the pellet from cells expressing p51 was mixed in excess with pellet expressing p66. Subunit dimerization occurred during cell lysis. During the subsequent chromatography steps, stable p66/p51 heterodimer was purified to homogeneity. The heterodimeric nature of the final preparations of RT was confirmed by analytical gel filtration, mass spectrometry, and denaturing gel electrophoresis. Further, the sensitivity of these enzyme preparations to AZTTP indicated that the histidine tag had no effect on nucleoside inhibitor binding, nucleotide binding or insertion, or DNA binding. The application of these expression/purification methodologies represents a useful method to purify large quantities of heterodimeric RT for structural investigations and provides an efficient protocol to produce subunit-specific amino acid alterations necessary for unambiguous structure/function investigations.

Using pyrrolo-deoxycytosine to probe RNA/DNA hybrids containing the human immunodeficiency virus type-1 3' polypurine tract

Recent structural analyses indicate that localized regions of abnormal base pairing exist within RNA/DNA hybrids containing the HIV-1 polypurine tract (PPT) and that these distortions may play a role in PPT function. To examine this directly, we have introduced pyrrolo-deoxycytosine (pdC), a fluorescent, environmentally sensitive analog of deoxycytosine (dC), into the DNA strand of PPT-containing hybrids. Steady-state fluorescence analysis of these hybrids reveals that the DNA base 11 nt from the PPT-U3 junction is unpaired even in the absence of reverse transcriptase (RT). Unstable base pairing is also observed within the (rG:dC)6 tract in the downstream portion of the duplex, suggesting that HIV-1 RT may recognize multiple pre-existing distortions during PPT selection. HIV-1 RT hydrolyzes pdC-containing hybrids primarily at the PPT-U3 junction, indicating that the analog does not induce a gross structural deformation of the duplex. However, aberrant cleavage is frequently observed 3 bp from the site of pdC substitution, most likely reflecting a specific interaction between the analog and amino acid residues within the RNase H primer grip. pdC substitution within the template strand of a DNA duplex does not appear to significantly affect RT-catalyzed DNA synthesis. Implications of these findings on the use of pdC to examine nucleic acid structure are discussed.

DNA-thumb interactions and processivity of T7 DNA polymerase in comparison to yeast polymerase eta

The replicative polymerase of bacteriophage T7 is structurally and mechanistically well characterized. The crystal structure of T7 DNA polymerase or gene 5 protein complexed to its processivity factor, Escherichia coli thioredoxin, a primer-template, and a dideoxynucleotide reveals how this enzyme interacts with the 3'-end of the primer-template, but does not show how thioredoxin confers processivity to the polymerase. In the crystal structure highly conserved amino acids Asn(335) and Ser(338) of the thumb subdomain of T7 DNA polymerase are seen to interact with phosphates 7 and 8 of the DNA template strand. Results with a mutant T7 DNA polymerase in which aliphatic residues are substituted for these amino acids and experiments with different length and methylphosphonate-modified primer-templates demonstrate that these interactions are essential for processive synthesis and d(A.T)(n) tract bypass. Our data with methylphosphonate-modified DNA suggests that thioredoxin confers processivity to T7 DNA polymerase in part by causing an interaction with the phosphate backbone or minor groove of DNA. Residues Asn(335) and Ser(338) may also function with a nearby helix-loop-helix motif located at residues 339-372 to enclose the DNA during processive synthesis. Our results suggest that this structure must be held close to the DNA by ionic interactions to function. These interactions also allow for DNA sliding but physically block the passage of a 3T bulge in the template. In contrast, yeast polymerase eta, a polymerase that non-mutagenically repairs cis-syn thymidine dimers, allows the same bulge to slide past its thumb subdomain during synthesis. A relaxed thumb interaction with the DNA could account for the notably low processivity of polymerase eta.

Molecular basis of fidelity of DNA synthesis and nucleotide specificity of retroviral reverse transcriptases

Reverse transcription involves the conversion of viral genomic RNAinto proviral double-stranded DNA that integrates into the host cell genome. Cellular DNA polymerases replicate the integrated viral DNA and RNA polymerase II transcribes the proviral DNA into RNA genomes that are packaged into virions. Although mutations can be introduced at any of these replication steps, reverse transcriptase (RT) errors play a major role in retroviral mutation. This review summarizes our current knowledge on fidelity of reverse transcriptases. Estimates of retroviral mutation rates or fidelity of retroviral RTs are discussed in the context of the different techniques used for this purpose (i.e., retroviral vectors replicated in culture, misinsertion and mispair extension fidelity assay, etc.). In vitro fidelity assays provide information on the RT's accuracy during the elongation reaction of DNA synthesis. In addition, other steps such as initiation of reverse transcription, or strand transfer, and factors including viral proteins such as Vpr [in the case of the human immunodeficiency virus type 1 (HIV-1)] have been shown to influence fidelity. A comprehensive description of the effect of amino acid substitutions on the fidelity of HIV-1 RT is presented. Published data point to certain dNTP-binding residues, as well as to various amino acids involved in interactions with the template or the primer strand, and to residues in the minor groove-binding track as major components of the fidelity center of retroviral RTs. Implications of these studies include the design of novel therapeutic strategies leading to virus extinction, by increasing the viral mutation rate beyond a tolerable threshold.

High processivity of the reverse transcriptase from a non-long terminal repeat retrotransposon

R2 is a retrotransposable element that specifically inserts into the 28 S rRNA genes of arthropods. The element encodes a single protein with endonuclease activity that cleaves the 28 S gene target site and reverse transcriptase (RT) activity that uses the cleaved DNA to prime reverse transcription. Here we compare various properties of the R2 RT activity with those of the well characterized retroviral RT, avian myeloblastosis virus (AMV). In processivity assays using heterogeneous RNA templates, R2 RT can synthesize cDNA over twice the length of that synthesized by AMV RT and can synthesize cDNA over 4 times longer than AMV RT in assays with poly(rA) templates. The higher processivity of R2 RT compared with retroviral RTs is a result of the slower rate of dissociation of the enzyme from RNA templates. The elongation rates of the two enzymes are similar. Finally, a highly distinct property of the R2 RT, compared with retroviral enzymes, is its ability to displace RNA strands annealed to RNA templates during cDNA synthesis. We suggest that both the higher processivity and displacement properties of R2 RT compared with retroviral RT result from the greater affinity of the R2 protein for the RNA template upstream of its active site.

DNA synthesis by HIV-1 reverse transcriptase at the central termination site: a kinetic study

Human immunodeficiency virus, type 1 (HIV-1) reverse transcriptase (RT) terminates plus-strand DNA synthesis at the center of the HIV-1 genome, a process important for HIV-1 infectivity. The central termination sequence contains two termination sites (Ter1 and Ter2) located at the 3'-end of A(n)T(m) motifs, and the narrowing of the DNA minor groove generated by these motifs is responsible for termination. Kinetic data associated with the binding of RT and its ability to elongate in vitro various DNA duplexes and triplexes surrounding the Ter2 terminator were analyzed using a simple kinetic scheme. At Ter2, RT still displays a reasonable affinity for the corresponding DNA, but the binding of the next nucleotide and above all its incorporation rate are markedly hampered. Features affecting the width of the minor groove act directly at this last step. The constraint exerted against elongation by the A(n)T(m) tract persists at two positions downstream of the terminator.

A novel interaction of tRNA(Lys,3) with the feline immunodeficiency virus RNA genome governs initiation of minus strand DNA synthesis

Complementarity between nucleotides at the 5' terminus of tRNA(Lys,3) and the U5-IR loop of the feline immunodeficiency virus RNA genome suggests a novel intermolecular interaction controls initiation of minus strand synthesis in a manner analogous to other retroviral systems. Base pairing of this tRNA-viral RNA duplex was confirmed by nuclease mapping of the RNA genome containing full-length or 5'-deleted variants of tRNA(Lys,3) hybridized to the primer-binding site. A major pause in RNA-dependent DNA synthesis occurred 14 nucleotides ahead of the primer-binding site with natural and synthetic tRNA(Lys,3) primers, indicating it was not a consequence of tRNA base modifications. The majority of the paused complexes resulted in dissociation of the reverse transcriptase from the template/primer, as demonstrated by an assay limited to a single binding event. Hybridization of a tRNA mutant whose 5' nucleotides are deleted relieved pausing at this position and subsequently allowed high level DNA synthesis. Additional experiments with tRNA-DNA chimeric primers were used to localize the stage of minus strand synthesis at which the tRNA-viral RNA interaction was disrupted. Finally, replacing nucleotides of the feline immunodeficiency virus U5-IR loop with the (A)(4) sequence of its human immunodeficiency virus (HIV)-1 counterpart also relieved pausing, but did not induce pausing immediately downstream of the primer-binding site previously noted during initiation of HIV-1 DNA synthesis. These combined observations provide further evidence of cis-acting sequences immediately adjacent to the primer-binding site controlling initiation of minus strand DNA synthesis in retroviruses and retrotransposons.

The effect of increased processivity on overall fidelity of human immunodeficiency virus type 1 reverse transcriptase

We previously reported that two insertions of 15 amino acids in the beta3-beta4 hairpin loop of fingers subdomain of HIV-1(NL4-3) RT confer an increased polymerase processivity. The processivity of human immunodeficiency virus (HIV) reverse transcriptase (RT) is thought to influence the fidelity of HIV-1 RT, which tends to create errors at template sites with high termination probability. Employing the two insertion variants of HIV-1 RT (FE20 and FE103), we examined the relationship between processivity, overall fidelity and error specificity. Although the overall mutation rate was unaffected by increased processivity, one of the mutants, FE103, generated significantly fewer frameshift errors. The other mutant, FE20, generated errors at hotspots not previously observed for HIV-1 RT. Our results indicate that an increase in the polymerase processivity of HIV-1 RT does not necessarily result in a decreased mutation rate and confirm that changes in processivity alter the sequence context in which the errors are made. Furthermore, our results also reveal that the mutation frequency obtained via in vitro gap-filling reactions with wild-type HIV-1(NL4-3) RT is only 2-fold higher than that obtained via a single cycle infection assay using the same, wild-type HIV-1(NL4-3) RT sequence as part of the helper pol function [Mansky and Temin: J Virol 69:5087-5094;1995].

Role of the dinB gene product in spontaneous mutation in Escherichia coli with an impaired replicative polymerase

We isolated several new mutator mutations of the Escherichia coli replicative polymerase dnaE subunit alpha and used them and a previously reported dnaE mutation to study spontaneous frameshift and base substitution mutations. Two of these dnaE strains produce many more mutants when grown on rich (Luria-Bertani) than on minimal medium. A differential effect of the medium was not observed when these dnaE mutations were combined with a mismatch repair mutation. The selection scheme for the dnaE mutations required that they be able to complement a temperature-sensitive strain. However, the ability to complement is not related to the mutator effect for at least one of the mutants. Comparison of the mutation rates for frameshift and base substitution mutations in mutS and dnaE mutS strains suggests that the mismatch repair proteins respond differently to the two types of change. Deletion of dinB from both chromosome and plasmid resulted in a four- to fivefold decrease in the rate of frameshift and base substitution mutations in a dnaE mutS double mutant background. This reduction indicates that most mistakes in replication occur as a result of the action of the auxiliary rather than the replicative polymerase in this dnaE mutant. Deletion of dinB from strains carrying a wild-type dnaE had a measurable effect, suggesting that a fraction of spontaneous mutations occur as a result of dinB polymerase action even in cells with a normal replicative polymerase.

Virus mutators and antimutators: roles in evolution, pathogenesis and emergence

Virus mutators (mutant alleles that confer a higher mutant-frequency phenotype than that of the wild type) and antimutators (mutant alleles that confer a lower mutant-frequency phenotype) were discovered in bacteriophage T4 over three decades ago, but there is only limited detailed knowledge about such genetic variants in viruses that infect humans and threaten public health. The creation of mutators and antimutators during the course of viral infection (particularly in the case of RNA viruses) could play a pivotal role in virus evolution, pathogenesis and emergence, and could also frustrate antiviral therapy.

Poliovirus RNA-dependent RNA polymerase (3Dpol): structural, biochemical, and biological analysis of conserved structural motifs A and B

We have constructed a structural model for poliovirus RNA-dependent RNA polymerase (3D(pol)) in complex with a primer-template (sym/sub) and ATP. Residues found in conserved structural motifs A (Asp-238) and B (Asn-297) are involved in nucleotide selection. Asp-238 appears to couple binding of nucleotides with the correct sugar configuration to catalytic efficiency at the active site of the enzyme. Asn-297 is involved in selection of ribonucleoside triphosphates over 2'-dNTPs, a role mediated most likely via a hydrogen bond between the side chain of this residue and the 2'-OH of the ribonucleoside triphosphate. Substitutions at position 238 or 297 of 3D(pol) produced derivatives exhibiting a range of catalytic efficiencies when assayed in vitro for poly(rU) polymerase activity or sym/sub elongation activity. A direct correlation existed between activity on sym/sub and biological phenotypes; a 2.5-fold reduction in polymerase elongation rate produced virus with a temperature-sensitive growth phenotype. These data permit us to propose a detailed, structural model for nucleotide selection by 3D(pol), confirm the biological relevance of the sym/sub system, and provide additional evidence for kinetic coupling between RNA synthesis and subsequent steps in the virus life cycle.

Structural determinants of murine leukemia virus reverse transcriptase that affect the frequency of template switching

Retroviral reverse transcriptases (RTs) frequently switch templates within the same RNA or between copackaged viral RNAs to generate mutations and recombination. To identify structural elements of murine leukemia virus RT important for template switching, we developed an in vivo assay in which RT template switching within direct repeats functionally reconstituted the green fluorescent protein gene. We quantified the effect of mutations in the YXDD motif, the deoxynucleoside triphosphate binding site, the thumb domain, and the RNase H domain of RT and hydroxyurea treatment on the frequencies of template switching. Hydroxyurea treatment and some mutations in RT increased the frequency of RT template switching up to fivefold, while all of the mutations tested in the RNase H domain decreased the frequency of template switching by twofold. Based on these results, we propose a dynamic copy choice model in which both the rate of DNA polymerization and the rate of RNA degradation influence the frequency of RT template switching.

Vertical-scanning mutagenesis of a critical tryptophan in the "minor groove binding track" of HIV-1 reverse transcriptase. Major groove DNA adducts identify specific protein interactions in the minor groove

Biochemical and molecular modeling studies of human immunodeficiency virus type 1 reverse transcriptase (RT) have revealed that a structural element, the minor groove binding track (MGBT), is important for both replication frameshift fidelity and processivity. The MGBT interactions occur in the DNA minor groove from the second through sixth base pair from the primer 3'-terminus where the DNA undergoes a structural transition from A-like to B-form DNA. Alanine-scanning mutagenesis had previously demonstrated that Gly(262) and Trp(266) of the MGBT contributes important DNA interactions. To probe the molecular interactions occurring in this critical region, eight mutants of RT were studied in which alternate residues were substituted for Trp(266). These enzymes were characterized in primer extension assays in which the template DNA was adducted at a single adenine by either R- or S-enantiomers of styrene oxide. These lesions failed to block DNA polymerization by wild-type RT, yet the Trp(266) mutants and an alanine mutant of Gly(262) terminated synthesis on styrene oxide-adducted templates. Significantly, the sites of termination occurred primarily 1 and 3 bases following adduct bypass, when the lesion was positioned in the major groove of the template-primer stem. These results indicate that residue 266 serves as a "protein sensor" of altered minor groove interactions and identifies which base pair interactions are altered by these lesions. In addition, the major groove lesion must alter important structural transitions in the template-primer stem, such as minor groove widening, that allow RT access to the minor groove.

The HIV-1 reverse transcription (RT) process as target for RT inhibitors

Since the Human Immunodeficiency Virus Type 1 (HIV-1) was identified as the etiologic agent of the Acquired Immune Deficiency Syndrome (AIDS), the HIV-1 reverse transcriptase (RT) has been the subject of intensive study. The reverse transcription entails the transition of the single-stranded viral RNA into double-stranded proviral DNA, which is then integrated into the host chromosome. Therefore, the HIV-1 reverse transcriptase plays a pivotal role in the life cycle of the virus and is consequently an interesting target for anti-HIV drug therapy. In the first section, we describe the complex process of reverse transcription and the different activities involved in this process. We then highlight the structure-function relationship of the HIV-1 reverse transcriptase, which is of great importance for a better understanding of resistance development, a major problem in anti-AIDS therapies. Finally, we summarize the mechanisms of HIV resistance toward various RT inhibitors and the implications thereof for the current anti-HIV drug therapies.

Mutations in the primer grip region of HIV reverse transcriptase can increase replication fidelity

Mutations in the primer grip region of human immunodeficiency virus reverse transcriptase (HIV-RT) affect its replication fidelity. The primer grip region (residues 227-235) correctly positions the 3'-ends of primers. Point mutations were created by alanine substitution at positions 224-235. Error frequencies were measured by extension of a dG:dA primer-template mismatch. Mutants E224A, P225A, P226A, L228A, and E233A were approximately equal to the wild type in their ability to extend the mismatch. Mutants F227A, W229A, M230A, G231A, and Y232A extended 40, 66, 54, 72, and 76% less efficiently past a dG:dA mismatch compared with the wild type. We also examined the misinsertion rates of dG, dC, or dA across from a DNA template dA using RT mutants F227A and W229A. Mutant W229A exhibited high fidelity and did not produce a dG:dA or dC:dA mismatch. Interestingly, mutant F227A displayed high fidelity for dG:dA and dC:dA mismatches but low fidelity for dA:dA misinsertions. This indicates that F227A discriminates against particular base substitutions. However, a primer extension assay with three dNTPs showed that F227A generally displays higher fidelity than the wild type RT. Clearly, primer grip mutations can improve or worsen either the overall or base-specific fidelity of HIV-RT. We hypothesize that wild type RT has evolved to a fidelity that allows genetic variation without compromising yield of viable viruses.

New human immunodeficiency virus, type 1 reverse transcriptase (HIV-1 RT) mutants with increased fidelity of DNA synthesis. Accuracy, template binding, and processivity

Infidelity of DNA synthesis by human immunodeficiency virus, type 1 reverse transcriptase (HIV-1 RT) is a presumptive determinant of HIV-1 hypervariability and is incompletely understood at the mechanistic and structural levels. Amino acid substitution at only three residues, including Asp-76 (Kim, B., Hathaway, T. R., and Loeb, L. A. (1996) Biochemistry 37, 5831-5839), is known to increase fidelity. We report here that substitution at Arg-78 can also increase accuracy. Mutant R78A RT showed reduced primer extension in misincorporation assays lacking a complementary dNTP and exhibited a 9-fold decrease in mutation frequency in the M13mp2 lacZ forward mutation assay. Previous structural studies indicate that Arg-78 and Asp-76 lie in a region that interacts with template nucleotides. Interestingly, R78A RT exhibited 6- to 8-fold decreases in binding affinity (K(d)) for RNA and DNA templates relative to wild type RT. In contrast, D76V RT, which also increases fidelity (Kim et al., 1996), showed a 6- to 7-fold increased affinity. The processivity of R78A RT on both RNA and DNA templates was substantially reduced relative to wild type RT, whereas the processivity of D76V RT was increased. We discuss relationships of fidelity, template binding, and processivity in these and other HIV RT mutants.

Residues in the alphaH and alphaI helices of the HIV-1 reverse transcriptase thumb subdomain required for the specificity of RNase H-catalyzed removal of the polypurine tract primer

During retrovirus replication, reverse transcriptase (RT) must specifically interact with the polypurine tract (PPT) to generate and subsequently remove the RNA primer for plus-strand DNA synthesis. We have investigated the role that human immunodeficiency virus-1 RT residues in the alphaH and alphaI helices in the thumb subdomain play in specific RNase H cleavage at the 3'-end of the PPT; an in vitro assay modeling the primer removal step was used. Analysis of alanine-scanning mutants revealed that a subgroup exhibits an unusual phenotype in which the PPT is cleaved up to seven bases from its 3'-end. Further analysis of alphaH mutants (G262A, K263A, N265A, and W266A) with changes in residues in or near a structural motif known as the minor groove binding track showed that the RNase H activity of these mutants is more dramatically affected with PPT substrates than with non-PPT substrates. Vertical scan mutants at position 266 were all defective in specific RNase H cleavage, consistent with conservation of tryptophan at this position among lentiviral RTs. Our results indicate that residues in the thumb subdomain and the minor groove binding track in particular, are crucial for unique interactions between RT and the PPT required for correct positioning and precise RNase H cleavage.

HIV-1 reverse transcription: a brief overview focused on structure-function relationships among molecules involved in initiation of the reaction

An early step in the life cycle of the human immunodeficiency virus type 1 (HIV-1) is reverse transcription of viral RNA into proviral DNA, which can then be integrated into the host cell genome. Reverse transcription is a discontinuous process carried out by the viral encoded reverse transcriptase that displays DNA polymerase activities on RNA and DNA templates as well as an RNase H activity that degrades transcribed RNA. DNA synthesis is initiated by cellular tRNALys3 that binds at its 3'-terminus to the complementary primer binding site of the genomic RNA. The initiation of reverse transcription is itself a complex reaction that requires tRNA placement onto viral RNA and the formation of a specific primer/template complex that is recognized by reverse transcriptase. After initiation takes place, the enzyme translocates from the initially bound RNA/RNA duplex into chimeric replication intermediates and finally accommodates newly synthesized DNA/RNA hybrids. This review focuses on structure-function relationships among these various molecules that are involved in the initiation of HIV-1 reverse transcription.

Vertical-scanning mutagenesis of a critical tryptophan in the minor groove binding track of HIV-1 reverse transcriptase. Molecular nature of polymerase-nucleic acid interactions

While sequence-specific DNA-binding proteins interact predominantly in the DNA major groove, DNA polymerases bind DNA through interactions in the minor groove that are sequence nonspecific. Through functional analyses of alanine-substituted mutant enzymes that were guided by molecular dynamics modeling of the human immunodeficiency virus type 1-reverse transcriptase and DNA complex, we previously identified a structural element in reverse transcriptase, the minor groove binding track (MGBT). The MGBT is comprised of five residues (Ile94, Gln258, Gly262, Trp266, and Gln269) which interact 2-6 base pairs upstream from the polymerase active site in the DNA minor groove and are important in DNA binding, processivity, and frameshift fidelity. These residues do not contribute equally; functional analysis of alanine mutants suggests that Trp266 contributes the most to binding. To define the molecular interactions between Trp266 and the DNA minor groove, we have analyzed the properties of eight mutants, each with an alternate side chain at this position. A refined molecular dynamics model was used to calculate relative binding free energies based on apolar surface area buried upon complex formation. In general, there was a strong correlation between the relative calculated binding free energies for the alternate residue 266 side chains and the magnitude of the change in the properties which reflect template-primer interactions (template-primer dissociation rate constant, Ki,AZTTP, processivity, and frameshift fidelity). This correlation suggests that hydrophobic interactions make a major contribution to the stability of the polymerase-DNA complex. Additionally, tyrosine and arginine substitutions resulted in mutant enzymes with DNA binding properties better than predicted by buried surface area alone, suggesting that hydrogen bonding could also play a role in DNA binding at this position.

The influence of 3TC resistance mutation M184I on the fidelity and error specificity of human immunodeficiency virus type 1 reverse transcriptase

A common target for therapies against human immuno-deficiency virus type 1 (HIV-1) is the viral reverse transcriptase (RT). Treatment with the widely used nucleoside analog (-)-2', 3'-deoxy-3'-thiacytidine (3TC) leads to the development of resistance-conferring mutations at residue M184 within the YMDD motif of RT. First, variants of HIV with the M184I substitution appear transiently, followed by viruses containing the M184V substitution, which persist and become the dominant variant for the duration of therapy. In the three-dimensional crystal structure of HIV-1 RT complexed with double-stranded DNA, the M184 residue lies in the vicinity of the primer terminus, near the incoming dNTP substrate. Recent studies have shown that 3TC resistance mutations, including M184I, increase the nucleotide insertion and mispair extension fidelity. Therefore, we have examined the effects of the M184I mutation on the overall polymerase fidelity of HIV-1 RT via an M13-based forward mutation assay. We found the overall error rate of the M184I variant of HIV-1 RT to be 1.7 x 10(-5) per nucleotide. This represents a 4-fold increase in fidelity over wild-type HIV-1Hxb2RT (7.0 x 10(-5) per nucleotide) and a 2.5-fold increase in fidelity over the M184V variant (4.3 x 10(-5) per nucleotide). Of the nucleoside analog resistance mutations studied using the forward assay, the M184I variant has shown the greatest increase in fidelity observed to date. Interestingly, the M184I variant RT displays significantly altered error specificity, both in terms of error rate at specific sites and in the overall ratio of substitution to frameshift mutations in the entire target.

Effects of mutations in the polymerase domain on the polymerase, RNase H and strand transfer activities of human immunodeficiency virus type 1 reverse transcriptase

Based on structural analyses and on the behavior of mutants, we suggest that the polymerase domain of HIV-1 reverse transcriptase (RT) plays a critical role in holding and appropriately positioning the template-primer both at the polymerase active site and at the RNase H active site. For RT to successfully copy the viral RNA genome, RNase H must cleave the RNA with absolute precision. We believe that a combination of the structure of the template-primer and its precise positioning are responsible for the specific cleavages RNase H makes. We have proposed that resistance of HIV-1 RT to nucleoside analogs involves a subtle repositioning of the template-primer. This hypothesis is based on both structural and biochemical analyses. Mutations that confer resistance to nucleoside analogs do not cluster at the polymerase active site; however, they are in positions where they could alter the interaction between RT and the template-primer. If, as we have hypothesized, the polymerase domain is primarily responsible for positioning the template-primer and RNase H cleavage depends on this positioning, it should be possible to use RNase H cleavage to monitor at least some of the major changes in the position of the template-primer. We have used three assays (polymerase, RNase H, and strand transfer) to investigate the effects of mutations in the polymerase domain, including mutations that confer resistance to nucleotide analogs, on HIV-1 RT. All three assays involve RNA sequences derived from the viral genome. The data show that alterations in the polymerase domain, in particular, mutations that are in positions that would be expected to alter the interaction of RT with the template-primer, can alter both the efficiency and specificity of RNase H cleavage. These results are discussed in light of the structure of HIV-1 RT.

Construction and characterization of a temperature-sensitive human immunodeficiency virus type 1 reverse transcriptase mutant

A temperature-sensitive (ts) human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) mutant was generated by charged-cluster-to-alanine mutagenesis. The mutant virus, containing three charged residues within the RT finger domain changed to alanine (K64A, K66A, and D67A), replicated normally at 34.5 but not 39.5 degrees C. Quantitating virus particle production by p24 antigen capture or virion-associated RT activity and virus infectivity by the MAGI cell assay, we found that (i) mutant virions produced at the permissive temperature were indistinguishable from wild-type virus in assays performed at the nonpermissive temperature, suggesting that the ts mutation did not impair early steps in the virus replication cycle and that the mutant RT enzyme was not ts; and (ii) virus particle production in cells transfected with the ts mutant at the nonpermissive temperature was comparable to that of wild-type virus. However, the particle-associated RT activity and infectivity of mutant virions produced at the nonpermissive temperature were greatly reduced when assays were conducted at the permissive temperature. These results are consistent with an irreversible ts event affecting RT that occurs during virus particle production. Radioimmunoprecipitation analyses revealed that both p66 and p51 RT subunits were absent from mutant virions generated at 39.5 degrees C. The presence of normal levels of HIV-1 integrase in mutant particles produced at the nonpermissive temperature was inconsistent with defective Gag-Pol synthesis or Gag-Pol incorporation into progeny virions. Furthermore, wild-type levels of the mutant Pr160(gag-pol) were detected in virions produced at the nonpermissive temperature when the HIV-1 protease was inactivated by site-specific mutagenesis. Taken together, these results are most consistent with a ts defect affecting the degradation or aberrant processing of the mutated RT during its processing/maturation within nascent particles.

Interaction of retroviral reverse transcriptase with template-primer duplexes during replication

Conversion of the single-stranded RNA of an invading retrovirus into double-stranded proviral DNA is catalyzed in a multi-step process by a single virus-coded enzyme, reverse transcriptase (RT). Achieving this requires a combination of DNA polymerase abd ribonuclease H (RNase H) activities, which are located at the amino and carboxy terminus of the enzyme, respectively. Moreover, proviral DNA synthesis requires that three structurally-distinct nucleic acid duplexes are accommodated by this enzyme, namely (a) A-form RNA (initiation of minus strand synthesis), non-A, non-B RNA/DNA hybrid (minus strand synthesis and initiation of plus strand synthesis) and B-form duplex DNA (plus strand synthesis). This review summarizes our current understanding of the manner in which retroviral RT interacts with this diverse array of nucleic acid duplexes, exploiting in many cases mutants unable to catalyze a specific event. These studies illustrate that seemingly 'simple' events such as tRNA-primed initiation of minus strand synthesis are considerably more complex, involving intermolecular tRNA-viral RNA interactions outside the primer binding site. Moreover, RNase H activity, generally thought to catalyze non-specific degradation of the RNA-DNA replicative intermediate, is required for highly specialized events including DNA strand transfer and polypurine selection. Finally, a unique structure near the center of HIV proviral DNA, the central termination sequence, serves to halt the replication machinery in a manner analogous to termination of transcription. As these highly specialized events are better understood at the molecular level, they may open new avenues of therapeutic intervention in the continuing effort to stem the progression of HIV infection and AIDS.

Mispair extension fidelity of human immunodeficiency virus type 1 reverse transcriptases with amino acid substitutions affecting Tyr115

The role of Tyr115 of human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) in the mispair extension fidelity of DNA dependent DNA synthesis was analysed by using a series of 15 mutant enzymes with substitutions at Tyr115. Their kinetic parameters for elongation using homopolymeric RNA-DNA and heteropolymeric DNA-DNA complexes showed major effects of the amino acid substitutions on the Km value for dNTP. Enzymes with large hydrophobic residues at position 115 displayed lower Km values than enzymes with small and charged amino acids at this position. The influence of all these amino acid replacements in mispair extension fidelity assays was analyzed using three different mismatches (A:C, A:G and A:A) at the 3'-terminal position of the primer DNA. For the A:C mispair, a 2. 6-33.4-fold increase in mispair extension efficiency (fext) was observed as compared with the wild-type enzyme. Unexpectedly, all the mutants tested as well as the wild-type RT were very efficient in extending the A:G and A:A transversion mispairs. This effect was due to the template-primer sequence context and not to the buffer conditions of the assay. The data support a role of Tyr115 in accommodating the complementary nucleotide into the nascent DNA while polymerization takes place.

Probing structure/function relationships of HIV-1 reverse transcriptase with styrene oxide N2-guanine adducts

Details of the interactions between the human immunodeficiency virus (HIV-1) reverse transcriptase and substrate DNA were probed both by introducing site-specific and stereospecific modifications into DNA and by altering the structure of potential critical residues in the polymerase. Unadducted 11-mer DNAs and 11-mer DNAs containing R and S enantiomers of styrene oxide at N2-guanine were ligated with two additional oligonucleotides to create 63-mers that served as templates for HIV-1 reverse transcriptase replication. Oligonucleotides that primed synthesis 5 bases 3' to the adducts could be extended up to 1 base 3' and opposite the lesion. However, when the positions of the 3'-OH of the priming oligonucleotides were placed 1, 2, 3, 4, 5, and 6 bases downstream of the styrene oxide guanine adducts, replication was initiated, only to be blocked after incorporating 4, 5, 6, and 7 bases beyond the lesion. The sites of this adduct-induced termination corresponded to the position of the DNA where alpha-helix H makes contact with the DNA minor groove, 3-5 bases upstream of the growing 3' end. In addition, mutants of the polymerase in alpha-helix H (W266A and G262A) alter the termination probabilities caused by these DNA adducts, suggesting that alpha-helix H is a sensitive monitor of modifications in the minor groove of newly synthesized template-primer DNA several bases distal to the 3'-OH.

DNA curvature controls termination of plus strand DNA synthesis at the centre of HIV-1 genome

In vivo and in vitro, reverse transcriptase (RT) from human immunodeficiency virus type 1 (HIV-1) terminates plus strand synthesis at the centre of the viral genome. The central termination sequence (CTS) contains curved DNA fragments located upstream of each terminator site. Two different models, relying either on the A-tract or general sequence roll assumptions, were used to predict the extent and the direction of this curvature as well as to design mutants, which abolished it. Straightening of each curved element abolished termination at the site located immediately downstream from the curvature. When synthesis was performed on the other strand and in the opposite direction, the two curved elements C1 and C2 associated with the two termination sites Ter1 and Ter2, led again to termination of DNA synthesis. Therefore, termination occurred as a nascent bent duplex was synthesized within the template primer binding cleft of RT, even when putative strand-specific motifs have been removed by the inversion. Computation of DNA paths upstream of other known arrest sites suggested that this feature was of general relevance for termination. At the CTS, termination occurred more precisely at the 3' end of an AnTm motif (n + m = 7). The possible structures, adopted by this motif, are discussed and confronted with the present crystallographic and biochemical data obtained on HIV-1 RT-DNA interactions and on HIV-1 RT processivity.

Differential tolerance to DNA polymerization by HIV-1 reverse transcriptase on N6 adenine C10R and C10S benzo[a]pyrene-7,8-dihydrodiol 9,10-epoxide-adducted templates

To determine the effect of various stereoisomers of benzo[a]pyrene-7,8-dihydrodiol 9,10-epoxide (BPDE) on translesion bypass by human immunodeficiency virus-1 reverse transcriptase and its alpha-helix H mutants, six 33-mer templates were constructed bearing site- and stereospecific adducts. This in vitro model system was chosen to understand the structure-function relationships between the polymerase and damaged DNA during replication. Comparison of the replication pattern between wild type human immunodeficiency virus-1 reverse transcriptase and its mutants, using primers which were 3' to the lesion, revealed essentially similar patterns. While these primers terminated with all three of the C10R and two of the C10S BPDE-adducted templates 1 base 5' and 1 base 3' to the damaged site respectively, (+)-anti-trans-(C10S) BPDE-adducted DNA alone permitted the formation of full-length products. Utilization of a primer with its 3'-hydroxyl 1 base beyond the lesion resulted in full-length products with all the C10S BPDE-adducted templates and the (-)-syn-trans-(C10R)-BPDE-adducted template, following replication with either the wild type or mutant enzymes. However, the other two C10R BPDE-adducted templates failed to allow any primer extension, even with the wild type enzyme. Although T.P depletion studies further confirmed the differential primer extension abilities using the C10R and C10S adducted templates, their binding affinities were similar, yet distinct from the unadducted template.