A minor groove binding track in reverse transcriptase

Substitutions of Phe61 located in the vicinity of template 5'-overhang influence polymerase fidelity and nucleoside analog sensitivity of HIV-1 reverse transcriptase

Human immunodeficiency virus type 1 reverse transcriptase (RT) is an error-prone DNA polymerase. Structural determinants of its fidelity are incompletely understood. RT/template primer contacts have been shown to influence its fidelity and sensitivity to nucleoside analog inhibitors. The Phe(61) residue, located within the beta 3 sheet of the finger subdomain, is highly conserved among retroviral RTs. The crystal structure of a ternary complex revealed that Phe(61) contacts the first and second bases of the 5'-template overhang. To determine whether such contacts influence the dNTP-binding pocket, we performed a limited vertical scanning mutagenesis (Phe --> Ala, Leu, Trp, or Tyr) at Phe(61). The F61A mutant displayed the highest increase in fidelity, followed by the F61L and F61W variants, which had intermediate phenotypes. F61Y RT had a minimal effect. The increase in fidelity of the F61A mutant was corroborated by a 12-fold decrease in its forward mutation rate. The Phe(61) mutant RTs also displayed large reductions in sensitivity to 2',3'-dideoxythymidine triphosphate and 2',3'-dideoxy,2'3'-didehydrothymidine triphosphate. Mutants displaying the largest increase in fidelity (F61A and F61L) were also the most resistant. These results suggest that contacts between the finger subdomain of human immunodeficiency virus type 1 RT and the template 5'-overhang are important determinants of the geometry of the dNTP-binding pocket.

Mutations that confer resistance to template-analog inhibitors of human immunodeficiency virus (HIV) type 1 reverse transcriptase lead to severe defects in HIV replication

We isolated two template analog reverse transcriptase (RT) inhibitor-resistant mutants of human immunodeficiency virus (HIV) type 1 RT by using the DNA aptamer, RT1t49. The mutations associated, N255D or N265D, displayed low-level resistance to RT1t49, while high-level resistance could be observed when both mutations were present (Dbl). Molecular clones of HIV that contained the mutations produced replication-defective virions. All three RT mutants displayed severe processivity defects. Thus, while biochemical resistance to the DNA aptamer RT1t49 can be generated in vitro via multiple mutations, the overlap between the aptamer- and template-primer-binding pockets favors mutations that also affect the RT-template-primer interaction. Therefore, viruses with such mutations are replication defective. Potent inhibition and a built-in mechanism to render aptamer-resistant viruses replication defective make this an attractive class of inhibitors.

Mechanisms of retroviral recombination

Recombination is a major source of genetic variability in retroviruses. Each viral particle contains two single-stranded genomic RNAs. Recombination mostly results from a switch in template between these two RNAs during reverse transcription. Here we emphasize the main mechanisms underlying recombination that are emerging from recent advances in biochemical and cell culture techniques. Increasing evidence supporting the involvement of RNA secondary structures now complements the predominant role classically attributed to enzyme pausing during reverse transcription. Finally, the implications of recombination on the dynamics of emergence of genomic aberrations in retroviruses are discussed.

A mutation in the primer grip region of HIV-1 reverse transcriptase that confers reduced fidelity of DNA synthesis

A compensatory mutation (M230I) in the primer grip of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) restores the replication capacity of virus having a Y115W mutation in their RT coding region. The Y115W substitution impairs DNA polymerase activity and produces an enzyme with a lower fidelity of DNA synthesis. Gel-based fidelity assays with the double mutant Y115W/M230I revealed that the M230I substitution increased the accuracy of mutant Y115W. Y115W/M230I showed wild-type misinsertion fidelity in assays performed with DNA/DNA templates. However, when present alone, M230I conferred reduced fidelity as determined in misinsertion and mispair extension fidelity assays, as well as in primer extension assays carried out with three dNTPs. The mutant M230I showed a 3.3-16-fold increase in misinsertion efficiency for G, C and T opposite T, compared with the wild-type enzyme. Its fidelity was not influenced by nucleotide substitutions in the template/primer around the incorporation site. However, its accuracy was apparently affected by the structure of the 5'-overhang of the template strand. Unlike wild-type HIV-1 RT, nucleotide selectivity of mutant M230I at dT:dG, dT:dC and dT:dT mispairs was almost exclusively dependent on the K(m) values for correct and incorrect dNTPs, a characteristic that has not been described for other low fidelity mutants of HIV-1 RT.

Molecular dynamics of HIV-1 reverse transcriptase indicates increased flexibility upon DNA binding

HIV-1 reverse transcriptase (RT) is one of the main targets for drugs used in the treatment of AIDS, among them, the non-nucleoside RT inhibitors (NNRTIs). The flexibility of RT unliganded and complexed to double-stranded DNA (RT/dsDNA), in water, has been studied by means of molecular dynamics. The simulations show that RT flexibility depends on its ligation state. The RT/dsDNA trajectories show larger fluctuations in the atomic positions than uncomplexed RT, particularly at the tips of the p66 fingers and thumb subdomains. This increased flexibility is consistent with the ability of the p66 fingers of the RT/dsDNA complex to close down after the binding of a deoxynucleoside triphosphate (dNTP) molecule, as observed in the crystal structures of RT/dsDNA bound to dNTP. The two complexation states present different patterns of concerted motions, indicating that the bound dsDNA alters RT flexibility. The motions of amino acid residues that form the non-nucleoside RT inhibitor binding pocket upon complexation with a NNRTI are anticorrelated with the p66 fingers (in RT/dsDNA) and correlated to the RNase H subdomain (unliganded RT). These concerted motions indicate that binding of a NNRTI could alter the flexibility of the subdomains whose motions are correlated to those of the binding pocket.

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.

Structures of complexes formed by HIV-1 reverse transcriptase at a termination site of DNA synthesis

This study presents structural parameters associated with termination of human immunodeficiency virus, type 1 (HIV-1) reverse transcriptase (RT) at Ter2, the major termination site located in the center of the HIV-1 genome. DNA footprinting studies of various elongation complexes formed by RT around wild type and mutant Ter2 sites have revealed two major structural transformations of these complexes when the enzyme gets closer to Ter2. First, the interactions between RT and the DNA duplex are less extended, although the global affinity of the enzyme for this duplex is only decreased by 2-fold. Second, there is an atypical positioning of the RT RNase H domain on the DNA duplex. We interpret our data as indicating that the A(n)T(m) motif located upstream of Ter2 prevents a classical positioning of the enzyme on the double-stranded part of the DNA duplex at some precise positions of elongation downstream of this motif. Instead, novel species of binary and/or ternary complexes, characterized by atypical footprints, are formed. The new rate-limiting step of the reaction, characterized in the preceding paper (Lavigne, M., Polomack, L., and Buc, H. (2001) J. Biol. Chem. 276, 31429-31438), would be a transition leading from these new species to a catalytically competent ternary complex.

Hydrogen bonding, base stacking, and steric effects in dna replication

Understanding the mechanisms by which genetic information is replicated is important both to basic knowledge of biological organisms and to many useful applications in biomedical research and biotechnology. One of the main functions of a DNA polymerase enzyme is to help DNA recognize itself with high specificity when a strand is being copied. Recent studies have shed new light on the question of what physical forces cause a polymerase enzyme to insert a nucleotide into a strand of DNA and to choose the correct nucleotide over the incorrect ones. This is discussed in the light of three main forces that govern DNA recognition: base stacking, Watson-Crick hydrogen bonding, and steric interactions. These factors are studied with natural and structurally altered DNA nucleosides.

Evading the proofreading machinery of a replicative DNA polymerase: induction of a mutation by an environmental carcinogen

DNA replication fidelity is dictated by DNA polymerase enzymes and associated proteins. When the template DNA is damaged by a carcinogen, the fidelity of DNA replication is sometimes compromized, allowing mispaired bases to persist and be incorporated into the DNA, resulting in a mutation. A key question in chemical carcinogenesis by metabolically activated polycyclic aromatic hydrocarbons (PAHs) is the nature of the interactions between the carcinogen-damaged DNA and the replicating polymerase protein that permits the mutagenic misincorporation to occur. PAHs are environmental carcinogens that, upon metabolic activation, can react with DNA to form bulky covalently linked combination molecules known as carcinogen-DNA adducts. Benzo[a]pyrene (BP) is a common PAH found in a wide range of material ingested by humans, including cigarette smoke, car exhaust, broiled meats and fish, and as a contaminant in other foods. BP is metabolically activated into several highly reactive intermediates, including the highly tumorigenic (+)-anti-benzo[a]pyrene diol epoxide (BPDE). The primary product of the reaction of (+)-anti-BPDE with DNA, the (+)-trans-anti-benzo[a]pyrene diol epoxide-N(2)-dG ((+)-ta-[BP]G) adduct, is the most mutagenic BP adduct in mammalian systems and primarily causes G-to-T transversion mutations, resulting from the mismatch of adenine with BP-damaged guanine during replication. In order to elucidate the structural characteristics and interactions between the DNA polymerase and carcinogen-damaged DNA that allow a misincorporation opposite a DNA lesion, we have modeled a (+)-ta-[BP]G adduct at a primer-template junction within the replicative phage T7 DNA polymerase containing an incoming dATP, the nucleotide most commonly mismatched with the (+)-ta-[BP]G adduct during replication. A one nanosecond molecular dynamics simulation, using AMBER 5.0, has been carried out, and the resultant trajectory analyzed. The modeling and simulation have revealed that a (+)-ta-[BP]G:A mismatch can be accommodated stably in the active site so that the fidelity mechanisms of the polymerase are evaded and the polymerase accepts the incoming mutagenic base. In this structure, the modified guanine base is in the syn conformation, with the BP moiety positioned in the major groove, without interfering with the normal protein-DNA interactions required for faithful polymerase function. This structure is stabilized by a hydrogen bond between the modified guanine base and dATP partner, hydrophobic interactions between the BP moiety and the polymerase, a hydrogen bond between the modified guanine base and the polymerase, and several hydrogen bonds between the BP moiety and polymerase side-chains. Moreover, the G:A mismatch in this system closely resembles the size and shape of a normal Watson-Crick pair. These features reveal how the polymerase proofreading machinery may be evaded in the presence of a mutagenic carcinogen-damaged DNA, so that a mismatch can be accommodated readily, allowing bypass of the adduct by the replicative T7 DNA polymerase.

Analysis of efficiency and fidelity of HIV-1 (+)-strand DNA synthesis reveals a novel rate-limiting step during retroviral reverse transcription

We have analyzed the efficiency and accuracy of polymerization at several different stages during the initiation of human immunodeficiency virus type 1 (HIV-1) (+)-strand DNA synthesis. This reaction is of particular interest, as it involves the recruitment by reverse transcriptase of an RNA primer that serves as substrate for both the polymerase and RNase H activities of the enzyme. We found that the correct incorporation of the first two nucleotides was severely compromised and that formation of mismatches was completely absent at this stage of initiation. Although the fidelity of incorporations decreased concomitantly with ensuing polymerization, the elongation of mispaired primers was literally blocked. Instead, mispaired primer strands initiated a switch from active synthesis of DNA to premature RNase H-mediated primer removal. These findings suggest the existence of a fragile equilibrium between these two enzymatic activities that is shifted toward RNase H cleavage once the polymerization process is aggravated. Our data show that the initiation of HIV-1 (+)-strand DNA synthesis differs significantly from reactions involving other primer/template combinations, including tRNA-primed (-)-strand DNA synthesis.

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].

DNA replication fidelity

DNA replication fidelity is a key determinant of genome stability and is central to the evolution of species and to the origins of human diseases. Here we review our current understanding of replication fidelity, with emphasis on structural and biochemical studies of DNA polymerases that provide new insights into the importance of hydrogen bonding, base pair geometry, and substrate-induced conformational changes to fidelity. These studies also reveal polymerase interactions with the DNA minor groove at and upstream of the active site that influence nucleotide selectivity, the efficiency of exonucleolytic proofreading, and the rate of forming errors via strand misalignments. We highlight common features that are relevant to the fidelity of any DNA synthesis reaction, and consider why fidelity varies depending on the enzymes, the error, and the local sequence environment.

Requirements for the dGTP-dependent repeat addition processivity of recombinant Tetrahymena telomerase

Telomerase is a reverse transcriptase responsible for adding simple sequence repeats to chromosome 3'-ends. The template for telomeric repeat synthesis is carried within the RNA component of the telomerase ribonucleoprotein complex. Telomerases can copy their internal templates with repeat addition processivity, reusing the same template multiple times in the extension of a single primer. For some telomerases, optimal repeat addition processivity requires high micromolar dGTP concentrations, a much higher dGTP concentration than required for processive nucleotide addition within a repeat. We have investigated the requirements for dGTP-dependent repeat addition processivity using recombinant Tetrahymena telomerase. By altering the template sequence, we show that repeat addition processivity retains the same dGTP-dependence even if dGTP is not the first nucleotide incorporated in the second repeat. Furthermore, no dNTP other than dGTP can stimulate repeat addition processivity, even if it is the first nucleotide incorporated in the second repeat. Using structural variants of dGTP, we demonstrate that the stimulation of repeat addition processivity is specific for dGTP base and sugar constituents but requires only a single phosphate group. However, all nucleotides that stimulate repeat addition processivity also inhibit or compete with dGTP incorporation into product DNA. By assaying telomerase complexes reconstituted with a variety of altered templates, we find that repeat addition processivity has an unanticipated template or product sequence specificity. Finally, we show that a novel, nascent product DNA binding site establishes dGTP-dependent repeat addition processivity.

Substitution of Asp114 or Arg116 in the fingers domain of moloney murine leukemia virus reverse transcriptase affects interactions with the template-primer resulting in decreased processivity

Reverse transcriptase, an essential retroviral DNA polymerase, replicates the single-stranded RNA genome of the retrovirus, producing a double-stranded DNA copy, which is subsequently integrated into the host's genome. Substitution of Ala for either Asp114 or Arg116, two highly conserved residues in the fingers domain of Moloney murine leukemia virus reverse transcriptase, results in enzymes (D114A or R116A) with significant defects in their abilities to processively synthesize DNA using RNA or DNA as a template. D114A and R116A enzymes also bind more weakly to template-primer in the presence of added deoxyribonucleotides, as seen by gel-shift analysis, but retain the ability to strand transfer and accumulate smaller RNase H cleavage products when compared to the wild-type enzyme. In addition, mutant proviruses, including D114A and R116A substitutions in Moloney murine leukemia virus reverse transcriptase, are not viable despite the presence of processed reverse transcriptase in the viral particles. A potential mechanistic role in processive synthesis for D114 and R116 is discussed in the context of our results, related studies on HIV-1 reverse transcriptase, and previous structural studies.

Fidelity and processivity of DNA synthesis by DNA polymerase kappa, the product of the human DINB1 gene

Mammalian DNA polymerase kappa (pol kappa), a member of the UmuC/DinB nucleotidyl transferase superfamily, has been implicated in spontaneous mutagenesis. Here we show that human pol kappa copies undamaged DNA with average single-base substitution and deletion error rates of 7 x 10(-3) and 2 x 10(-3), respectively. These error rates are high when compared to those of most other DNA polymerases. pol kappa also has unusual error specificity, producing a high proportion of T.CMP mispairs and deleting and adding non-reiterated nucleotides at extraordinary rates. Unlike other members of the UmuC/DinB family, pol kappa can processively synthesize chains of 25 or more nucleotides. This moderate processivity may reflect a contribution of C-terminal residues, which include two zinc clusters. The very low fidelity and moderate processivity of pol kappa is novel in comparison to any previously studied DNA polymerase, and is consistent with a role in spontaneous mutagenesis.

Synthetically modified DNAs as substrates for polymerases

DNA polymerase enzymes process their natural substrates with very high specificity. Yet recent experiments have shown that these enzymes can also process DNA in which the backbone or bases are modified to a surprising degree. Such experiments have important implications in understanding the mechanisms of DNA replication, and suggest important biotechnological uses as well.

Accomodation of S-cis-tamoxifen-N(2)-guanine adduct within a bent and widened DNA minor groove

The non-steroidal anti-estrogen tamoxifen [TAM] has been in clinical use over the last two decades as a potent adjunct chemotherapeutic agent for treatment of breast cancer. It has also been given prophylactically to women with a strong family history of breast cancer. However, tamoxifen treatment has also been associated with increased endometrial cancer, possibly resulting from the reaction of metabolically activated tamoxifen derivatives with cellular DNA. Such DNA adducts can be mutagenic and the activities of isomeric adducts may be conformation-dependent. We therefore investigated the high resolution NMR solution conformation of one covalent adduct (cis-isomer, S-epimer of [TAM]G) formed from the reaction of tamoxifen [TAM] to N(2)-of guanine in the d(C-[TAM]G-C).d(G-C-G) sequence context at the 11-mer oligonucleotide duplex level. Our NMR results establish that the S-cis [TAM]G lesion is accomodated within a widened minor groove without disruption of the Watson-Crick [TAM]G. C and flanking Watson-Crick G.C base-pairs. The helix axis of the bound DNA oligomer is bent by about 30 degrees and is directed away from the minor groove adduct site. The presence of such a bulky [TAM]G adduct with components of the TAM residue on both the 5'- and the 3'-side of the modified base could compromise the fidelity of the minor groove polymerase scanning machinery.

Minor groove interactions at the DNA polymerase beta active site modulate single-base deletion error rates

The structures of open and closed conformations of DNA polymerase beta (pol beta) suggests that the rate of single-nucleotide deletions during synthesis may be modulated by interactions in the DNA minor groove that align the templating base with the incoming dNTP. To test this hypothesis, we measured the single-base deletion error rates of wild-type pol beta and lysine and alanine mutants of Arg(283), whose side chain interacts with the minor groove edge of the templating nucleotide at the active site. The error rates of both mutant enzymes are increased >100-fold relative to wild-type pol beta. Template engineering experiments performed to distinguish among three possible models for deletion formation suggest that most deletions in repetitive sequences by pol beta initiate by strand slippage. However, pol beta also generates deletions by a different mechanism that is strongly enhanced by the substitutions at Arg(283). Analysis of error specificity suggests that this mechanism involves nucleotide misinsertion followed by primer relocation, creating a misaligned intermediate. The structure of pol beta bound to non-gapped DNA also indicates that the templating nucleotide and its downstream neighbor are out of register in the open conformation and this could facilitate misalignment (dNTP or primer terminus) with the next template base.

The J-helix of Escherichia coli DNA polymerase I (Klenow fragment) regulates polymerase and 3'- 5'-exonuclease functions

To assess the functional importance of the J-helix region of Escherichia coli DNA polymerase I, we performed site-directed mutagenesis of the following five residues: Asn-675, Gln-677, Asn-678, Ile-679, and Pro-680. Of these, the Q677A mutant is polymerase-defective with no change in its exonuclease activity. In contrast, the N678A mutant has unchanged polymerase activity but shows increased mismatch-directed exonuclease activity. Interestingly, mutation of Pro-680 has a Q677A-like effect on polymerase activity and an N678A-like effect on the exonuclease activity. Mutation of Pro-680 to Gly or Gln results in a 10-30-fold reduction in k(cat) on homo- and heteropolymeric template-primers, with no significant change in relative DNA binding affinity or K(m)((dNTP)). The mutants P680G and P680Q also showed a nearly complete loss in the processive mode of DNA synthesis. Since the side chain of proline is generally non-reactive, mutation of Pro-680 may be expected to alter the physical form of the J-helix itself. The biochemical properties of P680G/P680Q together with the structural observation that J-helix assumes helical or coiled secondary structure in the polymerase or exonuclease mode-bound DNA complexes suggest that the structural alteration in the J-helix region may be responsible for the controlled shuttling of DNA between the polymerase and the exonuclease sites.

Ciliate telomerase biochemistry

Telomerase is a cellular reverse transcriptase specialized for use of a template carried within the RNA component of the enzyme ribonucleoprotein complex. Substrates for telomerase are single-stranded oligonucleotides in vitro and chromosome ends in vivo. In vitro, a bound substrate is extended by an initial round of DNA synthesis on the internal RNA template and in some cases by multiple rounds of template copying before product dissociation. In vivo, de novo synthesis of one strand of a telomeric repeat sequence by telomerase balances the sequence loss resulting from incomplete replication of linear chromosome ends by RNA primer-requiring DNA polymerases. Telomerase biochemistry has been studied extensively by using partially purified cell extracts. Telomerase components are being identified and beginning to be produced in recombinant form. This review focuses on the enzyme mechanism of telomerases from ciliate species, thus far the most intensively studied systems.

Protein-nucleic acid interactions and DNA conformation in a complex of human immunodeficiency virus type 1 reverse transcriptase with a double-stranded DNA template-primer

The conformation of the DNA and the interactions of the nucleic acid with the protein in a complex of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) and 19-mer/18-mer double-stranded DNA template-primer (dsDNA) are described. The structure of this HIV-1 RT complex with dsDNA serves as a useful paradigm for studying aspects of nucleotide polymerases such as catalysis, fidelity, drug inhibition, and drug resistance. The bound dsDNA has a bend of approximately 41 degrees at the junction of an A-form region (first five base pairs near the polymerase active site) and a B-form region (the last nine base pairs toward the RNase H active site). The 41 degrees bend occurs smoothly over the four base pairs between the A-form portion and the B-form portion in the vicinity of helices alpha H and alpha I of the p66 thumb subdomain. The interactions between the dsDNA and protein primarily involve the sugar-phosphate backbone of the nucleic acid and structural elements of the palm, thumb, and RNase H of p66, and are not sequence specific. Amino acid residues from the polymerase active site region, including amino acid residues of the conserved Tyr-Met-Asp-Asp (YMDD) motif and the "primer grip," interact with 3'-terminal nucleotides of the primer strand and are involved in positioning the primer terminal nucleotide and its 3'-OH group at the polymerase active site. Amino acid residues of the "template grip" have close contacts with the template strand and aid in positioning the template strand near the polymerase active site. Helix alpha H of the p66 thumb is partly inserted into the minor groove of the dsDNA and helix alpha I is directly adjacent to the backbone of the template strand. Amino acid residues of beta 1', alpha A', alpha B', and the loop containing His539 of the RNase H domain interact with the primer strand of the dsDNA.

Interference footprinting analysis of telomerase elongation complexes

Telomerase is a reverse transcriptase that adds single-stranded telomeric repeats to the ends of linear eukaryotic chromosomes. It consists of an RNA molecule including a template sequence, a protein subunit containing reverse transcriptase motifs, and auxiliary proteins. We have carried out an interference footprinting analysis of the Tetrahymena telomerase elongation complexes. In this study, single-stranded oligonucleotide primers containing telomeric sequences were modified with base-specific chemical reagents and extended with the telomerase by a single (32)P-labeled dGMP or dTMP. Base modifications that interfered with the primer extension reactions were mapped by footprinting. Major functional interactions were detected between the telomerase and the six or seven 3'-terminal residues of the primers. These interactions occurred not only with the RNA template region, but also with another region in the enzyme ribonucleoprotein complex designated the telomerase DNA interacting surface (TDIS). This was indicated by footprints generated with dimethyl sulfate (that did not affect Watson-Crick hydrogen bonding) and by footprinting assays performed with mutant primers. In primers aligned at a distance of 2 nucleotides along the RNA template region, the footprints of the six or seven 3'-terminal residues were shifted by 2 nucleotides. This shift indicated that during the elongation reaction, TDIS moved in concert with the 3' ends of the primers relative to the template region. Weak interactions occurred between the telomerase and residues located upstream of the seventh nucleotide. These interactions were stronger in primers that were impaired in the ability to align with the template.

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.

Trapping of a catalytic HIV reverse transcriptase*template:primer complex through a disulfide bond

BACKGROUND

HIV-1 reverse transcriptase (RT) is a major target for the treatment of acquired immunodeficiency syndrome (AIDS). Resistance mutations in RT compromise treatment, however. Efforts to understand the enzymatic mechanism of RT and the basis for mutational resistance to anti-RT drugs have been hampered by the failure to crystallize a catalytically informative RT-substrate complex.

RESULTS

We present here experiments that allow us to understand the reason for the failure to crystallize such a complex. Based on this understanding, we have devised a new approach for using a combinatorial disulfide cross-linking strategy to trap a catalytic RT*template:primer*dNTP ternary complex, thereby enabling the growth of co-crystals suitable for high-resolution structural analysis. The crystals contain a fully assembled active site poised for catalysis. The cross-link itself appears to be conformationally mobile, and the surrounding region is undistorted, suggesting that the cross-link is a structurally passive device that merely acts to prevent dissociation of the catalytic complex.

CONCLUSIONS

The new strategy discussed here has resulted in the crystallization and structure determination of a catalytically relevant RT*template:primer*dNTP complex. The structure has allowed us to analyze possible causes of drug resistance at the molecular level. This information will assist efforts to develop new classes of nucleoside analog inhibitors, which might help circumvent current resistance profiles. The covalent trapping strategy described here may be useful with other protein-DNA complexes that have been refractory to structural analysis.

An A-type double helix of DNA having B-type puckering of the deoxyribose rings

DNA usually adopts structure B in aqueous solution, while structure A is preferred in mixtures of trifluoroethanol (TFE) with water. However, the octamer d(CCCCGGGG) and other d(C(n)G(n)) fragments of DNA provide CD spectra that suggest that the base-pairs are stacked in an A-like fashion even in aqueous solution. Yet, d(CCCCGGGG) undergoes a cooperative TFE-induced transition into structure A, indicating that an important part of the aqueous duplex retains structure B. NMR spectroscopy shows that puckering of the deoxyribose rings is of the B-type. Hence, combination of the information provided by CD spectroscopy and NMR spectroscopy suggests an unprecedented double helix of DNA in which A-like base stacking is combined with B-type puckering of the deoxyribose rings. In order to determine whether this combination is possible, we used molecular dynamics to simulate the duplex of d(CCCCGGGG). Remarkably, the simulations, completely unrestrained by the experimental data, provided a very stable double helix of DNA, exhibiting just the intermediate B/A features described above. The double helix contained well-stacked guanine bases but almost unstacked cytosine bases. This generated a hole in the double helix center, which is a property characteristic for A-DNA, but absent from B-DNA. The minor groove was narrow at the double helix ends but wide at the central CG step where the Watson-Crick base-pairs were buckled in opposite directions. The base-pairs stacked tightly at the ends but stacking was loose in the duplex center. The present double helix, in which A-like base stacking is combined with B-type sugar puckering, is relevant to replication and transcription because both of these phenomena involve a local B-to-A transition.

Crystal structures of an N-terminal fragment from Moloney murine leukemia virus reverse transcriptase complexed with nucleic acid: functional implications for template-primer binding to the fingers domain

Reverse transcriptase (RT) serves as the replicative polymerase for retroviruses by using RNA and DNA-directed DNA polymerase activities coupled with a ribonuclease H activity to synthesize a double-stranded DNA copy of the single-stranded RNA genome. In an effort to obtain detailed structural information about nucleic acid interactions with reverse transcriptase, we have determined crystal structures at 2.3 A resolution of an N-terminal fragment from Moloney murine leukemia virus reverse transcriptase complexed to blunt-ended DNA in three distinct lattices. This fragment includes the fingers and palm domains from Moloney murine leukemia virus reverse transcriptase. We have also determined the crystal structure at 3.0 A resolution of the fragment complexed to DNA with a single-stranded template overhang resembling a template-primer substrate. Protein-DNA interactions, which are nearly identical in each of the three lattices, involve four conserved residues in the fingers domain, Asp114, Arg116, Asn119 and Gly191. DNA atoms involved in the interactions include the 3'-OH group from the primer strand and minor groove base atoms and sugar atoms from the n-2 and n-3 positions of the template strand, where n is the template base that would pair with an incoming nucleotide. The single-stranded template overhang adopts two different conformations in the asymmetric unit interacting with residues in the beta4-beta5 loop (beta3-beta4 in HIV-1 RT). Our fragment-DNA complexes are distinct from previously reported complexes of DNA bound to HIV-1 RT but related in the types of interactions formed between protein and DNA. In addition, the DNA in all of these complexes is bound in the same cleft of the enzyme. Through site-directed mutagenesis, we have substituted residues that are involved in binding DNA in our crystal structures and have characterized the resulting enzymes. We now propose that nucleic acid binding to the fingers domain may play a role in translocation of nucleic acid during processive DNA synthesis and suggest that our complex may represent an intermediate in this process.

Varied Molecular Interactions at the Active Sites of Several DNA Polymerases: Nonpolar Nucleoside Isosteres as Probes

We describe a survey of protein-DNA interactions with seven different DNA polymerases and reverse transcriptases, carried out with nonpolar nucleoside isosteres F (a thymidine analog) and Z and Q (deoxyadenosine analogues). Previous results have shown that Z and F can be efficiently replicated opposite each other by the exonuclease-free Klenow fragment of DNA polymerase I from Escherichia coli (KF(-)), although both of them lack Watson-Crick H-bonding ability. We find that exonuclease-inactive T7 DNA polymerase (T7(-)), Thermus aquaticus DNA polymerase (Taq), and HIV-reverse transcriptase (HIV-RT) synthesize the nonnatural base pairs A-F, F-A, F-Z, and Z-F with high efficiency, similarly to KF(-). Steady-state kinetics were also measured for T7(-) and the efficiency of insertion is very similar to that of KF(-); interestingly, the replication selectivity with this pair is higher for T7(-) than KF(-), possibly due to a tighter active site. A second group comprised of calf thymus DNA polymerase α (Pol α) and avian myeloblastosis virus reverse transcriptase (AMV-RT) was able to replicate the A-F and F-A base pairs to some extent but not the F-Z and the Z-F base pairs. Most of the insertion was recovered when Z was replaced by the nucleoside Q (9-methyl-1-H-imidazo[(4,5)-b]pyridine), which is analogous to Z but possesses a minor groove acceptor nitrogen. This strongly supports the existence of an energetically important hydrogen-bonded interaction between the polymerase and the minor groove at the incipient base pair for these enzymes. A third group, formed by human DNA polymerase β (Pol β) and Moloney murine leukemia virus reverse transcriptase (MMLV-RT), failed to replicate the F-Z and Z-F base pairs. No insertion recovery was observed when Z was replaced by Q, possibly indicating that hydrogen bonds are needed at both the template and the triphosphate sites. The results point out the importance of DNA minor groove interactions at the incipient base pair for the activity of some polymerases, and demonstrate the variation in these interactions from enzyme to enzyme.

Varied Molecular Interactions at the Active Sites of Several DNA Polymerases: Nonpolar Nucleoside Isosteres as Probes

We describe a survey of protein-DNA interactions with seven different DNA polymerases and reverse transcriptases, carried out with nonpolar nucleoside isosteres F (a thymidine analog) and Z and Q (deoxyadenosine analogues). Previous results have shown that Z and F can be efficiently replicated opposite each other by the exonuclease-free Klenow fragment of DNA polymerase I from Escherichia coli (KF(-)), although both of them lack Watson-Crick H-bonding ability. We find that exonuclease-inactive T7 DNA polymerase (T7(-)), Thermus aquaticus DNA polymerase (Taq), and HIV-reverse transcriptase (HIV-RT) synthesize the nonnatural base pairs A-F, F-A, F-Z, and Z-F with high efficiency, similarly to KF(-). Steady-state kinetics were also measured for T7(-) and the efficiency of insertion is very similar to that of KF(-); interestingly, the replication selectivity with this pair is higher for T7(-) than KF(-), possibly due to a tighter active site. A second group comprised of calf thymus DNA polymerase α (Pol α) and avian myeloblastosis virus reverse transcriptase (AMV-RT) was able to replicate the A-F and F-A base pairs to some extent but not the F-Z and the Z-F base pairs. Most of the insertion was recovered when Z was replaced by the nucleoside Q (9-methyl-1-H-imidazo[(4,5)-b]pyridine), which is analogous to Z but possesses a minor groove acceptor nitrogen. This strongly supports the existence of an energetically important hydrogen-bonded interaction between the polymerase and the minor groove at the incipient base pair for these enzymes. A third group, formed by human DNA polymerase β (Pol β) and Moloney murine leukemia virus reverse transcriptase (MMLV-RT), failed to replicate the F-Z and Z-F base pairs. No insertion recovery was observed when Z was replaced by Q, possibly indicating that hydrogen bonds are needed at both the template and the triphosphate sites. The results point out the importance of DNA minor groove interactions at the incipient base pair for the activity of some polymerases, and demonstrate the variation in these interactions from enzyme to enzyme.

Uniquely altered DNA replication fidelity conferred by an amino acid change in the nucleotide binding pocket of human immunodeficiency virus type 1 reverse transcriptase

Arginine 72 in human immunodeficiency virus type 1 reverse transcriptase (RT), a highly conserved residue among retroviral polymerases and telomerases, forms part of the binding pocket for the nascent base pair. We show here that replacement of Arg(72) by alanine strongly alters fidelity in a highly unusual manner. R72A reverse transcriptase is a frameshift and base substitution antimutator polymerase whose increased fidelity results both from increased nucleotide selectivity and from a decreased ability to extend mismatched primer termini. Thus, Arg(72)-substrate interactions in wild-type human immunodeficiency virus type 1 RT can stabilize incorrect nucleotides allowing misinsertion and promoting extension of mismatched and perhaps misaligned template-primers. In contrast to the higher fidelity at most sites, R72A RT is highly error-prone for misincorporations opposite template T in the sequence context: 5'-CTGG. Surprisingly, this results mostly from a 1200-fold increase in the apparent K(m) for correct dAMP incorporation. Thus, Arg(72) interactions with substrate are critical for the stability of the correct T.dAMP base pair when the 5'-CTGG sequence is present in the binding pocket for the nascent base pair. Collectively, the data show that a mutant polymerase may yield higher than normal average replication fidelity, yet paradoxically place specific sequences at very high risk of mutation.

DNA structure and polymerase fidelity

The accuracy of DNA replication results from both the intrinsic DNA polymerase fidelity and the DNA sequence. Although the recent structural studies on polymerases have brought new insights on polymerase fidelity, the role of DNA sequence and structure is less well understood. Here, the analysis of the crystal structures of hotspots for polymerase slippage including (CA)n and (A)n tracts in different intermolecular contexts reveals that, in the B-form, these sequences share common structural alterations which may explain the high rate of replication errors. In particular, a two-faced "Janus-like" structure with shifted base-pairs in the major groove but an apparent normal geometry in the minor groove constitutes a molecular decoy specifically suitable to mislead the polymerases. A model of the rat polymerase beta bound to this structure suggests that an altered conformation of the nascent template-primer duplex can interfere with correct nucleotide incorporation by affecting the geometry of the active site and breaking the rules of base-pairing, while at the same time escaping enzymatic mechanisms of error discrimination which scan for the correct geometry of the minor groove.In contrast, by showing that the A-form greatly attenuates the sequence-dependent structural alterations in hotspots, this study suggests that the A-conformation of the nascent template-primer duplex at the vicinity of the polymerase active site will contribute to fidelity. The A-form may play the role of a structural buffer which preserves the correct geometry of the active site for all sequences. The detailed comparison of the conformation of the nascent template-primer duplex in the available crystal structures of DNA polymerase-DNA complexes shows that polymerase beta, the least accurate enzyme, is unique in binding to a B-DNA duplex even close to its active site. This model leads to several predictions which are discussed in the light of published experimental data.

The base substitution fidelity of HIV-1 reverse transcriptase on DNA and RNA templates probed with 8-oxo-deoxyguanosine triphosphate

We have used 8-O-dGTP, a mutagenic nucleotide generated by oxidative metabolism, to probe the misincorporation potential of HIV-1 reverse transcriptase (RT) during DNA synthesis templated by the same nucleotide sequence as either RNA or DNA. With either template, 8-O-dGMP was misincorporated opposite template A, yielding characteristic A-->C transversions. The error rate with DNA was similar to that with RNA, suggesting that base misincorporation by the RT during first-strand and second-strand replication may contribute equally to the HIV-1 base substitution mutation rate. The rate of 8-O-dGMP misincorporation differed by more than 10-fold among the 20 adenines in the M13mp2 template where A-->C transversions can be detected. The transversion distribution was similar with the two templates, indicating that the effects of flanking nucleotides on misincorporation rates were similar. This is consistent with structural and biochemical data suggesting that HIV-1 RT binds RNA x DNA and DNA x DNA template-primers in the same orientation. The similarities in error rates and distribution further indicate that, despite differences in the structures of free RNA x DNA and DNA x DNA duplexes (e.g., minor groove dimensions), the polymerase active site that assembles upon substrate binding establishes a similar degree of nucleotide selectivity with both types of template-primers. Comparison of the RT error distribution to that observed with two Pol I family DNA polymerases and a Pol alpha family polymerase revealed common hot and cold spots for misincorporation. This suggests that the local nucleotide sequence influences the nucleotide selectivity of four polymerases in a similar manner, despite their differences in structure, biochemical properties, and functions.

Decreased processivity of human immunodeficiency virus type 1 reverse transcriptase (RT) containing didanosine-selected mutation Leu74Val: a comparative analysis of RT variants Leu74Val and lamivudine-selected Met184Val

We previously showed that a didanosine-selected mutation in pNL4-3 background conferred a replication disadvantage on human immunodeficiency virus type 1, resulting in a loss of replication fitness. This work has been extended by showing that a recombinant virus with the HXBc2 backbone and reverse transcriptase (RT) fragments from pNL4-3 containing the Leu74Val mutation produce decreasing amounts of p24 antigen over a 3-week period. The HXBc2 recombinant containing the wild-type RT from pNL4-3 replicated efficiently. When the virion-associated RT containing the Leu74Val mutation was used in an RT processivity assay with homopolymer RNA template-primer, poly(A), and oligo(dT), the RT with altered Leu74Val mutation was less processive, generating fewer cDNA products in comparison to wild-type pNL4-3 RT. The replication kinetics and RT processivity of the mutant with the Leu74Val mutation were compared to those of a lamivudine-selected mutant Met184Val. In replication kinetics assays, mutant Leu74Val replicated slower than the mutant Met184Val. In a processivity assay, the mutant RTs from both viruses show comparable decreases in processivity. These observations provide biochemical evidence of decreased processivity to support the decrease in replication fitness observed with the Leu74Val or Met184Val mutations.

Base substitution specificity of DNA polymerase beta depends on interactions in the DNA minor groove

To examine the hypothesis that interactions between a DNA polymerase and the DNA minor groove are critical for accurate DNA synthesis, we studied the fidelity of DNA polymerase beta mutants at residue Arg(283), where arginine, which interacts with the minor groove at the active site, is replaced by alanine or lysine. Alanine substitution, removing minor groove interactions, strongly reduces polymerase selectivity for all single-base mispairs examined. In contrast, the lysine substitution, which retains significant interactions with the minor groove, has wild-type-like selectivity for T.dGMP and A.dGMP mispairs but reduced selectivity for T.dCMP and A.dCMP mispairs. Examination of DNA crystal structures of these four mispairs indicates that the two mispairs excluded by the lysine mutant have an atom (N2) in an unfavorable position in the minor groove, while the two mispairs permitted by the lysine mutant do not. These results suggest that unfavorable interactions between an active site amino acid side chain and mispair-specific atoms in the minor groove contribute to DNA polymerase specificity.

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.

Touching the heart of HIV-1 drug resistance: the fingers close down on the dNTP at the polymerase active site

Comparison of the recently solved structure of HIV-1 reverse transcriptase (RT)-DNA-dNTP ternary complex with the previously solved structure of RT-DNA binary complex suggests mechanisms by which the HIV-1 RT becomes resistant to nucleoside-analog inhibitors, drugs currently used in the treatment of AIDS.

An open and closed case for all polymerases

The recently determined structures of HIV-1 reverse transcriptase and Taq DNA polymerase in complex with DNA primer-template and an incoming nucleotide have shown that a large conformational change configures the polymerase active site for nucleotidyl transfer. The structure of reverse transcriptase in the catalytic complex will open the path to the rational design of novel nucleoside analog inhibitors of viral replication.

The fidelity of DNA polymerase beta during distributive and processive DNA synthesis

During base excision repair, DNA polymerase beta fills 1-6-nucleotide gaps processively, reflecting a contribution of both its 8- and 31-kDa domains to DNA binding. Here we report the fidelity of pol beta during synthesis to fill gaps of 1, 5, 6, or >300 nucleotides. Error rates during distributive synthesis by recombinant rat and human polymerase (pol) beta with a 390-base gap are similar to each other and to previous values with pol beta purified from tissues. The base substitution fidelity of human pol beta when processively filling a 5-nucleotide gap is similar to that with a 361-nucleotide gap, but "closely-spaced" substitutions are produced at a rate at least 60-fold higher than for distributive synthesis. Base substitution fidelity when filling a 1-nucleotide gap is higher than when filling a 5-nucleotide gap, suggesting a contribution of the 8-kDa domain to the dNTP binding pocket and/or a difference in base stacking or DNA structure imposed by pol beta. Nonetheless, 1-nucleotide gap filling is inaccurate, even generating complex substitution-addition errors. Finally, the single-base deletion error rate during processive synthesis to fill a 6-nucleotide gap is indistinguishable from that of distributive synthesis to fill a 390-nucleotide gap. Thus the mechanism of processivity by pol beta does not allow the enzyme to suppress template misalignments.

Side chains that influence fidelity at the polymerase active site of Escherichia coli DNA polymerase I (Klenow fragment)

To investigate the interactions that determine DNA polymerase accuracy, we have measured the fidelity of 26 mutants with amino acid substitutions in the polymerase domain of a 3'-5'-exonuclease-deficient Klenow fragment. Most of these mutant polymerases synthesized DNA with an apparent fidelity similar to that of the wild-type control, suggesting that fidelity at the polymerase active site depends on highly specific enzyme-substrate interactions and is not easily perturbed. In addition to the previously studied Y766A mutator, four novel base substitution mutators were identified; they are R668A, R682A, E710A, and N845A. Each of these five mutator alleles results from substitution of a highly conserved amino acid side chain located on the exposed surface of the polymerase cleft near the polymerase active site. Analysis of base substitution errors at four template positions indicated that each of the five mutator polymerases has its own characteristic error specificity, suggesting that the Arg-668, Arg-682, Glu-710, Tyr-766, and Asn-845 side chains may contribute to polymerase fidelity in a variety of different ways. We separated the contributions of the nucleotide insertion and mismatch extension steps by using a novel fidelity assay that scores base substitution errors during synthesis to fill a single nucleotide gap (and hence does not require mismatch extension) and by measuring the rates of polymerase-catalyzed mismatch extension reactions. The R682A, E710A, Y766A, and N845A mutations cause decreased fidelity at the nucleotide insertion step, whereas R668A results in lower fidelity in both nucleotide insertion and mismatch extension. Relative to wild type, several Klenow fragment mutants showed substantially more discrimination against extension of a T.G mismatch under the conditions of the fidelity assay, providing one explanation for the anti-mutator phenotypes of mutants such as R754A and Q849A.

Compression of the DNA minor groove is responsible for termination of DNA synthesis by HIV-1 reverse transcriptase

HIV-1 reverse transcriptase (RT) generally terminates plus strand DNA synthesis at the centre of the viral genome. The central termination sequence (CTS) contains two termination sites which are located at the 3' end of AnTm motifs. These motifs generate a global curvature of the DNA helix which correlates with termination of DNA synthesis. Here, we have characterized HIV-1 RT termination sites on different DNA sequences. Again, they are located at the 3' end of A-tracts. Using hydroxyl radicals as a probe of the width of the DNA helix, we have shown that RT termination sites are always located a few base-pairs downstream of a compressed minor groove. Mutations which relieve these compressions also abolish the termination events. The replacement of the adenine tracts by 2,6-diaminopurine tracts has a similar effect. Moreover, no termination site is observed on DNA sequences containing phased GC-tracts which curve the DNA helix but compress the major groove. The compression of the DNA minor groove and not necessarily the curved trajectory of the DNA is, therefore, responsible for termination of DNA synthesis at the CTS by HIV-1 RT. This conclusion is consistent with interpretation of other biochemical data on the processivity of HIV-1 RT, based on the structure of a DNA-enzyme complex.

Structure and functional implications of the polymerase active site region in a complex of HIV-1 RT with a double-stranded DNA template-primer and an antibody Fab fragment at 2.8 A resolution

The structure of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) complexed with a 19-mer/18-mer double-stranded DNA template-primer (dsDNA) and the Fab fragment of monoclonal antibody 28 (Fab28) has been refined at 2.8 A resolution. The structures of the polymerase active site and neighboring regions are described in detail and a number of novel insights into mechanisms of polymerase catalysis and drug inhibition are presented. The three catalytically essential amino acid residues (Asp110, Asp185, and Asp186) are located close to the 3' terminus of the primer strand. Observation of a hydrogen bond between the 3'-OH of the primer terminus and the side-chain of Asp185 suggests that the carboxylate of Asp185 could act as a general base in initiating the nucleophilic attack during polymerization. Nearly all of the close protein-DNA interactions involve atoms of the sugar-phosphate backbone of the nucleic acid. However, the phenoxyl side-chain of Tyr183, which is part of the conserved YMDD motif, has hydrogen-bonding interactions with nucleotide bases of the second duplex base-pair and is predicted to have at least one hydrogen bond with all Watson-Crick base-pairs at this position. Comparison of the structure of the active site region in the HIV-1 RT/dsDNA complex with all other HIV-1 RT structures suggests that template-primer binding is accompanied by significant conformational changes of the YMDD motif that may be relevant for mechanisms of both polymerization and inhibition by non-nucleoside inhibitors. Interactions of the "primer grip" (the beta12-beta13 hairpin) with the 3' terminus of the primer strand primarily involve the main-chain atoms of Met230 and Gly231 and the primer terminal phosphate. Alternative positions of the primer grip observed in different HIV-1 RT structures may be related to conformational changes that normally occur during DNA polymerization and translocation. In the vicinity of the polymerase active site, there are a number of aromatic residues that are involved in energetically favorable pi-pi interactions and may be involved in the transitions between different stages of the catalytic process. The protein structural elements primarily responsible for precise positioning of the template-primer (including the primer grip, template grip, and helices alphaH and alphaI of the p66 thumb) can be thought of functioning as a "translocation track" that guides the relative movement of nucleic acid and protein during polymerization.

Structure of a covalently trapped catalytic complex of HIV-1 reverse transcriptase: implications for drug resistance

A combinatorial disulfide cross-linking strategy was used to prepare a stalled complex of human immunodeficiency virus-type 1 (HIV-1) reverse transcriptase with a DNA template:primer and a deoxynucleoside triphosphate (dNTP), and the crystal structure of the complex was determined at a resolution of 3.2 angstroms. The presence of a dideoxynucleotide at the 3'-primer terminus allows capture of a state in which the substrates are poised for attack on the dNTP. Conformational changes that accompany formation of the catalytic complex produce distinct clusters of the residues that are altered in viruses resistant to nucleoside analog drugs. The positioning of these residues in the neighborhood of the dNTP helps to resolve some long-standing puzzles about the molecular basis of resistance. The resistance mutations are likely to influence binding or reactivity of the inhibitors, relative to normal dNTPs, and the clustering of the mutations correlates with the chemical structure of the drug.

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.

Contacts between reverse transcriptase and the primer strand govern the transition from initiation to elongation of HIV-1 reverse transcription

HIV-1 reverse transcriptase (RT) utilizes RNA oligomers to prime DNA synthesis. The initiation of reverse transcription requires specific interactions between HIV-1 RNA, primer tRNA3Lys, and RT. We have previously shown that extension of an oligodeoxyribonucleotide, a situation that mimicks elongation, is unspecific and differs from initiation by the polymerization rate and dissociation rate of RT from the primer-template complex. Here, we used replication intermediates to analyze the transition from the initiation to the elongation phases. We found that the 2'-hydroxyl group at the 3' end of tRNA had limited effects on the polymerization and dissociation rate constants. Instead, the polymerization rate increased 3400-fold between addition of the sixth and seventh nucleotide to tRNA3Lys. The same increase in the polymerization rate was observed when an oligoribonucleotide, but not an oligodeoxyribonucleotide, was used as a primer. In parallel, the dissociation rate of RT from the primer-template complex decreased 30-fold between addition of the 17th and 19th nucleotide to tRNA3Lys. The polymerization and dissociation rates are most likely governed by interactions of the primer strand with helix alphaH in the p66 thumb subdomain and the RNase H domain of RT, respectively.