Getting a grip: polymerases and their substrate complexes

Pre-steady state kinetic analysis of HIV-1 reverse transcriptase for non-canonical ribonucleoside triphosphate incorporation and DNA synthesis from ribonucleoside-containing DNA template

Non-dividing macrophages maintain extremely low cellular deoxyribonucleotide triphosphate (dNTP) levels, but high ribonucleotide triphosphate (rNTP) concentrations. The disparate nucleotide pools kinetically forces Human Immunodeficiency Virus 1 (HIV-1) reverse transcriptase (RT) to incorporate non-canonical rNTPs during reverse transcription. HIV-1 RT pauses near ribonucleoside monophosphates (rNMPs) embedded in the template DNA, which has previously been shown to enhance mismatch extension. Here, pre-steady state kinetic analysis shows rNTP binding affinity (Kd) of HIV-1 RT for non-canonical rNTPs was 1.4- to 43-fold lower, and the rNTP rate of incorporation (kpol) was 15- to 1551-fold slower than for dNTPs. This suggests that RT is more selective for incorporation of dNTPs rather than rNTPs. HIV-1 RT selectivity for dNTP versus rNTP is the lowest for ATP, implying that HIV-1 RT preferentially incorporates ATP when dATP concentration is limited. We observed that incorporation of a dNTP occurring one nucleotide before an embedded rNMP in the template had a 29-fold greater Kd and a 20-fold slower kpol as compared to the same template containing dNMP. This reduced the overall dNTP incorporation efficiency of HIV-1 RT by 581-fold. Finally, the RT mutant Y115F displayed lower discrimination against rNTPs due to its increase in binding affinity for non-canonical rNTPs. Overall, these kinetic results demonstrate that HIV-1 RT utilizes both substrate binding and a conformational change during: (1) enzymatic discrimination of non-canonical rNTPs from dNTPs and (2) during dNTP primer extension with DNA templates containing embedded rNMP.

An overview of Y-Family DNA polymerases and a case study of human DNA polymerase η

Y-Family DNA polymerases specialize in translesion synthesis, bypassing damaged bases that would otherwise block the normal progression of replication forks. Y-Family polymerases have unique structural features that allow them to bind damaged DNA and use a modified template base to direct nucleotide incorporation. Each Y-Family polymerase is unique and has different preferences for lesions to bypass and for dNTPs to incorporate. Y-Family polymerases are also characterized by a low catalytic efficiency, a low processivity, and a low fidelity on normal DNA. Recruitment of these specialized polymerases to replication forks is therefore regulated. The catalytic center of the Y-Family polymerases is highly conserved and homologous to that of high-fidelity and high-processivity DNA replicases. In this review, structural differences between Y-Family and A- and B-Family polymerases are compared and correlated with their functional differences. A time-resolved X-ray crystallographic study of the DNA synthesis reaction catalyzed by the Y-Family DNA polymerase human polymerase η revealed transient elements that led to the nucleotidyl-transfer reaction.

Role of the LEXE motif of protein-primed DNA polymerases in the interaction with the incoming nucleotide

The LEXE motif, conserved in eukaryotic type DNA polymerases, is placed close to the polymerization active site. Previous studies suggested that the second Glu was involved in binding a third noncatalytic ion in bacteriophage RB69 DNA polymerase. In the protein-primed DNA polymerase subgroup, the LEXE motif lacks the first Glu in most cases, but it has a conserved Phe/Trp and a Gly preceding that position. To ascertain the role of those residues, we have analyzed the behavior of mutants at the corresponding ϕ29 DNA polymerase residues Gly-481, Trp-483, Ala-484, and Glu-486. We show that mutations at Gly-481 and Trp-483 hamper insertion of the incoming dNTP in the presence of Mg(2+) ions, a reaction highly improved when Mn(2+) was used as metal activator. These results, together with previous crystallographic resolution of ϕ29 DNA polymerase ternary complex, allow us to infer that Gly-481 and Trp-483 could form a pocket that orients Val-250 to interact with the dNTP. Mutants at Glu-486 are also defective in polymerization and, as mutants at Gly-481 and Trp-483, in the pyrophosphorolytic activity with Mg(2+). Recovery of both reactions with Mn(2+) supports a role for Glu-486 in the interaction with the pyrophosphate moiety of the dNTP.

Aptamer-based therapeutics: new approaches to combat human viral diseases

Viruses replicate inside the cells of an organism and continuously evolve to contend with an ever-changing environment. Many life-threatening diseases, such as AIDS, SARS, hepatitis and some cancers, are caused by viruses. Because viruses have small genome sizes and high mutability, there is currently a lack of and an urgent need for effective treatment for many viral pathogens. One approach that has recently received much attention is aptamer-based therapeutics. Aptamer technology has high target specificity and versatility, i.e., any viral proteins could potentially be targeted. Consequently, new aptamer-based therapeutics have the potential to lead a revolution in the development of anti-infective drugs. Additionally, aptamers can potentially bind any targets and any pathogen that is theoretically amenable to rapid targeting, making aptamers invaluable tools for treating a wide range of diseases. This review will provide a broad, comprehensive overview of viral therapies that use aptamers. The aptamer selection process will be described, followed by an explanation of the potential for treating virus infection by aptamers. Recent progress and prospective use of aptamers against a large variety of human viruses, such as HIV-1, HCV, HBV, SCoV, Rabies virus, HPV, HSV and influenza virus, with particular focus on clinical development of aptamers will also be described. Finally, we will discuss the challenges of advancing antiviral aptamer therapeutics and prospects for future success.

Structural organization of viral RNA-dependent RNA polymerases

This review describes available data on the structure of viral RNA-dependent RNA polymerases (RdRP) obtained from X-ray analysis and discusses the functional significance of the structural elements of these enzymes. Because most of the studies done to date relate to RdRP structures of picorna-, flavi-, and caliciviruses, here we consider mostly the structures of RdRP of these groups of viruses, and also include information about polymerases of other virus families.

Structural changes in the hydrophobic hinge region adversely affect the activity and fidelity of the I260Q mutator DNA polymerase β

The I260Q variant of DNA polymerase β is an efficient mutator polymerase with fairly indiscriminate misincorporation activities opposite all template bases. Previous modeling studies have suggested that I260Q harbors structural variations in its hinge region. Here, we present the crystal structures of wild type and I260Q rat polymerase β in the presence and absence of substrates. Both the I260Q apoenzyme structure and the closed ternary complex with double-stranded DNA and ddTTP show ordered water molecules in the hydrophobic hinge near Gln260, whereas this is not the case in the wild type polymerase. Compared to wild type polymerase β ternary complexes, there are subtle movements around residues 260, 272, 295, and 296 in the mutant. The rearrangements in this region, coupled with side chain movements in the immediate neighborhood of the dNTP-binding pocket, namely, residues 258 and 272, provide an explanation for the altered activity and fidelity profiles observed in the I260Q mutator polymerase.

Genetic and biochemical diversity in the HCV NS5B RNA polymerase in the context of interferon α plus ribavirin therapy

The hepatitis C virus (HCV) RNA polymerase (RdRp) may be a target of the drug ribavirin, and it is an object of drug development. Independent isolates of any HCV subtype differ genetically by approximately 10%, but the effects of this variation on enzymatic activity and drug sensitivity are poorly understood. We proposed that nucleotide use profiles (G/U ratio) among subtype 1b RdRps may reflect their use of ribavirin. Here, we characterized how subtype 1b genetic variation affects RNA polymerase activity and evaluated the G/U ratio as a surrogate for ribavirin use during pegylated interferon α and ribavirin therapy. Genetic and biochemical variation in the RdRp was compared between responders who would be largely sensitive to ribavirin and relapsers who would be mostly resistant. There were no consistent genetic differences between responder and relapser RdRps. RNA polymerization, RNA binding and primer usage varied widely among the RdRps, but these parameters did not differ significantly between the response groups. The G/U ratio among a set of subtype 1a RdRps increased rather than decreased following failed therapy, as would be expected if it reflected ribavirin use. Finally, RdRp activity was significantly associated with ALT levels. These data indicate that (i) current genetic approaches cannot predict RNA polymerase behaviour, (ii) the G/U ratio is not a surrogate for ribavirin use, (iii) RdRp activity may contribute to liver disease by modulating viral mRNA and antigen levels, and (iv) drug candidates should be tested against multiple patient-derived enzymes to ensure widespread efficacy even within a viral subtype.

Evidence for similarity-assisted recombination and predicted stem-loop structure determinant in potato virus X RNA recombination

Virus RNA recombination, one of the main factors for genetic variability and evolution, is thought to be based on different mechanisms. Here, the recently described in vivo potato virus X (PVX) recombination assay [Draghici, H.-K. & Varrelmann, M. (2009). J Virol 83, 7761-7769] was applied to characterize structural parameters of recombination. The assay uses an Agrobacterium-mediated expression system incorporating a PVX green fluorescent protein (GFP)-labelled full-length clone. The clone contains a partial coat protein (CP) deletion that causes defectiveness in cell-to-cell movement, together with a functional CP+3' non-translated region (ntr) transcript, in Nicotiana benthamiana leaf tissue. The structural parameters assessed were the length of sequence overlap, the distance between mutations and the degree of sequence similarity. The effects on the observed frequency of reconstitution and the composition of the recombination products were characterized. Application of four different type X intact PVX CP genes with variable composition allowed the estimation of the junction sites of precise homologous recombination. Although one template switch would have been sufficient for functional reconstitution, between one and seven template switches were observed. Use of PVX-GFP mutants with CP deletions of variable length resulted in a linear decrease of the reconstitution frequency. The critical length observed for homologous recombination was 20-50 nt. Reduction of the reconstitution frequency was obtained when a phylogenetically distant PVX type Bi CP gene was used. Finally, the prediction of CP and 3'-ntr RNA secondary structure demonstrated that recombination-junction sites were located mainly in regions of stem-loop structures, allowing the recombination observed to be categorized as similarity-assisted.

phi29 DNA polymerase active site: role of residue Val250 as metal-dNTP complex ligand and in protein-primed initiation

DNA polymerases require two acidic residues to coordinate metal ions A and B at their polymerisation active site during catalysis of nucleotide incorporation. Crystallographic resolution of varphi29 DNA polymerase ternary complex showed that metal B coordination also depends on the carbonyl group of Val250 that belongs to the highly conserved Dx(2)SLYP motif of eukaryotic-type (family B) DNA polymerases. In addition, multiple sequence alignments have shown the specific conservation of this residue among the DNA polymerases that use a protein as primer. Thus, to ascertain its role in polymerisation, we have analysed the behaviour of single mutations introduced at the corresponding Val250 of varphi29 DNA polymerase. The differences in nucleotide binding affinity shown by mutants V250A and V250F with respect to the wild-type DNA polymerase agree to a role for Val250 as a metal B-dNTP complex ligand. In addition, mutant V250F was severely affected in varphi29 DNA replication because of a large reduction in the catalytic efficiency of the protein-primed reactions. In the light of the varphi29 DNA polymerase structures, a role for Val250 residue in the maintenance of the proper architecture of the enzyme to perform the protein-primed reactions is also proposed.

Evidence for action of ribavirin through the hepatitis C virus RNA polymerase

Hepatitis C virus (HCV) infections are treated with interferon alpha plus ribavirin, but it is unknown how ribavirin works against HCV. Ribavirin is a guanosine analogue that can be a substrate for the viral RNA polymerase. HCV is genetically variable, and this genetic variation could affect the polymerase's use of ribavirin triphosphate. Thirteen patients infected with HCV who failed interferon alpha monotherapy and were retreated with interferon alpha plus ribavirin were identified; seven were responders and six were nonresponders to combination therapy. The consensus sequences encoding the 13 polymerases plus seven sequences from treatment-naive controls were determined. The responder sequences were more genetically variable than the nonresponders and controls, the amino acid variations unique to responders had lower BLOSUM90 scores than variations in nonresponders and controls, and the amino acid variations correlated with response to therapy clustered around the RNA-binding channel of the polymerase. These data imply that that the responder enzymes were probably more functionally variable than the nonresponder enzymes. Enzymatic activity was measured for 10 recombinant polymerases; RNA synthesis activity varied by over sevenfold and polymerases from two of the responders used GTP much better than UTP, but technical limitations prevented direct measurement of ribavirin triphosphate use. Because response to combination therapy in these patients was primarily due to addition of ribavirin to the treatment regimen, these data imply that genetic variation in the polymerase may have affected the efficiency of ribavirin incorporation into the viral genome and hence may have modulated ribavirin's efficacy against HCV.

Bacterial RNase P: a new view of an ancient enzyme

Ribonuclease P (RNase P) is a ubiquitous endonuclease that catalyses the maturation of the 5' end of transfer RNA (tRNA). Although it carries out a biochemically simple reaction, RNase P is a complex ribonucleoprotein particle composed of a single large RNA and at least one protein component. In bacteria and some archaea, the RNA component of RNase P can catalyse tRNA maturation in vitro in the absence of proteins. The discovery of the catalytic activity of the bacterial RNase P RNA triggered numerous mechanistic and biochemical studies of the reactions catalysed by the RNA alone and by the holoenzyme and, in recent years, structures of individual components of the RNase P holoenzyme have been determined. The goal of the present review is to summarize what is known about the bacterial RNase P, and to bring together the recent structural results with extensive earlier biochemical and phylogenetic findings.

A mass spectrometry-based approach for identifying novel DNA polymerase substrates from a pool of dNTP analogues

There has been a long-standing interest in the discovery of unnatural nucleotides that can be incorporated into DNA by polymerases. However, it is difficult to predict which nucleotide analogs will prove to have biological relevance. Therefore, we have developed a new screening method to identify novel substrates for DNA polymerases. This technique uses the polymerase itself to select a dNTP from a pool of potential substrates via incorporation onto a short oligonucleotide. The unnatural nucleotide(s) is then identified by high-resolution mass spectrometry. By using a DNA polymerase as a selection tool, only the biologically relevant members of a small nucleotide library can be quickly determined. We have demonstrated that this method can be used to discover unnatural base pairs in DNA with a detection threshold of ≤10% incorporation.

Control of template positioning during de novo initiation of RNA synthesis by the bovine viral diarrhea virus NS5B polymerase

The RNA-dependent RNA polymerase of the hepatitis C virus and the bovine viral diarrhea virus(BVDV)is able to initiate RNA synthesis denovo in the absence of a primer. Previous crystallographic data have pointed to the existence of a GTP-specific binding site (G-site) that is located in the vicinity of the active site of the BVDV enzyme. Here we have studied the functional role of the G-site and present evidence to show that specific GTP binding affects the positioning of the template during de novo initiation. Following the formation of the first phosphodiester bond, the polymerase translocates relative to the newly synthesized dinucleotide, which brings the 5'-end of the primer into the G-site, releasing the previously bound GTP. At this stage, the 3'-end of the template can remain opposite to the 5'-end of the primer or be repositioned to its original location before RNA synthesis proceeds. We show that the template can freely move between the two locations, and both complexes can isomerize to equilibrium. These data suggest that the bound GTP can stabilize the interaction between the 3'-end of the template and the priming nucleotide, preventing the template to overshoot and extend beyond the active site during de novo initiation. The hepatitis C virus enzyme utilizes a dinucleotide primer exclusively from the blunt end; the existence of a functionally equivalent G-site is therefore uncertain. For the BVDV polymerase we showed that de novo initiation is severely compromised by the T320A mutant that likely affects hydrogen bonding between the G-site and the guanine base. Dinucleotide-primed reactions are not influenced by this mutation, which supports the notion that the G-site is located in close proximity but not at the active site of the enzyme.

A quantitative model of error accumulation during PCR amplification

The amplification of target DNA by the polymerase chain reaction (PCR) produces copies which may contain errors. Two sources of errors are associated with the PCR process: (1) editing errors that occur during DNA polymerase-catalyzed enzymatic copying and (2) errors due to DNA thermal damage. In this study a quantitative model of error frequencies is proposed and the role of reaction conditions is investigated. The errors which are ascribed to the polymerase depend on the efficiency of its editing function as well as the reaction conditions; specifically the temperature and the dNTP pool composition. Thermally induced errors stem mostly from three sources: A+G depurination, oxidative damage of guanine to 8-oxoG and cytosine deamination to uracil. The post-PCR modifications of sequences are primarily due to exposure of nucleic acids to elevated temperatures, especially if the DNA is in a single-stranded form. The proposed quantitative model predicts the accumulation of errors over the course of a PCR cycle. Thermal damage contributes significantly to the total errors; therefore consideration must be given to thermal management of the PCR process.

Nucleotide channel of RNA-dependent RNA polymerase used for intermolecular uridylylation of protein primer

Poliovirus VPg is a 22 amino acid residue peptide that serves as the protein primer for replication of the viral RNA genome. VPg is known to bind directly to the viral RNA-dependent RNA polymerase, 3D, for covalent uridylylation, yielding mono and di-uridylylated products, VPg-pU and VPg-pUpU, which are subsequently elongated. To model the docking of the VPg substrate to a putative VPg-binding site on the 3D polymerase molecule, we performed a variety of structure-based computations followed by experimental verification. First, potential VPg folded structures were identified, yielding a suite of predicted beta-hairpin structures. These putative VPg structures were then docked to the region of the polymerase implicated by genetic experiments to bind VPg, using grid-based and fragment-based methods. Residues in VPg predicted to affect binding were identified through molecular dynamics simulations, and their effects on the 3D-VPg interaction were tested computationally and biochemically. Experiments with mutant VPg and mutant polymerase molecules confirmed the predicted binding site for VPg on the back side of the polymerase molecule during the uridylylation reaction, opposite to that predicted to bind elongating RNA primers.

A macroscopic kinetic model for DNA polymerase elongation and high-fidelity nucleotide selection

The enzymatically catalyzed template-directed extension of ssDNA/primer complex is an important reaction of extraordinary complexity. The DNA polymerase does not merely facilitate the insertion of dNMP, but it also performs rapid screening of substrates to ensure a high degree of fidelity. Several kinetic studies have determined rate constants and equilibrium constants for the elementary steps that make up the overall pathway. The information is used to develop a macroscopic kinetic model, using an approach described by Ninio [Ninio J., 1987. Alternative to the steady-state method: derivation of reaction rates from first-passage times and pathway probabilities. Proc. Natl. Acad. Sci. U.S.A. 84, 663-667]. The principle idea of the Ninio approach is to track a single template/primer complex over time and to identify the expected behavior. The average time to insert a single nucleotide is a weighted sum of several terms, including the actual time to insert a nucleotide plus delays due to polymerase detachment from either the ternary (template-primer-polymerase) or quaternary (+nucleotide) complexes and time delays associated with the identification and ultimate rejection of an incorrect nucleotide from the binding site. The passage times of all events and their probability of occurrence are expressed in terms of the rate constants of the elementary steps of the reaction pathway. The model accounts for variations in the average insertion time with different nucleotides as well as the influence of G + C content of the sequence in the vicinity of the insertion site. Furthermore the model provides estimates of error frequencies. If nucleotide extension is recognized as a competition between successful insertions and time delaying events, it can be described as a binomial process with a probability distribution. The distribution gives the probability to extend a primer/template complex with a certain number of base pairs and in general it maps annealed complexes into extension products.

Inter- and intra-molecular distances determined by EPR spectroscopy and site-directed spin labeling reveal protein-protein and protein-oligonucleotide interaction

Recent developments including pulse and multi-frequency techniques make the combination of site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy an attractive approach for the study of protein-protein or protein-oligonucleotide interaction. Analysis of the spin label side chain mobility, its solvent accessibility, the polarity of the spin label micro-environment and distances between spin label side chains allow the modeling of protein domains or protein-protein interaction sites and their conformational changes with a spatial resolution at the level of the backbone fold. Structural changes can be detected with millisecond time resolution. Inter- and intra-molecular distances are accessible in the range from approximately 0.5 to 8 nm by the combination of continuous wave and pulse EPR methods. Recent applications include the study of transmembrane substrate transport, membrane channel gating, gene regulation and signal transfer.

The activity of selected RB69 DNA polymerase mutants can be restored by manganese ions: the existence of alternative metal ion ligands used during the polymerization cycle

Site specific mutants in the pol active center of RB69 DNA polymerase have been produced and studied using rapid chemical-quench techniques. Pre-steady-state kinetic analysis carried out with Mg(2+) and Mn(2+) has enabled us to divide the mutants into two groups. One group had greatly reduced k(pols) values in the presence of Mg(2+) but responded to Mn(2+) which restored the k(pol) values for the nucleotidyl transfer reaction to near wild-type levels. The other group of mutants also had lower k(pol) values, relative to that of the wild-type polymerase, but could not be rescued by Mn(2+). The behavior of these mutants was interpreted in terms of the crystal structures of the available RB69 pol complexes. Our results on the metal ion dependence of the D621A and E686A mutants, together with knowledge of the position of their side chains in two different RB69 pol conformations, suggest that these acidic residues serve as alternative ligands for the metal ions destined to occupy the A and B catalytic sites. We infer that this occurs prior to the conformational change that produces the ternary RB69 pol complex in which the A and B metal ions are ligated by D623 and D411 as the enzyme is poised for phosphoryl transfer.

Natural selection and the emergence of a mutation phenotype: an update of the evolutionary synthesis considering mechanisms that affect genome variation

Most descriptions of evolution assume that all mutations are completely random with respect to their potential effects on survival. However, much like other phenotypic variations that affect the survival of the descendants, intrinsic variations in the probability, type, and location of genetic change can feel the pressure of natural selection. From site-specific recombination to changes in polymerase fidelity and repair of DNA damage, an organism's gene products affect what genetic changes occur in its genome. Through the action of natural selection on these gene products, potentially favorable mutations can become more probable than random. With examples from variation in bacterial surface proteins to the vertebrate immune response, it is clear that a great deal of genetic change is better than "random" with respect to its potential effect on survival. Indeed, some potentially useful mutations are so probable that they can be viewed as being encoded implicitly in the genome. An updated evolutionary theory includes emergence, under selective pressure, of genomic information that affects the probability of different classes of mutation, with consequences for genome survival.

C-terminal hydrophobic interactions play a critical role in oligomeric assembly of the P22 tailspike trimer

The tailspike protein from the bacteriophage P22 is a well characterized model system for folding and assembly of multimeric proteins. Folding intermediates from both the in vivo and in vitro pathways have been identified, and both the initial folding steps and the protrimer-to-trimer transition have been well studied. In contrast, there has been little experimental evidence to describe the assembly of the protrimer. Previous results indicated that the C terminus plays a critical role in the overall stability of the P22 tailspike protein. Here, we present evidence that the C terminus is also the critical assembly point for trimer assembly. Three truncations of the full-length tailspike protein, TSPDeltaN, TSPDeltaC, and TSPDeltaNC, were generated and tested for their ability to form mixed trimer species. TSPDeltaN forms mixed trimers with full-length P22 tailspike, but TSPDeltaC and TSPDeltaNC are incapable of forming similar mixed trimer species. In addition, mutations in the hydrophobic core of the C terminus were unable to form trimer in vivo. Finally, the hydrophobic-binding dye ANS inhibits the formation of trimer by inhibiting progression through the folding pathway. Taken together, these results suggest that hydrophobic interactions between C-terminal regions of P22 tailspike monomers play a critical role in the assembly of the P22 tailspike trimer.

Function and assembly of the bacteriophage T4 DNA replication complex: interactions of the T4 polymerase with various model DNA constructs

Complexes formed between DNA polymerase and genomic DNA at the replication fork are key elements of the replication machinery. We used sedimentation velocity, fluorescence anisotropy, and surface plasmon resonance to measure the binding interactions between bacteriophage T4 DNA polymerase (gp43) and various model DNA constructs. These results provide quantitative insight into how this replication polymerase performs template-directed 5' --> 3' DNA synthesis and how this function is coordinated with the activities of the other proteins of the replication complex. We find that short (single- and double-stranded) DNA molecules bind a single gp43 polymerase in a nonspecific (overlap) binding mode with moderate affinity (Kd approximately 150 nm) and a binding site size of approximately 10 nucleotides for single-stranded DNA and approximately 13 bp for double-stranded DNA. In contrast, gp43 binds in a site-specific (nonoverlap) mode and significantly more tightly (Kd approximately 5 nm) to DNA constructs carrying a primer-template junction, with the polymerase covering approximately 5 nucleotides downstream and approximately 6-7 bp upstream of the 3'-primer terminus. The rate of this specific binding interaction is close to diffusion-controlled. The affinity of gp43 for the primer-template junction is modulated specifically by dNTP substrates, with the next "correct" dNTP strengthening the interaction and an incorrect dNTP weakening the observed binding. These results are discussed in terms of the individual steps of the polymerase-catalyzed single nucleotide addition cycle and the replication complex assembly process. We suggest that changes in the kinetics and thermodynamics of these steps by auxiliary replication proteins constitute a basic mechanism for protein coupling within the replication complex.

Isolation of Qbeta polymerase complexes containing mutant species of elongation factor Tu

The RNA genome of coliphage Qbeta is replicated by a complex of four proteins, one of them being the translation elongation factor Tu. The role of EF-Tu in this RNA polymerase complex is still unclear, but the obligate presence of translationally functional EF-Tu in the cell hampers the use of conventional mutational analysis. Therefore, we designed a system based on affinity chromatography and could separate two types of complexes by placing an affinity tag on mutated EF-Tu species. Thus, we were able to show a direct link between the vital tRNA binding property of EF-Tu and polymerase activity.

Interaction of DNA polymerase I (Klenow fragment) with the single-stranded template beyond the site of synthesis

Cocrystal structures of DNA polymerases from the Pol I (or A) family have provided only limited information about the location of the single-stranded template beyond the site of nucleotide incorporation, revealing contacts with the templating position and its immediate 5' neighbor. No structural information exists for template residues more remote from the polymerase active site. Using a competition binding assay, we have established that Klenow fragment contacts at least the first four unpaired template nucleotides, though the quantitative contribution of any single contact is relatively small. Photochemical cross-linking indicated that the first unpaired template base beyond the primer terminus is close to Y766, as expected, and the two following template bases are close to F771 on the surface of the fingers subdomain. We have constructed point mutations in the region of the fingers subdomain implicated by these experiments. Cocrystal structures of family A DNA polymerases predict contacts between the template strand and S769, F771, and R841, and our DNA binding assays provide evidence for the functional importance of these contacts. Overall, the data are most consistent with the template strand following a path over the fingers subdomain, close to the side chain of R836 and a neighboring cluster of positively charged residues.

Transcription strategy in a Closterovirus: a novel 5'-proximal controller element of Citrus Tristeza Virus produces 5'- and 3'-terminal subgenomic RNAs and differs from 3' open reading frame controller elements

Citrus tristeza virus (CTV) produces more than thirty 3'- or 5'-terminal subgenomic RNAs (sgRNAs) that accumulate to various extents during replication in protoplasts and plants. Among the most unusual species are two abundant populations of small 5'-terminal sgRNAs of approximately 800 nucleotides (nt) termed low-molecular-weight tristeza (LMT1 and LMT2) RNAs. Remarkably, CTV replicons with all 10 3' genes deleted produce only the larger LMT1 RNAs. These 5'-terminal positive-sense sgRNAs do not have corresponding negative strands and were hypothesized to be produced by premature termination during plus-strand genomic RNA synthesis. We characterized a cis-acting element that controls the production of the LMT1 RNAs. Since manipulation of this cis-acting element in its native position (the L-ProI region of replicase) was not possible because the mutations negatively affect replication, a region (5'TR) surrounding the putative termination sites (nt approximately 550 to 1000) was duplicated in the 3' end of a CTV replicon to allow characterization. The duplicated sequence continued to produce a 5'-terminal plus-strand sgRNA, here much larger ( approximately 11 kb), apparently by termination. Surprisingly, a new 3'-terminal sgRNA was observed from the duplicated 5'TR. A large 3'-terminal sgRNA resulting from the putative promoter activity of the native 5'TR was not observed, possibly because of the down-regulation of a promoter approximately 19 kb from the 3' terminus. However, we were able to observe a sgRNA produced from the native 5'TR of a small defective RNA, which placed the native 5'TR closer to the 3' terminus, demonstrating sgRNA promoter activity of the native 5'TR. Deletion mutagenesis mapped the promoter and the terminator activities of the 5'TR (in the 3' position in the CTV replicon) to a 57-nt region, which was folded by the MFOLD computer program into two stem-loops. Mutations in the putative stem-loop structures equally reduced or prevented production of both the 3'- and 5'-terminal sgRNAs. These mutations, when introduced in frame in the native 5'TR, similarly abolished the synthesis of the LMT1 RNAs and presumably the large 3'-terminal sgRNA while having no impact on replication, demonstrating that neither 5'- nor 3'-terminal sgRNA is necessary for replication of the replicon or full-length CTV in protoplasts. Differences between the 5'TR, which produced two plus-strand sgRNAs, and the cis-acting elements controlling the 3' open reading frames, which produced additional minus-strand sgRNAs corresponding to the 3'-terminal mRNAs, suggest that the different sgRNA controller elements had different origins in the modular evolution of closteroviruses.

RNA recombination in brome mosaic virus: effects of strand-specific stem-loop inserts

A model system of a single-stranded trisegment Brome mosaic bromovirus (BMV) was used to analyze the mechanism of homologous RNA recombination. Elements capable of forming strand-specific stem-loop structures were inserted at the modified 3' noncoding regions of BMV RNA3 and RNA2 in either positive or negative orientations, and various combinations of parental RNAs were tested for patterns of the accumulating recombinant RNA3 components. The structured negative-strand stem-loops that were inserted in both RNA3 and RNA2 reduced the accumulation of RNA3-RNA2 recombinants to a much higher extent than those in positive strands or the unstructured stem-loop inserts in either positive or negative strands. The use of only one parental RNA carrying the stem-loop insert reduced the accumulation of RNA3-RNA2 recombinants even further, but only when the stem-loops were in negative strands of RNA2. We assume that the presence of a stable stem-loop downstream of the landing site on the acceptor strand (negative RNA2) hampers the reattachment and reinitiation processes. Besides RNA3-RNA2 recombinants, the accumulation of nontargeted RNA3-RNA1 and RNA3-RNA3 recombinants were observed. Our results provide experimental evidence that homologous recombination between BMV RNAs more likely occurs during positive- rather than negative-strand synthesis.

Common structural features of nucleic acid polymerases

Structures of multisubunit RNA polymerases strongly differ from the many known structures of single subunit DNA and RNA polymerases. However, in functional complexes of these diverse enzymes, nucleic acids take a similar course through the active center. This finding allows superposition of diverse polymerases and reveals features that are functionally equivalent. The entering DNA duplex is bent by almost 90 degrees with respect to the exiting template-product duplex. At the point of bending, a dramatic twist between subsequent DNA template bases aligns the "coding" base with the binding site for the incoming nucleoside triphosphate (NTP). The NTP enters through an opening that is found in all polymerases, and, in most cases, binds between an alpha-helix and two catalytic metal ions. Subsequent phosphodiester bond formation adds a new base pair to the exiting template-product duplex, which is always bound from the minor groove side. All polymerases may undergo "induced fit" upon nucleic acid binding, but the underlying conformational changes differ.

Similar structural basis for membrane localization and protein priming by an RNA-dependent RNA polymerase

Protein primers are used to initiate genomic synthesis of several RNA and DNA viruses, although the structural details of the primer-polymerase interactions are not yet known. Poliovirus polymerase binds with high affinity to the membrane-bound viral protein 3AB but uridylylates only the smaller peptide 3B in vitro. Mutational analysis of the polymerase identified four surface residues on the three-dimensional structure of poliovirus polymerase whose wild-type identity is required for 3AB binding. These mutants also decreased 3B uridylylation, arguing that the binding sites for the membrane tether and the protein primer overlap. Mutation of flanking residues between the 3AB binding site and the polymerase active site specifically decreased 3B uridylylation, likely affecting steps subsequent to binding. The physical overlap of sites for protein priming and membrane association should facilitate replication initiation in the membrane-associated complex.

3'-5' exonuclease of Klenow fragment: role of amino acid residues within the single-stranded DNA binding region in exonucleolysis and duplex DNA melting

The mechanism of the 3'-5' exonuclease activity of the Klenow fragment of DNA polymerase I has been investigated with a combination of biochemical and spectroscopic techniques. Site-directed mutagenesis was used to make alanine substitutions of side chains that interact with the DNA substrate on the 5' side of the scissile phosphodiester bond. Kinetic parameters for 3'-5' exonuclease cleavage of single- and double-stranded DNA substrates were determined for each mutant protein in order to probe the role of the selected side chains in the exonuclease reaction. The results indicate that side chains that interact with the penultimate nucleotide (Q419, N420, and Y423) are important for anchoring the DNA substrate at the active site or ensuring proper geometry of the scissile phosphate. In contrast, side chains that interact with the third nucleotide from the DNA terminus (K422 and R455) do not participate directly in exonuclease cleavage of single-stranded DNA. Alanine substitutions of Q419, Y423, and R455 have markedly different effects on the cleavage of single- and double-stranded DNA, causing a much greater loss of activity in the case of a duplex substrate. Time-resolved fluorescence anisotropy decay measurements with a dansyl-labeled primer/template indicate that the Q419A, Y423A, and R455A mutations disrupted the ability of the Klenow fragment to melt duplex DNA and bind the frayed terminus at the exonuclease site. In contrast, the N420A mutation stabilized binding of a duplex terminus to the exonuclease site, suggesting that the N420 side chain facilitates the 3'-5' exonuclease reaction by introducing strain into the bound DNA substrate. Together, these results demonstrate that protein side chains that interact with the second or third nucleotides from the terminus can participate in both the chemical step of the exonuclease reaction, by anchoring the substrate in the active site or by ensuring proper geometry of the scissile phosphate, and in the prechemical steps of double-stranded DNA hydrolysis, by facilitating duplex melting.

DNA-binding interactions and conformational fluctuations of Tc3 transposase DNA binding domain examined with single molecule fluorescence spectroscopy

The fluorescent dye tetramethylrhodamine (TMR) was conjugated to a synthetic peptide containing the sequence-specific DNA binding domain of Tc3 transposase. Steady-state and single molecule fluorescence spectroscopy was used to investigate protein conformational fluctuations and the thermodynamics of binding interactions. Evidence is presented to show that the TMR-Tc3 conjugate exists in at least two conformational states. The most stable conformation is one in which the TMR fluorescence is quenched. Upon binding to DNA, the total fluorescence from TMR-Tc3 increases by three- to fourfold. Single molecule measurements of TMR-Tc3 bound to DNA shows that this complex also fluctuates between a fluorescent and quenched form. The fluorescent form of the conjugate is stabilized when bound to DNA, and this accounts for part of the increase in total fluorescence. In addition, the inherent photodynamics of the dye itself is also altered (e.g., fluorescent lifetime or triplet yield) in such a way that the total fluorescence from the conjugate bound to DNA is enhanced relative to the unbound form.

Crystal structures of active and inactive conformations of a caliciviral RNA-dependent RNA polymerase

The structure of the RNA-dependent RNA polymerase (RdRP) from the rabbit hemorrhagic disease virus has been determined by x-ray crystallography to a 2.5-A resolution. The overall structure resembles a "right hand," as seen before in other polymerases, including the RdRPs of polio virus and hepatitis C virus. Two copies of the polymerase are present in the asymmetric unit of the crystal, revealing active and inactive conformations within the same crystal form. The fingers and palm domains form a relatively rigid unit, but the thumb domain can adopt either "closed" or "open" conformations differing by a rigid body rotation of approximately 8 degrees. Metal ions bind at different positions in the two conformations and suggest how structural changes may be important to enzymatic function in RdRPs. Comparisons between the structures of the alternate conformational states of rabbit hemorrhagic disease virus RdRP and the structures of RdRPs from hepatitis C virus and polio virus suggest novel structure-function relationships in this medically important class of enzymes.

Inhibition of CMP-sialic acid transport into Golgi vesicles by nucleoside monophosphates

We examined the interactions of nucleotides with the CMP-sialic acid transporter in order to better understand which features play a role in binding and to investigate the relationship between binding and subsequent transport. With respect to the sugar, the transporter requires a complete ribose ring for tight binding, and the 2'-ara hydrogen makes an important contact. The enzyme exhibits little specificity with respect to the 2'- and 3'-hydroxyls, as it tolerated substitutions ranging from fluorine to an azido group. In the base, the C4 amine and C2 carbonyl groups make important contacts, while the N3 nitrogen does not. However, adding a methyl group to N3 dramatically reduced binding, indicating that mass at this position sterically hinders binding. Adding a group at C5 had either no effect or slightly enhanced binding. To determine if the transporter recognizes these CMP analogues as substrates, we assayed them for their ability to trans stimulate CMP-sialic acid import. These data suggest that the enzyme transports a wide variety of NMPs, and the rate of transport is inversely proportional to the K(I) of the analogue. The importance of our findings for understanding the specificities of the different nucleotide-sugar tranlocators and the design of novel glycosylation inhibitors are discussed.

Studies on functional interaction between brome mosaic virus replicase proteins during RNA recombination, using combined mutants in vivo and in vitro

Two viral proteins, 1a and 2a, direct replication of brome mosaic bromovirus (BMV) RNAs as well as they participate in BMV RNA recombination. To study the relationship between replication and recombination, double BMV variants that carried mutations in 1a and 2a genes were tested. The observed effects revealed that the 1a helicase and 2a N-terminal or core domains were functionally linked during both processes in vivo. The use of a series of mutant BMV replicase (RdRp) preparations demonstrated in vitro the participation of the 1a and 2a domains in BMV RNA copying and in template switching during minus-strand synthesis. The observed effects support previous observations that the characteristics of homologous and nonhomologous recombination can be modified separately by mutations at different sites on BMV replicase proteins.

A DNA polymerase beta mutator mutant with reduced nucleotide discrimination and increased protein stability

DNA polymerase beta (pol beta) offers a simple system to examine the role of polymerase structure in the fidelity of DNA synthesis. In this study, the M282L variant of pol beta (M282Lbeta) was identified using an in vivo genetic screen. Met282, which does not contact the DNA template or the incoming deoxynucleoside triphosphate (dNTP) substrate, is located on alpha-helix N of pol beta. This mutant enzyme demonstrates increased mutagenesis in both in vivo and in vitro assays. M282Lbeta has a 7.5-fold higher mutation frequency than wild-type pol beta; M282Lbeta commits a variety of base substitution and frameshift errors. Transient-state kinetic methods were used to investigate the mechanism of intrinsic mutator activity of M282Lbeta. Results show an 11-fold decrease in dNTP substrate discrimination at the level of ground-state binding. However, during the protein conformational change and/or phosphodiester bond formation, the nucleotide discrimination is improved. X-ray crystallography was utilized to gain insights into the structural basis of the decreased DNA synthesis fidelity. Most of the structural changes are localized to site 282 and the surrounding region in the C-terminal part of the 31-kDa domain. Repositioning of mostly hydrophobic amino acid residues in the core of the C-terminal portion generates a protein with enhanced stability. The combination of structural and equilibrium unfolding data suggests that the mechanism of nucleotide discrimination is possibly affected by the compacting of the hydrophobic core around residue Leu282. Subsequent movement of an adjacent surface residue, Arg283, produces a slight increase in volume of the pocket that may accommodate the incoming correct base pair. The structural changes of M282Lbeta ultimately lead to an overall reduction in polymerase fidelity.

Tethered processivity of the vitamin K-dependent carboxylase: factor IX is efficiently modified in a mechanism which distinguishes Gla's from Glu's and which accounts for comprehensive carboxylation in vivo

The vitamin K-dependent (VKD) carboxylase binds VKD proteins via their propeptide and converts Glu's to gamma-carboxylated Glu's, or Gla's, in the Gla domain. Multiple carboxylation is required for activity, which could be achieved if the carboxylase is processive. In the only previous study to test for this capability, an indirect assay was used which suggested processivity; however, the efficiency was poor and raised questions regarding how full carboxylation is accomplished. To unequivocally determine if the carboxylase is processive and if it can account for comprehensive carboxylation in vivo, as well as to elucidate the enzyme mechanism, we developed a direct test for processivity. The in vitro carboxylation of a complex containing carboxylase and full-length factor IX (fIX) was challenged with an excess amount of a distinguishable fIX variant. Remarkably, carboxylation of fIX in the complex was completely unaffected by the challenge protein, and comprehensive carboxylation was achieved, showing conclusively that the carboxylase is processive and highly efficient. These studies also showed that carboxylation of individual fIX/carboxylase complexes was nonsynchronous and implicated a driving force for the reaction which requires the carboxylase to distinguish Glu's from Gla's. We found that the Gla domain is tightly associated with the carboxylase during carboxylation, blocking the access of a small peptide substrate (EEL). The studies describe the first analysis of preformed complexes, and the rate for full-length, native fIX in the complex was equivalent to that of the substrate EEL. Thus, intramolecular movement within the Gla domain to reposition new Glu's for catalysis is as rapid as diffusion-limited positioning of a small substrate, and the Gla domain is not sterically constrained by the rest of the fIX molecule during carboxylation. The rate of carboxylation of fIX in the preformed complex was 24-fold higher than for fIX modified by free carboxylase, which supports carboxylase processivity and which indicates that binding and/or release is the rate-limiting step in protein carboxylation. These data indicate a model of tethered processivity, in which the VKD proteins remain bound to the carboxylase throughout the reaction via their propeptide, while the Gla domain undergoes intramolecular movement to reposition new Glu's for catalysis to ultimately achieve comprehensive carboxylation.

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.

Crystal structure of a DinB lesion bypass DNA polymerase catalytic fragment reveals a classic polymerase catalytic domain

The UmuC/DinB family of bypass polymerases is responsible for translesion DNA synthesis and includes the human polymerases eta, iota, and kappa. We determined the 2.3 A resolution crystal structure of a catalytic fragment of the DinB homolog (Dbh) polymerase from Sulfolobus solfataricus and show that it is nonprocessive and can bypass an abasic site. The structure of the catalytic domain is nearly identical to those of most other polymerase families. Homology modeling suggests that there is minimal contact between protein and DNA, that the nascent base pair binding pocket is quite accessible, and that the enzyme is already in a closed conformation characteristic of ternary polymerase complexes. These observations afford insights into the sources of low fidelity and low processivity of the UmuC/DinB polymerases.

Molecular mechanisms of the functional coupling of the helicase (gp41) and polymerase (gp43) of bacteriophage T4 within the DNA replication fork

Processive strand-displacement DNA synthesis with the T4 replication system requires functional "coupling" between the DNA polymerase (gp43) and the helicase (gp41). To define the physical basis of this functional coupling, we have used analytical ultracentrifugation to show that gp43 is a monomeric species at physiological protein concentrations and that gp41 and gp43 do not physically interact in the absence of DNA, suggesting that the functional coupling between gp41 and gp43 depends significantly on interactions modulated by the replication fork DNA. Results from strand-displacement DNA synthesis show that a minimal gp41-gp43 replication complex can perform strand-displacement synthesis at approximately 90 nts/s in a solution containing poly(ethylene glycol) to drive helicase loading. In contrast, neither the Klenow fragment of Escherichia coli DNA polymerase I nor the T7 DNA polymerase, both of which are nonprocessive polymerases, can carry out strand-displacement DNA synthesis with gp41, suggesting that the functional helicase-polymerase coupling may require the homologous system. However, we show that a heterologous helicase-polymerase pair can work if the polymerase is processive. Strand-displacement DNA synthesis using the gp41 helicase with the T4 DNA polymerase holoenzyme or the phage T7 DNA polymerase-thioredoxin complex, both of which are processive, proceeds at the rate of approximately 250 nts/s. However, replication fork assembly is less efficient with the heterologous helicase-polymerase pair. Therefore, a processive (homologous or heterologous) "trailing" DNA polymerase is sufficient to improve gp41 processivity and unwinding activity in the elongation stage of the helicase reaction, and specific T4 helicase-polymerase coupling becomes significant only in the assembly (or initiation) stage.

Replication by a single DNA polymerase of a stretched single-stranded DNA

A new approach to the study of DNA/protein interactions has been opened through the recent advances in the manipulation of single DNA molecules. These allow the behavior of individual molecular motors to be studied under load and compared with bulk measurements. One example of such a motor is the DNA polymerase, which replicates DNA. We measured the replication rate by a single enzyme of a stretched single strand of DNA. The marked difference between the elasticity of single- and double-stranded DNA allows for the monitoring of replication in real time. We have found that the rate of replication depends strongly on the stretching force applied to the template. In particular, by varying the load we determined that the biochemical steps limiting replication are coupled to movement. The replication rate increases at low forces, decreases at forces greater than 4 pN, and ceases when the single-stranded DNA substrate is under a load greater than approximately 20 pN. The decay of the replication rate follows an Arrhenius law and indicates that multiple bases on the template strand are involved in the rate-limiting step of each cycle. This observation is consistent with the induced-fit mechanism for error detection during replication.

Walking on two heads: the many talents of kinesin

The gallop of a race horse and the minute excursions of a cellular vesicle have one thing in common: they are based on the directional movement of proteins termed molecular motors -- many trillions in the case of the horse, just a few in the case of the cell vesicle. These tiny machines take nanometre steps on a millisecond timescale to drive all biological movements. Over the past 15 years new biochemical and biophysical approaches have allowed us to take a giant step forward in understanding the molecular basis of motor mechanics.

Temperature-dependent equilibrium between the open and closed conformation of the p66 subunit of HIV-1 reverse transcriptase revealed by site-directed spin labelling

X-ray crystallographic studies of human immunodeficiency virus type 1 reverse transcriptase complexed with or without substrates or inhibitors show that the heterodimeric enzyme adopts distinct conformations that differ in the orientation of the so-called thumb subdomain in the large subunit. Site-directed spin labelling of mutated residue positions W24C and K287C is applied here to determine the distances between the fingers and thumb subdomains of liganded and unliganded RT in solution. The inter-spin distances of a DNA/DNA and a pseudoknot RNA complexed reverse transcriptase in solution was found to agree with the respective crystal data of the open and closed conformations. For the unliganded reverse transcriptase a temperature-dependent equilibrium between these two states was observed. The fraction of the closed conformation decreased from 95% at 313 K to 65% at 273 K. The spectral separation between the two structures was facilitated by the use of a perdeuterated ([15)N]nitroxide methane-thiosulfonate spin label.

HIV-1 reverse transcriptase-pseudoknot RNA aptamer interaction has a binding affinity in the low picomolar range coupled with high specificity

Systematic evolution of ligands by exponential enrichment (SELEX) is a powerful method for the identification of small oligonucleotides that bind with high affinity and specificity to target proteins. Such DNAs/RNAs are a new class of potential chemotherapeutics that could block the enzymatic activity of pathologically relevant proteins. We have conducted a detailed biochemical study of the interaction of human immunodeficiency virus 1 (HIV-1) reverse transcriptase (RT) with a SELEX-derived pseudoknot RNA aptamer. Electron paramagnetic resonance spectroscopy of site-directed spin-labeled RT mutants revealed that this aptamer was selected for binding to the "closed" conformation of the enzyme. Kinetic analysis showed that the RNA inhibitor bound to HIV RT in a two-step process, with association rates similar to those described for model DNA/DNA and DNA/RNA substrates. However, the dissociation of the pseudoknot RNA from RT was dramatically slower than observed for model substrates. Equilibrium binding studies revealed an extraordinarily low K(d), of about 25 pm, for the enzyme-aptamer interaction, presumably a consequence of the slow off-rates. Additionally, this pseudoknot aptamer is highly specific for HIV-1 RT, with the closely related HIV-2 enzyme showing a binding affinity close to 4 orders of magnitude lower.

Mutation is modulated: implications for evolution

Evolution occurs through genome variation followed by selection. Because DNA sequence context affects the activity of enzymes that copy, move and repair DNA, there are intrinsic variations in the probability of genetic variation along a genome. These intrinsic variations can be affected by selective pressure. Codon changes that do not alter the encoded amino acids may still have effects on the local rate of sequence change. Large gene families could encode a successful genetic framework by which to evolve new, functional members. The speed of adaptation to environmental challenges may be improved when the distinct mechanisms of genetic change come under regulatory control. Natural selection operates on mechanisms that generate and modulate diversity as it does on all biological functions.

DNA replication at high resolution

Several decades of research have delineated the roles of many proteins central to DNA replication. Here we present a structural perspective of this work spanning the past 15 years and highlight several recent advances in the field.

Crystal structure of the RNA-dependent RNA polymerase of hepatitis C virus

We report the crystal structure of the RNA-dependent RNA polymerase of hepatitis C virus, a major human pathogen, to 2.8-A resolution. This enzyme is a key target for developing specific antiviral therapy. The structure of the catalytic domain contains 531 residues folded in the characteristic fingers, palm, and thumb subdomains. The fingers subdomain contains a region, the "fingertips," that shares the same fold with reverse transcriptases. Superposition to the available structures of the latter shows that residues from the palm and fingertips are structurally equivalent. In addition, it shows that the hepatitis C virus polymerase was crystallized in a closed fingers conformation, similar to HIV-1 reverse transcriptase in ternary complex with DNA and dTTP [Huang H., Chopra, R., Verdine, G. L. & Harrison, S. C. (1998) Science 282, 1669-1675]. This superposition reveals the majority of the amino acid residues of the hepatitis C virus enzyme that are likely to be implicated in binding to the replicating RNA molecule and to the incoming NTP. It also suggests a rearrangement of the thumb domain as well as a possible concerted movement of thumb and fingertips during translocation of the RNA template-primer in successive polymerization rounds.

Crystal structure of an archaebacterial DNA polymerase

BACKGROUND

Members of the Pol II family of DNA polymerases are responsible for chromosomal replication in eukaryotes, and carry out highly processive DNA replication when attached to ring-shaped processivity clamps. The sequences of Pol II polymerases are distinct from those of members of the well-studied Pol I family of DNA polymerases. The DNA polymerase from the archaebacterium Desulfurococcus strain Tok (D. Tok Pol) is a member of the Pol II family that retains catalytic activity at elevated temperatures.

RESULTS

The crystal structure of D. Tok Pol has been determined at 2.4 A resolution. The architecture of this Pol II type DNA polymerase resembles that of the DNA polymerase from the bacteriophage RB69, with which it shares less than approximately 20% sequence identity. As in RB69, the central catalytic region of the DNA polymerase is located within the 'palm' subdomain and is strikingly similar in structure to the corresponding regions of Pol I type DNA polymerases. The structural scaffold that surrounds the catalytic core in D. Tok Pol is unrelated in structure to that of Pol I type polymerases. The 3'-5' proofreading exonuclease domain of D. Tok Pol resembles the corresponding domains of RB69 Pol and Pol I type DNA polymerases. The exonuclease domain in D. Tok Pol is located in the same position relative to the polymerase domain as seen in RB69, and on the opposite side of the palm subdomain compared to its location in Pol I type polymerases. The N-terminal domain of D. Tok Pol has structural similarity to RNA-binding domains. Sequence alignments suggest that this domain is conserved in the eukaryotic DNA polymerases delta and epsilon.

CONCLUSIONS

The structure of D. Tok Pol confirms that the modes of binding of the template and extrusion of newly synthesized duplex DNA are likely to be similar in both Pol II and Pol I type DNA polymerases. However, the mechanism by which the newly synthesized product transits in and out of the proofreading exonuclease domain has to be quite different. The discovery of a domain that seems to be an RNA-binding module raises the possibility that Pol II family members interact with RNA.

Isolation and characterization of a split B-type DNA polymerase from the archaeon Methanobacterium thermoautotrophicum deltaH

We describe here the isolation and characterization of a B-type DNA polymerase (PolB) from the archaeon Methanobacterium thermoautotrophicum DeltaH. Uniquely, the catalytic domains of M. thermoautotrophicum PolB are encoded from two different genes, a feature that has not been observed as yet in other polymerases. The two genes were cloned, and the proteins were overexpressed in Escherichia coli and purified individually and as a complex. We demonstrate that both polypeptides are needed to form the active polymerase. Similar to other polymerases constituting the B-type family, PolB possesses both polymerase and 3'-5' exonuclease activities. We found that a homolog of replication protein A from M. thermoautotrophicum inhibits the PolB activity. The inhibition of DNA synthesis by replication protein A from M. thermoautotrophicum can be relieved by the addition of M. thermoautotrophicum homologs of replication factor C and proliferating cell nuclear antigen. The possible roles of PolB in M. thermoautotrophicum replication are discussed.