Site-directed mutagenesis of recombinant rat DNA polymerase beta: involvement of arginine-183 in primer recognition

Induced Fit in the Selection of Correct versus Incorrect Nucleotides by DNA Polymerase β

DNA polymerase β (Pol β) repairs single-nucleotide gapped DNA (sngDNA) by enzymatic incorporation of the Watson-Crick partner nucleotide at the gapped position opposite the templating nucleotide. The process by which the matching nucleotide is incorporated into a sngDNA sequence has been relatively well-characterized, but the process of discrimination from nucleotide misincorporation remains unclear. We report here NMR spectroscopic characterization of full-length, uniformly labeled Pol β in apo, sngDNA-bound binary, and ternary complexes containing matching and mismatching nucleotide. Our data indicate that, while binding of the correct nucleotide to the binary complex induces chemical shift changes consistent with the process of enzyme closure, the ternary Pol β complex containing a mismatching nucleotide exhibits no such changes and appears to remain in an open, unstable, binary-like conformation. Our findings support an induced-fit mechanism for polymerases in which a closed ternary complex can only be achieved in the presence of matching nucleotide.

Phylogenetic analysis and evolutionary origins of DNA polymerase X-family members

Mammalian DNA polymerase (pol) β is the founding member of a large group of DNA polymerases now termed the X-family. DNA polymerase β has been kinetically, structurally, and biologically well characterized and can serve as a phylogenetic reference. Accordingly, we have performed a phylogenetic analysis to understand the relationship between pol β and other members of the X-family of DNA polymerases. The bacterial X-family DNA polymerases, Saccharomyces cerevisiae pol IV, and four mammalian X-family polymerases appear to be directly related. These enzymes originated from an ancient common ancestor characterized in two Bacillus species. Understanding distinct functions for each of the X-family polymerases, evolving from a common bacterial ancestor is of significant interest in light of the specialized roles of these enzymes in DNA metabolism.

Modulation of the structure, catalytic activity, and fidelity of African swine fever virus DNA polymerase X by a reversible disulfide switch

African swine fever virus polymerase X (pol X) is the smallest DNA polymerase known (174 amino acids), and its tertiary structure resembles the C-terminal half of prototypical X-family pol beta, which includes a catalytic dNTP-binding site (palm domain) and a finger domain. This structural similarity and the presence of viral genes coding for other base excision repair proteins suggest that pol X functions in a manner similar to pol beta, but inconsistencies concerning pol X catalysis have been reported. We examined the structural and functional properties of two forms of pol X using spectroscopic and kinetic analysis. Using (1)H-(15)N correlated NMR, we unambiguously demonstrated the slow interconversion of pol X between a reduced (pol X(red)) and an oxidized form (pol X(ox)), confirmed by mass spectrometry. Steady-state kinetic analysis revealed that pol X(ox), with a disulfide bond between Cys-81 and Cys-86, has approximately 10-fold lower fidelity than pol X(red) during dNTP insertion opposite a template G. The disulfide linkage is located between two beta-strands in the palm domain, near the putative dNTP-binding site. Structural alignment of pol X with a pol beta ternary structure suggests that the disulfide switch may modulate fidelity by altering the ability of the palm domain to align and stabilize the primer terminus and catalytic metal ion for deprotonation of the 3'-OH group and subsequent phosphoryl transfer. Thus, DNA polymerase fidelity is altered by the redox state of the enzyme and its related conformational changes.

Catalytic mechanism of human DNA polymerase lambda with Mg2+ and Mn2+ from ab initio quantum mechanical/molecular mechanical studies

DNA polymerases play a crucial role in the cell cycle due to their involvement in genome replication and repair. Understanding the reaction mechanism by which these polymerases carry out their function can provide insights into these processes. Recently, the crystal structures of human DNA polymerase lambda (Pollambda) have been reported both for pre- and post-catalytic complexes [García-Díaz et al., DNA Repair 3 (2007), 1333]. Here we employ the pre-catalytic complex as a starting structure for the determination of the catalytic mechanism of Pollambda using ab initio quantum mechanical/molecular mechanical methods. The reaction path has been calculated using Mg(2+) and Mn(2+) as the catalytic metals. In both cases the reaction proceeds through a two-step mechanism where the 3'-OH of the primer sugar ring is deprotonated by one of the conserved Asp residues (D490) in the active site before the incorporation of the nucleotide to the nascent DNA chain. A significant charge transfer is observed between both metals and some residues in the active site as the reaction proceeds. The optimized reactant and product structures agree with the reported crystal structures. In addition, the calculated reaction barriers for both metals are close to experimentally estimated barriers. Energy decomposition analysis to explain individual residue contributions suggests that several amino acids surrounding the active site are important for catalysis. Some of these residues, including R420, R488 and E529, have been implicated in catalysis by previous mutagenesis experiments on the homologous residues on Polbeta. Furthermore, Pollambda residues R420 and E529 found to be important from the energy decomposition analysis, are homologous to residues R183 and E295 in Polbeta, both of which are linked to cancer. In addition, residues R386, E391, K422 and K472 appear to have an important role in catalysis and could be a potential target for mutagenesis experiments. There is partial conservation of these residues across the Pol X family of DNA polymerases.

Regulation of DNA repair fidelity by molecular checkpoints: "gates" in DNA polymerase beta's substrate selection

With an increasing number of structural, kinetic, and modeling studies of diverse DNA polymerases in various contexts, a complex dynamical view of how atomic motions might define molecular "gates" or checkpoints that contribute to polymerase specificity and efficiency is emerging. Such atomic-level information can offer insights into rate-limiting conformational and chemical steps to help piece together mechanistic views of polymerases in action. With recent advances, modeling and dynamics simulations, subject to the well-appreciated limitations, can access transition states and transient intermediates along a reaction pathway, both conformational and chemical, and such information can help bridge the gap between experimentally determined equilibrium structures and mechanistic enzymology data. Focusing on DNA polymerase beta (pol beta), we present an emerging view of the geometric, energetic, and dynamic selection criteria governing insertion rate and fidelity mechanisms of DNA polymerases, as gleaned from various computational studies and based on the large body of existing kinetic and structural data. The landscape of nucleotide insertion for pol beta includes conformational changes, prechemistry, and chemistry "avenues", each with a unique deterministic or stochastic pathway that includes checkpoints for selective control of nucleotide insertion efficiency. For both correct and incorrect incoming nucleotides, pol beta's conformational rearrangements before chemistry include a cascade of slow and subtle side chain rearrangements, followed by active site adjustments to overcome higher chemical barriers, which include critical ion-polymerase geometries; this latter notion of a prechemistry avenue fits well with recent structural and NMR data. The chemical step involves an associative mechanism with several possibilities for the initial proton transfer and for the interaction among the active site residues and bridging water molecules. The conformational and chemical events and associated barriers define checkpoints that control enzymatic efficiency and fidelity. Understanding the nature of such active site rearrangements can facilitate interpretation of existing data and stimulate new experiments that aim to probe enzyme features that contribute to fidelity discrimination across various polymerases via such geometric, dynamic, and energetic selection criteria.

Energy analysis of chemistry for correct insertion by DNA polymerase beta

X-ray crystallographic structures of human DNA polymerase beta with nonhydrolyzable analogs containing all atoms in the active site required for catalysis provide a secure starting point for a theoretical analysis (quantum mechanics/molecular mechanics) of the mechanism of chemistry without biasing of modeling assumptions as required in previous studies. These structures provide the basis for a detailed quantum mechanics/molecular mechanics study of the path for the complete transfer of a monophosphate nucleoside donor to the sugar acceptor in the active site. The reaction is largely associative with the main energetic step preceded by proton transfer from the terminal primer deoxyribose O3' to Asp-256. The key residues that provide electrostatic stabilization of the transition state are identified and compared with those identified by mutational studies.

Structural insight into the DNA polymerase beta deoxyribose phosphate lyase mechanism

A large number of biochemical and genetic studies have demonstrated the involvement of DNA polymerase beta (Pol beta) in mammalian base excision repair (BER). Pol beta participates in BER sub-pathways by contributing gap filling DNA synthesis and lyase removal of the 5'-deoxyribose phosphate (dRP) group from the cleaved abasic site. To better understand the mechanism of the dRP lyase reaction at an atomic level, we determined a crystal structure of Pol beta complexed with 5'-phosphorylated abasic sugar analogs in nicked DNA. This DNA ligand represents a potential BER intermediate. The crystal structure reveals that the dRP group is bound in a non-catalytic binding site. The catalytic nucleophile in the dRP lyase reaction, Lys72, and all other potential secondary nucleophiles, are too far away to participate in nucleophilic attack on the C1' of the sugar. An approximate model of the dRP group in the expected catalytic binding site suggests that a rotation of 120 degrees about the dRP 3'-phosphate is required to position the epsilon-amino Lys72 close to the dRP C1'. This model also suggests that several other side chains are in position to facilitate the beta-elimination reaction. From results of mutational analysis of key residues in the dRP lyase active site, it appears that the substrate dRP can be stabilized in the observed non-catalytic binding conformation, hindering dRP lyase activity.

Neonatal lethality with abnormal neurogenesis in mice deficient in DNA polymerase beta

DNA polymerase beta (Polbeta) has been implicated in base excision repair in mammalian cells. However, the physiological significance of this enzyme in the body remains unclear. Here, we demonstrate that mice carrying a targeted disruption of the Polbeta gene showed growth retardation and died of a respiratory failure immediately after the birth. Histological examination of the embryos revealed defective neurogenesis characterized by apoptotic cell death in the developing central and peripheral nervous systems. Extensive cell death occurred in newly generated post-mitotic neuronal cells and was closely associated with the period between onset and cessation of neurogenesis. These findings indicate that Polbeta plays an essential role in neural development.

Specific interaction of DNA polymerase beta and DNA ligase I in a multiprotein base excision repair complex from bovine testis

Base excision repair (BER) is a cellular defense mechanism repairing modified bases in DNA. Recently, a G:U repair reaction has been reconstituted with several purified enzymes from Escherichia coli (Dianov, G., and Lindahl, T.(1994) Curr. Biol. 4, 1069-1076). Using bovine testis crude nuclear extract, we have shown that G:U is repaired efficiently in vitro, and DNA polymerase beta (beta-pol) is responsible for the single nucleotide gap-filling synthesis (Singhal, R. K., Prasad, R., and Wilson, S. H.(1995) J. Biol. Chem. 270, 949-957). To investigate potential interaction of beta-pol with other BER protein(s), we developed affinity chromatography matrices by cross-linking purified rat beta-pol or antibody against beta-pol to solid supports. Crude nuclear extract from bovine testis was applied to these affinity columns, which were then extensively washed. Proteins that bound specifically to the affinity columns were co-eluted in a complex with beta-pol. This complex had a molecular mass of approximately 180 kDa and was able to conduct the complete uracil-initiated BER reaction. The BER complex contained both beta-pol and DNA ligase I. An antibody to beta-pol was able to shift the complex in sucrose gradients to a much larger molecular mass (>300 kDa) that again contained both beta-pol and DNA ligase I. Furthermore, DNA ligase I and beta-pol were co-immunoprecipitated from the testis nuclear extract with anti beta-pol IgG. Thus, we conclude that beta-pol and DNA ligase I are components of a multiprotein complex that performs BER.

Detection and characterization of mammalian DNA polymerase beta mutants by functional complementation in Escherichia coli

We have designed and utilized a bacterial complementation system to identify and characterize mammalian DNA polymerase beta mutants. In this complementation system, wild-type rat DNA polymerase beta replaces both the replicative and repair functions of DNA polymerase I in the Escherichia coli recA718 polA12 double mutant; our 263 DNA polymerase beta mutants replace E. coli polymerase I less efficiently or not at all. Of the 10 mutants that have been shown to contain DNA sequence alterations, 2 exhibit a split phenotype with respect to complementation of the growth defect and methylmethanesulfonate sensitivity of the double mutant; one is a null mutant. The mutants possessing a split phenotype contain amino acid residue alterations within a putative nucleotide binding site of DNA polymerase beta. This approach for the isolation and evaluation of mutants of a mammalian DNA polymerase in E. coli may ultimately lead to a better understanding of the mechanism of action of this enzyme and to precisely defining its role in vertebrate cells.

Two regions in human DNA polymerase beta mRNA suppress translation in Escherichia coli

Although human DNA polymerase beta (DNA pol beta) shows 96% identity with rat DNA pol beta at the amino acid level, it is weakly expressed in Escherichia (E.) coli relative to the rat enzyme. The mechanism of this suppression was investigated. Pulse-chase protein labeling and steady state mRNA analysis showed that mature human DNA pol beta protein is relatively stable in E. coli and the levels of human and rat DNA pol beta mRNA were comparable indicating that the human DNA pol beta expression is suppressed at the translational level. By systematic expression analysis of a number of chimeric genes composed of human and rat cDNAs, two strong translational suppression regions were mapped in the human DNA pol beta mRNA; one was named TSR-1, corresponding to CGG encoding arginine (arg) at position 4 and the other, termed TSR-2, is located between codons 153 and 199. Since substitution of the rat Arg-4 codon with synonymous codons showed strong effects upon the expression level, we propose that the arg codon at the N-terminal coding region plays a role in modulating expression.

Structure-function analysis of DNA polymerase-beta using monoclonal antibodies: identification of a putative nucleotide binding domain

DNA polymerase-beta was purified from Novikoff hepatoma and used as an antigen in an in vitro immunization system to produce monoclonal antibodies. These reagents surprisingly showed cross-reactivity to a number of proteins, including several DNA polymerases. Nearly all of these proteins possess nucleotide binding sites, which suggested the potential value of using the monoclonals to elucidate structure-function relationships within polymerase-beta. Furthermore, these antibodies were able to partially neutralize (40-50%) polymerase-beta activity, and this effect could be blocked by dNTP1 but not by dNMP or rNTP. The limited neutralization phenomenon is at least partially explained by the weak binding affinity of these antibodies. Scatchard analysis of immunoprecipitation data predicted a Kd of 1.8 x 10(-8) M. Epitope mapping studies showed that the region of polymerase-beta recognized by one of the monoclonal antibodies is within residues 235-335, and sequence homology studies indicated that the epitope is probably located in the region of amino acids 283-320. At least a portion of this area, namely residues 301-308 and 311-315, appears to be part of a nucleotide binding domain which has sequence homology with a portion of the highly conserved ATP binding site in adenylate kinase.

Structure and expression during development of Drosophila melanogaster gene for DNA polymerase alpha

The Drosophila melanogaster gene and cDNA which span the entire open reading frame for DNA polymerase alpha, were cloned, and their nucleotide sequences were determined. The gene consists of 6 exons separated by 5 short introns. The major transcription initiation site was localized 85 bp upstream from the initiation codon. The nucleotide sequence of the open reading frame revealed a polypeptide of 1,505 amino acid residues with a molecular weight of 170,796. The amino acid sequence of the polypeptide was 37% homologous with that of the catalytic subunit of human DNA polymerase alpha. This sequence contains six regions, the orders and amino acid sequences of which are highly conserved among a number of other viral and eukaryotic DNA polymerases. We found 7 amino acid residues in the region between the 639th and 758th positions, identical to those essential for the active site of Escherichia coli DNA polymerase I-associated 3'----5' exonuclease. Thus, the exonuclease activity may be associated with Drosophila DNA polymerase alpha. Levels of the DNA polymerase alpha mRNA were high in unfertilized eggs and early embryos, relatively high in adult female flies and second-instar larva, and low in bodies at other stages of development. This feature of the expression is similar to that of the proliferating cell nuclear antigen (an auxiliary protein of DNA polymerase delta) and seems to coincide with the proportions of proliferating cells in various developmental stages. As the half life of the mRNA for DNA polymerase alpha in cultured Drosophila Kc cells was 15 min, expression of the DNA polymerase alpha gene is probably strictly regulated at the step of transcription.