Bypass of N²-ethylguanine by human DNA polymerase κ

The efficiency and fidelity of nucleotide incorporation and next-base extension by DNA polymerase (pol) κ past N(2)-ethyl-Gua were measured using steady-state and rapid kinetic analyses. DNA pol κ incorporated nucleotides and extended 3' termini opposite N(2)-ethyl-Gua with measured efficiencies and fidelities similar to that opposite Gua indicating a role for DNA pol κ at the insertion and extension steps of N(2)-ethyl-Gua bypass. The DNA pol κ was maximally activated to similar levels by a twenty-fold lower concentration of Mn(2+) compared to Mg(2+). In addition, the steady state analysis indicated that high fidelity DNA pol κ-catalyzed N(2)-ethyl-Gua bypass is Mg(2+)-dependent. Strikingly, Mn(2+) activation of DNA pol κ resulted in a dramatically lower efficiency of correct nucleotide incorporation opposite both N(2)-ethyl-Gua and Gua compared to that detected upon Mg(2+) activation. This effect is largely governed by diminished correct nucleotide binding as indicated by the high K(m) values for dCTP insertion opposite N(2)-ethyl-Gua and Gua with Mn(2+) activation. A rapid kinetic analysis showed diminished burst amplitudes in the presence of Mn(2+) compared to Mg(2+) indicating that DNA pol κ preferentially utilizes Mg(2+) activation. These kinetic data support a DNA pol κ wobble base pairing mechanism for dCTP incorporation opposite N(2)-ethyl-Gua. Furthermore, the dramatically different polymerization efficiencies of the Y-family DNA pols κ and ι in the presence of Mn(2+) suggest a metal ion-dependent regulation in coordinating the activities of these DNA pols during translesion synthesis.     

Poliovirus RNA-dependent RNA polymerase (3D(pol)). Divalent cation modulation of primer, template, and nucleotide selection

We have analyzed the divalent cation specificity of poliovirus RNA-dependent RNA polymerase, 3D(pol). The following preference was observed: Mn(2+) > Co(2+) > Ni(2+) > Fe(2+) > Mg(2+) > Ca(2+) > Cu(2+), and Zn(2+) was incapable of supporting 3D(pol)-catalyzed nucleotide incorporation. In the presence of Mn(2+), 3D(pol) activity was increased by greater than 10-fold relative to that in the presence of Mg(2+). Steady-state kinetic analysis revealed that the increased activity observed in the presence of Mn(2+) was due, primarily, to a reduction in the K(M) value for 3D(pol) binding to primer/template, without any significant effect on the K(M) value for nucleotide. The ability of 3D(pol) to catalyze RNA synthesis de novo was also stimulated approximately 10-fold by using Mn(2+), and the enzyme was now capable of also utilizing a DNA template for primer-independent RNA synthesis. Interestingly, the use of Mn(2+) as divalent cation permitted 3D(pol) activity to be monitored by following extension of 5'-(32)P-end-labeled, heteropolymeric RNA primer/templates. The kinetics of primer extension were biphasic because of the enzyme binding to primer/template in both possible orientations. When bound in the incorrect orientation, 3D(pol) was capable of efficient addition of nucleotides to the blunt-ended duplex; this activity was also apparent in the presence of Mg(2+). In the presence of Mn(2+), 3D(pol) efficiently utilized dNTPs, ddNTPs, and incorrect NTPs. On average, three incorrect nucleotides could be incorporated by 3D(pol). The ability of 3D(pol) to incorporate the correct dNTP, but not the correct ddNTP, was also observed in the presence of Mg(2+). Taken together, these results provide the first glimpse into the nucleotide specificity and fidelity of the poliovirus polymerase and suggest novel alternatives for the design of primer/templates to study the mechanism of 3D(pol)-catalyzed nucleotide incorporation.     

Poliovirus RNA-dependent RNA polymerase (3Dpol): pre-steady-state kinetic analysis of ribonucleotide incorporation in the presence of Mn2+

The use of Mn(2+) as the divalent cation cofactor in polymerase-catalyzed reactions instead of Mg(2+) often diminishes the stringency of substrate selection and incorporation fidelity. We have solved the complete kinetic mechanism for single nucleotide incorporation catalyzed by the RNA-dependent RNA polymerase from poliovirus (3D(pol)) in the presence of Mn(2+). The steps employed during a single cycle of nucleotide incorporation are identical to those employed in the presence of Mg(2+) and include a conformational-change step after nucleotide binding to achieve catalytic competence of the polymerase-primer/template-nucleotide complex. In the presence of Mn(2+), the conformational-change step is the primary determinant of enzyme specificity, phosphoryl transfer appears as the sole rate-limiting step for nucleotide incorporation, and the rate of phosphoryl transfer is the same for all nucleotides: correct and incorrect. Because phosphoryl transfer is the rate-limiting step in the presence of Mn(2+), it was possible to determine that the maximal phosphorothioate effect in this system is in the range of 8-11. This information permitted further interrogation of the nucleotide-selection process in the presence of Mg(2+), highlighting the capacity of this cation to permit the enzyme to use the phosphoryl-transfer step for nucleotide selection. The inability of Mn(2+) to support a reduction in the efficiency of phosphoryl transfer when incorrect substrates are employed is the primary explanation for the loss of fidelity observed in the presence of this cofactor. We propose that the conformational change involves reorientation of the triphosphate moiety of the bound nucleotide into a conformation that permits binding of the second metal ion required for catalysis. In the presence of Mg(2+), this conformation requires interactions with the enzyme that permit a reduction in catalytic efficiency to occur during an attempt to incorporate an incorrect nucleotide. Adventitious interactions in the cofactor-binding site with bound Mn(2+) may diminish fidelity by compensating for interaction losses used to modulate catalytic efficiency when incorrect nucleotides are bound in the presence of Mg(2+).     

Amino acid substitutions at conserved tyrosine 52 alter fidelity and bypass efficiency of human DNA polymerase eta

DNA polymerase eta (Pol eta) is a member of a new class of DNA polymerases that is able to copy DNA containing damaged nucleotides. These polymerases are highly error-prone during copying of unaltered DNA templates. We analyzed the relationship between bypass efficiency and fidelity of DNA synthesis by introducing substitutions for Tyr-52, a highly conserved amino acid, within the human DNA polymerase eta (hPol eta) finger domain. Most substitutions for Tyr-52 caused reduction in bypass of UV-associated damage, measured by the ability to rescue the viability of UV-sensitive yeast cells at a high UV dose. For most mutants, the reduction in bypass ability paralleled the reduction in polymerization activity. Interestingly, the hPol eta Y52E mutant exhibited a greater reduction in bypass efficiency than polymerization activity. The reduction in bypass efficiency was accompanied by an up to 11-fold increase in the incorporation of complementary nucleotides relative to non-complementary nucleotides. The fidelity of DNA synthesis, measured by copying a gapped M13 DNA template in vitro, was also enhanced as much as 15-fold; the enhancement resulted from a decrease in transitions, which were relatively frequent, and a large decrease in transversions. Our demonstration that an amino acid substitution within the active site enhances the fidelity of DNA synthesis by hPol eta, one of the most inaccurate of DNA polymerases, supports the hypothesis that even error-prone DNA polymerases function in base selection.     

Human DNA Polymerase ? Is Able to Efficiently Extend from Multiple Consecutive Ribonucleotides

Replicative DNA polymerases (Pols) help to maintain the high fidelity of replication in large part through their strong selectivity against mispaired deoxyribonucleotides. It has recently been demonstrated that several replicative Pols from yeast have surprisingly low selectivity for deoxyribonucleotides over their analogous ribonucleotides. In human cells, ribonucleotides are found in great abundance over deoxyribonucleotides, raising the possibility that ribonucleotides are incorporated in the human genome at significant levels during normal cellular functions. To address this possibility, the ability of human DNA polymerase ϵ to incorporate ribonucleotides was tested. At physiological concentrations of nucleotides, human Pol ϵ readily inserts and extends from incorporated ribonucleotides. Almost half of inserted ribonucleotides escape proofreading by 3′ → 5′ exonuclease-proficient Pol ϵ, indicating that ribonucleotide incorporation by Pol ϵ is likely a significant event in human cells. Human Pol ϵ is also efficient at extending from primers terminating in up to five consecutive ribonucleotides. This efficient extension appears to result from reduced exonuclease activity on primers containing consecutive 3′-terminal ribonucleotides. These biochemical properties suggest that Pol ϵ is a likely source of ribonucleotides in human genomic DNA.     

Terminal deoxynucleotidyl transferase indiscriminately incorporates ribonucleotides and deoxyribonucleotides.

Terminal deoxynucleotidyl transferase (TdT) catalyzes the condensation of deoxyribonucleotides on 3'-hydroxyl ends of DNA strands in a template-independent manner and adds N-regions to gene segment junctions during V(D)J recombination. Although TdT is able to incorporate a few ribonucleotides in vitro, TdT discrimination between ribo- and deoxyribonucleotides has never been studied. We found that TdT shows only a minor preference for incorporation of deoxyribonucleotides over ribonucleotides on DNA strands. However, incorporation of ribonucleotides alone or in the presence of deoxyribonucleotides generally leads to premature chain termination, reflecting an impeded accommodation of ribo- or mixed ribo/deoxyribonucleic acid substrates by TdT. An essential catalytic aspartate in TdT was identified, which is a first step toward understanding the apparent lack of sugar discrimination by TdT.     

AMP inhibition of pig kidney fructose-1,6-bisphosphatase.

Lys-112 and Tyr-113 in pig kidney fructose-1,6-bisphosphatase (FBPase) make direct interactions with AMP in the allosteric binding site. Both residues interact with the phosphate moiety of AMP while Tyr-113 also interacts with the 3'-hydroxyl of the ribose ring. The role of these two residues in AMP binding and allosteric inhibition was investigated. Site-specific mutagenesis was used to convert Lys-112 to glutamine (K112Q) and Tyr-113 to phenylalanine (Y113F). These amino acid substitutions result in small alterations in k(cat) and increases in K(m). However, both the K112Q and Y113F enzymes show alterations in Mg(2+) affinity and dramatic reductions in AMP affinity. For both mutant enzymes, the AMP concentration required to reduced the enzyme activity by one-half, [AMP](0.5), was increased more than a 1000-fold as compared to the wild-type enzyme. The K112Q enzyme also showed a 10-fold reduction in affinity for Mg(2+). Although the allosteric site is approximately 28 A from the metal binding sites, which comprise part of the active site, these site-specific mutations in the AMP site influence metal binding and suggest a direct connection between the allosteric and the active sites.     

Characterization of deoxyribozymes that synthesize branched RNA

We recently reported deoxyribozymes (DNA enzymes) that synthesize 2',5'-branched RNA. The in vitro-selected 9F7 and 9F21 deoxyribozymes mediate reaction of a branch-site adenosine 2'-hydroxyl on one RNA substrate with the 5'-triphosphate of another RNA substrate. Here we characterize these DNA enzymes with respect to their branch-forming activity. Both 9F7 and 9F21 are much more active with Mn(2+) than with Mg(2+). The K(d,app)(Mg(2+)) > 400 mM but K(d,app)(Mn(2+)) approximately 20-50 mM, and the ligation rates k(obs) are orders of magnitude faster with Mn(2+) than with Mg(2+) (e.g., 9F7 approximately 0.3 min(-1) with 20 mM Mn(2+) versus 0.4 h(-1) with 100 mM Mg(2+), both at pH 7.5 and 37 degrees C). Of the other tested transition metal ions Zn(2+), Ni(2+), Co(2+), and Cd(2+), only Co(2+) supports a trace amount of activity. 9F7 is more tolerant than 9F21 of varying the RNA substrate sequences. For the RNA substrate that donates the adenosine 2'-hydroxyl, 9F7 requires YUA, where Y = pyrimidine and A is the branch site. The 3'-tail emerging from the branch-site A may have indefinite length, but it must be at least one nucleotide long for high activity. The 5'-triphosphate RNA substrate requires several additional nucleotides with varying sequence requirements (5'-pppGRMWR). Outside of these regions that flank the ligation site, 9F7 and 9F21 tolerate any RNA substrate sequences via Watson-Crick covariation of the DNA binding arms that interact directly with the substrates. 9F7 provides a high yield of 2',5'-branched RNA on the preparative nanomole scale. The ligation reaction is effectively irreversible; the pyrophosphate leaving group in the ligation reaction does not induce 2',5'-cleavage, and pyrophosphate does not significantly inhibit ligation except in 1000-fold excess. Deleting a specific nucleotide in one of the DNA binding arms near the ligation junction enhances ligation activity, suggesting an interesting structure near this region of the deoxyribozyme-substrate complex. These data support the utility of deoxyribozymes in creating synthetic 2',5'-branched RNAs for investigations of group II intron splicing, debranching enzyme (Dbr) activity, and other biochemical reactions.     

On the fidelity of DNA replication. Studies with human placenta DNA polymerases.

The fidelity of DNA synthesis with purified DNA polymerase alpha and beta from human placenta has been studied. With poly[d(A-T)] as the template-primer and Mg2+ as the metal activator, DNA polymerase alpha incorporates 1 mol of dGMP for every 6,000 to 12,000 mol of complementary nucleotides polymerized. Under the same conditions, DNA polymerase beta is more accurate, the error rate being 1/20,000 to 1/60,000. This greater accuracy of DNA polymerase beta is observed with a variety of homopolymer templates. With both enzymes, substitution of Mg2+ with activating concentrations of Mn2+ or Co2+ enhances the frequency of misincorporation. At greater than activating concentrations of Mn2+ and Co2+, there is an inhibition of complementary nucleotide incorporation, further increasing the frequency of misincorporation. Nearest neighbor analysis of the products synthesized with both enzymes indicates that the noncomplementary nucleotides are incorporated predominantly as single base substitutions. The greater accuracy of DNA polymerase beta over DNA polymerase alpha should be considered in relationship to their possible roles in DNA replication and repair.     

Mutations in the R2 subunit of ribonucleotide reductase that confer resistance to hydroxyurea

Ribonucleotide reductase is an essential enzyme that catalyzes the reduction of ribonucleotides to deoxyribonucleotides for use in DNA synthesis. Ribonucleotide reductase from Escherichia coli consists of two subunits, R1 and R2. The R2 subunit contains an unusually stable radical at tyrosine 122 that participates in catalysis. Buried deep within a hydrophobic pocket, the radical is inaccessible to solvent although subject to inactivation by radical scavengers. One such scavenger, hydroxyurea, is a highly specific inhibitor of ribonucleotide reductase and therefore of DNA synthesis; thus it is an important anticancer and antiviral agent. The mechanism of radical access remains to be established; however, small molecules may be able to access Tyr-122 directly via channels from the surface of the protein. We used random oligonucleotide mutagenesis to create a library of 200,000 R2 mutants containing random substitutions at five contiguous residues (Ile-74, Ser-75, Asn-76, Leu-77, Lys-78) that partially comprise one side of a channel where Tyr-122 is visible from the protein surface. We subjected this library to increasing concentrations of hydroxyurea and identified mutants that enhance survival more than 1000-fold over wild-type R2 at high drug concentrations. Repetitive selections yielded S75T as the predominant R2 mutant in our library. Purified S75TR2 exhibits a radical half-life that is 50% greater than wild-type R2 in the presence of hydroxyurea. These data represent the first demonstration of R2 protein mutants in E. coli that are highly resistant to hydroxyurea; elucidation of their mechanism of resistance may provide valuable insight into the development of more effective inhibitors.     

Structural mechanism of ribonucleotide discrimination by a Y-family DNA polymerase

The ability of DNA polymerases to differentiate between ribonucleotides and deoxribonucleotides is fundamental to the accurate replication and maintenance of an organism's genome. The active sites of Y-family DNA polymerases are highly solvent accessible, yet these enzymes still maintain a high selectivity towards deoxyribonucleotides. Here, we biochemically demonstrate that a single active-site mutation (Y12A) in Dpo4, a model Y-family DNA polymerase, causes both a dramatic loss of ribonucleotide discrimination and a decrease in nucleotide incorporation efficiency. We also determined two ternary crystal structures of the Dpo4 Y12A mutant incorporating either dATP or ATP nucleotides opposite a template dT base. Interestingly, both dATP and ATP were hydrolyzed to dADP and ADP, respectively. In addition, the dADP and ADP molecules adopt a similar conformation and position at the polymerase active site to a ddADP molecule in the ternary crystal structure of wild-type Dpo4. The Y12A mutant loses stacking interactions with the deoxyribose of dNTP, which destabilizes the binding of incoming nucleotides. The mutation also opens a space to accommodate the 2′-OH group of the ribose of NTP in the polymerase active site. The structural change leads to the reduction in deoxynucleotide incorporation efficiency and allows ribonucleotide incorporation.