Single-molecule live-cell imaging reveals RecB-dependent function of DNA polymerase IV in double strand break repair.

Several functions have been proposed for the Escherichia coli DNA polymerase IV (pol IV). Although much research has focused on a potential role for pol IV in assisting pol III replisomes in the bypass of lesions, pol IV is rarely found at the replication fork in vivo. Pol IV is expressed at increased levels in E. coli cells exposed to exogenous DNA damaging agents, including many commonly used antibiotics. Here we present live-cell single-molecule microscopy measurements indicating that double-strand breaks induced by antibiotics strongly stimulate pol IV activity. Exposure to the antibiotics ciprofloxacin and trimethoprim leads to the formation of double strand breaks in E. coli cells. RecA and pol IV foci increase after treatment and exhibit strong colocalization. The induction of the SOS response, the appearance of RecA foci, the appearance of pol IV foci and RecA-pol IV colocalization are all dependent on RecB function. The positioning of pol IV foci likely reflects a physical interaction with the RecA* nucleoprotein filaments that has been detected previously in vitro. Our observations provide an in vivo substantiation of a direct role for pol IV in double strand break repair in cells treated with double strand break-inducing antibiotics.

An AP endonuclease 1-DNA polymerase beta complex: theoretical prediction of interacting surfaces.

Abasic (AP) sites in DNA arise through both endogenous and exogenous mechanisms. Since AP sites can prevent replication and transcription, the cell contains systems for their identification and repair. AP endonuclease (APEX1) cleaves the phosphodiester backbone 5' to the AP site. The cleavage, a key step in the base excision repair pathway, is followed by nucleotide insertion and removal of the downstream deoxyribose moiety, performed most often by DNA polymerase beta (pol-beta). While yeast two-hybrid studies and electrophoretic mobility shift assays provide evidence for interaction of APEX1 and pol-beta, the specifics remain obscure. We describe a theoretical study designed to predict detailed interacting surfaces between APEX1 and pol-beta based on published co-crystal structures of each enzyme bound to DNA. Several potentially interacting complexes were identified by sliding the protein molecules along DNA: two with pol-beta located downstream of APEX1 (3' to the damaged site) and three with pol-beta located upstream of APEX1 (5' to the damaged site). Molecular dynamics (MD) simulations, ensuring geometrical complementarity of interfaces, enabled us to predict interacting residues and calculate binding energies, which in two cases were sufficient (approximately -10.0 kcal/mol) to form a stable complex and in one case a weakly interacting complex. Analysis of interface behavior during MD simulation and visual inspection of interfaces allowed us to conclude that complexes with pol-beta at the 3'-side of APEX1 are those most likely to occur in vivo. Additional multiple sequence analyses of APEX1 and pol-beta in related organisms identified a set of correlated mutations of specific residues at the predicted interfaces. Based on these results, we propose that pol-beta in the open or closed conformation interacts and makes a stable interface with APEX1 bound to a cleaved abasic site on the 3' side. The method described here can be used for analysis in any DNA-metabolizing pathway where weak interactions are the principal mode of cross-talk among participants and co-crystal structures of the individual components are available.

Differing conformational pathways before and after chemistry for insertion of dATP versus dCTP opposite 8-oxoG in DNA polymerase beta.

To elucidate how human DNA polymerase beta (pol beta) discriminates dATP from dCTP when processing 8-oxoguanine (8-oxoG), we analyze a series of dynamics simulations before and after the chemical step with dATP and dCTP opposite an 8-oxoG template started from partially open complexes of pol beta. Analyses reveal that the thumb closing of pol beta before chemistry is hampered when the incorrect nucleotide dATP is bound opposite 8-oxoG; the unfavorable interaction between active-site residue Tyr(271) and dATP that causes an anti to syn change in the 8-oxoG (syn):dATP complex explains this slow motion, in contrast to the 8-oxoG (anti):dCTP system. Such differences in conformational pathways before chemistry for mismatched versus matched complexes help explain the preference for correct insertion across 8-oxoG by pol beta. Together with reference studies with a nonlesioned G template, we propose that 8-oxoG leads to lower efficiency in pol beta's incorporation of dCTP compared with G by affecting the requisite active-site geometry for the chemical reaction before chemistry. Furthermore, because the active site is far from ready for the chemical reaction after partial closing or even full thumb closing, we suggest that pol beta is tightly controlled not only by the chemical step but also by a closely related requirement for subtle active-site rearrangements after thumb movement but before chemistry.

Correct and incorrect nucleotide incorporation pathways in DNA polymerase beta.

Tracking the structural and energetic changes in the pathways of DNA replication and repair is central to the understanding of these important processes. Here we report favorable mechanisms of the polymerase-catalyzed phosphoryl transfer reactions corresponding to correct and incorrect nucleotide incorporations in the DNA by using a novel protocol involving energy minimizations, dynamics simulations, quasi-harmonic free energy calculations, and mixed quantum mechanics/molecular mechanics dynamics simulations. Though the pathway proposed may not be unique and invites variations, geometric and energetic arguments support the series of transient intermediates in the phosphoryl transfer pathways uncovered here for both the G:C and G:A systems involving a Grotthuss hopping mechanism of proton transfer between water molecules and the three conserved aspartate residues in pol beta's active-site. In the G:C system, the rate-limiting step is the initial proton hop with a free energy of activation of at least 17 kcal/mol, which corresponds closely to measured k(pol) values. Fidelity discrimination in pol beta can be explained by a significant loss of stability of the closed ternary complex of the enzyme in the G:A system and much higher activation energy of the initial step of nucleophilic attack, namely deprotonation of terminal DNA primer O3'H group. Thus, subtle differences in the enzyme active-site between matched and mismatched base pairs generate significant differences in catalytic performance.

Sequential side-chain residue motions transform the binary into the ternary state of DNA polymerase lambda.

The nature of conformational transitions in DNA polymerase lambda (pol lambda), a low-fidelity DNA repair enzyme in the X-family that fills short nucleotide gaps, is investigated. Specifically, to determine whether pol lambda has an induced-fit mechanism and open-to-closed transition before chemistry, we analyze a series of molecular dynamics simulations from both the binary and ternary states before chemistry, with and without the incoming nucleotide, with and without the catalytic Mg(2+) ion in the active site, and with alterations in active site residues Ile(492) and Arg(517). Though flips occurred for several side-chain residues (Ile(492), Tyr(505), Phe(506)) in the active site toward the binary (inactive) conformation and partial DNA motion toward the binary position occurred without the incoming nucleotide, large-scale subdomain motions were not observed in any trajectory from the ternary complex regardless of the presence of the catalytic ion. Simulations from the binary state with incoming nucleotide exhibit more thumb subdomain motion, particularly in the loop containing beta-strand 8 in the thumb, but closing occurred only in the Ile(492)Ala mutant trajectory started from the binary state with incoming nucleotide and both ions. Further connections between active site residues and the DNA position are also revealed through our Ile(492)Ala and Arg(517)Ala mutant studies. Our combined studies suggest that while pol lambda does not demonstrate large-scale subdomain movements as DNA polymerase beta (pol beta), significant DNA motion exists, and there are sequential subtle side chain and other motions-associated with Arg(514), Arg(517), Ile(492), Phe(506), Tyr(505), the DNA, and again Arg(514) and Arg(517)-all coupled to active site divalent ions and the DNA motion. Collectively, these motions transform pol lambda to the chemistry-competent state. Significantly, analogs of these residues in pol beta (Lys(280), Arg(283), Arg(258), Phe(272), and Tyr(271), respectively) have demonstrated roles in determining enzyme efficiency and fidelity. As proposed for pol beta, motions of these residues may serve as gate-keepers by controlling the evolution of the reaction pathway before the chemical reaction.