DNA polymerase I of Mycobacterium tuberculosis: functional role of a conserved aspartate in the hinge joining the M and N helices

The Expression of Human DNA Helicase B Is Affected by G-Quadruplexes in the Promoter

G-Quadruplexes are secondary structures that can form in guanine-rich DNA and RNA that have been implicated in regulating multiple biological processes, including transcription. G-Quadruplex-forming sequences are prevalent in promoter regions of proto-oncogenes and DNA repair proteins. HELB is a human helicase involved in DNA replication and repair with 12 runs of three to four guanines in the proximal promoter. This sequence has the potential to form three canonical three-tetrad G-quadruplexes. Our results show that although all three G-quadruplexes can form, a structure containing two noncanonical G-quadruplexes with longer loops containing runs of three to four guanines is the most prevalent. These HELB G-quadruplexes are stable under physiological conditions. In cells, stabilization of the G-quadruplexes results in a decrease in the level of HELB expression, suggesting that the G-quadruplexes in the HELB promoter serve as transcriptional repressors.

M. tuberculosis class II apurinic/ apyrimidinic-endonuclease/3'-5' exonuclease (XthA) engages with NAD+-dependent DNA ligase A (LigA) to counter futile cleavage and ligation cycles in base excision repair

Class-II AP-endonuclease (XthA) and NAD⁺-dependent DNA ligase (LigA) are involved in initial and terminal stages of bacterial DNA base excision repair (BER), respectively. XthA acts on abasic sites of damaged DNA to create nicks with 3′OH and 5′-deoxyribose phosphate (5′-dRP) moieties. Co-immunoprecipitation using mycobacterial cell-lysate, identified MtbLigA-MtbXthA complex formation. Pull-down experiments using purified wild-type, and domain-deleted MtbLigA mutants show that LigA-XthA interactions are mediated by the BRCT-domain of LigA. Small-Angle-X-ray scattering, ¹⁵N/¹H-HSQC chemical shift perturbation experiments and mutational analysis identified the BRCT-domain region that interacts with a novel ₁₀₄DGQPSWSGKP₁₁₃ motif on XthA for complex-formation. Isothermal-titration calorimetry experiments show that a synthetic peptide with this sequence interacts with MtbLigA and disrupts XthA–LigA interactions. In vitro assays involving DNA substrate and product analogs show that LigA can efficiently reseal 3′OH and 5′dRP DNA termini created by XthA at abasic sites. Assays and SAXS experiments performed in the presence and absence of DNA, show that XthA inhibits LigA by specifically engaging with the latter's BRCT-domain to prevent it from encircling substrate DNA. Overall, the study suggests a coordinating function for XthA whereby it engages initially with LigA to prevent the undesirable consequences of futile cleavage and ligation cycles that might derail bacterial BER.

Mycobacterial DNA polymerase I: activities and crystal structures of the POL domain as apoenzyme and in complex with a DNA primer-template and of the full-length FEN/EXO-POL enzyme

Mycobacterial Pol1 is a bifunctional enzyme composed of an N-terminal DNA flap endonuclease/5' exonuclease domain (FEN/EXO) and a C-terminal DNA polymerase domain (POL). Here we document additional functions of Pol1: FEN activity on the flap RNA strand of an RNA:DNA hybrid and reverse transcriptase activity on a DNA-primed RNA template. We report crystal structures of the POL domain, as apoenzyme and as ternary complex with 3'-dideoxy-terminated DNA primer-template and dNTP. The thumb, palm, and fingers subdomains of POL form an extensive interface with the primer-template and the triphosphate of the incoming dNTP. Progression from an open conformation of the apoenzyme to a nearly closed conformation of the ternary complex entails a disordered-to-ordered transition of several segments of the thumb and fingers modules and an inward motion of the fingers subdomain-especially the O helix-to engage the primer-template and dNTP triphosphate. Distinctive structural features of mycobacterial Pol1 POL include a manganese binding site in the vestigial 3' exonuclease subdomain and a non-catalytic water-bridged magnesium complex at the protein-DNA interface. We report a crystal structure of the bifunctional FEN/EXO-POL apoenzyme that reveals the positions of two active site metals in the FEN/EXO domain.

A Small-Molecule Inhibitor of Human DNA Polymerase η Potentiates the Effects of Cisplatin in Tumor Cells

Translesion DNA synthesis (TLS) performed by human DNA polymerase eta (hpol η) allows tolerance of damage from cis-diamminedichloroplatinum(II) (CDDP or cisplatin). We have developed hpol η inhibitors derived from N-aryl-substituted indole barbituric acid (IBA), indole thiobarbituric acid (ITBA), and indole quinuclidine scaffolds and identified 5-((5-chloro-1-(naphthalen-2-ylmethyl)-1H-indol-3-yl)methylene)-2-thioxodihydropyrimidine-4,6(1H,5H)-dione (PNR-7-02), an ITBA derivative that inhibited hpol η activity with an IC₅₀ value of 8 μM and exhibited 5-10-fold specificity for hpol η over replicative pols. We conclude from kinetic analyses, chemical footprinting assays, and molecular docking that PNR-7-02 binds to a site on the little finger domain and interferes with the proper orientation of template DNA to inhibit hpol η. A synergistic increase in CDDP toxicity was observed in hpol η-proficient cells co-treated with PNR-7-02 (combination index values = 0.4-0.6). Increased γH2AX formation accompanied treatment of hpol η-proficient cells with CDDP and PNR-7-02. Importantly, PNR-7-02 did not impact the effect of CDDP on cell viability or γH2AX in hpol η-deficient cells. In summary, we observed hpol η-dependent effects on DNA damage/replication stress and sensitivity to CDDP in cells treated with PNR-7-02. The ability to employ a small-molecule inhibitor of hpol η to improve the cytotoxic effect of CDDP may aid in the development of more effective chemotherapeutic strategies.

Mycobacterium smegmatis DinB2 misincorporates deoxyribonucleotides and ribonucleotides during templated synthesis and lesion bypass

Mycobacterium smegmatis DinB2 is the founder of a clade of Y-family DNA polymerase that is naturally adept at utilizing rNTPs or dNTPs as substrates. Here we investigate the fidelity and lesion bypass capacity of DinB2. We report that DinB2 is an unfaithful DNA and RNA polymerase with a distinctive signature for misincorporation of dNMPs, rNMPs and oxoguanine nucleotides during templated synthesis in vitro. DinB2 has a broader mutagenic spectrum with manganese than magnesium, though low ratios of manganese to magnesium suffice to switch DinB2 to its more mutagenic mode. DinB2 discrimination against incorrect dNTPs in magnesium is primarily at the level of substrate binding affinity, rather than k_pol. DinB2 can incorporate any dNMP or rNMP opposite oxo-dG in the template strand with manganese as cofactor, with a kinetic preference for synthesis of an A:oxo-dG Hoogsteen pair. With magnesium, DinB2 is adept at synthesizing A:oxo-dG or C:oxo-dG pairs. DinB2 effectively incorporates deoxyribonucleotides, but not ribonucleotides, opposite an abasic site, with kinetic preference for dATP as the substrate. We speculate that DinB2 might contribute to mycobacterial mutagenesis, oxidative stress and quiescence, and discuss the genetic challenges to linking the polymerase biochemistry to an in vivo phenotype.

A new DNA polymerase I from Geobacillus caldoxylosilyticus TK4: cloning, characterization, and mutational analysis of two aromatic residues

DNA polymerase I gene was cloned and sequenced from the thermophilic bacterium Geobacillus caldoxylosilyticus TK4. The gene is 2,634 bp long and encodes a protein of 878 amino acids in length. The enzyme has a molecular mass of 99 kDa and shows sequence homology with DNA polymerase I from Bacillus species (89% identity). The gene was overexpressed in Escherichia coli and the purified enzyme was biochemically characterized. It has all of the primary structural elements necessary for DNA polymerase and 5' --> 3' exonuclease activity, but lacks the motifs required for 3' --> 5' exonuclease activity. 5' nuclease and 3' --> 5' exonuclease assays confirmed that Gca polymerase I has a double-stranded DNA-dependent 5' --> 3' nuclease activity but no 3' --> 5' exonuclease activity. Its specific activity was observed to be 495,000 U/mg protein, and K (D) (DNA) , K (D) (dNTP) , and K (pol) were found to be 0.19 nM, 22.64 microM, and 24.99 nucleotides(-1), respectively. The enzyme showed significant reverse-transcriptase activity (RT) with Mn(2+), but very little RT activity with Mg(2+). Its error rate was found to be 2.5 x 10(-5) which is comparable to that of the previously reported error rate for the E. coli DNA polymerase I. Two aromatic residues required for dideoxyribonucleotide triphosphate sensitivity (F712Y) and strand displacement activity (Y721F) were identified.

Mechanistic insights into replication across from bulky DNA adducts: a mutant polymerase I allows an N-acetyl-2-aminofluorene adduct to be accommodated during DNA synthesis

The molecular mechanism that allows a polymerase to incorporate a nucleotide opposite a DNA lesion is not well-understood. One way to study this process is to characterize the altered molecular interactions that occur between the polymerase and a damaged template. Prior studies have determined the polymerase-template dissociation constants and used kinetic analyses and a protease digestion assay to measure the effect of various DNA adducts positioned in the active site of Klenow fragment (KF). Here, a mutator polymerase was used in which the tyrosine at position 766 of the KF has been replaced with a serine. This position is located at the junction of the fingers and palm domain and is thought to be involved in maintaining the active site geometry. The primer-template was modified with N-acetyl-2-aminofluorene (AAF), a well-studied carcinogenic adduct. The mutant polymerase displayed a significant increase in the rate of incorporation of the correct nucleotide opposite the adduct but was much less prone to incorporate an incorrect nucleotide relative to the wild-type polymerase. Both the wild-type and the mutant polymerase bound much more tightly to the AAF-modified primer-template; however, unlike the wild-type polymerase, the binding strength of the mutant was influenced by the presence of a dNTP. Moreover, the mutant polymerase was able to undergo a dNTP-induced conformational change when the AAF adduct was positioned in the active site, while the wild-type enzyme could not. A model is proposed in which the looser active site of the mutant is able to better accommodate the AAF adduct.

Presence of 18-A long hydrogen bond track in the active site of Escherichia coli DNA polymerase I (Klenow fragment). Its requirement in the stabilization of enzyme-template-primer complex

The analysis of the active site region in the crystal structures of template-primer-bound KlenTaq (Klenow fragment equivalent of Thermus aquaticus polymerase I) shows the presence of an approximately 18-A long H-bonding track contributed by the Klenow fragment equivalent of Asn(845), Gln(849), Arg(668), His(881), and Gln(677). Its location is nearly diagonal to the helical axis of the template-primer. Four base pairs in the double stranded region proximal to 3' OH end of the primer terminus appear to interact with individual amino acid components of the track through either the bases or sugar moieties. To understand the functional significance of this H-bonding network in the catalytic function of Klenow fragment (KF), we generated N845A, N845Q, Q849A, Q849N, R668A, H881A, H881V, Q677A, and Q677N mutant species by site-directed mutagenesis. All of the mutant enzymes showed low catalytic activity. The kinetic analysis of mutant enzymes indicated that K(m)(.dNTP) was not significantly altered, but K(D)(.DNA) was significantly increased. Thus the mutant enzymes of the H-bonding track residues had decreased affinity for template-primer, although the extent of decrease was variable. Most interestingly, even the reduced binding of TP by the mutant enzymes occurs in the nonproductive mode. These results demonstrate that an H-bonding track is necessary for the binding of template-primer in the catalytically competent orientation in the pol I family of enzymes. The examination of the interactive environment of individual residues of this track further clarifies the mode of cooperation in various functional domains of pol I.

Lysine 152 of MuLV reverse transcriptase is required for the integrity of the active site

Comparison of the three-dimensional structure of the active sites of MuLV and HIV-1 reverse transcriptases shows the presence of a lysine residue (K152) in the substrate-binding region in MuLV RT, while its equivalent position in HIV-1 RT is occupied by a glycine (G112). To investigate the role of K152 in the mechanism of the polymerase reaction catalyzed by MuLV RT, four mutant RTs, namely, K152A, K152R, K152E, and K152G, were generated and biochemically characterized. All muteins exhibited reduced polymerase activity on both RNA and DNA template-primers with K152E being the most defective. The template-primer binding affinity and the processivity of DNA synthesis, however, remained unchanged. The steady-state kinetic characterization showed little change in K(m.dNTP) (except for that of K152E) and an approximately 3-10-fold decrease in k(cat) depending upon the template-primer and mutational substitutions. The ddNTP resistance patterns were unchanged for all muteins, suggesting no participation of K152 in ddNTP recognition. The ability of individual muteins to add dNTP on the covalently cross-linked enzyme-template-primer complex was significantly decreased. These results together with the analysis of the ion pairs in the catalytic apparatus of MuLV RT suggest that K152 participates in maintaining the integrity of the active site of MuLV RT. Examination of the prepolymerase ternary complex formation showed that neither the wild type nor any of the K152 muteins of MuLV RT are capable of forming stable ternary complexes. This property is in contrast to that of HIV-1 RT, which readily forms stable ternary complexes under similar conditions. These results further indicate that the catalytic mechanism of MuLV RT is significantly different from that of HIV-1 RT, despite the presence of a number of conserved motifs and amino acid residues.

Participation of active-site carboxylates of Escherichia coli DNA polymerase I (Klenow fragment) in the formation of a prepolymerase ternary complex

We have investigated the roles of four active-site carboxylates in the formation of a prepolymerase ternary complex of Escherichia coli DNA polymerase I (Klenow fragment), containing the template-primer and dNTP. The analysis of nine mutant enzymes with conserved and nonconserved substitutions of Asp(705), Glu(710), Asp(882), and Glu(883) clearly shows that both catalytically essential aspartates, Asp(705) and Asp(882), are required for the formation of a stable ternary complex. Of the two glutamates, only Glu(710) is required for ternary complex formation, while Glu(883) does not participate in this process. This investigation also reveals two interesting properties of the Klenow fragment with regard to enzyme-template-primer binary and enzyme-template-primer-dNTP ternary complex formation. These are (a) the significant resistance of enzyme-template-primer-dNTP ternary complexes to the addition of high salt or template-primer challenge and (b) the ability of the Klenow fragment to form ternary complexes in the presence of noncatalytic divalent cations such as Ca(2+), Co(2+), Ni(2+), and Zn(2+).