DNA polymerase III of Gram-positive eubacteria is a zinc metalloprotein conserving an essential finger-like domain

Identification of potential drug targets by subtractive genome analysis of Escherichia coli O157:H7: an in silico approach

Bacterial enteric infections resulting in diarrhea, dysentery, or enteric fever constitute a huge public health problem, with more than a billion episodes of disease annually in developing and developed countries. In this study, the deadly agent of hemorrhagic diarrhea and hemolytic uremic syndrome, Escherichia coli O157:H7 was investigated with extensive computational approaches aimed at identifying novel and broad-spectrum antibiotic targets. A systematic in silico workflow consisting of comparative genomics, metabolic pathways analysis, and additional drug prioritizing parameters was used to identify novel drug targets that were essential for the pathogen’s survival but absent in its human host. Comparative genomic analysis of Kyoto Encyclopedia of Genes and Genomes annotated metabolic pathways identified 350 putative target proteins in E. coli O157:H7 which showed no similarity to human proteins. Further bio-informatic approaches including prediction of subcellular localization, calculation of molecular weight, and web-based investigation of 3D structural characteristics greatly aided in filtering the potential drug targets from 350 to 120. Ultimately, 44 non-homologous essential proteins of E. coli O157:H7 were prioritized and proved to have the eligibility to become novel broad-spectrum antibiotic targets and DNA polymerase III alpha (dnaE) was the top-ranked among these targets. Moreover, druggability of each of the identified drug targets was evaluated by the DrugBank database. In addition, 3D structure of the dnaE was modeled and explored further for in silico docking with ligands having potential druggability. Finally, we confirmed that the compounds N-coeleneterazine and N-(1,4-dihydro-5H-tetrazol-5-ylidene)-9-oxo-9H-xanthene-2-sulfon-amide were the most suitable ligands of dnaE and hence proposed as the potential inhibitors of this target protein. The results of this study could facilitate the discovery and release of new and effective drugs against E. coli O157:H7 and other deadly human bacterial pathogens.

In silico screening for novel inhibitors of DNA polymerase III alpha subunit of Mycobacterium tuberculosis (MtbDnaE2, H37Rv)

Tuberculosis, a pandemic disease is caused by Mycobacterium tuberculosis (Mtb). DNA polymerase III encoded by DnaE2 of Mtb is specifically required for its survival in vivo, and hence can be considered to be a potential drug target. Amino acid sequence analysis of the MtbDnaE2 and its human counterpart does not show any significant similarity. Therefore, a 3D model of the MtbDnaE2 was generated using Modeller 9v10 with the template structure of E. Coli DNA polymerase III alpha subunit (2HNH_A). The generated models were validated using a number of programmes such as RAMPAGE/PROCHECK, VERIFY_3D, and ProSA. MtbDnaE2 has few conserved residues and four conserved domains similar to that present in DNA polymerase III of E. coli. In silico screening was performed with bioactive anti-tuberculosis compounds and 6-AU (a known inhibitor of DNA polymerase III of Bacillus subtilis) and its analogues against the modeled MtbDnaE2 structure. Docking was performed using GOLD v5.2 software which resulted in the identification of top ten compounds with high GOLD fitness scores and binding affinity (X-Score). To further evaluate the efficacy of these compounds, in silico ADMET analysis was performed using MedChem Designer v3. Given their high binding affinity to the targeted MtbDnaE2, which is essential for DNA replication in the Mtb and good ADMET properties, these compounds are promising candidates for further evaluation and development as anti-tubercular agents.

DNA replicases from a bacterial perspective

Bacterial replicases are complex, tripartite replicative machines. They contain a polymerase, polymerase III (Pol III), a β₂ processivity factor, and a DnaX complex ATPase that loads β₂ onto DNA and chaperones Pol III onto the newly loaded β₂. Bacterial replicases are highly processive, yet cycle rapidly during Okazaki fragment synthesis in a regulated way. Many bacteria encode both a full-length τ and a shorter γ form of DnaX by a variety of mechanisms. γ appears to be uniquely placed in a single position relative to two τ protomers in a pentameric ring. The polymerase catalytic subunit of Pol III, α, contains a PHP domain that not only binds to a prototypical ε Mg²⁺-dependent exonuclease, but also contains a second Zn²⁺-dependent proofreading exonuclease, at least in some bacteria. This review focuses on a critical evaluation of recent literature and concepts pertaining to the above issues and suggests specific areas that require further investigation.

Adaptations to submarine hydrothermal environments exemplified by the genome of Nautilia profundicola

Submarine hydrothermal vents are model systems for the Archaean Earth environment, and some sites maintain conditions that may have favored the formation and evolution of cellular life. Vents are typified by rapid fluctuations in temperature and redox potential that impose a strong selective pressure on resident microbial communities. Nautilia profundicola strain Am-H is a moderately thermophilic, deeply-branching Epsilonproteobacterium found free-living at hydrothermal vents and is a member of the microbial mass on the dorsal surface of vent polychaete, Alvinella pompejana. Analysis of the 1.7-Mbp genome of N. profundicola uncovered adaptations to the vent environment--some unique and some shared with other Epsilonproteobacterial genomes. The major findings included: (1) a diverse suite of hydrogenases coupled to a relatively simple electron transport chain, (2) numerous stress response systems, (3) a novel predicted nitrate assimilation pathway with hydroxylamine as a key intermediate, and (4) a gene (rgy) encoding the hallmark protein for hyperthermophilic growth, reverse gyrase. Additional experiments indicated that expression of rgy in strain Am-H was induced over 100-fold with a 20 degrees C increase above the optimal growth temperature of this bacterium and that closely related rgy genes are present and expressed in bacterial communities residing in geographically distinct thermophilic environments. N. profundicola, therefore, is a model Epsilonproteobacterium that contains all the genes necessary for life in the extreme conditions widely believed to reflect those in the Archaean biosphere--anaerobic, sulfur, H2- and CO2-rich, with fluctuating redox potentials and temperatures. In addition, reverse gyrase appears to be an important and common adaptation for mesophiles and moderate thermophiles that inhabit ecological niches characterized by rapid and frequent temperature fluctuations and, as such, can no longer be considered a unique feature of hyperthermophiles.

Structure of PolC reveals unique DNA binding and fidelity determinants

PolC is the polymerase responsible for genome duplication in many Gram-positive bacteria and represents an attractive target for antibacterial development. We have determined the 2.4-A resolution crystal structure of Geobacillus kaustophilus PolC in a ternary complex with DNA and dGTP. The structure reveals nascent base pair interactions that lead to highly accurate nucleotide incorporation. A unique beta-strand motif in the PolC thumb domain contacts the minor groove, allowing replication errors to be sensed up to 8 nt upstream of the active site. PolC exhibits the potential for large-scale conformational flexibility, which could encompass the catalytic residues. The structure suggests a mechanism by which the active site can communicate with the rest of the replisome to trigger proofreading after nucleotide misincorporation, leading to an integrated model for controlling the dynamic switch between replicative and repair polymerases. This ternary complex of a cellular replicative polymerase affords insights into polymerase fidelity, evolution, and structural diversity.

A method to assay inhibitors of DNA polymerase IIIC activity

The need for new drugs to treat infections caused by antibiotic-resistant bacterial strains has prompted many studies to identify novel targets in pathogenic bacteria. Among the three DNA polymerases expressed by bacteria, one of these, designated pol III, is responsible for DNA replication and growth of bacteria and, therefore, warrants consideration as a drug target. However, the pol III enzymes of Gram-positive and Gram-negative species are quite different, and the Gram-positive enzyme pol IIIC has been more extensively studied as a drug target than the Gram-negative enzyme pol IIIE.DNA polymerases are unique enzymes with respect to the five substrates (four dNTPs, one of which is radiolabeled, and primer:template DNA) that they typically utilize. Variations of the assay, e.g., by leaving out one dNTP but allowing measurable incorporation of the remaining substrates, or use of homopolymer primer:templates, may be used to simplify the assay or to obtain mechanistic information about inhibitors. Use of gel analysis of primer extension assays can also be applied to study alternate substrates of DNA polymerases. Methods to isolate pol IIIC from Gram-positive bacterial cells and to clone and express the polC gene are described in this chapter. In addition, the assay conditions commonly used to identify and study the mechanism of inhibitors of pol IIIC are emphasized.

Conserved interactions in the Staphylococcus aureus DNA PolC chromosome replication machine

The PolC holoenzyme replicase of the Gram-positive Staphylococcus aureus pathogen has been reconstituted from pure subunits. We compared individual S. aureus replicase subunits with subunits from the Gram-negative Escherichia coli polymerase III holoenzyme for activity and interchangeability. The central organizing subunit, tau, is smaller than its Gram-negative homolog, yet retains the ability to bind single-stranded DNA and contains DNA-stimulated ATPase activity comparable with E. coli tau. S. aureus tau also stimulates PolC, although they do not form as stabile a complex as E. coli polymerase III.tau. We demonstrate that the extreme C-terminal residues of PolC bind to and function with beta clamps from different bacteria. Hence, this polymerase-clamp interaction is highly conserved. Additionally, the S. aureus delta wrench of the clamp loader binds to E. coli beta. The S. aureus clamp loader is even capable of loading E. coli and Streptococcus pyogenes beta clamps onto DNA. Interestingly, S. aureus PolC lacks functionality with heterologous beta clamps when they are loaded onto DNA by the S. aureus clamp loader, suggesting that the S. aureus clamp loader may have difficulty ejecting from heterologous clamps. Nevertheless, these overall findings underscore the conservation in structure and function of Gram-positive and Gram-negative replicases despite >1 billion years of evolutionary distance between them.

DNA polymerase III of Enterococcus faecalis: expression and characterization of recombinant enzymes encoded by the polC and dnaE genes

Enterococcus faecalis (Ef) dnaE and polC, the respective genes encoding the DNA replication-specific DNA polymerase III E and DNA polymerase III C, were cloned and engineered for expression in Escherichia coli as hexahistidine (his6)-tagged recombinant proteins. Each gene expressed a catalytically active DNA polymerase of the expected molecular weight. The recombinant polymerases were purified and each was characterized with respect to catalytic properties, inhibitor sensitivity, and recognition by specific antibody raised against the corresponding DNA polymerase III of the model Gram-positive (Gr(+)) organism, Bacillus subtilis (Bs). In conclusion, the properties of each Enterococcus polymerase enzymes were similar to those of the respective B. subtilis enzymes.

Low frequencies of resistance among Staphylococcus and Enterococcus species to the bactericidal DNA polymerase inhibitor N(3)-hydroxybutyl 6-(3'-ethyl-4'-methylanilino) uracil

The 6-anilinouracils (AUs) constitute a new class of bactericidal antibiotics selective against gram-positive (Gr(+)) organisms. The AU family of compounds specifically inhibits a novel target, replicative DNA polymerase Pol IIIC. Like other antibiotics, AUs can be expected to engender the development of resistant bacteria. We have used a representative AU and clinically relevant strains of Staphylococcus aureus and Enterococcus to determine the frequency and mechanism(s) of resistance development. The frequency of resistance was determined by using N(3)-hydroxybutyl 6-(3'-ethyl-4'-methylanilino) uracil (HBEMAU) and commercially available antibiotics at eight times the MICs. For all five Gr(+) organisms tested, the frequency of resistance to HBEMAU ranged from 1 x 10(-8) to 3 x 10(-10). The frequencies of resistance to the antibiotics tested, including rifampin, gentamicin, and ciprofloxacin, were either greater than or equal to those for HBEMAU. In order to understand the mechanism of resistance, HBEMAU-resistant organisms were isolated. MIC assays showed that the organisms had increased resistance to AU inhibitors but not to other families of antibiotics. Inhibition studies with DNA polymerases from HBEMAU-sensitive and -resistant strains demonstrated that the resistance was associated with Pol IIIC. DNA sequence analysis of the entire polC genes from both wild-type and resistant organisms revealed that the resistant organisms had a sequence change that mapped to a single amino acid codon in all strains examined.

DNA polymerases of low-GC gram-positive eubacteria: identification of the replication-specific enzyme encoded by dnaE

dnaE, the gene encoding one of the two replication-specific DNA polymerases (Pols) of low-GC-content gram-positive bacteria (E. Dervyn et al., Science 294:1716-1719, 2001; R. Inoue et al., Mol. Genet. Genomics 266:564-571, 2001), was cloned from Bacillus subtilis, a model low-GC gram-positive organism. The gene was overexpressed in Escherichia coli. The purified recombinant product displayed inhibitor responses and physical, catalytic, and antigenic properties indistinguishable from those of the low-GC gram-positive-organism-specific enzyme previously named DNA Pol II after the polB-encoded DNA Pol II of E. coli. Whereas a polB-like gene is absent from low-GC gram-positive genomes and whereas the low-GC gram-positive DNA Pol II strongly conserves a dnaE-like, Pol III primary structure, it is proposed that it be renamed DNA polymerase III E (Pol III E) to accurately reflect its replicative function and its origin from dnaE. It is also proposed that DNA Pol III, the other replication-specific Pol of low-GC gram-positive organisms, be renamed DNA polymerase III C (Pol III C) to denote its origin from polC. By this revised nomenclature, the DNA Pols that are expressed constitutively in low-GC gram-positive bacteria would include DNA Pol I, the dispensable repair enzyme encoded by polA, and the two essential, replication-specific enzymes Pol III C and Pol III E, encoded, respectively, by polC and dnaE.

PolC-type polymerase III of Streptococcus pyogenes and its use in screening for chemical inhibitors

The polC gene from Streptococcus pyogenes (S. pyogenes, strain SF370) has been cloned and expressed in Escherichia coli (E. coli) as a fusion protein containing an N-terminal histidine tag. The purified recombinant enzyme showed an apparent molecular mass of 160 kDa on SDS-PAGE and a specific activity of 3.5 nmol/min/mg when assayed in the presence of calf thymus DNA and the four deoxyribonucleoside triphosphates. This activity was inhibited by TMAU, a specific inhibitor of PolC. To facilitate kinetic studies, and high-throughput assays, a double-stranded oligo DNA primer/template was used as a substrate. The minimum requirement for the length of the substrate was a 20-base oligo primer annealed to a 35-base template. PolC activity was detected either by a filter-binding format or by a novel homogeneous scintillation proximity assay (SPA). Sensitivity to inhibition by anilinouracil analogs was improved by incorporating three deoxycytidines in the template strand as the first 3 bases to be copied by the polymerase. Inhibition of PolC activity by trimethyleneanilinouracil by the filtration and SPA methods gave comparable results, but the SPA assay uses less radioactive label, is less time-consuming, and is amenable to high-throughput formatting.

Replicative DNA polymerases

SUMMARY

Replicative DNA polymerases are essential for the replication of the genomes of all living organisms. On the basis of sequence similarities they can be classified into three types. Type A polymerases are homologous to bacterial polymerases I, Type B comprises archaebacterial DNA polymerases and eukaryotic DNA polymerase alpha, and the bacterial polymerase III class make up type C. Structures have been solved for several type A and B polymerases, which share a similar architecture. The structure of type C is not yet known. The catalytic mechanism of all three types involves two metal-ion-binding acidic residues in the active site. Replicative polymerases are constitutively expressed, but their activity is regulated through the cell cycle and in response to different growth conditions.

In vitro antimicrobial activities of novel anilinouracils which selectively inhibit DNA polymerase III of gram-positive bacteria

The 6-anilinouracils are novel dGTP analogs that selectively inhibit the replication-specific DNA polymerase III of gram-positive eubacteria. Two specific derivatives, IMAU (6-[3'-iodo-4'-methylanilino]uracil) and EMAU (6-[3'-ethyl-4'-methylanilino]uracil), were substituted with either a hydroxybutyl (HB) or a methoxybutyl (MB) group at their N3 positions to produce four agents: HB-EMAU, MB-EMAU, HB-IMAU, and MB-IMAU. These four new agents inhibited Staphylococcus aureus, coagulase-negative staphylococci, Enterococcus faecalis, and Enterococcus faecium. Time-kill assays and broth dilution testing confirmed bactericidal activity. These anilinouracil derivatives represent a novel class of antimicrobials with promising activities against gram-positive bacteria that are resistant to currently available agents, validating replication-specific DNA polymerase III as a new target for antimicrobial development.

A DNA ligase from the psychrophile Pseudoalteromonas haloplanktis gives insights into the adaptation of proteins to low temperatures

The cloning, overexpression and characterization of a cold-adapted DNA ligase from the Antarctic sea water bacterium Pseudoalteromonas haloplanktis are described. Protein sequence analysis revealed that the cold-adapted Ph DNA ligase shows a significant level of sequence similarity to other NAD+-dependent DNA ligases and contains several previously described sequence motifs. Also, a decreased level of arginine and proline residues in Ph DNA ligase could be involved in the cold-adaptation strategy. Moreover, 3D modelling of the N-terminal domain of Ph DNA ligase clearly indicates that this domain is destabilized compared with its thermophilic homologue. The recombinant Ph DNA ligase was overexpressed in Escherichia coli and purified to homogeneity. Mass spectroscopy experiments indicated that the purified enzyme is mainly in an adenylated form with a molecular mass of 74 593 Da. Ph DNA ligase shows similar overall catalytic properties to other NAD+-dependent DNA ligases but is a cold-adapted enzyme as its catalytic efficiency (kcat/Km) at low and moderate temperatures is higher than that of its mesophilic counterpart E. coli DNA ligase. A kinetic comparison of three enzymes adapted to different temperatures (P. haloplanktis, E. coli and Thermus scotoductus DNA ligases) indicated that an increased kcat is the most important adaptive parameter for enzymatic activity at low temperatures, whereas a decreased Km for the nicked DNA substrate seems to allow T. scotoductus DNA ligase to work efficiently at high temperatures. Besides being useful for investigation of the adaptation of enzymes to extreme temperatures, P. haloplanktis DNA ligase, which is very efficient at low temperatures, offers a novel tool for biotechnology.

Did DNA replication evolve twice independently?

DNA replication is central to all extant cellular organisms. There are substantial functional similarities between the bacterial and the archaeal/eukaryotic replication machineries, including but not limited to defined origins, replication bidirectionality, RNA primers and leading and lagging strand synthesis. However, several core components of the bacterial replication machinery are unrelated or only distantly related to the functionally equivalent components of the archaeal/eukaryotic replication apparatus. This is in sharp contrast to the principal proteins involved in transcription and translation, which are highly conserved in all divisions of life. We performed detailed sequence comparisons of the proteins that fulfill indispensable functions in DNA replication and classified them into four main categories with respect to the conservation in bacteria and archaea/eukaryotes: (i) non-homologous, such as replicative polymerases and primases; (ii) containing homologous domains but apparently non-orthologous and conceivably independently recruited to function in replication, such as the principal replicative helicases or proofreading exonucleases; (iii) apparently orthologous but poorly conserved, such as the sliding clamp proteins or DNA ligases; (iv) orthologous and highly conserved, such as clamp-loader ATPases or 5'-->3' exonucleases (FLAP nucleases). The universal conservation of some components of the DNA replication machinery and enzymes for DNA precursor biosynthesis but not the principal DNA polymerases suggests that the last common ancestor (LCA) of all modern cellular life forms possessed DNA but did not replicate it the way extant cells do. We propose that the LCA had a genetic system that contained both RNA and DNA, with the latter being produced by reverse transcription. Consequently, the modern-type system for double-stranded DNA replication likely evolved independently in the bacterial and archaeal/eukaryotic lineages.

Inhibitors of DNA polymerase III as novel antimicrobial agents against gram-positive eubacteria

6-Anilinouracils are selective inhibitors of DNA polymerase III, the enzyme required for the replication of chromosomal DNA in gram-positive bacteria (N. C. Brown, L. W. Dudycz, and G. E. Wright, Drugs Exp. Clin. Res. 12:555-564, 1986). A new class of 6-anilinouracils based on N-3 alkyl substitution of the uracil ring was synthesized and analyzed for activity as inhibitors of the gram-positive bacterial DNA polymerase III and the growth of gram-positive bacterial pathogens. Favorable in vitro properties of N-3-alkyl derivatives prompted the synthesis of derivatives in which the R group at N-3 was replaced with more-hydrophilic methoxyalkyl and hydroxyalkyl groups. These hydroxyalkyl and methoxyalkyl derivatives displayed K(i) values in the range from 0.4 to 2.8 microM against relevant gram-positive bacterial DNA polymerase IIIs and antimicrobial activity with MICs in the range from 0.5 to 15 microg/ml against a broad spectrum of gram-positive bacteria, including methicillin-resistant staphylococci and vancomycin-resistant enterococci. Two of these hydrophilic derivatives displayed protective activity in a simple mouse model of lethal staphylococcal infection.

Identification of the acidic residues in the active site of DNA polymerase III

The mechanism of nucleotide addition by DNA polymerases involves two metal ions that are coordinated in the active site by conserved acidic residues. The three acidic residues that chelate Mg2+ in the active site of Escherichia coli DNA polymerase III have been identified as Asp401, Asp403, and Asp555 by site-directed mutagenesis. Candidates for mutagenesis were initially chosen based on absolute conservation of acidic residues in an alignment of more than 20 diverse DnaE sequences. Conservative Asp to Glu mutations at positions 401 and 403 reduced the activities of the mutant polymerases 2000 and 333-fold, respectively, from that of the wild-type. The third carboxylate was identified by a series of mutations for each critical candidate. With the exception of Glu, all of the mutations at Asp555 led to severely diminished polymerase activity, while each of the other candidates exhibited several relatively active mutant polymerases. Moreover, only the identified active site mutant polymerases displayed a significant enhancement of activity in Mn2+ compared with Mg2+. These data suggest a direct involvement of the mutated amino acid in metal ion binding.