DNA polymerase III holoenzyme of Escherichia coli: Components and function of a true replicative complex

Summary The DNA polymerase III holoenzyme is a complex, multisubunit enzyme that is responsible for the synthesis of most of the Escherichia coli chromosome. Through studies of the structure, function and regulation of this enzyme over the past decade, considerable progress has been made in the understanding of the features of a true replicative complex. The holoenzyme contains at least seven different subunits. Three of these, , and , compose the catalytic core. Apparently is the catalytic subunit and the product of the dnaE gene. Epsilon, encoded by dnaQ (mutD), is responsible for the proofreading 35 activity of the polymerase. The function of the B subunit remains to be established. The auxiliary subunits, , and , encoded by dnaN, dnaZ and dnaX, respectively, are required for the functioning of the polymerase on natural chromosomes. All of the proteins participate in increasing the processivity of the polymerase and in the ATP-dependent formation of an initiation complex. Tau causes the polymerase to dimerize, perhaps forming a structure that can coordinate leading and lagging strand synthesis at the replication fork. This dimeric complex may be asymmetric with properties consistent with the distinct requirements for leading and lagging strand synthesis.     

Insights into the replisome from the structure of a ternary complex of the DNA polymerase III alpha-subunit

The crystal structure of the catalytic α−subunit of the DNA polymerase III (PolIIIα) holoenzyme bound to primer-template DNA and an incoming deoxy-nucleoside 5′-triphosphate has been determined at 4.6-Å resolution. The polymerase interacts with the sugar-phosphate backbone of the DNA across its minor groove, which is made possible by significant movements of the thumb, finger, and β-binding domains relative to their orientations in the unliganded polymerase structure. Additionally, the DNA and incoming nucleotide are bound to the active site of PolIIIα nearly identically as they are in their complex with DNA polymerase β, thereby proving that the eubacterial replicating polymerase, but not the eukaryotic replicating polymerase, is homologous to DNA polymerase β. Finally, superimposing a recent structure of the clamp bound to DNA on this PolIIIα complex with DNA places a loop of the β-binding domain into the appropriate clamp cleft and supports a mechanism of polymerase switching.     

DNA polymerase V-dependent mutator activity in an SOS-induced Escherichia coli strain with a temperature-sensitive DNA polymerase III.

The temperature-sensitive DNA polymerase III (Pol III) encoded by the dnaE486 allele confers a spontaneous mutator activity in SOS-induced bacteria that is largely dependent upon DNA polymerase V (Pol V), encoded by umuD, C. This mutator activity is influenced by the defective proof-reading sub-unit of Pol III encoded by the dnaQ905 (mutD5) allele arguing that Pol V is most likely fixing mutations arising from mismatched primer termini produced by Pol III(486). The size of the dnaQ effect is, however, modest leaving open the possibility that Pol V may be responsible for some of the mutator effect by engaging in bursts of processive activity.     

Evolution of hominoid mitochondrial DNA with special reference to the silent substitution rate over the genome

Summary Focusing on the synonymous substitution rate, we carried out detailed sequence analyses of hominoid mitochondrial (mt) DNAs of ca. 5-kb length. Owing to the outnumbered transitions and strong biases in the base compositions, synonymous substitutions in mtDNA reach rapidly a rather low saturation level. The extent of the compositional biases differs from gene to gene. Such changes in base compositions, even if small, can bring about considerable variation in observed synonymous differences and may result in the region-dependent estimate of the synonymous substitution rate. We demonstrate that such a region dependency is due to a failure to take proper account of heterogeneous compositional biases from gene to gene but that the actual synonymous substitution rate is rather uniform. The synonymous substitution rate thus estimated is 2.37 ± 0.11 × 10^–8 per site per year and comparable to the overall rate for the noncoding region. On the other hand, the rate of nonsynonymous substitutions differs considerably from gene to gene, as expected under the neutral theory of molecular evolution. The lowest rate is 0.8 × 10^–9 per site per year forCOI and the highest rate is 4.5 × 10^–9 forATPase 8, the degree of functional constraints (measured by the ratio of the nonsynonymous to the synonymous substitution rate) being 0.03 and 0.19, respectively. Transfer RNA (tRNA) genes also show variability in the base contents and thus in the nucleotide differences. The average rate for 11 tRNAs contained in the 5-kb region is 3.9 × 10^–9 per site per year. The nucleotide substitutions in the genome suggest that the transition rate is about 17 times faster than the transversion rate.     

Binding analysis of ytterbium(III) complex containing 1,10-phenanthroline with DNA and its antimicrobial activity

To evaluate the biological preference of [Yb(phen)₂(OH₂)Cl₃](H₂O)₂ (phen is 1,10-phenanthroline) for DNA, interaction of Yb(III) complex with DNA in Tris–HCl buffer is studied by various biophysical and spectroscopic techniques which reveal that the complex binds to DNA. The results of fluorescence titration reveal that [Yb(phen)₂(OH₂)Cl₃](H₂O)₂ has strongly quenched in the presence of DNA. The binding site number n, apparent binding constant K _b, and the Stern–Volmer quenching constant K _SV are determined. ΔH ⁰, ΔS ⁰, and ΔG ⁰ are obtained based on the quenching constants and thermodynamic theory (ΔH ⁰?>?0, ΔS ⁰?>?0, and ΔG ⁰?<?0). The experimental results show that the Yb(III) complex binds to DNA by non-intercalative mode. Groove binding is the preferred mode of interaction for [Yb(phen)₂(OH₂)Cl₃](H₂O)₂ to DNA. The DNA cleavage results show that in the absence of any reducing agent, Yb(III) complex can cleave DNA. The antimicrobial screening tests are also recorded and give good results in the presence of Yb(III) complex.     

Polymerase chaperoning and multiple ATPase sites enable the E. coli DNA polymerase III holoenzyme to rapidly form initiation complexes

Cellular replicases include three subassemblies: a DNA polymerase, a sliding clamp processivity factor, and a clamp loader complex. The Escherichia coli clamp loader is the DnaX complex (DnaX₃δδ′χψ), where DnaX occurs either as τ or as the shorter γ that arises by translational frameshifting. Complexes composed of either form of DnaX are fully active clamp loaders, but τ confers important replicase functions including chaperoning the polymerase to the newly loaded clamp to form an initiation complex for processive replication. The kinetics of initiation complex formation were explored for DnaX complexes reconstituted with varying τ and γ stoichiometries, revealing that τ-mediated polymerase chaperoning accelerates initiation complex formation by 100-fold. Analyzing DnaX complexes containing one or more K51E variant DnaX subunits demonstrated that only one active ATP binding site is required to form initiation complexes, but the two additional sites increase the rate by ca 1000-fold. For τ-containing complexes, the ATP analogue ATPγS was found to support initiation complex formation at 1/1000th the rate with ATP. In contrast to previous models that proposed ATPγS drives hydrolysis-independent initiation complex formation by τ-containing complexes, the rate and stoichiometry of ATPγS hydrolysis coincide with those for initiation complex formation. These results show that although one ATPase site is sufficient for initiation complex formation, the combination of polymerase chaperoning and the binding and hydrolysis of three ATPs dramatically accelerates initiation complex formation to a rate constant (25-50 s^− 1 ) compatible with double-stranded DNA replication.     

Synthesis, characterization, cytotoxic activity and DNA binding properties of the novel dinuclear cobalt(III) complex with the condensation product of 2-acetylpyridine and malonic acid dihydrazide

A novel dinuclear cobalt(III) complex with the condensation product of 2-acetylpyridine and malonic acid dihydrazide, N′,N′²-bis[(1E)-1-(2-pyridyl)ethylidene]propanedihydrazide was synthesized and characterized by elemental analysis, spectroscopy (NMR and infrared), and X-ray crystal analysis. The complex showed a moderate activity towards Artemia salina. The highest cytotoxic potential of the complex was observed on the epithelial breast cancer (MDA-361) cell line. The investigated complex induced apoptosis, the early apoptotic cells comprising 28.18%, compared to 5.64% of control cells in the same phase. The interaction of the complex with calf thymus DNA (CT-DNA) was monitored by blue shift and hyperchromism in the UV-vis spectra. The observed intrinsic binding constant (K_b = 4.2 × 10⁵ M^− 1) together with structural analysis of the complex indicate the groove binding.     

Application of electrospray ionization mass spectrometry to study the hydrophobic interaction between the epsilon and theta subunits of DNA polymerase III

The interactions between the N-terminal domain of the epsilon (epsilon186) and theta subunits of DNA polymerase III of Escherichia coli were investigated using electrospray ionization mass spectrometry. The epsilon186-theta complex was stable in 9 M ammonium actetate (pH 8), suggesting that hydrophobic interactions have a predominant contribution to the stability of the complex. Addition of primary alkanols to epsilon186-theta in 0.1 M ammonium acetate (pH 8), led to dissociation of the complex, as observed in the mass spectrometer. The concentrations of methanol, ethanol, and 1-propanol required to dissociate 50% of the complex were 8.9 M, 4.8 M, and 1.7 M, respectively. Closer scrutiny of the effect of alkanols on epsilon186, theta, and epsilon186-theta showed that epsilon186 formed soluble aggregates prior to precipitation, and that the association of epsilon186 with theta stabilized epsilon186. In-source collision-induced dissociation experiments and other results suggested that the epsilon186-theta complex dissociated in the mass spectrometer, and that the stability (with respect to dissociation) of the complex in vacuo was dependent on the solution from which it was sampled.     

Phosphorylation of Escherichia coli poly(A) polymerase I and effects of this modification on the enzyme activity

In Escherichia coli, RNA polyadenylation is catalyzed mainly by poly(A) polymerase I (PAP I). Here we demonstrate that a PAP I variant with a C-terminal His tag (PAP I-His) can be phosphorylated both in vivo and in an artificial in vitro system. The in vivo phosphorylation of PAP I-His impairs activity of this enzyme. Previous studies, performed by others, indicated that phosphorylation of His-tagged proteins usually reflects such a modification of their native counterparts in bacterial cells. Therefore, our results suggest that phosphorylation and dephosphorylation of PAP I may be important regulatory processes in the control of activity of this enzyme.     

In vitro anticancer and antibacterial activates of the yttrium(III) complex and its nano-carriers toward DNA cleavage and biological interactions with DNA and BSA; An experimental and computational studie

ObjectivesIn this research, the biological properties of the yttrium (III) (Y) complex, with 2,9-dimethyl- 1,10-phenanthroline (Me₂Phen) ligand, were examined for in vitro fish DNA (FS-DNA)/ bovine serum albumin (BSA) interactions, DNA-cleavage, anticancer and antibacterial activities.MethodsMulti-spectrophotometric techniques and computational calculations were used for the interaction studies of the BSA and FS-DNA with the Y-complex. Absorption and fluorescence spectroscopy methods were used to define thermodynamic parameters, the binding constants (K_b), and the probable binding mechanism. Also, the DFT (density functional theory) study and molecular docking calculation of the Y-complex were done. Besides, the nanocarriers of Y-complex (lipid nanoencapsulation (LNEP) and the starch nanoencapsulation (SNEP)), as active anticancer candidates, were prepared. Finally, DNA-cleavage, anticancer, and antibacterial activities of this complex were investigated.ResultsThe absorption and fluorescence measurements were exhibited that the Y-complex has a high binding affinity to FS-DNA and BSA through a static mechanism. The negative thermodynamic parameter values for both DNA/BSA binding were confirmed that the hydrogen bonds and van der Waals forces played an essential role in the spontaneous bonding procedure. The site marker competitive studies for BSA confirmed that the Y-complex bonds to the sub-domain IB of protein (site III) on BSA, which was entirely agreement by docking calculation. The complex has displayed efficient DNA cleavage, antifungal and antibacterial activities. The anticancer activity of the Y-complex and its starch/lipid nano-encapsulated was carried out in cancer cell lines, which exposed considerably high activity.ConclusionsThus, Y-complex can be transported professionally through BSA in the blood and bonds in the groove of DNA. Base on biological applications of the Y-complex, it can be concluded that this complex and its nanocarriers can suggest as novel anticancer and antibacterial candidates.     

Mutagenic DNA repair in Escherichia coli. XIV. Influence of two DNA polymerase III mutator alleles on spontaneous and UV mutagenesis

Summary We introduced the dnaE486 and polC74 mutations (which are associated with decreased DNA polymerase III replication fidelity) into excision defective Escherichia coli strains with varying SOS responses. These mutations increased the UV-induced frequency of base pair substitution mutations in all strains tested, except recA430 and umuC122 derivatives. This UV mutator effect therefore requires expression of the SOS error-prone repair system. In recA441 lexA51 strains where the SOS system is constitutively expressed, the UV mutator effect of the dnaE alleles was similar in relative terms (though greater in absolute terms). Since these dnaE alleles decrease rather than increase survival after UV it is argued that they promote a burst of untargeted mutations close to UV photoproducts (hitch-hiking mutations) rather than increase the number of translesion synthesis events. The fact that there was no UV mutagenesis in dnaE486 umuC122 or polC74 umuC122 strains indicates that infidelity associated with these dnaE alleles did not of itself enable translesion synthesis to occur. The spontaneous mutator effect conferred by dnaE486 and polC74 was not affected by umuC122 or recA430 indicating that it is not dependent upon error-prone repair ability. In recA441 lexA51 bacteria, where SOS error-prone repair is constitutively induced, the mutator effect of dnaE486 was greater and was largely blocked by umuC122. It is suggested that spontaneously occurring cryptic lesions that are themselves unable to induce the SOS system are subject to translesion synthesis under these conditions and trigger a burst of hitch-hiking mutations that are therefore effectively umuC dependent.     

Experimental and theoretical investigations of Dy(III) complex with 2,2′-bipyridine ligand: DNA and BSA interactions and antimicrobial activity study

Abstract

In this study, the interactions of a novel metal complex [Dy(bpy)₂Cl₃.OH₂] (bpy is 2,2'-bipyridine) with fish salmon DNA (FS-DNA) and bovine serum albumin (BSA) were investigated by experimental and theoretical methods. All results suggested significant binding between the Dy(III) complex with FS-DNA and BSA. The binding constants (K_b), Stern-Volmer quenching constants (K_SV) of Dy(III)-complex with FS-DNA and BSA at various temperatures as well as thermodynamic parameters using Van’t Hoff equation were obtained. The experimental results from absorption, ionic strength, iodide ion quenching, ethidium bromide (EtBr) quenching studies and positive ΔH? and ΔS? suggested that hydrophobic groove-binding mode played a predominant role in the binding of Dy(III)-complex with FS-DNA. Indeed, the molecular docking results for DNA-binding were in agreement with experimental data. Besides, the results found from experimental and molecular modeling indicated that the Dy(III)-complex bound to BSA via Van der Waals interactions. Moreover, the results of competitive tests by phenylbutazone, ibuprofen, and hemin (as a site-I, site-II and site-III markers, respectively) considered that the site-III of BSA is the most possible binding site for Dy(III)-complex. In addition, Dy(III) complex was concurrently screened for its antimicrobial activities. The presented data provide a promising platform for the development of novel metal complexes that target nucleic acids and proteins with antimicrobial activity.

Communicated by Ramaswamy H. Sarma     

Protective effects of sodium selenite on killing and mutation by N-methyl-N''-nitro-N-nitrosoguanidine in E. coli.

Sodium selenite was found to protect Escherichia coli cells against killing and mutagenic effects of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG). Such protective effects were not observed when cells were treated with N-methyl-N-nitrosourea (MNU). The protection by sodium selenite was not controlled by the ada gene, which is responsible for the repair of alkylated damage in DNA. A reduction of the amount of glutathione was found when cells were treated with sodium selenite, and glutathione is known to be involved in the methylation of DNA by MNNG, not by MNU. Reduced methylation by MNNG due to the reduction of the amount of glutathione caused by abundant sodium selenite was suggested to be the mechanism of protection.     

Escherichia coli RNA polymerase binding to a DNA terminus prevents formation of a closed promoter complex

A 302 bp DNA fragment and a 113 bp subfragment of the former, both containing the fd gene VIII promoter (P VIII), were found to exhibit temperature-dependent differential behaviour in RNA chain initiation from P VIII. At 37°C no significant differences were observed, while at 17°C chain initiation was strongly suppressed only with the 113 bp fragment. This phenomenon depended on the presence of the (blunt) DNA terminus upstream from P VIII (position −70). Footprinting revealed that at 17°C RNA polymerase was bound to this DNA fragment in a different mode. Contacts were observed only upstream from position −25. On the contrary, at 37°C only the promoter complex footprint was visible. These results indicate that at 17°C formation of the non-initiating complex is more favourable than formation of the promoter complex (which is closed at 17°C; Hofer, B., Müller, D. and Köster, H. (1985) Nucleic Acids Res. 13, 5995–6013) and that formation of both complexes is mutually exclusive. No footprints of RNA polymerase were observed at other DNA termini. This indicates a sequence-specificity for the interaction at the terminus of the 113 bp fragment. The footprint pattern, together with features of the DNA sequence, suggests that the contacts involved in this interaction are similar to those promoter contacts formed upstream from position −20 and that DNA without a −10 region can be specifically recognized by RNA polymerase.     

Iron(III) Schiff base complexes of arginine and lysine as netropsin mimics showing AT-selective DNA binding and photonuclease activity

Iron(III) complexes [Fe(L)₂]Cl (1-3), where L is monoanionic N-salicylidene-arginine (sal-argH for 1), hydroxynaphthylidene-arginine (nap-argH for 2) and N-salicylidene-lysine (sal-lysH for 3), were prepared and their DNA binding and photo-induced DNA cleavage activity studied. Complex 3 as its hexafluorophosphate salt [Fe(sal-lysH)₂](PF₆)·6H₂O (3a) was structurally characterized by single crystal X-ray crystallography. The crystals belonged to the triclinic space group P-1. The complex has two tridentate ligands in FeN₂O₄ coordination geometry with two pendant cationic amine moieties. Complexes 1 and 2 with two pendant cationic guanidinium moieties are the structural models for the antitumor antibiotics netropsin. The complexes are stable and soluble in water. They showed quasi-reversible Fe(III)/Fe(II) redox couple near 0.6 V in H₂O-0.1 M KCl. The high-spin 3d⁵-iron(III) complexes with μ_eff value of ∼5.9 μ_B displayed ligand-to-metal charge transfer electronic band near 500 nm in Tris-HCl buffer. The complexes show binding to Calf Thymus (CT) DNA. Complex 2 showed better binding propensity to the synthetic oligomer poly(dA)·poly(dT) than to CT-DNA or poly(dG)·poly(dC). All the complexes displayed chemical nuclease activity in the presence of 3-mercaptopropionic acid as a reducing agent and cleaved supercoiled pUC19 DNA to its nicked circular form. They exhibited photo-induced DNA cleavage activity in UV-A light and visible light via a mechanistic pathway that involves the formation of reactive hydroxyl radical species.     

Synthesis, structure and DNA binding studies of a mononuclear cobalt(III) complex with a NNO donor Schiff base derived from 4-methyl-2,6-dibenzoylphenol and ethane-1,2-diamine

The mononuclear cationic cobalt(III) complex 1 [Co(L)₂]⁺ [where HL is H₂N(CH₂)₂NC(Ph)C₆H₂(Me)(OH)COPh] has been obtained by the condensation of 4-methyl-2,6-dibenzoylphenol and ethane-1,2-diamine in the presence of CoCl₂ · 6H₂O and isolated as the chloride solvate {1 · Cl · 2H₂O · EtOH}. The water and ethanol do not form part of the cobalt(III) pseudo-octahedral [Co(L)₂]⁺ coordination sphere, which is cis-CoN₄O₂ with the NNO-ligands mer. Compound 1 has been characterised by mass spectrometry, IR, electronic, ¹H and ¹³C NMR spectroscopy, conductivity measurements, elemental analysis, TGA, cyclic voltammetry and an X-ray structural determination. The average Co-N and Co-O distances are, respectively, 1.929(4) and 1.882(3) Å. The N?N intraligand bite distance is 2.73(4) Å and the N-Co-N and O-Co-O angles are, respectively, 86.2(15)° and 93.3(13)°. Cyclic voltammetric studies of complex 1 indicate an irreversible cathodic peak (E_pc, ca. −0.61 V) corresponding to the reduction of cobalt(III) to cobalt(II). Absorption titration experiments gave a binding constant for DNA interaction of 1.4 × 10⁴ M⁻¹ and a binding site size 0.16 base pairs.     

Structural study of immunoaffinity-purified DNA polymerase α-DNA primase complex from calf thymus

The DNA polymerase α-DNA primase complex was purified over 17 000-fold to near homogeneity from calf thymus using an immunoaffinity column. Sodium dodecyl sulfate gel electrophoresis revealed three polypeptides with molecular weights of 140, 50 and 47 kDa, in a ratio of 1:2:0.25. The complex showed a sedimentation coefficient of 9.7 S, a Stokes radius of 56 Å and a native molecular weight of 250–260 kDa. Taken together, the data suggest that the calf thymus dNA polymerase α-DNA primase complex is essentially a heterotrimer of large (140 kDa) and small (50 kDa) subunits in a ratio of 1:2, with a globular conformation. Electron-microscopic studies of the complex revealed a spherical particle of 120 Å in diameter, in agreement with the physicochemical results. The binding of the complex to DNA was also demonstrated.