Functional cooperation of the dnaE and dnaN gene products in Escherichia coli

Multi-Omics Study on Molecular Mechanisms of Single-Atom Fe-Doped Two-Dimensional Conjugated Phthalocyanine Framework for Photocatalytic Antibacterial Performance

Currently, photocatalysis of the two-dimensional (2D) conjugated phthalocyanine framework with a single Fe atom (CPF-Fe) has shown efficient photocatalytic activities for the removal of harmful effluents and antibacterial activity. Their photocatalytic mechanisms are dependent on the redox reaction-which is led by the active species generated from the photocatalytic process. Nevertheless, the molecular mechanism of CPF-Fe antimicrobial activity has not been sufficiently explored. In this study, we successfully synthesized CPF-Fe with great broad-spectrum antibacterial properties under visible light and used it as an antibacterial agent. The molecular mechanism of CPF-Fe against Escherichia coli and Salmonella enteritidis was explored through multi-omics analyses (transcriptomics and metabolomics correlation analyses). The results showed that CPF-Fe not only led to the oxidative stress of bacteria by generating large amounts of h+ and ROS but also caused failure in the synthesis of bacterial cell wall components as well as an osmotic pressure imbalance by disrupting glycolysis, oxidative phosphorylation, and TCA cycle pathways. More surprisingly, CPF-Fe could disrupt the metabolism of amino acids and nucleic acids, as well as inhibit their energy metabolism, resulting in the death of bacterial cells. The research further revealed the antibacterial mechanism of CPF-Fe from a molecular perspective, providing a theoretical basis for the application of CPF-Fe photocatalytic antibacterial nanomaterials.

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

The crystal structure of the catalytic alpha-subunit of the DNA polymerase III (Pol IIIalpha) holoenzyme bound to primer-template DNA and an incoming deoxy-nucleoside 5'-triphosphate has been determined at 4.6-A 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 beta-binding domains relative to their orientations in the unliganded polymerase structure. Additionally, the DNA and incoming nucleotide are bound to the active site of Pol IIIalpha nearly identically as they are in their complex with DNA polymerase beta, thereby proving that the eubacterial replicating polymerase, but not the eukaryotic replicating polymerase, is homologous to DNA polymerase beta. Finally, superimposing a recent structure of the clamp bound to DNA on this Pol IIIalpha complex with DNA places a loop of the beta-binding domain into the appropriate clamp cleft and supports a mechanism of polymerase switching.

Cellular DNA replicases: components and dynamics at the replication fork

DNA replicases are multicomponent machines that have evolved clever strategies to perform their function. Although the structure of DNA is elegant in its simplicity, the job of duplicating it is far from simple. At the heart of the replicase machinery is a heteropentameric AAA+ clamp-loading machine that couples ATP hydrolysis to load circular clamp proteins onto DNA. The clamps encircle DNA and hold polymerases to the template for processive action. Clamp-loader and sliding clamp structures have been solved in both prokaryotic and eukaryotic systems. The heteropentameric clamp loaders are circular oligomers, reflecting the circular shape of their respective clamp substrates. Clamps and clamp loaders also function in other DNA metabolic processes, including repair, checkpoint mechanisms, and cell cycle progression. Twin polymerases and clamps coordinate their actions with a clamp loader and yet other proteins to form a replisome machine that advances the replication fork.

Identification of the beta-binding domain of the alpha subunit of Escherichia coli polymerase III holoenzyme

Rapid and processive DNA synthesis by Escherichia coli DNA polymerase III holoenzyme is achieved by the direct interaction between the alpha subunit of DNA polymerase III core and the beta sliding clamp (LaDuca, R. J., Crute, J. J., McHenry, C. S., and Bambara, R. A. (1986) J. Biol. Chem. 261, 7550-7557; Stukenberg, T. P., Studwell-Vaughan, P. S., and O'Donnell, M. (1991) J. Biol. Chem. 266, 11328-11334). In this study, we localized the beta-binding domain of alpha to a carboxyl-terminal region by quantifying the interaction of beta with a series of alpha deletion proteins. Purification and binding analysis was facilitated by insertion of hexahistidine and short biotinylation sequences on the deletion terminus of alpha. Interaction of beta with alpha deletion proteins was studied by gel filtration and surface plasmon resonance. alpha lacking 169 COOH-terminal residues still possessed beta-binding activity; whereas deletion of 342 amino acids from the COOH terminus abolished beta binding. Deletion of 542 amino acids from the NH2 terminus of the 1160 residue alpha subunit resulted in a protein that bound beta 10-20-fold more strongly than native alpha. Hence, portions of alpha between residues 542 and 991 are involved in beta binding. DNA binding to alpha apparently triggers an increased affinity for beta (Naktinis, V., Turner, J., and O'Donnell, M. (1996) Cell 84, 137-145). Our findings extend this observation by implicating the amino-terminal polymerase domain in inducing a low affinity taut conformation in the carboxyl-terminal beta-binding domain. Deletion of the polymerase domain (or, presumably, its occupancy by DNA) relaxes the COOH-terminal domain, permitting it to assume a conformation with high affinity for beta.

DNA replication defect in Salmonella typhimurium mutants lacking the editing (epsilon) subunit of DNA polymerase III

In Salmonella typhimurium, dnaQ null mutants (encoding the epsilon editing subunit of DNA polymerase III [Pol III]) exhibit a severe growth defect when the genetic background is otherwise wild type. Suppression of the growth defect requires both a mutation affecting the alpha (polymerase) subunit of DNA polymerase III and adequate levels of DNA polymerase I. In the present paper, we report on studies that clarify the nature of the physiological defect imposed by the loss of epsilon and the mechanism of its suppression. Unsuppressed dnaQ mutants exhibited chronic SOS induction, indicating exposure of single-stranded DNA in vivo, most likely as gaps in double-stranded DNA. Suppression of the growth defect was associated with suppression of SOS induction. Thus, Pol I and the mutant Pol III combined to reduce the formation of single-stranded DNA or accelerate its maturation to double-stranded DNA. Studies with mutants in major DNA repair pathways supported the view that the defect in DNA metabolism in dnaQ mutants was at the level of DNA replication rather than of repair. The requirement for Pol I was satisfied by alleles of the gene for Pol I encoding polymerase activity or by rat DNA polymerase beta (which exhibits polymerase activity only). Consequently, normal growth is restored to dnaQ mutants when sufficient polymerase activity is provided and this compensatory polymerase activity can function independently of Pol III. The high level of Pol I polymerase activity may be required to satisfy the increased demand for residual DNA synthesis at regions of single-stranded DNA generated by epsilon-minus pol III. The emphasis on adequate polymerase activity in dnaQ mutants is also observed in the purified alpha subunit containing the suppressor mutation, which exhibits a modestly elevated intrinsic polymerase activity relative to that of wild-type alpha.

Nucleotide sequences of dnaE, the gene for the polymerase subunit of DNA polymerase III in Salmonella typhimurium, and a variant that facilitates growth in the absence of another polymerase subunit

The dnaE gene of Salmonella typhimurium, like that of Escherichia coli, encodes the alpha subunit containing the polymerase activity of the principal replicative enzyme, DNA polymerase III. This gene, or one nearby, has been identified as the locus of suppressor mutations that promote growth by cells deleted for dnaQ, the gene for the editing subunit of this enzyme complex. Using a combination of nucleotide sequencing and marker rescue experiments, the alteration in one such suppressor was identified as a valine-to-glycine substitution at amino acid 832 of the 1,160-amino-acid alpha polypeptide. The alpha polypeptides of E. coli and S. typhimurium are identical in size and in 97% of their amino acid residues. Their identity includes the valine residue that was changed in the suppressor allele of S. typhimurium. We also localized a temperature-sensitive dnaE mutation to the 3' half of dnaE.

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

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, alpha, epsilon and theta, compose the catalytic core. Apparently alpha is the catalytic subunit and the product of the dnaE gene. Epsilon, encoded by dnaQ (mutD), is responsible for the proofreading 3'----5' activity of the polymerase. The function of the theta subunit remains to be established. The auxiliary subunits, beta, gamma and delta, 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.

Genetic analysis of DNA replication in bacteria: dnaB mutations that suppress dnaC mutations and dnaQ mutations that suppress dnaE mutations in Salmonella typhimurium

We have isolated and characterized extragenic suppressors of mutations in two different target genes that affect DNA replication in Salmonella typhimurium. Both the target and the suppressor genes are functional homologues of known replication genes of E. coli that were identified in intergeneric complementation tests. Our results point to interactions in vivo involving the dnaB and dnaC proteins in one case and the dnaQ and dnaE proteins in the other case. The suppressor mutations, which were isolated as derivatives of lambda-Salmonella in vitro recombinants, were detected by an adaptation of the red plaque complementation assay. This method was applicable even when the locus of suppressor mutations was not chosen in advance.

The recF-dependent endonuclease from Escherichia coli K12. Formation and resolution of pBR322 DNA multimers

The instability of supercoiled pBR322 DNA obtained from different cells has been investigated. Partially purified plasmid DNA species from rec+, recA and recBC sbcB cells are converted in vitro first to relaxed and then to linear molecules. The recA and recBC sbcB cells produce the best conditions for the monomerization of the pBR322 DNA and the stable maintenance of plasmids. The supercoiled pBR322 DNA from the recBC sbcB recF144 cells has been isolated preferentially in multimeric form (circular oligomers). These DNA forms are not converted to plasmid monomers and are converted to linear molecules three-fold slower than the monomer linearization in the case of the recBC sbcB cells. On the other hand, incubation of the pure pBR322 DNA with the recF-dependent protein Z (Krivonogov and Novitskaja 1982) results in the ATP-independent conversion of supercoiled plasmid DNA to relaxed and linear molecules. These results demonstrate an endonuclease activity of the recF-controlled protein Z, which may be involved in general recA-dependent recombination and formation of the pBR322 monomers in the cell. The results also show that the recF144 mutation in recBC sbcB recF and recF cells leads to the absence of detectable amounts of a 49,000 molecular weight protein.

Map location of the pcbA mutation and physiology of the mutant

Many temperature-resistant revertants of a polA1 polB polCts (HS432) strain are PolI+ (by either suppression of the polA1 amber allele or intragenic reversion) but remain polCts (contain a temperature-sensitive DNA polymerase III). It appears that DNA replication in such temperature-resistant revertants depends on an extragenic mutation, pcbA, already present in the parent strain and not linked to any of the DNA polymerase loci. This allele allows DNA replication dependent on DNA polymerase I and bypasses a temperature-sensitive DNA polymerase III (polC bypass), so that reversion to PolI+ makes the strain temperature resistant. This pathway of DNA replication also supports phage and plasmid DNA replication. At restrictive temperature, these mutants display a normal response to UV irradiation but show increased sensitivity to the alkylating agent methyl methanesulfonate. We have located pcbA linked to dnaA.

Physiological properties of cold-sensitive suppressor mutations of a temperature-sensitive dnaZ mutant of Escherichia coli

Suppressors of a temperature-sensitive dnaZ polymerization mutant of Escherichia coli have been identified by selecting temperature-insensitive revertants. Those suppressed strains which concomitantly became cold sensitive were chosen for further study. Intragenic suppressor mutations, which caused cold-sensitive defects in DNA polymerization, were located in dnaZ by transduction with lambda dnaZ+ phages. Extragenic suppressor mutations were mapped within the initiation gene dnaA. These suppressor-containing strains were defective in initiation at low temperature as determined by measurements of DNA synthesis in vivo and in toluene-treated cells. The occurrence of suppressor mutations of dnaZ(Ts) within the dnaA gene is considered evidence that the dnaA and dnaZ products interact in vivo. A second indication of a dnaA-dnaZ protein-protein interaction was provided by the observation that the introduction of additional copies of the dnaZ+ gene into a strain carrying the dnaA suppressor mutation was lethal [whether the strain was dnaZ+ or dnaZ(Ts)].

The dnaN gene codes for the beta subunit of DNA polymerase III holoenzyme of escherichia coli

An Escherichia coli mutant, dnaN59, stops DNA synthesis promptly upon a shift to a high temperature; the wild-type dnaN gene carried in a transducing phage encodes a polypeptide of about 41,000 daltons [Sakakibara, Y. & Mizukami, T. (1980) Mol. Gen. Genet. 178, 541-553; Yuasa, S. & Sakakibara, Y. (1980) Mol. Gen. Genet. 180, 267-273]. We now find that the product of dnaN gene is the beta subunit of DNA polymerase III holoenzyme, the principal DNA synthetic multipolypeptide complex in E. coli. The conclusion is based on the following observations: (i) Extracts from dnaN59 cells were defective in phage phi X174 and G4 DNA synthesis after the mutant cells had been exposed to the increased temperature. (ii) The enzymatic defect was overcome by addition of purified beta subunit but not by other subunits of DNA polymerase III holoenzyme or by other replication proteins required for phi X174 DNA synthesis. (iii) Partially purified beta subunit from the dnaN mutant, unlike that from the wild type, was inactive in reconstituting the holoenzyme when mixed with the other purified subunits. (iv) Increased dosage of the dnaN gene provided by a plasmid carrying the gene raised cellular levels of the beta subunit 5- to 6-fold.