Toshikazu Shiba

Escherichia coli RuvC protein is an endonuclease that resolves the Holliday structure.

Genetic evidence suggests that the Escherichia coli ruvC gene is involved in DNA repair and in the late step of RecE and RecF pathway recombination. To study the biochemical properties of RuvC protein, we overproduced and highly purified the protein. By employing model substrates, we examined the possibility that RuvC protein is an endonuclease that resolves the Holliday structure, an intermediate in genetic recombination in which two double‐stranded DNA molecules are linked by single‐stranded crossover. RuvC protein cleaves cruciform junctions, which are formed by the extrusion of inverted repeat sequences from a supercoiled plasmid and which are structurally analogous to Holliday junctions, by introducing nicks into strands with the same polarity. The nicked ends are ligated by E.coli or T4 DNA ligases. Analysis of the cleavage sites suggests that DNA topology rather than a particular sequence determines the cleavage site. RuvC protein also cleaves Holliday junctions which are formed between gapped circular and linear duplex DNA by the function of RecA protein. However, it does not cleave a synthetic four‐way junction that does not possess homology between arms. The active form of RuvC protein, as studied by gel filtration, is a dimer. This is mechanistically suited for an endonuclease involved in swapping DNA strands at the crossover junctions. From these properties of RuvC protein and the phenotypes of the ruvC mutants, we infer that RuvC protein is an endonuclease that resolves Holliday structures in vivo.

Developing Support System for Sequence Design in DNA Computing

Sequence design is the important factor which governs the reaction of DNA. In related researches, the method to minimize (or maxmize) the evaluation function based on knowledge of sequence design has been used. In this paper, we develop support system for sequence design in DNA computing, which minimizes the evaluation function calculated as the linear sum of the plural evaluation terms. Our system not only searches for good sequences but also presents contribution ratio of each evaluation term to the evaluation function and can reduce the number of combination of evaluation terms by reduction of the evaluation function. It helps us to find a good criteria for sequence design in DNA computing.

A novel ATP regeneration system using polyphosphate-AMP phosphotransferase and polyphosphate kinase

Polyphosphate-AMP phosphotransferase (PAP) and polyphosphate kinase (PPK) were used for designing a novel ATP regeneration system, named the PAP-PPK ATP regeneration system. PAP is an enzyme that catalyzes the phospho-conversion of AMP to ADP, and PPK catalyzes ATP formation from ADP. Both enzymes use inorganic polyphosphate [poly(P)] as a phosphate donor. In the PAP-PPK ATP regeneration system, ATP was continuously synthesized from AMP by the coupling reaction of PAP and PPK using poly(P). Poly(P) is a cheap material compared to acetyl phosphate, phosphoenol pyruvate and creatine phosphate, which are phosphate donors used for conventional ATP regeneration systems. To achieve efficient synthesis of ATP from AMP, an excessive amount of poly(P) should be added to the reaction solution because both PAP and PPK consume poly(P) as a phosphate donor. Using this ATP generation reaction, we constructed the PAP-PPK ATP regeneration system with acetyl-CoA synthase and succeeded in synthesizing acetyl-CoA from CoA, acetate and AMP. Since too much poly(P) may chelate MG2+ and inhibit enzyme activity, the Mg2+ concentration was optimized to 24 mM in the presence of 30 mM poly(P) in the reaction. In this reaction, ATP was regenerated 39.8 times from AMP, and 99.5% of CoA was converted to acetyl-CoA. In addition, since the PAP-PPK ATP regeneration system can regenerate GTP from GMP, it could also be used as a GTP regeneration system.

Involvement of inorganic polyphosphate in expression of SOS genes.

Inorganic polyphosphate (poly(P)) is a linear polymer that has been found in every organism so far examined. To elucidate the functions of poly(P) in the regulation of gene expression, the level of cellular poly(P) in Escherichia coli was reduced to a barely detectable concentration by overproduction of exopolyphosphatase (exopoly(P)ase) with a plasmid encoding yeast exopoly(P)ase (Shiba et al., Proc. Natl. Acad. Sci. USA 94 (1997) 11210-11215). It was found that exopoly(P)ase-overproducing cells were more sensitive to UV or mitomycin C (MMC) than were control cells. Poly(P) accumulation was observed after treatment with MMC, whereas the poly(P) level was below the detectable level in cells that overproduced exopoly(P)ase. When exopoly(P)ase-overproducing cells were transformed again by a multiple copy number plasmid that carries the polyphosphate kinase gene (ppk), the cells accumulated a great amount of poly(P) and restored the UV and MMC sensitivities to the level of control cells. In exopoly(P)ase-overproducing cells, the expression of recA and umuDC were not induced by MMC. In addition, a strain containing multiple copies of ppk accumulated not only a large amount of poly(P) but also recA mRNA. Since recA expression was induced in a recA-deletion strain harboring a plasmid with the ppk gene, poly(P) could be necessary for regulating the expression of SOS genes without depending on the RecA-LexA regulatory network.

Escherichia coli RuvA and RuvB proteins involved in recombination repair: physical properties and interactions with DNA

SummaryEscherichia coli RuvA and RuvB proteins are encoded by an SOS-regulated operon, which is involved in DNA repair and recombination. RuvB has weak ATPase activity, which is enhanced by the addition of RuvA and DNA, and RuvA and RuvB in the presence of ATP promote branch migration at Holliday junctions. In this work, the physical states of RuvA and RuvB and their interactions with DNA were studied by sedimentation analysis and gel filtration chromatography. RuvA formed a stable tetramer in solution, which resisted dissociation by SDS at room temperature. RuvB formed a dimer in solution. When RuvA and RuvB were mixed, an oligomer complex was formed consisting of a tetrameric form of RuvA and a dimeric form of RuvB, and this complex bound to DNA. The maximal enhancement of the RuvB ATPase activity by RuvA was achieved at this stoichiometry in the presence of excess DNA.

A separation method for DNA computing based on concentration control

A separation method for DNA computing based on concentration control is presented. The concentration control method was earlier developed and has enabled us to use DNA concentrations as input data and as filters to extract target DNA. We have also applied the method to the shortest path problems, and have shown the potential of concentration control to solve large-scale combinatorial optimization problems. However, it is still quite difficult to separate different DNA with the same length and to quantify individual DNA concentrations. To overcome these difficulties, we use DGGE and CDGE in this paper. We demonstrate that the proposed method enables us to separate different DNA with the same length efficiently, and we actually solve an instance of the shortest path problems.

Proteolytic processing of MucA protein in SOS mutagenesis: Both processed and unprocessed MucA may be active in the mutagenesis

SummaryThe mucAB operon carried on plasmid pKM101, which is an analogue of the umuDC operon of Escherichia coli, is involved in UV mutagenesis and mutagenesis induced by many chemicals. Mutagenesis dependent on either the umuDC or mucAB operon requires the function of the recA gene and is called SOS mutagenesis. By treating the cell with agents that damage DNA, RecA protein is activated by conversion into a form (RecA*) that mediates proteolytic cleavage of the LexA repressor and derepresses the SOS genes including mucAB. Since UmuD protein is proteolytically processed to an active form (UmuD*) in a RecA*-dependent fashion, and MucA shares extensive amino acid homology with UmuD, we examined whether MucA is similarly processed in the cell, using antiserum against a LacZ′-′MucA fusion protein. Like UmuD, MucA protein is indeed proteolytically processed in a RecA*-dependent fashion. In recA430 strains, MucAB but not UmuDC can mediate UV mutagenesis. However, MucA was not processed in the recA430 cells treated with mitomycin C. We constructed, by site-directed mutagenesis, several mutant mucA genes that encode MucA proteins with alterations in the amino acids flanking the putative cleavage site (Ala25-Gly26). MucA(Cys25) was processed and was as mutagenically active as wild-type MucA; MucA(Asp26) and MucA(Cys25,Asp26) were not processed, and were mutagenically inactive; MucA-(Thr25) was not processed, but was mutagenically as active as wild-type MucA. The mutant mucA gene that encoded the putative cleavage product of MucA was as active as mucA+ in UV mutagenesis. These results raise the possibility that both the nascent MucA and the processed product are active in mutagenesis.

Polyphosphate:AMP phosphotransferase as a polyphosphate-dependent nucleoside monophosphate kinase in Acinetobacter johnsonii 210A.

We have cloned the gene for polyphosphate:AMP phosphotransferase (PAP), the enzyme that catalyzes phosphorylation of AMP to ADP at the expense of polyphosphate [poly(P)] in Acinetobacter johnsonii 210A. A genomic DNA library was constructed in Escherichia coli, and crude lysates of about 6,000 clones were screened for PAP activity. PAP activity was evaluated by measuring ATP produced by the coupled reactions of PAP and purified E. coli poly(P) kinases (PPKs). In this coupled reaction, PAP produces ADP from poly(P) and AMP, and the resulting ADP is converted to ATP by PPK. The isolated pap gene (1,428 bp) encodes a protein of 475 amino acids with a molecular mass of 55.8 kDa. The C-terminal region of PAP is highly homologous with PPK2 homologs isolated from Pseudomonas aeruginosa PAO1. Two putative phosphate-binding motifs (P-loops) were also identified. The purified PAP enzyme had not only strong PAP activity but also poly(P)-dependent nucleoside monophosphate kinase activity, by which it converted ribonucleoside monophosphates and deoxyribonucleoside monophosphates to ribonucleoside diphosphates and deoxyribonucleoside diphosphates, respectively. The activity for AMP was about 10 times greater than that for GMP and 770 and about 1,100 times greater than that for UMP and CMP.

LOCAL SEARCH BY CONCENTRATION-CONTROLLED DNA COMPUTING

Concentration-controlled DNA computing is presented for accomplishing a local search for the solution of a shortest path problem. In this method, the concentrations of DNA representing edges are determined according to the costs on edges, and then the hybridization process is performed. Since the concentrations of hopeless candidate solutions tend to be small after the hybridization process, a local search by concentration-controlled DNA computing is a promising approach. In order to discuss about the relationship between given costs on edges in the graph and concentrations of generated DNA paths, a simulation model of the hybridization process is used and the results of a laboratory experiment are shown.

Involvement in DNA repair of the ruvA gene of Escherichia coli

SummaryThe ruv operon of Escherichia coli consists of two genes, orfl1 and ruv, which encode 22 and 37 kilodalton proteins, respectively, and are regulated by the SOS system. Although the distal gene, ruv, is known to be involved in DNA repair, the function of orf1 has not been studied. To examine whether orf1 is also involved in DNA repair, we constructed a strain with a deletion of the entire ruv operon. The strain was sensitive to UV even after introduction of low copy number plasmids carrying either orf1 or ruv, but UV resistance was restored by introduction of a plasmid carrying both orfl and ruv. These results suggest that orf1 as well as ruv is involved in DNA repair. Therefore, orf1 and ruv should be renamed ruvA and ruvB, respectively.