Evidence for unique DNA repair activity encoded by a cloned Serratia marcescens gene: suppression of Escherichia coli mutations that reduce repair of alkylated DNA.

A recombinant plasmid containing a Serratia marcescens DNA repair gene has been analyzed biochemically and genetically in Escherichia coli mutants deficient for repair of alkylated DNA. The cloned gene suppressed sensitivity to methyl methanesulfonate of an E. coli strain deficient in 3-methyladenine DNA glycosylases I and II (i.e., E. coli tag alkA) and two different E. coli recA mutants. Attempts to suppress the methyl methanesulfonate sensitivity of the E. coli recA mutant by using the cloned E. coli tag and alkA genes were not successful. Southern blot analysis did not reveal any homology between the S. marcescens gene and various known E. coli DNA repair genes. Biochemical analysis with the S. marcescens gene showed that the encoded DNA repair protein liberated 3-methyladenine from alkylated DNA, indicating that the DNA repair molecular is an S. marcescens 3-methyladenine DNA glycosylase. The ability to suppress both types of E. coli DNA repair mutations, however, suggests that the S. marcescens gene is a unique bacterial DNA repair gene.     

Role of DNA in Bacterial Aggregation

The role of DNA in bacterial aggregation was determined using various types of DNA and Escherichia coli, a good model for investigating the correlation between added polymer and bacterial aggregation and adsorption of polymer to bacterial surfaces. The results of the aggregation assay suggest that extracellular DNA indeed increased the aggregation percentage of E. coli, but this effect was dependent on DNA concentration and length. Moreover, DNA promoted bacterial aggregation in a type-nonspecific way. The combined results of the aggregation assay and the adsorption assay show further that the promotion of E. coli aggregation by DNA occurred along with adsorption of DNA to E. coli. Consequently, the possible mechanisms for DNA-promoted bacterial aggregation are discussed. Using fluorescent-labeled DNA, we mapped DNA within the E. coli aggregates. Subsequently, introduction of DNase I broke up the DNA-involved E. coli aggregates. These results suggest that DNA functions as a molecular bridge to promote E. coli aggregation.     

Isolation of Minicircular Deoxyribonucleic Acids from Wild Strains of Escherichia coli and their Relationship to other Bacterial Plasmids

Supercoiled minicircular deoxyribonucleic acid (DNA) molecules with molecular weights of 1.8 x 10(6) and 2.3 x 10(6) have been isolated from two wild strains of Escherichia coli. DNA-DNA hybridization experiments indicate that these DNA molecules share extended homologies with the minicircular DNA of E. coli 15. The DNA of the colicinogenic factor E1 (ColE1) also hybridizes to a large extent with minicircular DNA of E. coli 15. In contrast, no hybridization could be detected with various large extrachromosomal DNA elements such as the colicinogenic factor V (ColV), the beta-hemolytic factor (Hly), or the P1-like DNA of E. coli 15. Two different insertion DNA species of E. coli integrated into lambdadg-DNA (lambdadg UP(in) 128, lambdadg UP(in) 308) do not show any annealing with minicircular DNA of E. coli 15.     

The expression of the DNA ligase gene of Escherichia coli is stimulated by relaxation of chromosomal supercoiling

Many genes of Escherichia coli have been shown to be sensitive to DNA superhelicity. The superhelicity of the chromosome is itself also supercoiling-dependent. We have developed a general strategy for investigating how a particular gene responds to changes in DNA topology. This approach is used to study the E. coli ligase gene. The thermosensitivity of the E. coli ligts251 mutation can be phenotypically suppressed by mutations which map close to, or in, the gyrB gene and which affect the degree of DNA supercoiling. The level of suppression correlates with the degree of DNA relaxation observed, suggesting that the gene encoding the E. coli DNA ligase is activated by relaxation of the chromosomal DNA.     

Eukaryotic HMGB proteins as replacements for HU in E. coli repression loop formation

DNA looping is important for gene repression and activation in Escherichia coli and is necessary for some kinds of gene regulation and recombination in eukaryotes. We are interested in sequence-nonspecific architectural DNA-binding proteins that alter the apparent flexibility of DNA by producing transient bends or kinks in DNA. The bacterial heat unstable (HU) and eukaryotic high-mobility group B (HMGB) proteins fall into this category. We have exploited a sensitive genetic assay of DNA looping in living E. coli cells to explore the extent to which HMGB proteins and derivatives can complement a DNA looping defect in E. coli lacking HU protein. Here, we show that derivatives of the yeast HMGB protein Nhp6A rescue DNA looping in E. coli lacking HU, in some cases facilitating looping to a greater extent than is observed in E. coli expressing normal levels of HU protein. Nhp6A-induced changes in the DNA length-dependence of repression efficiency suggest that Nhp6A alters DNA twist in vivo. In contrast, human HMGB2-box A derivatives did not rescue looping.     

Interaction of DNA with DNA binding proteins. III. Infectivity of protein-complexed phage fd DNA in Escherichia coli spheroplasts.

Complex formation of circular, single-stranded phage fd DNA with Escherichia coli DNA binding protein HD or phage fd gene 5 protein keeps infection of E. coli spheroplasts at the level of free phage DNA, whereas complexes of this DNA with E. coli DNA unwinding protein show a strongly reduced efficiency of transfection. Displacement of the unwinding protein by HD protein or gene 5 protein also maintains the poor adsorption of the complexes to spheroplasts. Free E. coli DNA unwinding protein and residual amounts of this protein bound to the DNA may interfere with the adsorption and the uptake of the phage genome.     

A rapid procedure to purify Escherichia coli DNA topoisomerase I

On the basis of the asymmetrical charge distribution of Escherichia coli DNA topoisomerase I, we developed a new procedure to purify E. coli DNA topoisomerase I in the milligram range. The new procedure includes using both cation- and anion-exchange columns, i.e., SP-Sepharose FF and Q-Sepharose FF columns. The E. coli DNA topoisomerase I purified here is free of DNase contamination. The kinetic constants of the DNA relaxation reaction of E. coli DNA topoisomerase I were also determined.     

Screening recombinant clones containing sequences homologous to Escherichia coli genes using single-stranded bacteriophage vector

Detection and isolation of Escherichia coli clones carrying vectors with foreign DNA sequences partially homologous to specific E. coli genes is difficult because denatured DNA in the host genome can hybridize with the probe. In this paper we present a procedure which simplifies this task by using bacteriophage M13 as the cloning vector. The procedure takes advantage of the secretory properties of the phage, as well as the property of nitrocellulose membrane to bind protein and single-stranded DNA but not double-stranded DNA. This procedure is shown to be effective in identifying E. coli clones containing sequences of Chlamydomonas reinhardtii chloroplast DNA that are homologous to the rpoC gene of E. coli. We suggest that this procedure can be used generally for rapid isolation of DNA sequences that are homologous to E. coli genes.     

DNA polymerase beta can substitute for DNA polymerase I in the initiation of plasmid DNA replication.

We previously demonstrated that mammalian DNA polymerase beta can substitute for DNA polymerase I of Escherichia coli in DNA replication and in base excision repair. We have now obtained genetic evidence suggesting that DNA polymerase beta can substitute for E. coli DNA polymerase I in the initiation of replication of a plasmid containing a pMB1 origin of DNA replication. Specifically, we demonstrate that a plasmid with a pMB1 origin of replication can be maintained in an E. coli polA mutant in the presence of mammalian DNA polymerase beta. Our results suggest that mammalian DNA polymerase beta can substitute for E. coli DNA polymerase I by initiating DNA replication of this plasmid from the 3' OH terminus of the RNA-DNA hybrid at the origin of replication.     

The Escherichia coli dam DNA methyltransferase modifies DNA in a highly processive reaction

The Escherichia coli dam adenine-N6 methyltransferase modifies DNA at GATC sequences. It is involved in post-replicative mismatch repair, control of DNA replication and gene regulation. We show that E. coli dam acts as a functional monomer and methylates only one strand of the DNA in each binding event. The preferred way of ternary complex assembly is that the enzyme first binds to DNA and then to S-adenosylmethionine. The enzyme methylates an oligonucleotide containing two dam sites and a 879 bp PCR product with four sites in a fully processive reaction. On lambda-DNA comprising 48,502 bp and 116 dam sites, E. coli dam scans 3000 dam sites per binding event in a random walk, that on average leads to a processive methylation of 55 sites. Processive methylation of DNA considerably accelerates DNA methylation. The highly processive mechanism of E. coli dam could explain why small amounts of E. coli dam are able to maintain the methylation state of dam sites during DNA replication. Furthermore, our data support the general rule that solitary DNA methyltransferase modify DNA processively whereas methyltransferases belonging to a restriction-modification system show a distributive mechanism, because processive methylation of DNA would interfere with the biological function of restriction-modification systems.     

Thermal Stability of Escherichia coli–Salmonella typhimurium Deoxyribonucleic Acid Duplexes

Single-stranded, labeled deoxyribonucleic acid (DNA) fragments from Escherichia coli were incubated at 60 and 66 C with a large excess of single-stranded, unlabeled DNA fragments from E. coli and Salmonella typhimurium. The resulting reassociated DNA was adsorbed to hydroxylapatite and eluted in a series of washes at increasing temperatures. The thermal stability of the reassociated DNA was determined by means of this procedure. Neither the extent of reassociation nor stability of the reassociated E. coli DNA was affected by increasing the incubation temperature from 60 to 66 C. The double-stranded molecules resulting from the reassociation of E. coli DNA with S. typhimurium DNA had a markedly lower thermal stability than reassociated E. coli DNA. More reassociation occurred between E. coli and S. typhimurium at 60 C than at 66 C. In addition, the product of interspecies reassociation occurring at 66 C had a higher thermal stability than that occurring at 60 C. Preliminary results indicate that the decreased thermal stability of the interspecies duplex is in part the result of unpaired bases.     

Myocardium of mdx mice contains factor(s) that damage DNA structure and retard DNA reparation after gamma-irradiation (experiences in modeling system)

We studied the action of saline extracts of ventricle myocard (EM) of C57BL and mdx mice on DNA structure and repair of one-strand breaks of DNA in a modelling system. The system involves DNA repair in E. coli WP2 cells after gamma-irradiation. Using standard technique, DNA reparation was estimated on measuring the speed of E. coli DNA sedimentation in alkaline sucrose gradients. It was shown, that EM of C57BL or mdx mice exerted no influence on DNA repair, which was completely declined within 60 min with EM present in the growth medium of permeabilized E. coli. Addition of C57BL mice EM into lytic solution does not accelerate DNA sedimentation of nonirradiated E. coli. At the same time, EM of mdx mice sharply accelerates DNA sedimentation of nonirradiated E. coli reducing DNA molecular weight from 200 x 10(6) to 135 x 10(6) Da. At entering in the lytic solution the EM of mdx mice also slows down E. coli DNA repair after gamma-irradiation. It is supposed, that EM of mdx mice may contain a factor(s) damaging DNA in the E. coli lysate and presumably slowing down DNA reparation after gamma-irradiation. Russian Foundation of Basic Research Grants 99-04-49390, 02-04-49870 and 00-04-49390.     

The replicative origin of the E. coli chromosome binds to cell membranes only when hemimethylated

DNA from the E. coli replicative origin binds with high affinity to outer membrane preparations. Specific binding regions are contained within a 463 bp stretch of origin DNA between positions -46 and +417 on the oriC map. This region of DNA contains an unusually high number of GATC sites, the recognition sequence for the E. coli DNA adenine methylase. We show here that oriC DNA binds to membrane only when it is hemimethylated. The E. coli chromosomal origin is hemimethylated for 8-10 min after initiation of replication, and origin DNA binds to membranes only during this time period. Based on these results, we propose a speculative model for chromosome segregation in E. coli.     

Cloning and analysis of the spc ribosomal protein operon of Bacillus subtilis: comparison with the spc operon of Escherichia coli.

A segment of Bacillus subtilis chromosomal DNA homologous to the Escherichia coli spc ribosomal protein operon was isolated using cloned E. coli rplE (L5) DNA as a hybridization probe. DNA sequence analysis of the B. subtilis cloned DNA indicated a high degree of conservation of spc operon ribosomal protein genes between B. subtilis and E. coli. This fragment contains DNA homologous to the promoter-proximal region of the spc operon, including coding sequences for ribosomal proteins L14, L24, L5, S14, and part of S8; the organization of B. subtilis genes in this region is identical to that found in E. coli. A region homologous to the E. coli L16, L29 and S17 genes, the last genes of the S10 operon, was located upstream from the gene for L14, the first gene in the spc operon. Although the ribosomal protein coding sequences showed 40-60% amino acid identity with E. coli sequences, we failed to find sequences which would form a structure resembling the E. coli target site for the S8 translational repressor, located near the beginning of the L5 coding region in E. coli, in this region or elsewhere in the B. subtilis spc DNA.     

Analysis of genome plasticity in pathogenic and commensal Escherichia coli isolates by use of DNA arrays

Genomes of prokaryotes differ significantly in size and DNA composition. Escherichia coli is considered a model organism to analyze the processes involved in bacterial genome evolution, as the species comprises numerous pathogenic and commensal variants. Pathogenic and nonpathogenic E. coli strains differ in the presence and absence of additional DNA elements contributing to specific virulence traits and also in the presence and absence of additional genetic information. To analyze the genetic diversity of pathogenic and commensal E. coli isolates, a whole-genome approach was applied. Using DNA arrays, the presence of all translatable open reading frames (ORFs) of nonpathogenic E. coli K-12 strain MG1655 was investigated in 26 E. coli isolates, including various extraintestinal and intestinal pathogenic E. coli isolates, 3 pathogenicity island deletion mutants, and commensal and laboratory strains. Additionally, the presence of virulence-associated genes of E. coli was determined using a DNA "pathoarray" developed in our laboratory. The frequency and distributional pattern of genomic variations vary widely in different E. coli strains. Up to 10% of the E. coli K-12-specific ORFs were not detectable in the genomes of the different strains. DNA sequences described for extraintestinal or intestinal pathogenic E. coli are more frequently detectable in isolates of the same origin than in other pathotypes. Several genes coding for virulence or fitness factors are also present in commensal E. coli isolates. Based on these results, the conserved E. coli core genome is estimated to consist of at least 3,100 translatable ORFs. The absence of K-12-specific ORFs was detectable in all chromosomal regions. These data demonstrate the great genome heterogeneity and genetic diversity among E. coli strains and underline the fact that both the acquisition and deletion of DNA elements are important processes involved in the evolution of prokaryotes.     

The identification and partial characterization of a plasmid containing the gene for the membrane-associated hydrogenase from E. coli

Escherichia coli DNA was digested with restriction endonuclease PstI and ligated into the PstI site of plasmid pBR322. Recombinant plasmids that were constructed in this manner were used to transform E. coli H61, a mutant with a decreased level of hydrogenase activity. Complementation of this hydrogenase mutation identified a bacterial clone carrying the gene for the membrane-associated E. coli hydrogenase in plasmid pBL101. In E. coli minicells, the pBL101 DNA directed the synthesis of a protein of a size corresponding to that of the precursor of the E. coli membrane-associated hydrogenase, which appears to contain an uncleaved leader peptide. A restriction map of the cloned DNA was determined for 14 endonucleases.     

In vitro mutagenesis and functional expression in Escherichia coli of a cDNA encoding the catalytic domain of human DNA ligase I.

Human cDNAs encoding fragments of DNA ligase I, the major replicative DNA ligase in mammalian cells, have been expressed as lacZ fusion proteins in Escherichia coli. A cDNA encoding the carboxyl-terminal catalytic domain of human DNA ligase I was able to complement a conditional-lethal DNA ligase mutation in E. coli as measured by growth of the mutant strain at the non-permissive temperature. Targeted deletions of the amino and carboxyl termini of the catalytic domain identified a minimum size necessary for catalytic function and a maximum size for optimal complementing activity in E. coli. The human cDNA was subjected to systematic site-directed mutagenesis in vitro and mutant polypeptides assayed for functional expression in the E. coli DNA ligase mutant. Such functional analysis of the active site of DNA ligase I identified specific residues required for the formation of an enzyme-adenylate reaction intermediate.     

The irreversible binding of azacytosine-containing DNA fragments to bacterial DNA(cytosine-5)methyltransferases

DNA containing 5-azacytosine is an irreversible inhibitor of DNA(cytosine-5)methyltransferase. This paper describes the binding of DNA methyltransferase to 32P-labeled fragments of DNA containing 5-azacytosine. The complexes were identified by gel electrophoresis. The EcoRII methyltransferase specified by the R15 plasmid was purified from Escherichia coli B(R15). This enzyme methylates the second C in the sequence CCAGG and has a molecular mass of 60,000 Da. Specific binding of enzyme to DNA fragments could be detected if either excess unlabeled DNA or 0.8% sodium dodecyl sulfate was added to the reaction mixture prior to electrophoresis. Binding was dependent upon the presence of both the CCAGG sequence and azacytosine in the DNA fragment. S-Adenosylmethionine stimulated the formation of the complex. The complex was stable to 6 M urea but could be digested with pronase. These DNA fragments could be used to detect the presence of several different methyltransferases in crude extracts of E. coli. No DNA protein complexes could be detected in E. coli B extracts, a strain that contains no DNA(cytosine-5)methyltransferases. The chromosomally determined methylase with the same specificity as the purified EcoRII methylase could be detected in crude extracts of E. coli K12 strains. The MspI methylase cloned in E. coli HB101 could also be detected in crude extracts. These enzymes are the only proteins that bind azacytosine-containing DNA in crude extracts of E. coli.     

M13-oriC cloning vehicles: use for amplification of high copy lethal (HCL) genetic elements

M13 cloning vehicles have been constructed which contain the Escherichia coli origin for DNA replication (oriC), with and without selectable antibiotic-resistance genes. Since the M13 viral strand origin requires a functional rep gene product, using oriC these vehicles propagate as low-copy-number plasmids in E. coli rep mutants. This property is exploited to amplify cloned "high copy lethal" (HCL) DNA fragments, those containing genetic elements which kill the E. coli host when present at multiple copies in the cell. Following cloning of such fragments in these vehicles and initial selection in E. coli rep cells, the M13-oriC chimeric plasmid DNA is used to transfect appropriate E. coli rep+ cells. The chimeric DNA propagates as M13 viral DNA, yielding double-stranded and single-stranded DNA products and phage particles prior to killing of the host via expression of the HCL element; these events mimic a lytic phage infection. Such amplification will greatly facilitate both DNA "library" constructions (HCL elements are absent a priori from libraries using high-copy-number cloning vehicles) and studies of HCL elements including restriction mapping, DNA sequencing, and physiological studies.     

Phenotypic and genotypic comparison of Escherichia coli from pristine tropical waters.

Nine fecal-coliform-positive strains were isolated from pristine sites in a tropical rain forest. These sites included nonpolluted rivers and water from bromeliads (epiphytes) which were 30 ft (ca. 910 cm) above the ground. Phenotypically, all of these isolates were identified as Escherichia coli. Their DNA was isolated and purified, and the base composition (G + C content) was determined and compared with that of E. coli B (ATCC 11303). The DNA from the environmental isolates was also hybridized to radiolabeled DNA from E. coli B. Eight strains had a DNA base composition similar to that of E. coli B and gave more than 75% homology with E. coli B. One strain had a different DNA base composition and a relatively low percentage of homology with the reference strain. The finding of E. coli in pristine tropical waters suggests that this bacterium could be a natural inhabitant in these environments and is not a reliable indicator of recent human fecal contamination in tropical waters. The indicators that are currently used in the tropics to test the biological quality of water should be reevaluated.