PriA participates in nascent DNA synthesis in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The question of whether discontinuous DNA replication operates only for the lagging strand or for both strands in E. coli remains unresolved. In this study, the participation of priA, B, C and rep genes in discontinuous DNA replication was examined by analyzing the size distribution of nascent DNA synthesized in wild-type, lig-7 and polA4113 genetic backgrounds. Inactivation of priA, but not priB, priC or rep, resulted in a significant increase of high molecular weight (HMW) DNA in the short pulse-labeled DNA in the wild-type lig ⁺ polA ⁺ strains. Inactivation of priA also produced a significant increase of HMW DNA in the nascent DNA synthesized in lig-7 and polA4113 strains. These results indicate that PriA is involved in the discontinuous synthesis of nascent DNA.     

Multiply branched replicative intermediates in E. coli and bacteriophage lambda

Summary Multiple branched DNA fragments present in a fast sedimenting complex comprising a minute fraction of the E. coli genome have been isolated. Similar structures were also observed among bacteriophage DNA replicative intermediates after infection of synchronized E. coli cells. These structures were found to be associated with the amino acid and thymidine starvation steps required for synchronization and originate either by initiation from secondary sites or by snap-back of daughter strands containing substantial single stranded regions in the vicinity of the growing point.     

Low-Molecular-Weight DNA Replication Intermediates in Escherichia coli: Mechanism of Formation and Strand Specificity

Chromosomal DNA replication intermediates, revealed in ligase-deficient conditions in vivo, are of low molecular weight (LMW) independently of the organism, suggesting discontinuous replication of both the leading and the lagging DNA strands. Yet, in vitro experiments with purified enzymes replicating sigma-structured substrates show continuous synthesis of the leading DNA strand in complete absence of ligase, supporting the textbook model of semi-discontinuous DNA replication. The discrepancy between the in vivo and in vitro results is rationalized by proposing that various excision repair events nick continuously synthesized leading strands after synthesis, producing the observed LMW intermediates. Here, we show that, in an Escherichia coli ligase-deficient strain with all known excision repair pathways inactivated, new DNA is still synthesized discontinuously. Furthermore, hybridization to strand-specific targets demonstrates that the LMW replication intermediates come from both the lagging and the leading strands. These results support the model of discontinuous leading strand synthesis in E. coli.     

Replication of Fpoh+ plasmid in mafA mutants of Escherichia coli defective in plasmid maintenance

Summary A class of F plasmids, designated Fpoh ⁺, was previously shown to be able to replicate extrachromosomally on Hfr strains by virtue of carrying the specific site or region poh ⁺ (permissive on Hfr) of the E. coli chromosome (Hiraga, 1975, 1976a). These plasmids were now found to replicate on E. coli mafA mutants (mafA1 and mafA23) that cannot support vegetative replication of F and some other F-like plasmids. The derivatives of Fpoh ⁺ that have lost the poh ⁺ site, on the other hand, failed to replicate on mafA mutants. These mutants harboring Fpoh ⁺ (but not Poh^- derivatives thereof) exhibit abnormal cell division and form elongated cells, presumably due to competition between Fpoh ⁺ and the host chromosome for some factor(s) essential for the initiation of DNA replication of the both replicons. It is tentatively concluded that the poh ⁺ site is required for F plasmids to replicate on mafA mutants as well as on Hfr strains. In view of the fact that the mechanism of inhibition of autonomous F DNA replication in mafA mutants and in Hfr strains are clearly different, the present data seem to provide strong support to the notion that the poh ⁺ region contains the replication origin of the E. coli chromosome.     

Plasmid replication and Hfr formation in strains of Escherichia coli carrying seg mutations.

Summary Several conditional-lethal mutations that do not permit the replication of F-factors ofEscherichia coli K-12 are located at a site calledseg. This gene is located on theE. coli chromosome betweenserB andthr. It is unrelated to other known genes involved in DNA replication. Strains carryingseg mutations were unable to replicate F-lac⁺, several F-gal⁺s, F-his⁺ and bacteriophage at 42°. However, neither phage T4, ColE1, nor any of the R factors tested were prevented from replicating at 42°C.When the kinetics of the loss of F-primes is studied inseg strains, it is found that the rate of curing depends on the size of the plasmid, larger F factors curing faster than smaller ones, and that Hfrs are formed at high frequencies. The Hfrs showed both F-genote enlargement and normal transfer of chromosomal markers. The F-genotes are unstable and segregate chromosomal markers at high frequencies. Some orthodox Hfrs were examined, and two that were known to revert to the F⁺ condition relatively frequently were found to generate enlarged F-genotes on mating, whereas two strains that were very stable with respect to reversion to the F⁺ state did not show F-genote formation.F-genote formation fromseg Hfr strains is dependent of a functionalrecA gene, as F-genote formation was not seen with aseg-2, recA-1 Hfr. This is in contrast to F-genote enlargement shown by both orthodox Hfrs and an Hfr strain constructed by integration of a temperature-sensitive F-gal⁺, whose F-genote enlargement is Rec-independent. Thus there may be more than one mechanism for the formation of enlarged F-genotes.     

Characterization of Simian virus 40 DNA component II during viral DNA replication

Replicating molecules of Simian virus 40 DNA labeled during a short pulse with [³H]thymidine have been fractionated by ultracentrifugation methods and the open circular form (DNA component II) has been characterized. The pulse-labeled DNA component II is a relatively small constituent (1 to 3%) of the pool of replicating molecules. Examination of the circular (18 S) and linear (16 S) strands of DNA component II by alkaline sedimentation and by degradation using exonuclease III of Escherichia coli reveals that the newly synthesized DNA is principally in the linear strand. Cleavage of pulse-labeled DNA component II by an fi⁺, R-factor restriction endonuclease from E. coli demonstrates that the interruption in the pulse-labeled strand is specifically located at the termination point for replication.During a chase period of 20 minutes the amount of DNA component II increases to about 6 to 8% of the total labeled viral DNA. The kinetics of formation of superhelical, DNA component I and disappearance of replicative intermediates are linear during the chase period. After several hours of continuous labeling of replicating viral DNA, the DNA component II pool consists mainly of molecules labeled in both strands with the interruption non-specifically located in either strand. These molecules probably arise by the random introduction of single-strand breaks in newly synthesized DNA component I. During short periods of continuous labeling with [³H]thymidine, the ratio of DNA components I to II increases as a function of the pulse duration. These results support a model for 8V 40 DNA replication in which the open circular form is a precursor of the superhelical form.     

Effect of Sucrose Concentration on the Infectivity of ϕX 174 DNA to Protoplast of Escherichia coli

The first step in branched-chain amino acid biosynthesis is catalyzed by acetohydroxyacid synthase (EC 2.2.1.6). This reaction involves decarboxylation of pyruvate followed by condensation with either an additional pyruvate molecule or with 2-oxobutyrate. The enzyme requires three cofactors, thiamine diphosphate (ThDP), a divalent ion, and flavin adenine dinucleotide (FAD). Escherichia coli contains three active isoenzymes, and acetohydroxyacid synthase I (AHAS I) large subunit is encoded by the ilvB gene. In this study, the ilvB gene from E. coli K-12 was cloned into expression vector pETDuet-1, and was expressed in E. coli BL21 (DH3). The purified protein was identified on a 12% SDS–PAGE gel as a single band with a mass of 65 kDa. The optimum temperature, buffer, and pH for E. coli K-12 AHAS I were 37 °C, potassium phosphate buffer, and 7.5. Km values for E. coli K-12 AHAS I binding to pyruvate, Mg⁺², ThDP, and FAD were 4.15, 1.26, 0.2 mM, and 0.61 μM respectively. Inhibition of purified AHAS I protein was determined with herbicides and new compounds.     

Repair of ultraviolet-light damaged ColE1 factor carrying Escherichia coli genes for guanine synthesis.

Summary Hybrid ColE1 plasmids called ColE1-cos-guaA or ColE1-cos-gal can be efficiently transduced into various E. coli K-12 cells through packaging into phage particles. Using these plasmids, repair of ultraviolet-light (UV) damaged ColE1 DNAs was studied in various UV sensitive E. coli K-12 mutants. (1) The host mutations uvrA and uvrB markedly reduced host-cell reactivation of UV-irradiated ColE1-cos-guaA. (2) Pre-existing hybrid ColE1 plasmids had no effect on the frequency of phage-mediated transduction of another differentially marked hybrid ColE1 DNAs. (3) ColE1-cos-guaA and ColE1-cos-gal DNAs could temporarily but not stably co-exist in E. coli K-12 recA cells. (4) The presence of ColE1-cos-gal in uvrB cells promoted the repair of super-infected UV-irradiated ColE1-cos-guaA about 7-fold. (5) The same ColE1-cos-gal plasmid in a uvrB recA double mutant did not have this promoting effect. These results indicate that the effect of resident hybrid ColE1 plasmids is manifested by the host recA ⁺ gen function(s) and suggest that ColE1 plasmid itself provides no recA ⁺-like functions.     

Induction of protein X in Escherichia coli.

Summary Certain treatments that damage DNA and/or inhibit replication in E. coli have been reported to induce synthesis of a new protein, termed protein X, in recA ⁺ lexA ⁺ strains. We have examined some of the treatments that might induce protein X and we have, in particular, tested the hypothesis of Gudas and Pardee (1975) that DNA degradation products play an essential role in the induction process.We confirmed that UV irradiation, nalidixic acid treatment, or thymine starvation result in protein X synthesis in wild type strains. However, we found that UV irradiation, unlike nalidixic acid, also induced protein X in recB strains, in which little DNA degradation occurs. Furthermore, we found that the presence of DNA fragments resulting from host-controlled restriction of phage DNA did not affect protein X synthesis. We conclude that no causal relationship exists between the production of DNA fragments and induction of protein X.The presence of the plasmid R46, which confers enhanced mutagenesis and UV resistance on its host, did not affect protein X synthesis. Growth in the presence of 5-bromouracil, which does not result in production of degradation fragments, resulted eventually in a low rate of protein X synthesis. In dnaA mutants, deficient in the initiation of new rounds of replication, UV irradiation induced protein X, again unlike nalidixic acid. Thus, the inhibition of active replication forks is not an essential requirement for protein X induction.     

Microbial Production of l-Threonine

l-Threonine producing α-amino-β-hydroxyvaleric acid resistant mutants were derived from E. coli K-12 with 3 x 10^-5 frequency. One of mutants, strain β-101, accummulated maximum amount of l-threonine (1. 9 g/liter) in medium. Among isoleucine, methionine and lysine auxotrophs derived from E. coli K-12, only methionine auxotrophs produced l-threonine. In contrast, among isoleucine, methionine and lysine auxotrophs derived from β-101, l-threonine accumulation was generally enhanced in isoleucine auxotrophs. One of isoleucine auxotrophs, strain βI-67, produced maximum amount of l-threonine (4. 7 g/liter). Methionine auxotroph, βM-7, derived from β-101 produced 3.8 g/liter, and βIM-4, methionine auxotroph derived from β1-67, produced 6.1 g/liter, when it was cultured in 3% glucose medium supplemented with 100 μg/ml of l-isoleucine and l-methionine, respectively. These l-threonine productivities of E. coli mutants were discussed with respect to the regulatory mechanisms of threonine biosynthesis. A favourable fermentation medium for l-threonine production by E. coli mutants was established by using strain βM-4.     

Structure and function of the region of the replication origin of the Bacillus subtilis chromosome

Summary A BamHI restriction endonuclease fragment, B7, which is replicated first among all other fragments derived from the Bacillus subtilis chromosome, was cloned in Escherichia coli using as vector a hybrid plasmid pMS102 that can replicate both in E. coli and B. subtilis. Digestion of pMS102 with BamHI produced two fragments and the smaller one was replaced by the B7 fragment.The cloned plasmid pMS102-B7 exhibited some peculiar properties that were not observed with plasmids containing other fragments from the B. subtilis chromosome. (1) E. coli cells harboring this plasmid stuck to each other and to glass. This property was more apparent when cells were grown in poor media. (2) E. coli cells tended to lose the plasmid spontaneously when they were grown without the selective pressure favorable to the plasmid. (3) The frequency of transformation of B. subtilis by pMS102-B7 was less than 1/1,000 of that by the vector plasmid pMS102. The number of copies of pMS102-B7 present in the transformants was also markedly reduced, although the pUB110 origin of replication on the vector was intact and should be functional in B. subtilis. This inhibitory effect of the B7 fragment on plasmid replication was confirmed more directly by developing a semi in vitro replication system using protoplasts.Both in E. coli and B. subtilis the B7 fragment affected replication of its own molecule but not that of the coexisting plasmid with an identical replication system. The implication of the function of the B7 fragment in the initiation of the B. subtilis chromosome will be discussed.     

The influence of colicinogenic plasmids ColIb-P9, ColIa-CA53 and ColV-K30 on the repair, mutagenesis and induction of colicin E1 synthesis

Summary The presence of colicinogenic plasmids ColIb-P9 and ColIa-CA53 in E. coli K-12 cells, wild-type with respect to repair, enhanced the survival of cells after UV irradiation and increased the frequency of UV-induced argE3 and his-4 reversions, while the presence of ColV-K30 negatively affected repair and mutagenesis. The plasmid ColIb-P9 showed a UV-protective effect in E. coli cells carrying mutations in genes uvrA, uvrB, uvrC, polA, recB, recF, though in none of the mutants did cell survival reach the wild-type level. The effect of ColIb-P9 on mutagenesis did not depend on the uvrA or recB genes. The plasmids' protective effect and the enhancement of mutagenesis depended on the recA ⁺ lexA⁺ genotype. The frequency of 2-aminopurine-induced mutations was not affected by ColIb-P9 or ColV-K30. The presence of ColIb-P9 decreased the ability of ColEl-carrying cells to induce colicin E1 synthesis caused by DNA-damaging agents: UV, MNNG, mitomycin C, whereas ColV-K30 increased the percentage of colicin E1-producing cells. These plasmid effects on the level of induction of colicin E1 synthesis were not observed in the case of induction caused by chloramphenicol which did not depend on the products of recA and lexA genes.Abbreviations AP 2-aminopurine - MNNG N-methyl-N-nitro-N-nitrosoguanidine - ICS induction of colicin synthesis - CM chlorampheniol - MC mitomycin C     

Transfer ofF′ fromEscherichia coli K 12 toEscherichia coli B and to strains ofParacolobacter andKlebsiella

The transfer of theF episome fromEscherichia coli K 12 toE. coli B,Paracolobacter andKlebsiella was studied. The frequency of transfer of the episomal markers toE. coli B was very low. The large majority ofE. coli B cells which had received the episomal markerslac ⁺ orgal ⁺ were F^–, which indicates that the episomal markers were stably integrated on the chromosome. Recombinants from K 12 F⁺ × B F^– crosses were mostly F^–. These results suggest that the multiplication of theF-factor ofE. coli K 12 is restricted inE. coli B. The transfer of theF-lac ⁺ Ad ⁺ episome fromE. coli K 12 toParacolobacter andKlebsiella strains was in most cases only possible when donor and acceptor strain were plated together on selective media. Stable incorporation of episomal markers was also found withParacolobacter coliforme. Paracolobacter aerogenoides andKlebsiella aerogenes strains could be infected withF-lac ⁺ Ad ⁺. The episomal markers were not incorporated and the episomes were easily lost, which indicates that these strains contained theF factor in the autonomous state.     

A suitable method for construction and cloning hybrid plasmids containing EcoRI-fragments of E. coli genome.

Summary A convenient procedure for the isolation of specificEcoRI-fragments ofE. coli genome and their amplification on Km-resistance plasmid vector CK 11 is described. The hybrid molecules were constructedin vitro usingEcoRI-digestion, followed by ligation. Then appropriatedE. coli strain was transformed with ligated DNA mixture and hybrid plasmids CK 11-arg ⁺, CK 11-his ⁺, CK 11-thr ⁺ and CK 11-leu ⁺ containing loci ofE. coli genome were selected by molecular cloning. The hybrid plasmids obtained consisted of oneEcoRI-fragment of initial plasmid CK 11 and one respective specific portion ofE. coli genome.     

DNA polymerase 3 and the replication of F and ColVBtrp in Escherichia coli K-12

Summary In an E. coli K-12 strain producing a thermolabile, mutagenic DNA polymerase III, enhanced reversion rates were observed for a trp missense mutation of Ftrp and ColVBtrp. In addition, replication of these plasmid DNA molecules was greatly reduced at the nonpermissive temperature. Both observations indicate that DNA polymerase III is involved in the replication of these plasmids.     

Mapping of IS1 elements flanking the argF gene region on the Escherichia coli K-12 chromosome

Summary Two directly-repeated IS1 elments have been mapped on the Escherichia coli K-12 chromosome at positions 23.2 kb and 34.5 kb counterclockwise of the IS3 element ₃₃ by using F-prime plasmids (including the F lac ^- proAB⁺ plasmid F128) that carry different portions of the bacterial chromosome in the purE to proA region. Mapping was accomplished in part by construction of EcoRI, BamHI, and BglII restriction enzyme cleavage maps. Electron microscope heteroduplex and hybridization studies indicate that the chromosomal region flanked by these IS1 elements is completely homologous to the IS1-argF-IS1 region (Tn2901) on the P1argF5 transducing phage (York and Stodolsky, 1981), which suggests that the argF gene region in the usual E. coli K-12 strains has a transposon-like structure.     

Plasmid (pKM101)-mediated enhancement of repair and mutagenesis: Dependence on chromosomal genes in Escherichia coli K-12

Summary The drug resistance plasmid pKM101 plays a major role in the Ames Salmonella/microsome carcinogen detecting system by enhancing chemical mutagenesis. It is shown that in Escherichia coli K-12 the plasmid pKM101 enhances both spontaneous and methyl methanesulfonate-caused reversion of an ochre mutation, bacterial survival after ultraviolet irradiation, and reactivation of ultraviolet-irradiated in unirradiated cells. All these effects are shown to be dependent on the recA ⁺ lexA⁺ genotype but not on the recB ⁺ recC⁺ or recF ⁺ genotypes. The recA lexA-dependence of the plasmid-mediated repair and mutagenesis suggests an interaction with the cell's inducible error-prone repair system. The presence of pKM101 is shown to cause an additional increase in methyl methanesulfonate mutagenesis in a tif mutant beyond that caused by growth at 42°. The presence of the plasmid raises the level of the Weigle-reactivation curve for the reactivation of ultraviolet-irradiated in E. coli and causes a shift of the maximum to a higher UV fluence. These observations suggest that pKM101 does not exert its effects by altering the regulation of the cell's error-prone repair system but rather by supplying a mechanistic component or components.     

The influence of pH and external H+ concentration on caesium toxicity and accumulation inEscherichia coli andBacillus subtilis

Summary Toxicity screening ofEscherichia coli NCIB 9484 andBacillus subtilis 007, NCIB 168 and NCIB 1650 has shown Cs⁺ to be the most toxic Group 1 metal cation. However, toxicity and accumulation of Cs⁺ by the bacteria was affected by two main external factors; pH and the presence of other monovalent cations, particularly K⁺. Over the pH range 6–9 bothE. coli andB. subtilis showed increasing sensitivity towards caesium as the pH was raised. The presence of K⁺ and Na⁺ in the laboratory media used lowered caesium toxicity and lowered acumulation of the metal. In order to assess accurately Cs⁺ toxicity towards the bacterial strains it was therefore necessary to define the K⁺:Cs⁺ ratio in the external medium. The minimum inhibitory K⁺:Cs⁺ concentration ratio for theBacillus strains tested was in the range 12–13 whileE. coli had a minimum inhibitory K⁺:Cs⁺ concentration ratio of 16.     

Involvement of DNA polymerase III in UV-induced mutagenesis of bacteriophage lambda

Summary It has been proposed that the mutation fixation processes stimulated by SOS induction result from an induced infidelity of DNA replication (Radman 1974). The aim of this study was to determine if mutator mutations in the E. coli DNA polymerase III might affect UV-induced mutagenesis.Using a phage mutation assay which can discriminate between targeted and untargeted mutations, we show that the polC74 mutator mutation (Sevastopoulos and Glaser 1977) primarily affects untargeted mutagenesis, which occurs in a recA1 genetic background and is amplified in the recA ⁺ genetic background. The polC74 mutation also increases the UV-induced mutagenesis of the bacterial chromosome. These results suggest that DNA polymerase III is involved in the process of UV-induced mutagenesis in E. coli.