Chromosome Replication in Toluenized <Emphasis Type="Italic">Bacillus subtilis</Emphasis> Cells

BIOCHEMICAL studies of chromosome replication have been hampered by the unavailability of an adequate in vitro system with the basic features of in vivo DNA replication. The criteria for such a system are: (1) semiconservative replication; (2) normal biological activity of newly synthesized DNA; (3) normal advancement of the original replication fork; (4) rate of DNA replication equivalent to in vivo; and (5) expected phenotypic behaviour of temperature-sensitive dna mutants. Systems in Escherichia coli, a membrane-DNA fraction¹, an agar-embedded cell lysate² and toluene-treated cells³ have met two or three of the requirements. Several laboratories have also reported the expected behaviour of ts-dna E. coli mutants in toluenized cells^3–5.     

<Emphasis Type="Italic">Deinococcus radiodurans</Emphasis> RecX and <Emphasis Type="Italic">Escherichia coli</Emphasis> RecX proteins are capable to replace each other in vivo and in vitro

A plasmid carrying the Deinococcus radiodurans recX gene under the control of a lactose promoter decreases the Escherichia coli cell resistance to UV irradiation and γ irradiation and also influences the conjugational recombination process. The D. radiodurans RecX protein functions in the Escherichia coli cells similarly to the E. coli RecX protein. Isolated and purified D. radiodurans RecX and E. coli RecX proteins are able to replace each other interacting with the E. coli RecA and D. radiodurans RecA proteins in vitro. Data obtained demonstrated that regulatory interaction of RecA and RecX proteins preserves a high degree of conservatism despite all the differences in the recombination reparation system between E. coli and D. radiodurans.     

Conjugative plasmid transfer from <Emphasis Type="Italic">Escherichia coli</Emphasis> is a versatile approach for genetic transformation of thermophilic <Emphasis Type="Italic">Bacillus</Emphasis> and <Emphasis Type="Italic">Geobacillus</Emphasis> species

We previously demonstrated efficient transformation of the thermophile Geobacillus kaustophilus HTA426 using conjugative plasmid transfer from Escherichia coli BR408. To evaluate the versatility of this approach to thermophile transformation, this study examined genetic transformation of various thermophilic Bacillus and Geobacillus spp. using conjugative plasmid transfer from E. coli strains. E. coli BR408 successfully transferred the E. coli–Geobacillus shuttle plasmid pUCG18T to 16 of 18 thermophiles with transformation efficiencies between 4.1 × 10^?7 and 3.8 × 10^?2/recipient. Other E. coli strains that are different from E. coli BR408 in intracellular DNA methylation also generated transformants from 9 to 15 of the 18 thermophiles, including one that E. coli BR408 could not transform, although the transformation efficiencies of these strains were generally lower than those of E. coli BR408. The conjugation was performed by simple incubation of an E. coli donor and a thermophile recipient without optimization of experimental conditions. Moreover, thermophile transformants were distinguished from abundant E. coli donor only by high temperature incubation. These observations suggest that conjugative plasmid transfer, particularly using E. coli BR408, is a facile and versatile approach for plasmid introduction into thermophilic Bacillus and Geobacillus spp., and potentially a variety of other thermophiles.     

Polysaccharide-based silver nanoparticles synthesized by <Emphasis Type="Italic">Klebsiella oxytoca</Emphasis> DSM 29614 cause DNA fragmentation in <Emphasis Type="Italic">E. coli</Emphasis> cells

Silver nanoparticles (AgNPs), embedded into a specific exopolysaccharide (EPS), were produced by Klebsiella oxytoca DSM 29614 by adding AgNO₃ to the cultures during exponential growth phase. In particular, under aerobic or anaerobic conditions, two types of silver nanoparticles, named AgNPs-EPS^aer and the AgNPs-EPS^anaer, were produced respectively. The effects on bacterial cells was demonstrated by using Escherichia coli K12 and Kocuria rhizophila ATCC 9341 (ex Micrococcus luteus) as Gram-negative and Gram-positive tester strains, respectively. The best antimicrobial activity was observed for AgNPs-EPS^aer, in terms of minimum inhibitory concentrations and minimum bactericidal concentrations. Observations by transmission electron microscopy showed that the cell morphology of both tester strains changed during the exposition to AgNPs-EPS^aer. In particular, an electron-dense wrapped filament was observed in E. coli cytoplasm after 3 h of AgNPs-EPS^aer exposition, apparently due to silver accumulation in DNA, and both E. coli and K. rhizophila cells were lysed after 18 h of exposure to AgNPs-EPS^aer. The DNA breakage in E. coli cells was confirmed by the comparison of 3-D fluorescence spectra fingerprints of DNA. Finally the accumulation of silver on DNA of E. coli was confirmed directly by a significant Ag⁺ release from DNA, using the scanning electrochemical microscopy and the voltammetric determinations.     

Roles of Parental and Progeny DNA in Two Mechanisms of Phage S13 Recombination

THERE are at least two mechanisms for genetic recombination of phage S13–primary and secondary. They are distinguished by the amount of phage recombination observed in recombination-deficient (recA) bacterial hosts. An S13 cross performed in either of the recA hosts, Escherichia coli JC1553¹ or AB2463², yields a recombination frequency that is greatly reduced from that found in a rec⁺ host^{3, 4}; this suggests that the recA gene is required for the primary mechanism of S13 recombination. But even in a recA host the phage undergoes a small residual amount of recombination³ which has been attributed to a minor, secondary mechanism. Apparently the secondary mechanism functions in a recA cell and is only revealed when the primary mechanism is eliminated.     

Direct cloning and transplanting of large DNA fragments from Escherichia coli chromosome

We applied a resistance split-fusion strategy to increase the in vivo direct cloning efficiency mediated by Red recombination. The cat cassette was divided into two parts: cma (which has a homologous sequence with cmb) and cmb, each of which has no resistance separately unless the two parts are fused together. The cmb sequence was integrated into one flank of a target cloning region in the chromosome, and a linear vector containing the cma sequence was electroporated into the cells to directly capture the target region. Based on this strategy, we successfully cloned an approximately 48 kb DNA fragment from the E. coli DH1-Z chromosome with a positive frequency of approximately 80%. Combined with double-strand breakage-stimulated homologous recombination, we applied this strategy to successfully replace the corresponding region of the E. coli DH36 chromosome and knock out four non-essential genomic regions in one step. This strategy could provide a powerful tool for the heterologous expression of microbial natural product biosynthetic pathways for genome assembly and for the functional study of DNA sequences dozens of kilobases in length.     

<Emphasis Type="Italic">In vitro</Emphasis> Blastogenesis inhibited by <Emphasis Type="Italic">Erwinia carotovora</Emphasis><Emphasis Type="SmallCaps">L</Emphasis>-Asparaginase

Escherichia coliL-asparaginase, an antileukaemic agent in man¹, inhibits in vitro mitogen or antigen-induced blastogenesis in man^2,3 and in animals (M. Bennett, E. G. Mayhew and T. Han, unpublished data) and suppresses bone-marrow derived antibody precursor cells in the mouse⁴. We now report that another L-asparaginase preparation—from Erwinia carotovora—also possesses antileukaemic activity^5,6 and has a more pronounced immunosuppressive effect on in vitro blastogenesis than the E. coli enzyme.     

Quantitation of Some DNA Precursor Data

THE work of Kornberg on DNA repair and synthesis^1,2 implicates deoxyribonucleoside 5′-triphosphate as a direct precursor of DNA synthesis. This relationship was questioned by the possibility of alternative replication schemes^3,4. Werner⁵ studied the flux of thymine and thymidine into Escherichia coli DNA to determine the in vivo precursors of replicating DNA. Werner studied the incorporation of ³H labelled thymine into DNA and intracellular nucleotide pools under steady state conditions, in which thymine is converted into thymidine, thymidine monophosphate (TMP), thymidine diphosphate (TDP) and thymidine triphosphate (TTP). Werner measured separately the activities of labelled TMP, TDP, TTP and DNA at various times after E. coli cells had been exposed to a ³H-thymine synthetic medium. From a qualitative consideration of his results, Werner concluded that both TDP and TTP—but not TMP—were possible direct precursors of DNA replication.     

Identification and Mutational Analysis of <Emphasis Type="Italic">Escherichia coli</Emphasis> Sorbitol-Enhanced Glucose-Repressed <Emphasis Type="Italic">srlA</Emphasis> Promoter Expressed in LB Medium by Using Homologous Recombination and One-Round PCR Products

Escherichia coli has been used for recombinant protein production for many years. However, no native E. coli promoters have been found for constitutive expression in LB medium. To obtain high-expression E. coli promoters active in LB medium, we inserted various promoter regions upstream of eEmRFP that encodes a red fluorescent protein. Among the selected promoters, only colonies of srlA promoter transformants turned red on LB plate. srlA is a gene that regulates sorbitol utilization. The addition of sorbitol enhanced eEmRFP expression but glucose and other sugars repressed, indicating that srlAp is a sorbitol-enhanced glucose-repressed promoter. To analyze the srlAp sequence, a novel site-directed mutagenesis method was developed. Since we demonstrated that homologous recombination in E. coli could occur between 12-bp sequences, 12-bp overlapping sequences were attached to the set of primers that were designed to produce a full-length plasmid, denoted “one-round PCR product.” Using this method, we identified that the srlA promoter region was 100 bp. Further, the sequence adjacent to the start codon was found to be essential for high expression, suggesting that the traditionally used restriction enzyme sites for cloning in the promoter region have hindered expression. The srlA-driven expression system and DNA manipulation with one-round PCR products are useful tools in E. coli genetic engineering.     

Defective DNA Synthesis in Permeabilized Yeast Mutants

THE simple eukaryote, Saccharomyces cerevisiae, is suitable for combined genetic and biochemical analysis of the cell division cycle. More than forty temperature-sensitive mutants of S. cerevisiae defective in fifteen genes that control various steps of the yeast cell cycle have been detected by screening a collection of mutants with time-lapse photomicroscopy¹. Mutations in two genes, cdc4 and cdc8, result in defective DNA synthesis at the restrictive temperature². The product of cdc8 is apparently required throughout the period of DNA synthesis, because if a strain defective in this gene is shifted to 36° C within the S period, DNA replication ceases. In contrast, the product of cdc4 is apparently required only at the initiation of DNA synthesis because when a strain carrying a defect in this gene is shifted to 36° C, DNA replication already in progress is not impaired. Cells defective in cdc4, however, fail to initiate new rounds of DNA synthesis at the restrictive temperature. Based on these observations the DNA mutants have been tentatively classified as defective in DNA replication (cdc8) and in the initiation of DNA synthesis (cdc4).     

Direct Inhibition of <Emphasis Type="Italic">Col</Emphasis> E<Subscript>1</Subscript> Plasmid DNA Replication in <Emphasis Type="Italic">Escherichia coli</Emphasis> by Rifampicin

COLICINOGENIC factor E₁ (Col E₁) is a small bacterial plasmid (4.2×10⁶ daltons) present in colicinogenic strains of Escherichia coli¹ to the extent of about twenty-four copies per cell (Clewell and Helinski, unpublished results), which continues to replicate in the presence of high levels of chloramphenicol, a specific inhibitor of protein synthesis, although the chromosome only completes current rounds of replication and ceases (Clewell and Helinski, unpublished results). The average rate of Col E₁ semiconservative replication in the absence of protein synthesis is, in certain conditions, faster than (as much as eight times) the normal rate of synthesis (Clewell, unpublished results). Replication continues for 10–15 h after the addition of chloramphenicol, resulting in nearly 3,000 copies of Col E¹ DNA per cell. We are taking advantage of this system to study the effects of a number of antibiotics on DNA replication and now report evidence that rifampicin (an active semisynthetic derivative of rifamycin B)², an antibiotic known specifically to inhibit bacterial DNA dependent RNA polymerase^3–6, has a dramatic inhibitory effect on Col E¹ DNA replication.     

Replication of the DNA of the Colicinogenic Factor E<Subscript>1</Subscript> (Col E<Subscript>1</Subscript>) at the Restrictive Temperature in a DNA Replication Mutant thermosensitive for DNA Polymerase III

Evidence that polymerase I is the essential enzyme for DNA replication in E. coli is presented. A number of mechanisms for DNA duplication are suggested by the data.     

Characterization of the lipopolysaccharide of <Emphasis Type="Italic">Escherichia coli</Emphasis> 126

The lipopolysaccharide (LPS) of Escherichia coli 126 was isolated and studied. The lipid A fatty acid composition of the investigated LPS was similar to that of other members of the family Enterobacteriaceae. The E. coli 126 LPS was more toxic than the LPSs of previously studied E. coli strains and of other members of the Enterobacteriaceae (Budvicia aquatica and Pragia fontium), and was less pyrogenic than pyrogenal. SDS-PAG electrophoresis showed a bimodal distribution typical of S-form LPSs. The LPS of E. coli 126 decreased the adhesive index indicating a possible competition between LPS molecules of E. coli 126 and adhesins of E. coli F-50 on rabbit erythrocytes. The LPS of E. coli 126 in a homologous system showed antigenic activity in the reactions of double immunodiffusion in agar by Ouchterlony. No serological cross-reaction of the LPS of other E. coli strains, as well as of that of the B. aquatica type strain, with the antiserum to E. coli 126 was observed. The structural components of the lipopolysaccharide obtained by mild acid hydrolysis were lipid A, the core oligosaccharide, and the O-specific polysaccharide. Based on the data of monosaccharide analysis and ¹H and ¹³C NMR spectroscopy it was found that the O-specific polysaccharide had the structure characteristic of the representatives of E. coli serogroup O15.     

Gene <Emphasis Type="Italic">yddG</Emphasis> of <Emphasis Type="Italic">Escherichia coli</Emphasis> encoding the putative exporter of aromatic amino acids: Constitutive transcription and dependence of the expression on the cell growth rate

Gene yddG of Escherichia coli encodes a protein of the inner membrane. Data obtained earlier demonstrated that under conditions of aromatic amino acids overproduction YddG promotes their export from E. coli cells. In this work, a method of primer extension was used to localize the P _yddG promoter, which corresponds to E. coli promoters recognized by RNA polymerase in complex with σ⁷⁰ or σ^S subunits. By constructing a gene of the hybrid protein YddG’-LacZ at the intrinsic site of gene yddG location in the E. coli chromosome and analyzing the activity of β-galactosidase in cells growing on laboratory media LB and M9, the constitutive type of yddG expression at a low level was demonstrated (the activity was about 3 to 4% of the LacZ level under induction of the lac operon in E. coli wild-type cells). The expression of yddG had a twofold increase under conditions of retarded cell growth upon the stress caused by the high NaCl content (0.6 M) or by the presence of phenylalanine excess quantities (>1 mM) in the culture medium.     

In vivo study of fidelity of DNA double-strand break repair in bacteriophage T4

A method for in vivo studying the fidelity of DNA double-strand break (DSB) repair in bacteriophage T4 has been developed. The frequency of reversion of rII mutations to the wild phenotype was measured in i segC ⁺ × i ets1 segCΔ crosses, where ets1 is an insertion in the initial part of the rIB gene carrying a sequence recognized by SegC endonuclease; i designates a rIIB or rIIA mutation located at some distance from ets1, and segCΔ is a deletion in the segC gene. In such cross, a DSB occurs in the site of ets1. Their repair involves genetic recombination and DNA replication in the neighborhood of ets1. In parallel, the frequency of reversion of the same i mutant in the absence of DSBs is measured in i × i self-crosses. Reversions of different types (base substitutions, deletions, insertions) can be studied with the use of structurally different i mutations located at varying distances from ets1. The reversion frequencies were determined for three rIIB mutations and one rIIA mutation. The results obtained suggest that DSB repair in bacteriophage T4 is a process of high fidelity with the rate of errors that does not essentially exceed that in the case of usual phage multiplication.     

Effects of Colistin and Bacteriocins Combinations on the In Vitro Growth of <Emphasis Type="Italic">Escherichia coli</Emphasis> Strains from Swine Origin

Escherichia coli strains from swine origin, either susceptible or resistant to colistin, were grown under planktonic and biofilm cultures. After which, they were treated with antibacterial agents including nisin and enterocin DD14 bacteriocins, colistin and their combinations. Importantly, the combination of colistin, enterocin DD14 and nisin eradicated the planktonic and biofilm cultures of E. coli CIP54127 and the E. coli strains with colistin-resistance phenotype such as E. coli 184 (mcr-1 ⁺) and E. coli 289 (mcr-1 ^?), suggesting therefore that bacteriocins from lactic acid bacteria could be used as agents with antibiotic augmentation capability.     

Marker rescue of the adsorption properties of bacteriophage T 4 by bacteriophage T 2

Rescue of adsorption properties from UV-irradiated T4 by T2 as a helper phage, revealed progeny phage with intermediate properties. Fourteen independent progeny phages, plating onE. coli B/2, were plated on several indicator strains and their adsorption properties were also studied with specific T4 antibodies. Two of these, plating onE. coli KS/4, were not inactivated by the T4 antiserum, and were T2h without apparent T4 properties. The other 12 progeny phages did not plate on KS/4, and were inactivated, but at a slower rate than the parental T4. Their mean efficiency of plating onE. coli B/2 (0.83) was significantly lower than that of the parental T4. The efficiency of plating was positively correlated with the velocity of inactivation by T4 antiserum. The observations were explained by assuming that the progeny phages were recombinants of T4 and T2 loci for adsorption sites. Plating of these 12 progeny phages on several indicator strains showed that they were allrII mutants and all, except one, wererI mutants too. In addition, two weretu andh ⁴, respectively. The condition for the appearance of multiple mutants might be a complementation by T2 of UV-damaged functions, which otherwise fail to induce the completion of the lytic cycle in monocomplexes of extracellularly irradiated T4.     

Inhibition of Bacterial DNA Replication by 6-(<Emphasis Type="Italic">p</Emphasis>-Hydroxyphenylazo)-uracil

THE semi-conservative replication of DNA of Gram-positive bacteria is specifically inhibited by 6-(p-hydroxyphenyIazo)-uracil (HPUra; obtained from ICI) in an apparently novel mechanism^1–4. We have attempted to characterize the HPUra-sensitive site in replication using in vitro preparations of drug-sensitive bacteria. In particulate and soluble preparations of sensitive bacteria, however, HPUra at high concentration does not significantly inhibit polymerization of deoxyribonucleotides^2,4. Since these systems may not accurately represent the process of DNA replication as it occurs in vivo, we have examined the effect of HPUra on a more suitable, toluene-treated preparation of Bacillus subtilis described by Matsushita et al.⁵. In this preparation, DNA replication is ATP-dependent, utilizes deoxyribonucleotides to give biologically active DNA, semi-conservatively and sequentially in the proper gene order. HPUra can inhibit DNA replication by this system. We describe here the characteristics of HPUra inhibition and the conditions necessary for it to occur.