Specific modification of DNA at E. coli RNA-polymerase binding sites

Specific modification of promoter regions of DNA has been studied. Plasmid pK56B1 DNA has been used as a model to test RNA-polymerase binding with DNA under various conditions. RNA-polymerase is shown to form specific complexes with DNA which are stable in solutions with a moderate ionic strength (0.1-0.2 M NaCl), under pH 5-8 in the presence of 0.5 M O-methylhydroxylamine of O-delta-aminooxybutylhydroxylamine. Escherichia coli JM103 cells have been transfected with DNAs treated with 0.5 M O-methylhydroxylamine at 37 degrees C, pH 5.2. The inactivation effects of the mutagen on single-stranded DNA of bacteriophage M13 m p1, double-stranded form of this bacteriophage (replicative form-RF) and on the complex of RNA-polymerase with RF DNA have been compared. The obtained data confirmed the specificity of reagent action with DNA sites binding with the enzyme. Selectivity of promoters modification has been confirmed also by the analysis of M13 m p1 DNA mutations induced in lacZ' gene by delta-aminooxybutylhydroxylamine effect on the DNA complex with DNA-polymerase.     

Z-form of intraphage DNA

The bacteriophage lambda gt10 DNA containing an insertion of 20 pairs of GC-bases capable of being arranged as Z-form was cloned. Two independent methodological approaches based on the main properties of Z-form were used to study the shape of the insertion: formation of transition bridges composed of unpaired nucleotides between left-rotating Z-forms and right-rotating B-forms of helix (j-domain) and high immunogenic activity of Z-form. O-beta-diethylaminoethylhydroxyamine (OHA), an analogue of hydroxylamine, is capable of reacting specifically with unpaired cytidines. In this work this modification was used to inhibit the process of restriction at BamH1-site adjacent to (gc)10 insertion, that N-Methyl-bis(2-chloethyl) amine (MBCA) is capable of fixing the Z-form of the insertion in situ. Fixed Z-form is conserved even after DNA has been isolated from bacteriophage, thereby providing an opportunity of its identification by anti-Z-antibodies. It was shown that from 4 to 6% of the total number of insertions are in the Z-form. The hypothesis of significant role of Z-form in the process of packing of DNA molecules in capsid is put forward.     

DNA repair in Bacillus subtilis: excision repair capacity of competent cells.

Competent Bacillus subtilis were investigated for their ability to support the repair of UV-irradiated bacteriophage and bacteriophage DNA. UV-irradiated bacteriophage DNA cannot be repaired to the same level as UV-irradiated bacteriophage, suggesting a deficiency in the ability of competent cells to repair UV damage. However, competent cells were as repair proficient as noncompetent cells in their ability to repair irradiated bacteriophage in marker rescue experiments. The increased sensitivity of irradiated DNA is shown to be due to the inability of excision repair to function on transfecting DNA in competent bacteria. Furthermore, competent cells show no evidence of possessing an inducible BsuR restriction system to complement their inducible BsuR modification enzyme.     

Irreversible changes in phage DNA after its protonation in solution and inside the virion detected by the transfection method

The dependence of irreversible structural changes in phage lambda DNA on the degree of its protonation in a solution and inside the virion has been found by measuring the transfection activity of bacteriophage. The different effect of ionic strength on pH-dependence of the irreversible changes in the structure of DNA upon its protonation in a solution or in situ has been registered and explained. The insignificant shift of pH from neutral region value in 0.1 M NaCl has resulted in a damaging effect of H+ ions on compact DNA in situ as compared to the DNA in a solution. The effect of H+ ions on compact DNA in situ is mainly based on the formation of noncovalent intermolecular DNA-protein and DNA-DNA linkages.     

Nucleotide sequence analysis of DNA. X. Complete nucleotide sequence of the cohesive ends of bacteriophage phi80 DNA

The base sequence of the cohesive ends of bacteriophage φ80 DNA has been shown to be identical to the base sequence of the cohesive ends of bacteriophage lambda DNA.     

Restriction map of the temperate phage E105 from the polylysogenic culture of Erwinia carotovora 268

DNA structure of the temperate bacteriophage E105 from polylysogenic culture of Erwinia carotovora 268 has been studied. The viral 29.12-29.17 MD DNA has been shown to be linear and nonpermuted. The complete restriction map of the viral DNA has been constructed for MvaI and HpaI and partial for Eco31 restriction endonucleases based on the pair hydrolysis of the native DNA as well as its fragments. Altogether, 19 sites for restriction endonucleases have been localized on bacteriophage DNA.     

Amino acid changes coded by bacteriophage T4 DNA polymerase mutator mutants. Relating structure to function

Previous studies on the selection of bacteriophage T4 mutator mutants have been extended and a method to regulate the mutator activity of DNA polymerase mutator strains has been developed. The nucleotide changes of 17 bacteriophage T4 DNA polymerase mutations that confer a mutator phenotype and the nucleotide substitutions of several other T4 DNA polymerase mutations have been determined. The most striking observation is that the distribution of DNA polymerase mutator mutations is not random; almost all mutator mutations are located in the N-terminal half of the DNA polymerase. It has been shown that the T4 DNA polymerase shares several regions of homology at the protein sequence level with DNA polymerases of herpes, adeno and pox viruses. From studies of bacteriophage T4 and herpes DNA polymerase mutants, and from analyses of similar protein sequences from several organisms, we conclude that DNA polymerase synthetic activities are located in the C-terminal half of the DNA polymerase and that exonucleolytic activity is located nearer the N terminus.     

Cloning fragments of bacteriophage T5 DNA, determining expression of phage-dependent ligase

Cloning vèctor lambda gt-p MB9 has been used for cloning of DNA fragments of bacteriophage T5 produced by EcoR*I activity. One clone contains a DNA fragment of 2.2 Md which has been mapped at 67-71% on the physical map of the genome. Functional studies have shown that bacteriophage lambda gt-T5 can grow on E. coli lights 7. Infection of this E.coli strain with phage lambda gt-T5 induces DNA-ligase activity which has been previously observed in E. Coli infected with bacteriophage T5.     

Restriction and Modification of Bacteriophage S2 in Haemophilus influenzae

The major conclusion from these studies is that variants of Haemophilus influenzae Rd which restrict and modify phage S2 are metastable and capable of giving rise to one another with high frequency. Nonrestrictive RdS cells segregate spontaneously to the restricting, modifying phenotype in about 5% of the progeny of a single clone. The restrictive cells derived from RdS revert to the nonrestrictive phenotype in 15 to 25% of the progeny of a single clone. These frequencies are not appreciably affected by treatment with acriflavine or ethidium bromide, compounds which affect plasmid stability, or by nitrosoguanidine, a powerful mutagen. The genetic locus for restriction and modification of bacteriophage S2 is found to have a chromosomal position between the biotin and proline loci. Restriction-modification of phage S2 has been shown to be a function of its deoxyribonucleic acid (DNA) in that transfection with S2 phage DNA or prophage DNA is subject to host restriction and modification. An enzyme preparation, which contains endodeoxyribonuclease but no appreciable exonuclease activity, from mutant H. influenzae com(-10) did not restrict phage S2.RdS DNA or prophage DNA transfecting activity, indicating that this endodeoxyribonuclease is not responsible for phage restriction. A new restriction enzyme isolated from H. influenzae Rd was found to be the major enzyme involved in the restriction of bacteriophage S2. The enzyme inactivated the transfecting activity of unmodified phage DNA but did not attack modified phage DNA. Unlike endodeoxyribonuclease R, this enzyme requires adenosine triphosphate and S-adenosylmethionine.     

Host specificity of DNA produced by Escherichia coli : XV. The role of nucleotide methylation in in vitro B-specific modification

It is shown that in vitro Escherichia coli strain B-specific modification of the replicative form of bacteriophage fd DNA is accompanied by the methylation of certain adenine moieties to form N-6-methyladenine. The reaction follows first order kinetics and saturation is reached when about four adenines are methylated per replicative form. No methyl groups are transferred to B-modified DNA.     

The effect of the phage lambda ral gene on the level of synthesis of the EcoK restriction endonuclease beta-subunit

E. coli hsd genes were subcloned from lambda 642 (ral+) into lambda L47.1 vector (ral-after replacement). The influence of bacteriophage lambda ral gene on the expression efficiency of hsdS kappa, hsdM kappa genes was investigated. It was shown, that its presence in vitro enhanced the synthesis of beta-subunit, hsdM gene product, and the increase of modification in vivo was observed. It is proposed that the increase of modification rate of lambda phage fully unmodified DNA is connected with the appearance of E. coli DNA methylase consisting of beta- and gamma-subunits but lacking alpha-subunit.     

The lysine residues implicated in the gene 5 protein association sites

Gene 5 protein, a DNA unwinding protein encoded by the bacteriophage fd, is self-associative in presence of DNA or oligonucleotides. The lysine residues implicated in the protein-protein binding domains have been identified after modification with acetimidate by means of peptide and amino acid analyses. These residues are Lys-7 and Lys-69.     

Isolation and characterization of a bacteriophage T5 mutant deficient in deoxynucleoside 5''-monophosphatase activity.

A bacteriophage T5 mutant has been isolated that is completely deficient in the induction of deoxynucleoside 5'-monophosphatase activity during infection of Escherichia coli F. The mutant bacteriophage has been shown to be deficient in the excretion of the final products of DNA degradation during infection of E. coli F, and about 30% of the host DNA's thymine residues were reinocorporated into phage DNA. During infection with this mutant, host DNA degradation to trichloroacetic acid-soluble products was normal, host DNA synthesis was shut off normally, and second-step transfer was not delayed. However, induction of early phage enzymes and production of DNA and phage were delayed by 5 to 15 min but eventually reached normal levels. The mutant's phenotype strongly suggests that the enzyme's role is to act at the final stage in the T5-induced system of host DNA degradation by hydrolyzing deoxynucleoside 5'-monophosphates to deoxynucleosides and free phosphate; failure to do this may delay expression of the second-step-transfer DNA.     

An efficient synthetic primer for the M13 cloning dideoxy sequencing system

The deoxytetradecamer d(AAAACGACGGCCAG) has been shown to be an excellent universal primer for sequence determination of DNA cloned into the bacteriophage M13 mp7, mp8, and mp9 series. This new primer offers several advantages over others currently available and it has been used to define the cloning of Hinf I fragments of bacteriophage S13 DNA into the Eco RI site of M13 mp7, utilizing the homologous complementary base pairing of the two restriction sites. Of the four possible sequence derivatives of the Hinf I GANTC recognition site, only those corresponding to GAATC and GATTC have been found at cloning sites in chimeras.     

Transfer of prophage Mu into methylotrophic bacteria in the plasmid RP4

Bacteriophage Mu genome has been transferred into the cells of Pseudomonas methanolica and Methylobacterium sp. SKF240, that are naturally resistant to the bacteriophage, as a fragment of a hybrid plasmid RP4::Mu cts62. Temperature induction of the bacteriophage results in host cell lysis. Plasmid RP::Mu cis62 is maintained in methylotrophic cells presenting a cointegrative structure.The genetic and electrophoretic, analyses of the DNA isolated from transconjugant cells have confirmed the conclusion. Bacteriophage Mu propagation has been shown to be restricted in methylotrophic cells.     

Biochemistry of DNA-Defective Amber Mutants of Bacteriophage T4 IV. DNA Synthesis in Plasmolyzed Cells

Requirements for bacteriophage T4 DNA synthesis have been investigated in situ by use of plasmolyzed infected cells. When such cells are incubated with dATP, dGTP, dTTP, hydroxymethyldeoxycytidine triphosphate, and rATP, significant semiconservative synthesis of DNA occurs. This DNA hybridizes preferentially to T4 DNA. T4 amber mutants defective in genes 44 and 45, which display a DNA-negative phenotype in vivo, are unable to synthesize DNA in situ. By contrast, T4 amber mutants bearing lesions in genes 41 and 62, which also display a DNA-negative phenotype in vivo, do allow DNA synthesis in situ, the extent of synthesis being 80 to 90% that of the wild-type synthesis under the same conditions. Cells infected with gene 42 mutants (dCMP hydroxymethylase) are unable to synthesize DNA in situ even though exogenous nucleotides are provided. Also one gene 1 mutant (deoxynucleotide kinase) was found to synthesize DNA in situ, but two other gene 1 mutants did not. These results point to possible roles of hydroxymethylase and kinase in DNA metabolism, in addition to provision of essential DNA precursors, as has recently been suggested by Wovcha et al. (1973).     

用蛋白质工程的方法改良枯草杆菌蛋白酶E(Subtilisin E)的抗氧化性

以含有蛋白酶E基因(aprE)的单链M13mp18-aprE DNA为模板,合成的寡核苷酸5′-3′为诱变引物,用缺口双链法对aprE进行Met-222-Ala点突变。经菌落印迹杂交筛选,选出阳性噬斑。用SaⅡ酶解M13mp18-aprE得到aprE,将它和pPZW103重组,转化中性、碱性蛋白酶缺失宿主菌DB104。经含卡那霉素和脱脂奶粉板筛选和比较aprE限制性内切酶NcoⅠ和SacⅡ水解电泳图谱分析,完成构建一个分泌抗氧化的枯草杆菌蛋白酶E的工程菌PW8888。     

Characterization of bacteriophage T3 DNA ligase

DNA ligases of bacteriophage T4 and T7 have been widely used in molecular biology for decades, but little is known about bacteriophage T3 DNA ligase. Here is the first report on the cloning, expression and biochemical characterization of bacteriophage T3 DNA ligase. The polyhistidine-tagged recombinant T3 DNA ligase was shown to be an ATP-dependent enzyme. The enzymatic activity was not affected by high concentration of monovalent cations up to 1 M, whereas 2 mM ATP could inhibit its activity by 50%. Under optimal conditions (pH 8.0, 0.5 mM ATP, 5 mM DTT, 1 mM Mg(2+) and 300 mM Na(+)), 1 fmol of T3 DNA ligase could achieve 90% ligation of 450 fmol of cohesive dsDNA fragments in 30 min. T3 DNA ligase was shown to be over 5-fold more efficient than T4 DNA ligase for ligation of cohesive DNA fragments, but less active for blunt-ended DNA fragments. Phylogenetic analysis showed that T3 DNA ligase is more closely related to T7 DNA ligase than to T4 DNA ligase.     

Transformation of a Bacillus subtilis L-form with bacteriophage deoxyribonucleic acid.

A stable L-form, sal-1, of Bacillus subtilis was transformed with deoxyribonucleic acid (DNA) from bacteriophages phi 25 and phi 29 to determine whether exogenous DNA can be introduced into this organism. The viral transformation (transfection) was successful with the use of polyethylene glycol. In the presence of the fusogen, bacteriophage phi 25 DNA initiated a single cycle of infection. When compared with transfection of competent cells of Bacillus subtilis, the appearance of viral particles was delayed and their production occurred over a longer time period. L-form cells were best able to support intracellular replication of phi 25 viral particles when in balanced growth in a rich medium. The addition of polyethylene glycol also induced infection of sal-1 with whole bacteriophage phi 25 particles which could not otherwise infect the L-form and enhanced infection by intact phi 29 particles. Primary recombination was shown to be required for polyethylene glycol-mediated phi 25 transfection, but not phi 29 transfection or for whole bacteriophage phi 25 infection mediated by polyethylene glycol. Successful transfection of sal-1 suggests that the L-form may be amenable to genetic modification with exogenous DNA.