Effect of ethylenediaminetetraacetic acid on deoxyribonucleic acid entry and recombination in transformation of a wild-type strain and a rec-1 mutant of Haemophilus influenzae

In transformation of Haemophilus influenzae, donor deoxyribonucleic acid (DNA) enters into competent cells in the presence of ethylenediaminetetraacetic acid (EDTA), which prevents the formation of single stranded regions in the donor DNA that has entered. If after entry of DNA the recipient cells were first incubated at 17 degrees C and then at 37 degrees C in the continuous presence of EDTA, almost no integration occurred. On the other hand, if after entry of DNA the cells were incubated first at 17 degrees C in the absence of EDTA, allowing the generation of single-stranded regions (integration is blocked at this temperature), and then at 37 degrees C in the presence of EDTA, donor-recipient DNA complexes were formed. These results suggest that single-stranded regions are required for integration. Integration to completion was strongly inhibited by EDTA. In a rec-1 mutant of H. influenzae no donor-recipient DNA complexes carrying recombinant-type activity were formed during incubation at 37 degrees C in the absence of EDTA. If rec-1 cells were incubated at 37 degrees C in the presence of EDTA, which strongly inhibited breakdown of DNA, donor-recipient DNA complexes were formed if previously single-stranded regions in the donor DNA that had entered were generated by incubation at 17 degrees C in the absence of EDTA. This suggests that the rec-1 protein protects the initial donor-recipient DNA complex against degradation, so that further steps in the recombination process can proceed.     

Single-stranded regions in Streptococcus pneumoniae chromosomal deoxyribonucleic acid and their relation to transformation.

Deoxyribonucleic acid (DNA) in lysates of both completent and noncompetent streptococcus pneumoniae cells was characterized by chromatography on benzoylated, naphthoylated diethylaminoethyl-cellulose columns, by sensitivity to Aspergillus oryzae S1 endonuclease, and by sucrose gradient analysis. The DNAs from both competent and noncompetent cells were found to contain similar extents of single-stranded regions. These single-stranded regions appeared to be intact, unpaired regions in double-stranded DNA rather than gaps, nicks, or unpaired ends in the DNA. Inhibition of cells with rifampin prior to lysis increased the amount of such single strandedness in the DNA. Lysates made at various times after [14C]thymidine-labeled cells had bound [3H]thymidine-labeled transforming DNA were also characterized by benzoylated, naphthoylated diethylaminoethyl-cellulose chromatography. Changes in the elution profiles of DNA from cells exposed to homospecific (S. pneumoniae) donor DNA were indicative of the formation of complexes between donor DNA and the single-stranded regions of recipient DNA. In contrast, profiles of DNA from cells exposed to heterospecific (S. sanguis) DNA did not show significant changes, indicating that few such donor-recipient complexes were formed during heterospecific transformation.     

Cloning of the rec-2 locus of Haemophilus influenzae

A collection of transposon mutants of Haemophilus influenzae was constructed by additive transformation with mutagenized chromosomal DNA. A rec-2::miniTn10 km mutation was cloned from a transformation-defective member of the mutant collection, followed by the reconstruction of the wild-type rec-2 locus by recombination to create pDM62. Southern blots showed that the commonly studied Rec-2 mutant, Rd(DB117)rec-, contained either a large deletion or a substitution that removed part of rec-2 locus. A collection of transposon mutations in pDM62 was used to characterize the rec-2 locus by complementation. A corresponding collection of mutants was also constructed. A single segment was required to complement the transformation defect in Rd(DB117)rec-. All of the transformation-defective transposon mutants failed to translocate donor DNA into then cell, in agreement with previous studies of Rd(DB117)rec-.     

Structural features of DNA in competent Bacillus subtilis

Summary For efficient transformation with B. subtilis, recipient cells must be grown to the state termed competence. Previous findings indicated that such competent cells contained DNA which exhibited about 5% single-strandedness. In this work, the physico-chemical properties of this DNA are compared to artificially nicked DNA. Evidence is presented that breakdown of the host DNA occurs during growth to competence. Inhibition of this breakdown also prevents the formation of partially single-stranded chromosomes within the competent cells. Use of this DNA as donor in transformation studies indicated a deficiency in biological activity within specific genes. Of three models considered, it is concluded that the results are best explained by the occurrence of single-stranded gaps within the chromosomes of competent cells.     

Electron microscopic studies of bacteriophage M13 DNA replication.

Intracellular forms of M13 phage DNA isolated after infection of Escherichia coli with wild-type phage have been studied by electron microscopy and ultracentrifugation. The data indicate the involvement of rolling-circle intermediates in single-stranded DNA synthesis. In addition to single-stranded circular DNA, we observed covalently closed and nicked replicative-form (RF) DNAs, dimer RF DNAs, concatenated RF DNAs, RF DNAs with single-stranded tails (theta, rolling circles), and, occasionally, RF DNAs with theta structures. The tails in theta molecules are always single stranded and are never longer than the DNA from mature phage; the proportion of theta to other RF molecules does not change significantly with time after infection. The origin of single-stranded DNA synthesis has been mapped by electron microscopy at a unique location on RF DNA by use of partial denaturation mapping and restriction endonuclease digestion. This location is between gene IV and gene II, and synthesis proceeds in a counterclockwise direction on the conventional genetic map.     

A competence specific inducible protein promotes in vivo recombination in Streptococcus sanguis

Summary We describe the first example of a recombination-specific protein induced during the development of competence for transformation in Streptococcus sanguis. Elaborated in response to stimulation by competence-protein, the 51,000 Molecular Weight (MW) polypeptide is one of at least 10 new polypeptides transiently induced during the competence phase. Biochemical and genetic analyses of the parental, cipA⁺ (competence specific inducible polypeptide A), and mutant, cipA, strains have shown that the 51,000 MW polypeptide has two roles: its low level constitutive synthesis is required for repair of damage to DNA due to UV light and methylmethane sulfonate; its induced synthesis (3–6x10⁴ copies/cell) during the competence phase is essential for promoting recombination between donor single-stranded DNA and the recipient chromosome. Also, ccc plasmid donor DNA transformation, which occurs as a decreasing probability of the increasing donor plasmid MW, requires the inducible function specified by the 51,000 MW polypeptide. The MW independent low level transformation with ccc plasmids, the inheritance of plasmids by conjugation, and the stable maintenance of plasmids introduced by transformation and conjugation, respectively, are independent of the function specified by the 51,000 MW polypeptide.     

Genetic transformation of Streptococcus pneumoniae by heterologous plasmid deoxyribonucleic acid.

A number of heterologous plasmid deoxyribonucleic acids (DNAs) coding for erythromycin, tylosin, lincomycin, tetracycline, or chloramphenicol resistance have been introduced into Streptococcus pneumoniae via genetic transformation with frequencies that varied between 10(-5) to as high as 5 x 10(-1) per colony-forming unit. Transformation with plasmid DNA required pneumococcal competence, was competed by chromosomal DNA, and showed a saturation at about 0.5 micrograms/ml (with a recipient population of 3 x 10(7) colony-forming units of competent cells per ml). Plasmid transformation did not occur with a recipient strain, 410, defective in endonuclease I activity and in chromosomal genetic transformation. All erythromycin-resistant transformants examined contained covalently closed circular DNA with the same electrophoretic mobility on agarose gels as the donor DNAs, and when examined in detail the plasmid reisolated from the transformants had the same restriction patterns and the same specific transforming activity as the donor DNA. In the cases of two plasmids examined in detail--pAM77 and pSA5700 Lc9--most of the transforming activity was associated with DNA monomers; DNA multimers present in pSA5700 Lc9 also had biological activity. An unexpected finding was the demonstration of transformation (2 x 10(-5) per colony-forming unit) with plasmid DNAs linearized by treatment with S1 nuclease or with restriction endonucleases.     

The transcriptional regulator Rok binds A+T-rich DNA and is involved in repression of a mobile genetic element in Bacillus subtilis

The rok gene of Bacillus subtilis was identified as a negative regulator of competence development. It also controls expression of several genes not related to competence. We found that Rok binds to extended regions of the B. subtilis genome. These regions are characterized by a high A+T content and are known or believed to have been acquired by horizontal gene transfer. Some of the Rok binding regions are in known mobile genetic elements. A deletion of rok resulted in higher excision of one such element, ICEBs1, a conjugative transposon found integrated in the B. subtilis genome. When expressed in the Gram negative E. coli, Rok also associated with A+T-rich DNA and a conserved C-terminal region of Rok contributed to this association. Together with previous work, our findings indicate that Rok is a nucleoid associated protein that serves to help repress expression of A+T-rich genes, many of which appear to have been acquired by horizontal gene transfer. In these ways, Rok appears to be functionally analogous to H-NS, a nucleoid associated protein found in Gram negative bacteria and Lsr2 of high G+C Mycobacteria.     

Formation of Single-Stranded DNA during DNA Transformation of Neisseria gonorrhoeae

Neisseria gonorrhoeae is naturally competent for DNA transformation. In contrast to other natural prokaryotic DNA transformation systems, single-stranded donor DNA (ssDNA) has not previously been detected during transformation of N. gonorrhoeae. We have reassessed the physical nature of gonococcal transforming DNA by using a sensitive nondenaturing native blotting technique that detects ssDNA. Consistent with previous analyses, we found that the majority of donor DNA remained in the double-stranded form, and only plasmid DNAs that carried the genus-specific DNA uptake sequence were sequestered in a DNase I-resistant state. However, when the DNA was examined under native conditions, S1 nuclease-sensitive ssDNA was identified in all strains tested except for those bacteria that carried the dud-1 mutation. Surprisingly, ssDNA was also found during transformation of N. gonorrhoeae comA mutants, which suggested that ssDNA was initially formed within the periplasm.     

Relationship Between Competence for Transformation of Bacillus subtilis with Native and Single-Stranded Deoxyribonucleic Acid

The response of populations of Bacillus subtilis to both native deoxyribonucleic acid (DNA) and denatured DNA was investigated at maximal competence and at various times during the development of compentency. The results indicate that competence for transformation with native and denatured DNA increases and decreases simultaneously. Competition occurs between native and single-stranded DNA during transformation, and the same cells in a population can be doubly transformed by DNA molecules of both configurations.     

Escherichia coli cell competence induced by calcium cations]

Escherichia coli K-12 cells grown to early and late exponential, and early and late stationary phases were treated with CA2+ and analysed for the ability of exogenous 14C-DNA uptake and genetic transformation. DNA-membrane complexes were detected detected by isopicnic centrifugation of cell lysates in sucrose density gradient. It is found that 1) during all the tested phases of the growth cycle, E. coli cells attain the ability of enhanced DNA uptake after Ca2+ treatment; 2) exogenous and host DNAs are associated with the cell membrane during all tested growth phases; 3) nevertheless, the ability to form transformants is strongly time-dependent: the cells can be transformed during logarithmic phase only; 4) Ca2+ protects exogenous DNA against its degradation by bovine pancreatic DNAase. The peculiarities of Ca2+-induced competence, actual and possible interference of Ca2+ at different transformation steps are briefly discussed.     

DNA forms of the geminivirus African cassava mosaic virus consistent with a rolling circle mechanism of replication.

We have analysed DNA from African cassava mosaic virus (ACMV)-infected Nicotiana benthamiana by two-dimensional agarose gel electrophoresis and detected ACMV-specific DNAs by blot-hybridisation. ACMV DNA forms including the previously characterised single-stranded, open-circular, linear and supercoiled DNAs along with five previously uncharacterised heterogeneous DNAs (H1-H5) were resolved. The heterogeneous DNAs were characterised by their chromatographic properties on BND-cellulose and their ability to hybridise to strand-specific and double-stranded probes. The data suggest a rolling circle mechanism of DNA replication, based on the sizes and strand specificity of the heterogeneous single-stranded DNA forms and their electrophoretic properties in relation to genome length single-stranded DNAs. Second-strand synthesis on a single-stranded virus-sense template is evident from the position of heterogeneous subgenomic complementary-sense DNA (H3) associated with genome-length virus-sense template (VT) DNA. The position of heterogeneous virus-sense DNA (H5), ranging in size from one to two genome lengths, is consistent with its association with genome-length complementary-sense template (CT) DNA, reflecting virus-sense strand displacement during replication from a double-stranded intermediate. The absence of subgenomic complementary-sense DNA associated with the displaced virus-sense strand suggests that replication proceeds via an obligate single-stranded intermediate. The other species of heterogeneous DNAs comprised concatemeric single-stranded virus-sense DNA (H4), and double-stranded or partially single-stranded DNA (H1 and H2).     

Targeting Holliday junctions by origin DNA-binding protein of herpes simplex virus type 1

In the present paper, the interactions of the origin binding protein (OBP) of herpes simplex virus type 1 (HSV1) with synthetic four-way Holliday junctions (HJs) were studied using electrophoresis mobility shift assay and the FRET method and compared with the interactions of the protein with duplex and single-stranded DNAs. It has been found that OBP exhibits a strong preference for binding to four-way and three-way DNA junctions and possesses much lower affinities to duplex and single-stranded DNAs. The protein forms three types of complexes with HJs. It forms complexes I and II which are reminiscent of the tetramer and octamer complexes with four-way junction of HJ-specific protein RuvA of Escherichia coli. The binding approaches saturation level when two OBP dimers are bound per junction. In the presence of Mg²⁺ ions (≥2 mM) OBP also interacts with HJ in the stacked arm form (complex III). In the presence of 5 mM ATP and 10 mM Mg²⁺ ions OBP catalyzes processing of the HJ in which one of the annealed oligonucleotides has a 3′-terminal tail containing 20 unpaired thymine residues. The observed preference of OBP for binding to the four-way DNA junctions provides a basis for suggestion that OBP induces large DNA structural changes upon binding to Box I and Box II sites in OriS. These changes involve the bending and partial melting of the DNA at A+T-rich spacer and also include the formation of HJ containing Box I and Box II inverted repeats and flanking DNA sequences.     

Purification and characterization of a DNA-pairing and strand transfer activity from mitotic Saccharomyces cerevisiae

An enzyme catalyzing homologous pairing of DNA chains has been extensively purified from mitotic yeast. The most highly purified fractions are enriched for a polypeptide with a molecular mass of approximately 120 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Protein-dependent pairing of single-stranded DNAs requires a divalent cation (Mg2+ or Ca2+) but proceeds rapidly in the absence of any nucleoside triphosphates. The kinetics of reassociation are extremely rapid, with more than 60% of the single-stranded DNA becoming resistant to S1 nuclease within 1 min at a ratio of 1 protein monomer/50 nucleotides. The results of enzyme titration and DNA challenge experiments suggest that this protein does not act catalytically during renaturation but is required stoichiometrically. The protein promotes formation of joint molecules between linear M13 replicative form DNA (form III) containing short single-stranded tails and homologous single-stranded M13 viral DNA. Removal of approximately 50 nucleotides from the ends of the linear duplex using either exonuclease III (5' ends) or T7 gene 6 exonuclease (3' ends) activates the duplex for extensive strand exchange. Electron microscopic analysis of product molecules suggests that the homologous circular DNA initially associates with the single-stranded tails of the duplexes, and the heteroduplex region is extended with displacement of the noncomplementary strand. The ability of this protein to pair and to promote strand transfer using either exonuclease III or T7 gene 6 exonuclease-treated duplex substrates suggests that this activity promotes heteroduplex extension in a nonpolar fashion. The biochemical properties of the transferase are consistent with a role for this protein in heteroduplex joint formation during mitotic recombination in Saccharomyces cerevisiae.     

Cell to cell transmission of donor DNA overcomes differential incorporation of non-homologous and homologous markers in Neisseria gonorrhoeae

The neisseriae are naturally competent for DNA transformation. This genetic study examines whether the modification status of chromosomal donor DNA affects transformation of Neisseria gonorrhoeae to drug resistance. When a single modification system was inactivated, unmodified chromosomal donor DNA was not restricted when used to transform the cognate restriction+ host, irrespective of whether the donor DNA carried a point mutation (homologous marker) or a drug-resistance gene cassette (non-homologous marker). These observations contrasted transformations performed with unmodified plasmid donor DNAs, where the incoming DNA was excluded. However, during the study, it became apparent that certain strains of gonococci showed differential incorporation of non-homologous markers when compared with the incorporation of the homologous marker, even when the donor DNAs were prepared from parental strains. Differential incorporation of markers could be rescued either through cell to cell transmission of donor DNA, or by performing in vitro transformations with donor DNA preparations that were obtained from spent culture supernatants. Overall, the data indicate that, in addition to the exclusion of foreign DNA through the requirement for a genus-specific uptake sequence, gonococci appear capable of excluding DNA on the basis of homology.     

Transformation in Escherichia coli: stages in the process.

Transformation experiments with Escherichia coli recipient cells and linear chromosomal deoxyribonucleic acid (DNA) are reported. E. coli can be rendered competent for DNA uptake by a temperature shock (0 degrees C leads to 42 degrees C leads to 0 degrees C) of the recipient cells in the presence of a high concentration of either Ca2+ or Mg2+ ions. Uptake of DNA into a deoxyribonuclease-resistant form, for which the presence of Ca2+ is essential, was possible during the temperature shock but appeared to occur most readily after the heat shock during incubation at 0 degrees C. When DNA was added to cells that had been heat shocked in the presence of divalent cations only, DNA uptake also occurred. This suggests that competence induction and uptake may be regarded as separate stages. Under conditions used to induce competence, we observed an extensive release of periplasmic enzymes, probably reflecting membrane damage induced during development of competence. After the conversion of donor DNA into a deoxyribonuclease-resistant form, transformants could be selected. It appeared that incubation, before plating, of the transformation mixture in a medium containing high Ca2+ and Mg2+ concentrations and supplemented with all growth requirements increased the transformation frequency. This incubation probably causes recovery of physiologically labile cells.     

Conditions for natural transformation of Ralstonia solanacearum.

The development of competence allowing natural transformation of Ralstonia solanacearum was found to occur during exponential growth and not in response to any excreted factors. Linear DNAs were effectively integrated by recombination requiring a minimum of 50 bp of homologous DNA. Therefore, DNA from other genera and species were ineffective.     

Single-stranded DNA from viruses, prokaryotes and eukaryotes]

The review presents the results of investigations of single-stranded DNAs of viruses, bacteria and cells of higher organisms. Methods of revealing, isolating and analysis of these DNAs are presented. A large variety of single-stranded DNA containing genomes of plant and animal viruses was revealed. Attention is drawn to the integration and replication of viral genomes. Results of SV40 integration during the first two days after infection of Chinese hamster cells are shown. Results of studying multi-copy single-stranded DNA in bacterial cells were analysed. In separate sections, the replication of plasmid single-stranded DNA was studied as well as the problem of plasmid stability in cells. Advances in bacteria transformation studies are stated. Data of single-stranded DNA investigation in cells of higher organisms are mainly presented on the example of early embryos. Data on the analysis of gene hypersensitivity to nuclease S1 are given. A table of proteins destabilizing and unweaving single-stranded DNA and a classification table of proteins bound with single-stranded DNA according to their functional significance are presented. It is stated that the problem of single-stranded DNA significance in cells remains open, although some results have been achieved.     

Mechanism of DNA degradation by the ATP-dependent DNase from Hemophilus influenzae Rd.

The rate of production of acid-soluble material during degradation of duplex DNA by Hemophilus influenzae ATP-dependent DNAse (Hind exonuclease V) has been shown to be directly dependent upon the Mg2+ concentration in the reaction mixture. At high concentrations of Mg2+ (5 to 20 mM), DNA degradation to acid-soluble products is rapid and the rate of ATP hydrolysis is slightly depressed. At low concentrations of Mg2+ (0.1 to 0.5 mM), the enzyme rapidly hydrolyzes ATP and converts up to 35% of linear duplex DNA to single-stranded material while degrading less than 0.2% of the DNA to acid-soluble products. We refer to this enzymatic production of single-stranded DNA as the "melting" activity. Under the conditions of our assay, the initial melting reaction is processive, lasting about 70s on phage T7 DNA. Using DNAs with several different lengths, we have established that the duration of the initial reaction is dependent upon DNA length, requiring approximately 1 s per 0.18 mum. The products of the initial reaction on phage T7 DNA are somewhat heterogeneous, consisting of short duplex fragments approximately 0.5 mum long, purely single-stranded products up to 7 mum long, and longer duplex fragments 3 to 11 mum in length, some of which have single-stranded tails. Nearly half of the single-stranded material remains linked to a duplex segment of DNA after the inital processive reaction. We propose that Hind exo V initiates attack at the DNA termini and then acts in a processive manner, migrating along the DNA molecule, converting some regions to single-stranded material by the combined action of the melting activity and limited phosphodiester cleavage, while leaving other regions double-stranded. At the completion of its processive movement through a single DNA molecule, it is released and then recycles onto either intact molecules or the partially degraded products, continuing in this manner until the DNA is finally reduced to oligonucleotides.