W-mutagenesis in competent cells of Bacillus subtilis

Summary The relative yield (N _m/N) of fluorescent mutants Ind^- after the transformation of Bacillus subtilis cells by means of UV-irradiated DNA is much higher in an uvr ^- recipient than in an uvr ⁺ strain, when compared at equal fluence, but practically identical at equal survival. Ind^- mutations are induced by UV-irradiation of separated single strands of transforming DNA. The H-strand is much more sensitive to the mutagenic action of UV light. Preliminary irradiation of competent recipient cells by moderate UV fluences increases the survival of UV-or -irradiated transforming DNA (W-reactivation) and the frequency of Ind^- mutations (W-mutagenesis). During transfection of B. subtilis cells by UV-irradiated prophage DNA isolated from lysogenic cells B. subtilis (Ø105 c ⁺) c-mutants of the phage are obtained in high yield only in conditions of W-mutagenesis, i.e. in UV-irradiated recipient cells. These data show that there is no substantial spontaneous induction of error-prone SOS-repair system in the competent cells of B. subtilis.     

Molecular Fate of Heterologous Bacterial DNA in Competent BACILLUS SUBTILIS. II. Unstable Association of Heterologous DNA with the Recipient Chromosome

In CsCl density gradients of lysates from competent Bacillus subtilis cells, which had been exposed to heterologous bacterial DNA, very little donor-recipient complex (DRC) formation could be detected. The present study demonstrates that photocrosslinking of such lysates by irradiation with long-wave UV light in the presence of 4,5',8-trimethylpsoralen results in a dramatic increase in the amount of heterologous DRC. This phenomenon may be interpreted as the stabilization of a pre-existing weak association between entered heterologous donor DNA and one recipient strand in unpaired regions of the chromosome. When a recombination-deficient mutant is used, the amount of stabilizable heterologous DRC is reduced to the same extent as the specific transforming activity of homologous DNA. Although the amount of stabilizable complex is related to the degree of homology between donor and recipient DNA, this relation is not a quantitative one. Probably the association is caused by very short regions of base pairing between the donor and recipient moieties in the complex. Heating of a lysate at 70° prior to photocrosslinking prevents stabilization, apparently because the regions of base pairing are rapidly melted out. The results described in this paper can be best interpreted as the fixation of a process in which entered donor DNA in competent cells tries to find homologous stretches in the recipient chromosome.     

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.     

Mechanism of transformation in B. subtilis

Summary Transformation in B. subtilis is achieved by the uptake of donor DNA into recipient cells and the integration of part of this donor DNA into the host chromosome. The evidence presented in this report is interpreted to indicate that donor double helical DNA, on entry into host cells is rapidly membrane bound and can remain in this state for a consicerable time, perhaps even until integration. This bound DNA consists of molecules which have been reduced in size and degraded on uptake, and appear as partially single-stranded molecules. It is suggested that the donor DNA initially forms single strands which rapidly assume a partially single stranded nature by association with the host DNA or by reannealing.Host cells, by virtue of the competent state, possess temporarily, and prior to the addition of donor DNA, chromosomes with single-stranded gaps. It is likely that such gaps are larger than the single-stranded segments of donor DNA which are to be integrated. Results are described which are best explained if integration is achieved by an initial annealing between the single-stranded donor and host segments followed by their covalent linkage.     

Characteristics of a complex formed by a nonintegrated fraction of transforming DNA and Bacillus subtilis recipient cell constituents.

Summary Nonintegrated transforming DNA was isolated from recipient cell lysates as a complex with cellular constituents (natural complex) and separated from free proteins on CsCl density gradients. Sensitivity of DNA in this complex to digestion with endonuclease S₁, liberation of denatured donor molecules by treatment of the cell lysates with phenol, as well as previously described liberation of single-stranded donor DNA by heating with detergents, pointed to the single-stranded nature of the donor DNA in the complex. About 1% of radioactive leucine or phenylalamine incorporated to cellular proteins were detected in the natural complex, with two associated enzymatic activities: one autolytic, the other endonucleolytic. The autolytic activity, known to be localized mainly in the cell wall and the endonucleolytic one, similar to the enzyme localized in cell membrane and periplasmic space of B. subtilis, suggest that donor DNA is complexed with a cell wall and/or a cell membrane fragment. Consideration of several characteristics of the natural complex: its density, protein content, and partial resistance of its DNA to DNase I, point to partial shielding of donor DNA in the cell fragment structure, and existence of a portion in a free uncovered form. Considerations on the possible role of the two enzymatic activities were based on the fact that they were not found in the complex formed by denatured DNA added to cells before lysis (reconstruction complex), and on hypotheses of their possible physioligical role.Part of the above results was presented in preliminary form at the Third European Meeting on Bacterial Transformation and Transfection, Granada, Spain, August 31–September 3, 1976     

Intracellular effects of phage phi W-14 DNA on transformation of Bacillus subtilis

Summary Uptake of transforming DNA by competent Bacillus subtilis cells in the presence of phage W-14 DNA (in which half the thymine residues are replaced by -putrescinyl-thymine) is accompanied by a decrease in the amount of trichloracetic acid-precipitable label of the former retained by recipient cells during subsequent incubation. Fractionation of lysates of cells incubated for 0.5 min at 37°C after DNA uptake at 30°C in the presence of low concentrations of W-14 DNA (0.1 g/ml) demonstrated the presence of single-stranded transforming DNA molecules, typical for DNA taken up by B. subtilis. The intracellular effect of W-14 DNA was enhanced by an increase in its concentration (to 0.5–1 g/ml), or by increasing the temperature of uptake (to 37°C). With either of these treatments transforming DNA taken up was found in the form of a broad asymmetric band, indicative of degradation, and partially located at the density characteristic for single-stranded molecules. Fractionation of lysates of cells treated (0.1 g/ml) or untreated with W-14 DNA, and incubated for 20 min at 37°C after DNA uptake, showed disappearance of the single-stranded band. Donor DNA label was then found exclusively in the recipient DNA band, its amount being lower in samples treated with W-14 DNA. The influence of a high concentration of W-14 DNA on retention of transforming DNA label was correlated with its effect on transformation. On exposure to low concentrations of phage DNA, such a correlation was observed only after longer periods of incubation, due to slower intracellular degradation of homologous DNA taken up. The results are consistent with the proposal that W-14 DNA-induced reduction in efficiency of transformation is due to intracellular stimulation of transforming DNA degradation, leading to a decrease in the number of donor molecules available for recombination with the recipient chromosome.     

Fate of transforming DNA following uptake by competent Bacillus subtilis. I. Formation and properties of the donor-recipient complex

Following uptake by competent Bacillus subtilis, transforming DNA is converted to two distinct slowly sedimenting molecular forms which possess little transforming activity (eclipse). A few minutes after uptake is initiated, a physical complex of donor and recipient DNA begins to form. The recovery of donor transforming activity following eclipse, and the appearance of recombinant activity, previously reported by Venema, Pritchard &; Venema-Schröder (1965), is shown to be due to changes occurring in the donor—recipient complex. This complex exists transiently in a form with low recombinant-type transforming activity. This transient form may be one in which the donor and recipient components are joined non-covalently. The donor-recipient complex is shown to be a heteroduplex structure in which the donor moiety has an approximate molecular weight of 750,000.     

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.     

Integration of Deoxyribonuclease-Treated DNA in Bacillus subtilis Transformation

Normal preparations of B. subtilis DNA have weight average native molecular weights of 10 to 30 x 10⁶. For any given preparation the upper and lower 95% size limits may differ by a factor of ten or more. Single-stranded molecular weights indicate an average of 1 to 4 breaks per single strand of the native DNA. The reduction in transforming activity and viscosity following DNAase I digestion can be accounted for by a direct relationship between the transforming activity of a DNA and its single-stranded molecular weight. Uptake studies with DNAase I treated heavy (²H¹⁵N ³H) DNA show that single strand breaks inhibit integration less than transformation. A provisional estimate of the size of the integrated region based on correlating the single strand size of the donor-recipient complex with the donor-recipient density differences following alkali denaturation came to 1530 nucleotides. Using a competent, nonleaky thymine-requiring strain of B. subtilis grown in 5-BU medium before and after transformation, it was shown that (a) No detectable amount of DNA synthesis is necessary for the initial stages of integration, (b) Cells which have recently been replicating DNA are not competent. (c) Cells containing donor DNA show a lag in DNA replication following transformation, (d) When donor DNA is replicated it initially appears in a density region between light and hybrid. This indicates that it includes the transition point formed at the time of reinitiation of DNA synthesis in the presence of 5-BU following transformation. A model is proposed in which donor DNA is integrated at the stationary growing point of the competent cell, which is in a state of suspended DNA synthesis.     

Repair of ultraviolet-irradiated transforming deoxyribonucleic acid in Haemophilus influenzae

Ultraviolet-sensitive and wild-type Haemophilus influenzae cells were exposed to irradiated and unirradiated transforming deoxyribonucleic acid (DNA) containing a marker which can be linked to another marker in the cells. Lysates were made after various times of incubation and assayed for transforming activity on an excisionless recipient. Repair can be noted as an increase in activity from the irradiated donor DNA after its linkage to the recipient DNA. No repair can be observed in a mutant which is unable to integrate transforming DNA. There is a little repair in another mutant which is unable to excise pyrimidine dimers. H. influenzae cells also repair nondimer damage, as judged by the increase in activity observed in lysates made with irradiated and maximally photoreactivated DNA.     

Molecular fate of heterologous bacterial DNA in competent Bacillus subtilis: further characterization of unstable association between donor and recipient DNA and the involvement of the cellular membrane

Summary Although heterospecific transformation is extremely inefficient and very little heterologous donor DNA integrates into the recipient chromosome in a stable way, we have previously shown that B. pumilus DNA entering competent B. subtilis efficiently associates with the recipient chromosome in an unstable way. This association can be stabilized by photocrosslinking in the presence of 4,5,8-trimethylpsoralen; it depends on the recombination proficiency of the recipient strain and on strand-separation of the recipient chromosome (te Riele and Venema 1982b). The present study provides further evidence that the heterologous donor DNA and the recipient DNA are associated by regions of base-pairing. Based on the high sensitivity of the donor moiety in the complex to nuclease S1 (90%) and the high sensitivity of the complex to moderate denaturing conditions (Tm=48°C), we presume that donor and recipient DNA are associated either by several short sequences of 15–25 fairly well matched base pairs or by a region of base-pairing of about 200 bases, which contains 25% of mismatches. During incubation, the unstable complex disappears, probably due to nucleolytic degradation.The unstable heterologous donor-recipient complex (DRC) was found to be membrane-bound. However, in contrast to homologous DRC, the unstable heterologous DRC remains membrane bound during incubation. Apparently, the predominantly single-stranded character of the heterologous DRC prevents release of the complex from the membrane.Abbreviations DRC donor-recipient complex - TMP 4,5,8-trimethyl-psoralen - DNAase I deoxyribonuclease 1 - TCA trichloroacetic acid     

Transformation in Bacillus subtilis: characterization of an intermediate in recombination observed during transformation.

Summary From recombination-proficient competent cells of Bacillus subtilis in which the donor DNA entered at 17°, and which were kept at the same temperature, a complex of donor DNA and the recipient chromosome can be obtained which has a relatively high buoyant density in CsCl gradients. Exposure of the isolated complex to nuclease S1 liberates donor radioactivity. The limited biological activity of DNA re-extracted from cells attempting to recombine at 17° is decreased upon incubation with nuclease S1. If recombination is allowed to proceed at 30°, the high buoyant density of the donor-recipient complex decreases to normal values and less radioactivity can be liberated from the complex by nuclease S1. Concomitantly the biological activity of re-extracted DNA becomes less vulnerable to nuclease S1 under these conditions. On the basis of these observations we assume that the intermediate complex partly consists of unpaired single-stranded donor DNA.Support for the correctness of this assumption is derived from experiments with a mutant, which is delayed in the processing of high buoyant density donor-recipient complex to normal buoyant density donor-recipient complex. This delay is reflected in the time of acquisition of resistance to nuclease S1 digestion of the isolated complex.     

Specific inactivation of heterospecific transforming DNA by a factor derived from Streptococcus sanguis lysates.

Summary A heat-sensitive factor obtained from lysates of competent Streptococcus sanguis cells reacts specifically with native DNA of heterospecific (S. pneumoniae or calf thymus) origin. In vitro it does not alter the double or single strand length of the DNA, nor does it affect uptake of the DNA by competent S. sanguis or S. pneumoniae cells in DNase I-resistant form. Following uptake, however, DNA previously exposed to the factor loses over 90% of its biological activity. Reaction of heterospecific DNA with the factor is cometitive, suggesting a competition for binding to the factor. Heating treated DNA prior to its reaction with recipient cells, apparently by irreversibly dissociating the factor, restores to the DNA its original potential transforming activity. Specific activity of the factor can be increased in cells grown under certain conditions; this increase is blocked by erythromycin.     

Phenotypic expression in vivo and transforming activity in vitro: Two related functions of folded bacterial chromosomes

Summary Nucleoids prepared by gentle lysis of non-complementing diploid cells resulting from Bacillus subtilis protoplast fusion have been used to transform competent cultures of appropriate recipient strains. The yields of transformants were regularly much larger when the transforming allele was expressed in vivo than when it was unexpressed. Ribonuclease treatment of the lysates prior to their use as donors in transformation did not change the yields of transformants. Proteinase treatment had no effect when the selected trait was expressed in vivo, but it restored transforming activity of unexpressed markers to the level of expressed markers.Proteins bound to the nucleoids of non-complementing diploids are thus responsible for their inability in vitro to transform for unexpressed markers. Whether these proteins are also responsible in vivo for the chromosomal extinctions observed remains unknown.     

Transformation in bacillus subtilis: fate of transforming DNA in transformation deficient mutants.

Summary Transformation deficient mutants were isolated by means of selection for sensitivity to methylmethane-sulfonate (MMS). The mutations were introduced into a multiple auxotrophic highly transformable recipient. The transformation deficient strains were characterized with respect to their sensitivity to UV-irradiation and treatment with MMS and mitomycin-C (MC) and with respect to both the physico-chemical and biological properties of reextracted donor DNA.As has been established previously (Davidoff-Abelson and Dubnau, 1973b) in the transformation proficient wild-type, double-stranded fragments (DSF), single-stranded fragments (SSF) and donorrecipient complex (DRC) are formed from donor DNA.The mutants we report on are of various types: Mutant 7G-73 (transformation frequency about 25 times lower than in the wild-type) is sensitive to UV-irradiation and treatment with MMS and MC, and is extremely deficient in the production of DRC.Mutant 7G-84 (transformation frequency about 12 times lower than in the wild-type) shows also sensitivity to UV-irradiation and treatment with MMS and MC. However, although it forms DSF, SSF, and DRC, the biological activity of DNA re-extracted from transforming cultures of 7G-84 is much reduced as compared to that of the wild-type.Mutant 7G-97 (transformation frequency about 500 times lower than in the wild-type) shows approximately wild-type resistance to UV-irradiation and treatment with MMS and MC, and forms DSF exclusively; the donor DNA is not processed further.Double mutants6G-103 and 6G-105, constructed by transformation of mutant 7G-97, with DNA from 7G-84 and 7G-73, are about 1250 and 5000 times less transformable than the wild-type respectively. They are sensitive to UV-irradiation and treatment with MMS and MC. Mutants 6G-103 and 6G-105 also produce DSF, which are not processed further.     

Homology-facilitated plasmid transfer in Haemophilus influenzae

Summary The 8 kbp plasmid pAT4 transformed Haemophilus influenzae Rd cells at low frequencies. Transformation was increased up to 100 times, however, when the recipient cells carried a DNA segment in either their chromosome or in a resident plasmid that was homologous to at least part of plasmid pAT4. Linearized plasmid DNA molecules did not transform cells without DNA homology; they efficiently transformed homology recipients, but only when the cuts had been made in the region of shared homology. In most cases examined the circular donor plasmid had been reconstituted from the transforming DNA; in some cases the reconstituted plasmid carried a mutation initially present in the recipient chromosome, provided the transforming plasmid had been linearized in the region of shared homology. Plasmid reconstitution was not observed in recA1 cells. We conclude that homology-facilitated plasmid transformation (transfer) is similar to that reported for Bacillus subtilis and Streptococcus pneumoniae.     

Conditions for quantitative transformation inAcinetobacter calcoaceticus

A transformation procedure that yielded high efficiencies was developed forAcinetobacter calcoaceticus. Strain BD413 Ura⁻ trpE was transformed to tryptophan prototrophy using highly purified DNA. Experimental parameters studied were: (i) recipient cell concentration, (ii) DNA concentration, (iii) growth phase of the recipient cell population, (iv) composition of the growth and transforming medium, and (v) time of incubation of recipient cells with donor DNA. Strain BD413 was competent for transformation throught the growth cycle, with highest competence occurring early in the exponential phase of growth. Maximal transformation efficiencies of 0.5% to 0.7% were obtained in media supporting rapid growth. Recipient cell concentrations of 1×10⁶ to 6×10⁶ cells/ml yielded the highest transformation frequencies, regardless of DNA concentration.     

Transformation inBacillus subtilis. Initial stages of the transformation process and their energy dependence

NaN₃ was found to inhibit transformation but not the irreversible binding of donor³H-DNA in competent cells of the original low-transformable strainBacillus subtilis 168trp ₂ . Addition of NaN₃ to cells of two mutantsBacillus subtilis HT39 and HT46 with an increased transformability decreased substantially the irreversible binding of the donor DNA to the competent cells. The decreased irreversible binding of DNA is caused by an increased osmotic sensitivity of competent cells of the mutants HT39 and HT46 in the presence of NaN₃, leading preferentially to lysis of the competent cells.     

The effect of trimethylpsoralen--crosslinks on entry of donor DNA in transformation and transfection of Bacillus subtilis

Summary Transforming chromosomal DNA, irradiated with long-wave UV light in the presence of 4,5,8-trimethylpsoralen (TMP) binds to competent B. subtilis cells as effectively as non-treated DNA, but its transforming activity is strongly reduced.Uptake studies show that the entry of transforming DNA, after some stimulation by short periods of irradiation in the presence of TMP, decreases proportionally with the dose of irradiation. Crosslinking was quantitated by electron microscopy. Since the number of crosslinks increases proportionally with the dose of irradiation, it is suggested that entry of donor DNA is prevented by crosslinks. The inhibition of entry of DNA is paralleled both by decreased breakdown of crosslinked DNA interacting with competent cells, and decreased breakdown by nuclease activity liberated during protoplasting of competent cultures. These data support the model of Lacks et al. (1976) which postulates that a membrane-bound deoxyribonuclease is engaged in the entry of donor DNA into the competent cell.The transforming activity of the chloramphenicol-resistance carrying plasmid pC194, originally obtained from Staphylococcus aureus, is also destroyed by TMP crosslinks. Contrary to chromosomal DNA, its association with the cells is stimulated by longwave UV irradiation in the presence of TMP, but experiments are presented suggesting that the DNA is still vulnerable to the action of exogenous pancreatic deoxyribonuclease.Transfecting SPP1 DNA is also inactivated by TMP crosslinks. Marker rescue of transfecting DNA containing crosslinks occurs; the extent of rescue of one marker is considerably in excess of that of linked markers.     

Transformation in Bacillus subtilis: biological and physical evidence for a novel DNA-intermediate in synchronously transforming cells.

Summary Competent B. subtilis cells exposed to transforming DNA in the presence of EDTA bind, but do not take up DNA. Rapid and almost synchronous uptake of the bound DNA is achieved by the addition of Mg²⁺ ions in excess of the EDTA. At 30° and at 17° comparable numbers of transformants are produced from cells pre-locaded with DNA at 30° (after termination of uptake by the addition of DNA ase the samples were incubated at 37°). However, almost no transformants are produced when cells are exposed to DNA at 17°, although binding does take place then. Because DNA is taken up at 17° after having loaded the cells at 30°, whereas no uptake occurs after binding at 17°, it is suggested that binding of DNA to the cellular surface involves at least two steps.In DNA re-extracted from cells at 17°, pre-loaded with DNA at 30°, little recombinant type activity is present, indicating that integration is blocked at 17°. However, physico-chemical analysis of the reextracted DNA indicates that a complex between single-stranded donor DNA and the recipient chromosome is formed at 17°. This complex has a higher buoyant density than donor-recipient complexes formed at 30°.