Heterospecific transformation in the genus Haemophilus

Summary The relationship between nine Haemophilus species and Haemophilus influenzae was studied by DNA-DNA hybridization, by transformation of H. influenzae to streptomycin resistance with heterospecific DNA, by competition of heterospecific DNA for transformation by homospecific DNA and by the lethal effect of heterospecific DNA on competent H. influenzae. H. parainfluenzae, H. parasuis, and H. aegyptius DNA transformed at more than 10% efficiency when compared to homologous transformation, but only H. aegyptius demonstrated, by hybridization, a relative binding ratio of more than 80%. H. aphrophilus and H. paraphrophilus DNA demonstrated a relative binding ratio of less than 30% and transformed H. influenzae at only 10^-5 the efficiency of homologous DNA, but they competed for H. influenzae transformation as well as or better than homospecific DNA. The data indicated that in some of the species sharing the common ecological habitat of the mammalian respiratory tract, sequences necessary for competition and efficient uptake into H. influenzae are present in large numbers in their DNAs, which nevertheless have little overall homology with H. influenzae DNA.     

Uptake and fate of bacteriophage phi W-14 DNA in competent Bacillus subtilis.

Phage phi W-14 DNA (in which one-half of the thymine residues are replaced by alpha-putrescinyl thymine) was taken up by competent Bacillus subtilis cells at a rate threefold higher than the rate of homologous DNA uptake. In contrast to other types of heterologous DNA, the amount of phi W-14 DNA taken up in 15 min exceeded the amount of homologous DNA taken up by a factor of two to three, as measured in terms of acid-precipitable material. The amount of phi W-14 DNA taken up was even greater than this analysis indicated if allowance was made for the fact that phi W-14 DNA was degraded more rapidly after uptake than homologous DNA. Competition experiments showed that the affinity of phi W-14 DNA for homologous DNA receptors was lower than the affinity of homologous DNA and was similar to the affinities of other types of heterologous DNA. The more rapid and more extensive uptake of phi W-14 DNA appeared to occur via receptors other than the receptors for homologous DNA, and these receptors (like those for homologous DNA) were an intrinsic property of competent cells. Uptake of phi W-14 DNA was affected by temperature, azide, EDTA, and chloramphenicol, as was uptake of homologous DNA. This was consistent with entry of both DNAs by means of active transport. After uptake, undegraded phi W-14 [3H]DNA was found in the cells in a single-stranded form, whereas a portion of the label was associated with recipient DNA, presumably as a result of incorporation of monomers resulting from degradation. Acetylation of the amino groups of the putrescine side chains in phi W-14 DNA decreased the affinity of this DNA for its receptors without affecting its ability to compete with homologous DNA.     

Restriction and modification in B. subtilis

Summary The effects of restriction in vivo by competent B. subtilis R cells and in vitro by purified endonuclease BsuR on transformation and transfection with native and denatured DNA were investigated.The results show that transformation by either native, or denatured DNA is not affected by restriction, whereas transfection both with native and denatured SPP1 DNA is severely restricted.In contrast to the results obtained in vivo, the biological activity of native and denatured transforming DNA is destroyed by BsuR in vitro, as is the transfecting activity of native and denatured SPP1 DNA. The sensitivity of denatured DNA, either with mixtures of the complementary strands or with separated single strands¹ alone, is significantly lower than that of native DNA.The results are discussed in the context of possible mechanisms underlying the different responses of transforming and transfecting DNA to in vivo restriction by B. subtilis R cells.Abbreviations EGTA ethyleneglycolbis-(aminoethylether)tetraacetic acid - m⁺ modified - m^- non-modified - moi multiplicity of infection - r⁺ m⁺ restricting and modifying - r^- m^- mon-restricting and non-modifying - SSC 0.15M NaCl+0.015 M trisodium citrate - SDS sodium dodecyl sulphate     

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.     

Genetic transformation and transfection ofBacillus subtilis spheroplasts

Genetic transformation and transfection of lysozyme-treatedBacillus subtilis spheroplasts 168M ind occurs only if they are stabilized with 0.5m phosphate buffer and not if they are stabilized with 0.5m sucrose. Spheroplasts prepared from maximally competent cells give maximum transformation and transfection results. The results indicate that the DNA receptors must also be intact in the spheroplasts.     

Plasmid transformation in Bacillus subtilis: Fate of plasmid DNA

Summary Only multimeric, and not monomeric forms of B. subtilis plasmids can transform B. subtilis cells (Canosi et al. 1978). This finding prompted us to study the physico-chemical fate of plasmid DNA in transformation. Competent cells of B. subtilis were exposed to either unfractionated preparations or to preparations of multimeric plasmid DNA. Plasmid DNA was re-extracted from such cells and then analyzed by sedimentation and isopycnic centrifugation and also defined by its sensitivity to nuclease S1 degradation. No double-stranded plasmid DNA could be recovered from cells transformed with unfractionated plasmid preparations which contained predominantly monomeric covalently closed circular (CCC) DNA, Re-extracted plasmid DNA was single-stranded, had a molecular weight considerably smaller than monomer length DNA and had been subject to degradation to acid soluble products. However, when transformations were performed with multimeric DNA (constructed by in vitro ligation of linearized pC194 DNA), both double-stranded and partially double-stranded DNA could be recovered in addition to single-stranded DNA.We assume that plasmid DNA is converted to a single-stranded form in transformation, irrespective of its molecular structure. Double-stranded and partially double-stranded DNAs found in transformation with multimeric DNA would be the products of intramolecular annealing.Some of these results were presented at the 5th European Meeting on Bacterial Transformation and Transfection, September 1980, Florence     

Plasmid-Encoded ComI Inhibits Competence in the Ancestral 3610 Strain of Bacillus subtilis

Natural competence is a process by which bacteria construct a membrane-associated machine for the uptake and integration of exogenous DNA. Many bacteria harbor genes for the DNA uptake machinery and yet are recalcitrant to DNA uptake for unknown reasons. For example, domesticated laboratory strains of Bacillus subtilis are renowned for high-frequency natural transformation, but the ancestral B. subtilis strain NCIB3610 is poorly competent. Here we find that endogenous plasmid pBS32 encodes a small protein, ComI, that inhibits transformation in the 3610 strain. ComI is a single-pass trans-membrane protein that appears to functionally inhibit the competence DNA uptake machinery. Functional inhibition of transformation may be common, and abolishing such inhibitors could be the key to permitting convenient genetic manipulation of a variety of industrially and medically relevant bacteria.     

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.     

An unstable donor-recipient DNA complex in transformation of Bacillus subtilis.

Summary In re-extracted DNA obtained shortly after uptake of transforming DNA by Bacillus subtilis, increased amounts of donor DNA radioactivity banding at the position of donor-recipient DNA complex (DRC) are observed in CsCl gradients, if the cells are irradiated with high doses of UV prior to reextraction of the DNA. Qualitatively, the same phenomenon is observed if lysates of transforming cells are irradiated. UV-irradiation of lysates of competent cells to which single-stranded DNA is added after lysis, does not result in linkage of this DNA to the chromosomal DNA. Two observations argue in favour of the formation of a specific labile complex between donor and resident DNA during transformation. Firstly, heterologous donor DNA from Escherichia coli, although being processed to single-stranded DNA in competent B. subtilis, does not seem to be linked to the recipient chromosome upon UV-irradiation, and secondly, the labile complex of donor and recipient DNA can be stabilized by means of treatment of the lysates of transforming cells with 4, 5¹, 8-trimethylpsoralen in conjuction with long-wave ultra violet light irradiation. This indicates that base-pairing is involved in the formation of the complex. On the basis of these results we assume that the unstable complex of donor and recipient DNA is an early intermediate in genetic recombination during transformation.     

Characterization of plasmid transformation in Bacillus subtilis: kinetic properties and the effect of DNA conformation.

Summary Transformation of competent cells of Bacillus subtilis with antibiotic resistance plasmid DNA has shown that (a) competence for plasmid and chromosomal DNA develops with similar kinetics; (b) DNA linearized with a variety of restriction endonucleases does not transform; (c) CCC plasmid DNA is inactivated for transformation by a single nick; (d) T4 ligase restores transforming activity to both nicked and linearized DNA; (e) CCC relaxed DNA is fully active in transformation; (f) the DNA concentration-dependence of plasmid transformation is first order; and (g) plasmid transformation proceeds with a low efficiency, requiring the uptake of 10³ to 10⁴ DNA molecules per transformant.Based on this information, a model for the processing of chromosomal, plasmid and transfecting DNA is proposed.Abbreviations Cm Chloramphenicol - Em erythromycin - Km kanamycin - Sm streptomycin - CCC covalently closed circular - TBAB tryptose blood agar base - NCE nicking and closing enzyme In partial fulfillment of the requirements for the doctoral degree in the Department of Microbiology at the New York University School of Medicine, for S.C.     

Spontaneous Transformation and Its Use for Genetic Mapping in Bacillus subtilis

Using a simple semi-synthetic competence and sporulation medium (CSM), we found evidence that Bacillus subtilis cells transformed in the competence phase can sporulate, indicating that genetic information acquired during the competence phase is inherited by the next generation after germination of the transformed spores. Moreover, the results from mixed cell culture experiments suggest that spontaneous genetic transformation can occur between competent cells and DNA released from lysed cells in the natural environment. We also found evidence that the spontaneous transformation system can be used for genetic mapping in B. subtilis.     

Stimulation of Bacillus subtilis transformation by spermidine

Summary Addition of spermidine in millimolar concentrations to Bacillus subtilis cells during competence development increases transformability. The spermidine must be added at least 30 min before DNA for maximum stimulation. An incubation period of about 30 minutes is also required for the maximum uptake of labeled spermidine. The amount of DNA initially attached and the rate of DNA uptake are increased to the same extent as transformation. The rate of protein synthesis is also equivalently increased. These observations are consistent with an increase in the number of competent cells in the cell population; this increase is mediated by a spermidine-stimulated protein synthesis.     

Plasmid transformation of naturally competent Acinetobacter calcoaceticus in non-sterile soil extract and groundwater

The natural transformation of Acinetobacter calcoaceticus BD413 (trp E27) was characterized with respect to features that might be important for a possible gene transfer by extracellular DNA in natural environments. Transformation of competent cells with chromosomal DNA (marker trp ⁺) occurred in aqueous solutions of single divalent cations. Uptake of DNA into the DNase I-resistant state but not the binding of DNA to cells was strongly stimulated by divalent cations. An increase of transformation of nearly 3 orders of magnitude was obtained as a response to the presence of 0.25 mM Ca²⁺. With CaCl₂ solutions the transformation frequencies approached the highest values obtained under standard broth conditions, followed by MnCl₂ and MgCl₂. It is concluded that transformation requires divalent cations. DNA competition experiments showed that A. calcoaceticus does not discriminate between homologous and heterologous DNA. Furthermore, circular plasmid DNA competed with chromosomal DNA fragments and vice versa. The equally efficient transformation with plasmid pKT210 isolated from A. calcoaceticus or Escherichia coli indicated absence of DNA restriction in transformation. High efficiency plasmid transformation was obtained in samples of non-sterile natural groundwater and in non-sterile extracts of fresh and air-dried soil. Heat-treatment (10 min, 80°C) of the non-sterile liquid samples increased transformation only in the dried soil extract, probably by inactivation of DNases. The results presented suggest that competent cells of A. calcoaceticus can take up free high molecular weight DNA including plasmids of any source in natural environments such as soil, sediment or groundwater.     

Fate of plasmid DNA in transformation of Bacillus subtilis protoplasts

Summary Polyethylene glycol-treated protoplasts of B. subtilis can be transformed by plasmid DNA at very high frequencies (Chang and Cohen 1979). From analysis of plasmid mediated transformation of transformation-deficient mutants it appeared that mutants, reduced in the transformation by plasmid DNA in the competent state, were plasmid transformation-proficient when transformed as protoplasts. By means of CsCl-gradient centrifugation of re-extracted plasmid DNA it could be demonstrated that plasmid DNA enters the protoplasts in the double-stranded form. In addition, sucrose gradient centrifugation of the re-extracted plasmid DNA showed that the entered DNA is predominantly present as covalently closed circular DNA. The efficiency of plasmid transformation in protoplasts was found to be close to one (each plasmid molecule having entered into the protoplasts gives rise to a transformed cell). This is in good agreement with the observation that little, if any, damage is done to this DNA during or after entry into protoplasts.     

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.     

Induction of homologous recombination in Saccharomyces cerevisiae

Summary We have investigated the effects of UV irradiation of Saccharomyces cerevisiae in order to distinguish whether UV-induced recombination results from the induction of enzymes required for homologous recombination, of the production of substrate sites for recombination containing regions of DNA damage. We utilized split-dose experiments to investigate the induction of proteins required for survival, gene conversion, and mutation in a diploid strain of S. cerevisiae. We demonstrate that inducing doses of UV irradiation followed by a 6 h period of incubation render the cells resistant to challenge doses of UV irradiation. The effects of inducing and challenge doses of UV irradiation upon interchromosomal gene conversion and mutation are strictly additive. Using the yeast URA3 gene cloned in non-replicating single- and double-stranded plasmid vectors that integrate into chromosomal genes upon transformation, we show that UV irradiation of haploid yeast cells and homologous plasmid DNA sequences each stimulate homologous recombination approximately two-fold, and that these effects are additive. Non-specific DNA damage has little effect on the stimulation of, homologous recombination, as shown by studies in which UV-irradiated heterologous DNA was included in transformation/recombination experiments. We further demonstrate that the effect of competing single- and double-stranded heterologous DNA sequences differs in UV-irradiated and unirradiated cells, suggesting an induction of recombinational machinery in UV-irradiated S. cerevisiae cells.     

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.     

DNA repair and the evolution of transformation IV. DNA damage increases transformation

Natural genetic transformation in the bacterium Bacillus subtilis provides a model system to explore the evolutionary function of sexual recombination. In the present work, we study the response of transformation to UV irradiation using donor DNAs that differ in sequence homology to the recipient's chromosome and in the mechanism of transformation. The four donor DNAs used include homologous-chromosomal-DNA, two plasmids containing a fragment of B. subtilis trp⁺ operon DNA and a plasmid with no sequence homology to the recipient cell's DNA. Transformation frequencies for these DNA molecules increase with increasing levels of DNA damage (UV radiation) to recipient cells, only if their transformation requires homologous recombination (i.e. is recA⁺-dependent). Transformation with non-homologous DNA is independent of the recipient's recombination system and transformation frequencies for it do not respond to increases in UV radiation. The transformation frequency for a selectable marker increases in response to DNA damage more dramatically when the locus is present on small, plasmid-borne, homologous fragments than if it is carried on high molecular weight chromosomal fragments. We also study the kinetics of transformation for the different donor DNAs. Different kinetics are observed for homologous transformation depending on whether the homologous locus is carried on a plasmid or on chromosomal fragments. Chromosomal DNA- and non-homologous-plasmid-DNA-mediated transformation is complete (maximal) within several minutes, while transformation with a plasmid containing homologous DNA is still occurring after an hour. The results indicate that DNA damage directly increases rates of homologous recombination and transformation in B. subtilis. The relevance of these results and recent results of other labs to the evolution of transformation are discussed.     

A determination of the efficiency of uptake of SP50 DNA by competent cells of B. subtilis

Summary Phage SP50 excludes phage SPP1 both in infection and in transfection of B. subtilis. The dependence of the efficiency of exclusion on the concentration of SP50 DNA shows that one SP50 DNA molecule within a competent cell is sufficient to exclude SPP1 phage development. The concentration dependence allows a determination of the efficiency of uptake of SP50 DNA by competent cells. Only 1 out of 200 SP50 DNA molecules in the transfection mixture will become biologically active in excluding SPP1 phage development in the competent cell.     

An efficient transformation method for <Emphasis Type="Italic">Bacillus subtilis</Emphasis> DB104

Bacillus subtilis strains are used for extracellular expression of enzymes (i.e., proteases, lipases, and cellulases) which are often engineered by directed evolution for industrial applications. B. subtilis DB104 represents an attractive directed evolution host since it has a low proteolytic activity and efficient secretion. B. subtilis DB104 is hampered like many other Bacillus strains by insufficient transformation efficiencies (≤10³ transformants/μg DNA). After investigating five physical and chemical transformation protocols, a novel natural competent transformation protocol was established for B. subtilis DB104 by optimizing growth conditions and histidine concentration during competence development, implementing an additional incubation step in the competence development phase and a recovery step during the transformation procedure. In addition, the influence of the amount and size of the transformed plasmid DNA on transformation efficiency was investigated. The natural competence protocol is “easy” in handling and allows for the first time to generate large libraries (1.5 × 10⁵ transformants/μg plasmid DNA) in B. subtilis DB104 without requiring microgram amounts of DNA.