Effect of mismatched base pairs on the fate of donor DNA in transformation of Streptococcus pneumoniae

Summary Investigation of the mechanism that discriminates against mismatched base pairs in transformation of Streptococcus pneumoniae of genotype hex ⁺ was based on the use of a radioactively labeled cloned fragment of pneumococcal DNA as donor in transformation. The fate of the donor label was followed by lysis of the transformed cells and separation by agarose gel electrophoresis of DNA fragments generated by restriction endonucleases. As a result of Hex action, most of the donor DNA fragment, which was a few kilobases in length, was lost when a mismatched base pair occurred between donor and recipient DNA. This was not observed in hex ^- recipient cells. Kinetic studies of mismatch-induced donor DNA loss showed that the process is faster in strain 800, an R6 derivative, than in DP 1601, a strain of different origin. In the latter strain, the amount of donor label that becomes double stranded rises substantially, indicating extensive formation of donorrecipient heteroduplex structures, before falling to the expected level. At 30°C the process is essentially completed 15 min after entry.     

The mechanism of competence in the transformation of streptococci of serological group H

Summary The production of a special competence factor (cpf) by the recipient cells is one of the key-elements of the complex mechanims of competence in transformation. The role of cpf and its interrelation with the other factors involved in competence remain obscure. The evidence regarding the genetic background of competence is also very scarce.The cpf production ability was demonstrated to be a genetic unit which could be transferred in transformation. The cpf marker was transformed in a heterospecific reaction, in which the S. challis (cpf ⁺) strain was the DNA donor, and S. wicky (cpf ^–) its recipient.As a result of the incorporation of this marker, S. wicky cells acquired the stable cpf production ability and, consequently, the transformation ability in a yield equal to that shown by the donor cells. DNA isolated from the S. wicky (cpf ⁺) transformants could be applied, in turn, as a donor of the cpf marker. The experiments were performed by a semiquantitative technique and the yield of the transfer of the cpf marker amounted to about 1%.     

Restriction of plasmid-mediated transformation in Bacillus subtilis 168.

Summary When plasmids carrying leucine genes of Bacillus subtilis 168 were isolated from a restriction and modification deficient (r^-m^-) strain and used for transformation of a restricting strain B. subtilis 168 leu recE4, the number of transformants was greatly reduced. Transformation of a rec ⁺ strain (transformation by integration of the donor DNA into the chromosome) with the plasmids was not affected irrespective of whether the recipient carried the r⁺ or r^- phenotype. These results show that the plasmid-mediated transformation is subject to the host controlled restriction and suggest that r^-m^- strains should be used for construction of recombinant DNA molecules in B. subtilis 168.     

Cotransformation of Aspergillus nidulans: a tool for replacing fungal genes

Summary When a non-selected DNA sequence was added during the transformation of amdS320 deletion strains of Aspergillus nidulans with a vector containing the wild-type amdS gene the AmdS⁺ transformants were cotransformed at a high frequency. Cotransformation of an amdS320, trpC801 double mutant strain showed that both the molar ratio of the two vectors and the concentration of the cotransforming vector affected the cotransformation frequency. The maximum frequency obtained was defined by the gene chosen as selection marker for transformation. Cotransformation was used to induce a gene replacement in A. nidulans. An amdS320 strain was transformed to AmdS⁺ and cotransformed with a DNA fragment containing a fusion between a non-functional A. nidulans trpC gene and the Escherichia coli lacZ gene. Ten AmdS⁺, LacZ⁺ transformants with a Trp^– mutant phenotype were selected. All of these strains could be transformed with a functional copy of the A. nidulans trpC gene, but only two strains yielded TrpC⁺ transformants which, with a low frequency, had a LacZ^– phenotype. These latter transformants had also lost the AmdS⁺ phenotype. Southern blotting analysis of DNA from these transformants confirmed the inactivation of the wild-type trpC gene, but revealed that amdS vector sequences were also involved in the gene replacement events.     

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.     

A Fast and Practical Yeast Transformation Method Mediated by Escherichia coli Based on a Trans-Kingdom Conjugal Transfer System: Just Mix Two Cultures and Wait One Hour

Trans-kingdom conjugation is a phenomenon by which DNA is transferred into a eukaryotic cell by a bacterial conjugal transfer system. Improvement in this method to facilitate the rapid co-cultivation of donor bacterial and recipient eukaryotic cell cultures could make it the simplest transformation method, requiring neither isolation of vector DNA nor preparation of competent recipient cells. To evaluate this potential advantage of trans-kingdom conjugation, we examined this simple transformation method using vector combinations, helper plasmids, and recipient Saccharomyces cerevisiae strains. Mixing donor Escherichia coli and recipient S. cerevisiae overnight cultures (50 μL each) consistently yielded on the order of 10¹ transformants using the popular experimental strain BY4742 derived from S288c and a shuttle vector for trans-kingdom conjugation. Transformation efficiency increased to the order of 10² using a high receptivity trans-kingdom conjugation strain. In addition, either increasing the amount of donor cells or pretreating the recipient cells with thiols such as dithiothreitol improved the transformation efficiency by one order of magnitude. This simple trans-kingdom conjugation-mediated transformation method could be used as a practical yeast transformation method upon enrichment of available vectors and donor E. coli strains.     

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.     

Transformation of pBR322-Derived Plasmids in Phytopathogenic Pseudomonas avenae and Enhanced Transformation in Its Proline-Auxotrophic Mutant

Efficient transformation of pBR322 and its derived plasmids, which have been widely used as cloning vectors in Escherichia coli, was observed in Pseudomonas avenae (K1), the pathogen of leaf blight disease in cereals. Moreover, there was a 10- to 50-fold transformation efficiency (1.3–3.0 × 10⁶/μg DNA) in the proline-auxotrophic mutant (Pr47), whose virulence to rice seedlings decreased. Similar enhancement of the frequency of transfer by mobilization of RSF1010, a broad host range plasmid, was observed in the recipient Pr47 strain in mating with donor Pseudomonas syringae. The plasmids harbored in these strains were maintained very stably after subcultures. Thus, a highly efficient transformation system with pBR322-derived plasmids used as a vector and Pseudomonas as a host bacterium was developed. Received: 13 July 1996 / Accepted: 26 August 1996     

Comparison of the cell surface barrier and enzymatic modification system inBrevibacterium flavum andB. lactofermentum

To investigate impediments to plasmid transformation inBrevibacterium flavum BF4 andB. lactofermentum BL1, cell surface barriers were determined by measuring growth inhibition whilst enzymatic barriers were determined by comparing DNA methylation properties.B. lactofermentum was more sensitive to growth inhibition by glycine thanB. flavum. Release of cellular proteins during sonication was more rapid forB. lactofermentum than forB. flavum. Plasmid DNA (pCSL17) isolated fromB. flavum transformed recipient McrBC⁺ strains ofEscherichia coli with lower efficiency than McrBC⁻.McrBC digestion of this DNA confirmed thatB. flavum contain methylated cytidines in the target sequence ofMcrBC sequences butB. lactofermentum contained a different methylation pattern. DNA derived from theB. lactofermentum transformed recipient EcoKR⁺ strains ofE. coli with lower efficiency than EcoKR⁻, indicating the presence of methylated adenosines in the target sequence of EcoK sequences. The present data describe the differences in the physical and enzymatic barriers between two species of corynebacteria and also provide some insight into the successful foreign gene expression in corynebacteria.     

Exchange of chromosomal markers by natural transformation between the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell

Both the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell, have been shown previously to be naturally transformable. This study reports the detection of genetic exchange by natural transformation between these two isolates. Transformation frequency was determined by filter transformation procedures. Three independent antibiotic resistance loci were used as chromosomal markers to monitor this exchange event: resistance to rifampicin, streptomycin, and nalidixic acid. The maximum frequencies of transformation were on the order of 3.1 to 3.8×10^-6 transformants per recipient; frequencies over an order of magnitude greater than those for spontaneous antibiotic resistance, although they are lower than those observed for soil: soil or marine: marine strain crosses. This exchange was inhibited by DNase I. Transformation was observed between soil and marine strains, both by filter transformation using purified DNA solutions and when transforming DNA was added in the form of viable donor cells. The results from this study support the close genetic relationship betweenP. stutzeri JM300 andP. stutzeri strain ZoBell. These results also further validate the utility ofP. stutzeri as a benchmark organism for modeling gene transfer by natural transformation in both soil and marine habitats.     

Heterospecific transformation of Pneumococcus and Streptococcus

Summary Transformations of two linked ribosomal loci (str and ery) were carried out between the SIII-1 strain of pneumococcus and the Challis and SBE strains of group H streptococcus. Transfer of markers between the Challis and SBE strains is as efficient as in the corresponding intrastrain transformations. Transfer between either of these strains and the pneumococcus, however, is less efficient than in the corresponding intrastrain transformation, and is referred to as heterospecific transformation. The inefficiency of the heterospecific transformation is due neither to specific lethality nor reduced uptake of heterologous DNA.When DNA was extracted from the hybrid resulting from a heterospecific cross and used to transform the original donor and recipient species, we found: (a) no donor material in the hybrid DNA responsible for the markedly low efficiency of integration into the recipient species; (b) donor material, in addition to the transforming marker itself, detectable by the higher efficiency with which hybrid DNA transforms the original donor species than does DNA from the original recipient species.DNA was extracted from each of 36 independently derived, doubly marked transformants resulting from the cross: Challis str-s ery-sxSIII-1 str-r53 ery-r2 DNA. Variability was observed between the different hybrid DNAs when the integration efficiency of the str marker in each DNA was compared with that of the ery marker. Variability of as great a magnitude was not observed when the same hybrid DNA was tested in repeated experiments, or when different DNA preparations were extracted from the same hybrid strain, or when several DNA preparations were obtained from a number of independent homospecific transformants. It is concluded that different kinds of donor material are present in the various hybrids, and that the nature of this extra-marker material affects the integration of the marker.Linkage of the str and ery markers was reduced in heterospecific transformations. The kind of donor DNA in the hybrid genome did not affect the linkage reduction observed when the str and ery markers were transferred back to the donor species in which they originated. Indeed, this linkage reduction was the same as that observed when the markers were originally transferred from the SIII-1 to the Challis strain. Specific factors reducing linkage in heterologous crosses must, therefore, be distinct from other factors which affect integration efficiency. The former, however, may be primarily responsible for the inefficiency of heterospecific transformation.One of the hybrid DNAs was used to obtain a second generation of hybrids by passing it through each of the original parental strains. Tests of the DNAs extracted from 24 independently produced, second-generation hybrids showed that hybrid DNA is subject to further alteration by a second integration involving some heterologous confrontation. The probability of such alteration appears to be increased if the second integration is accompanied by linkage reduction.Supported by NIH grant AI-00917.     

Conjugative transfer of tetracycline resistance in rumen streptococcal strains

In 11% of testedStreptococcus bovis strains a conjugative transfer of tetracycline resistance was observed when mating experiments were carried out on membrane filters. The recipient strain used wasS. bovis BM114 with chromosomal resistance to rifampicin. In addition, in two strains tetracycline resistance was transferred also to recipient strainEnterococcus faecium AL6. The transfer frequencies were in the range of 10⁻⁶ to 10⁻³. The donor strains were screened for the presence of plasmids and one up to four bands of plasmid DNA in all tested strains were revealed. In spite of that isolation of plasmid DNA was successful only in 53/4/114 transconjugants. Transconjugant 32/114 contained amylase activity which was higher than in the donor strain.     

Qualitative Differences in the Behavior of Pneumococcal Deoxyribonucleic Acids Transforming to the Same Capsular Type

A method is described for estimating quantitatively the frequency of transformation of pneumococci to new capsular types. It is found that, when S-(III) cells are exposed to deoxyribonucleic acid (DNA) from wild-type I strains, transformation to SI occurs at a frequency 20 to 60 times that of transformation to the binary type SI-III. SI markers on DNA isolated from binary strains behave qualitatively and quantitatively in a different manner from the same markers on DNA from wild-type I strains and will transform S-(III) cells only to SI-III. Strains are described which produce only one capsular polysaccharide, but which are genetically binary and carry a second capsular genome with a mutated gene so that the second polysaccharide is not produced. Stability and other characteristics of binary strains are discussed, and one hypothesis for the genetic organization of binary strains is presented.     

Variable influence of ferric and cupric ions on Saccharomyces cerevisiae strains used in asymmetric organic synthesis

Summary Fe (III) and Cu (II) each at 50 M in four commercial strains of Saccharomyces cerevisiae induced an increase of NAD(P)⁺ reduction in one strain (Turkish), but two others (Chilean and Brazilian), the presence of Fe(III) and/or Cu(II) diminished NAD(P)⁺ reduction presumably due to free radicais formation inside these living cells. Suprisingly, in the American strain, Fe(III) induced a decrease and Cu (II) an increase of NAD(P)⁺ reduction.     

Transforming activity of plasmid and chromosomal DNA inEscherichia coli

An auxotrophic strain ofEscherichia coli with therecB recC sbcB genotype was transformed by chromosomal DNA of the prototrophic strain and by plasmid DNA carrying genes for antibiotic resistance (R1drd 19). The donor plasmid DNA obtained by cell lysis in the presence of Triton X-100 and subsequent centrifugation in a caesium chloride-ethidium bromide gradient was shown to have a circulaf molecule and to retain its completeness after penetration into the recipient. Experiments with mixtures or plasmid and chromosomal DNA indicate a competition between these two DNA types during the transformation reaction in the given system.     

Restoration of mutability in non-mutable Escherichia coli carrying different plasmids.

Summary N and I group plasmids, which increase methylmethane sulfonate (MMS) mutagenesis in lexA ⁺ strains of E. coli WP2 may be divided into two classes: those restoring part of the mutability of lexA ^- strains (class I) and those leaving lexA ^- strains non-mutable (class II). Almost complete restoration of MMS mutability is obtained by class I plasmids in a partially suppressed lexA rnm strain, while class II plasmids cause far fewer MMS revertants in this strain than in lexA ⁺. A pair of class I and II plasmids in lexA ^- shows a synergistic effect on mutability. These two classes do not coincide with plasmid division into incompatibility groups.     

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.     

Transduction versus transformation of methicillin resistance inStaphylococcus aureus

Requirements for the transformation of methicillin resistance (Mec^r) inStaphylococcus aureus were found to differ from those of transduction in three significant respects. Production of -lactamase by the recipient strain is not a stringent requirement for Mec^r transformation as it is for transduction althoughbla ⁺ recipients exhibited a higher transformation frequency in the absence of added NaCl. Incorporation of NaCl into the methicillin-selective media markedly inhibited Mec^r transduction but increased the transformation frequency of plasmid-free recipients to the level obtained withbla ⁺ recipients. Four separately maintained clones of strain 8325-4 exhibited marked variation in recipient effectiveness for Mec^r transduction but were equally effective as recipients in transformation.     

Electroporation of Bradyrhizobium japonicum

Summary Electroporation offers a fast, efficient and reproducible way to introduce DNA into bacteria. We have successfully used this technique to transform two commercially important strains of Bradyrhizobium japonicum, the nitrogen-fixing soybean symbiont. Initially, electroporation conditions were optimized using plasmid DNA which had been prepared from the same B. japonicum strain into which the{imDNA was to b}e transformed. Efficiencies of 10⁵-10⁶ transformants/g DNA were obtained for strains USDA 110 and 61A152 with ready-to-use frozen cells. Successful electroporation of B. japonicum with plasmid DNA prepared from Escherichia coli varied with the E. coli strain from which the plasmid was purified. The highest transformation efficiencies (10⁴ transformants/g DNA) were obtained using DNA prepared from a dcm ^– dam ^– strain of E. coli. This suggests that routine isolation of DNA from an E. coli strain incapable of DNA modification should help in increasing transformation efficiencies for other strains of bacteria where DNA restriction appears to be a significant obstacle to successful transformation. We have also monitored the rate of spontaneous mutation in electroporated cells and saw no significant difference in the frequency of streptomycin resistance for electroporated cells compared to control cells.