Competence Mutant of Haemophilus influenzae with Abnormal Ratios of Marker Efficiencies in Transformation

In studies of competence-deficient mutants of Haemophilus influenzae which absorb deoxyribonucleic acid (DNA) but fail to produce transformants, it was observed that in some mutants the residual transforming activity for different markers varied widely, i.e., produced a ratio effect. One of these mutants, com⁻⁵⁶, was studied intensively to determine the cause of the residual efficiency of transformation and the reason for the ratio effect. The residual frequency of transformation was higher for markers considered single-site mutations (like naladixic acid resistance), whereas the least efficient markers tested were those conferring resistance to high levels of streptomycin or novobiocin which are more complex than single-site mutations. Measurement of frequencies of cotransformation indicated that overall genetic linkage was reduced. Transfection was fairly efficient with phage S2 DNA, but not prophage DNA. Donor marker activity could be detected in transformed cell lysates, but not linked to recipient markers in recombinant molecules. Sucrose gradient analysis of such lysates revealed that donor material was associated with recipient DNA in at least normal quantities, but lacked detectable genetic activity. Material from donor DNA labeled with heavy isotopes was incorporated into recipient chromosomal fragments having a density indistinguishable from normal density, unlike the hybrid density recombinant material found in normal cells. No excessive solubilization or nicking of unincorporated donor was detected. It is postulated that this strain contains a hyperactive nuclease, which reduces the effective size of the input DNA during the integration process.     

Specific Effects of Heating of Transformable Streptococci on Their Ability to Discriminate Between Homospecific, Heterospecific, and Hybrid Deoxyribonucleic Acid

Heating competent bacteria of the Challis strain of Streptococcus at a temperature of 48 C causes them to lose their transformability and mainfest a slight retardation of growth rate without loss of viability. The heat-induced loss of transformability is due to diminution in the ability of the bacteria to bind deoxyribonucleic acid (DNA) irreversibly. Another effect of heat is upon a step in the transformation process subsequent to binding, a step in which DNA molecules will compete if they multiply infect an unheated cell. Despite the reduction in irreversible binding exhibited by heated cells, competition between DNA molecules to transform these cells is decreased. Neither of these sites affected by heat exhibits any specificity with regard to origin of DNA. Since heat treatment causes a relative stimulation of transformation by heterospecific DNA, a third effect of heat must be envisaged. The amount of heat-induced stimulation is dependent upon the amount of heterospecific material in the transforming DNA. Linkage of heterospecific markers is increased as a consequence of heating the recipients. Transformation by markers of different transforming efficiency in homospecific DNA is also affected by heat treatment in a differential manner. Taken together, these results point to a heat-sensitive intracellular mechanism that recognizes DNA base sequences during transformation. The effect of heat upon discrimination against heterospecific DNA has been found to occur also in the pneumococcus and in Bacillus subtilis.     

Isolation and characterization of Bacillus subtilis mutants altered in competence.

We isolated and characterized four Bacillus subtilis competence-deficient mutants. The mutants were obtained by nitrosoguanidine mutagenesis and by screening for mutants unable to be transformed both on solid and in liquid medium. Most of the mutants obtained in this way were tested for their sensitivity to the DNA-damaging agents methyl methanesulfonate, mitomycin C, and UV light. Among the mutants which did not show an increased sensitivity to these agents, four were chosen for further characterization. Data were obtained which indicate that the mutants are reduced in chromosomal and plasmid transformation and in transfection, whereas they are not altered in transduction and in protoplast transformation. Transformation experiments carried out by mixing a culture of a mutant with a culture of a wild-type strain gave some complementation for competence with one of the strains. The mutants were also characterized for their capacity to bind, take up, and break down transforming DNA; furthermore, the four competence mutations were mapped, and the results indicate that they belong to four different genes.     

Competence mutants. 3. Responses to radiations

Class 3 com(-) mutants [normal in deoxyribonucleic acid (DNA) uptake but poor in ability to transform] were investigated with regard to ultraviolet (UV) and X-ray sensitivity of colony-forming ability and with regard to their ability to be transformed by UV- and X-ray-irradiated DNA. Three mutants, com(-)40, 60, and 78, were highly UV-sensitive in colony-forming ability. None of the mutants was more sensitive than wild type to UV-irradiated transforming DNA; in fact, six of the mutants showed considerably greater resistance. Two of the mutants (com(-)40 and 60) were slightly more sensitive to X ray in colony formation, whereas most of the mutants showed some degree of sensitivity to X-ray-irradiated transforming DNA. In addition, the physical fate of X-ray-irradiated transforming DNA has been examined, and in one case (com(-)48) there was a significant drop in sedimentation value of X-ray-irradiated donor DNA after uptake by recipient cells. The com(-) mutants analyzed have been classified on the basis of their UV and X-ray sensitivities, and, where appropriate, possible biochemical lesions have been implicated.     

Transformation in fungi.

Transformation with exogenous deoxyribonucleic acid (DNA) now appears to be possible with all fungal species, or at least all that can be grown in culture. This field of research is at present dominated by Saccharomyces cerevisiae and two filamentous members of the class Ascomycetes, Aspergillus nidulans and Neurospora crassa, with substantial contributions also from fission yeast (Schizosaccharomyces pombe) and another filamentous member of the class Ascomycetes, Podospora anserina. However, transformation has been demonstrated, and will no doubt be extensively used, in representatives of most of the main fungal classes, including Phycomycetes, Basidiomycetes (the order Agaricales and Ustilago species), and a number of the Fungi Imperfecti. The list includes a number of plant pathogens, and transformation is likely to become important in the analysis of the molecular basis of pathogenicity. Transformation may be maintained either by using an autonomously replicating plasmid as a vehicle for the transforming DNA or through integration of the DNA into the chromosomes. In S. cerevisiae and other yeasts, a variety of autonomously replicating plasmids have been used successfully, some of them designed for use as shuttle vectors for Escherichia coli as well as for yeast transformation. Suitable plasmids are not yet available for use in filamentous fungi, in which stable transformation is dependent on chromosomal integration. In Saccharomyces cerevisiae, integration of transforming DNA is virtually always by homology; in filamentous fungi, in contrast, it occurs just as frequently at nonhomologous (ectopic) chromosomal sites. The main importance of transformation in fungi at present is in connection with gene cloning and the analysis of gene function. The most advanced work is being done with S. cerevisiae, in which the virtual restriction of stable DNA integration to homologous chromosome loci enables gene disruption and gene replacement to be carried out with greater precision and efficiency than is possible in other species that show a high proportion of DNA integration events at nonhomologous (ectopic) sites. With a little more trouble, however, the methodology pioneered for S. cerevisiae can be applied to other fungi too. Transformation of fungi with DNA constructs designed for high gene expression and efficient secretion of gene products appears to have great commercial potential.     

Transformation in fungi.

Transformation with exogenous deoxyribonucleic acid (DNA) now appears to be possible with all fungal species, or at least all that can be grown in culture. This field of research is at present dominated by Saccharomyces cerevisiae and two filamentous members of the class Ascomycetes, Aspergillus nidulans and Neurospora crassa, with substantial contributions also from fission yeast (Schizosaccharomyces pombe) and another filamentous member of the class Ascomycetes, Podospora anserina. However, transformation has been demonstrated, and will no doubt be extensively used, in representatives of most of the main fungal classes, including Phycomycetes, Basidiomycetes (the order Agaricales and Ustilago species), and a number of the Fungi Imperfecti. The list includes a number of plant pathogens, and transformation is likely to become important in the analysis of the molecular basis of pathogenicity. Transformation may be maintained either by using an autonomously replicating plasmid as a vehicle for the transforming DNA or through integration of the DNA into the chromosomes. In S. cerevisiae and other yeasts, a variety of autonomously replicating plasmids have been used successfully, some of them designed for use as shuttle vectors for Escherichia coli as well as for yeast transformation. Suitable plasmids are not yet available for use in filamentous fungi, in which stable transformation is dependent on chromosomal integration. In Saccharomyces cerevisiae, integration of transforming DNA is virtually always by homology; in filamentous fungi, in contrast, it occurs just as frequently at nonhomologous (ectopic) chromosomal sites. The main importance of transformation in fungi at present is in connection with gene cloning and the analysis of gene function. The most advanced work is being done with S. cerevisiae, in which the virtual restriction of stable DNA integration to homologous chromosome loci enables gene disruption and gene replacement to be carried out with greater precision and efficiency than is possible in other species that show a high proportion of DNA integration events at nonhomologous (ectopic) sites. With a little more trouble, however, the methodology pioneered for S. cerevisiae can be applied to other fungi too. Transformation of fungi with DNA constructs designed for high gene expression and efficient secretion of gene products appears to have great commercial potential.     

Integration Efficiency in DNA-Induced Transformation of PNEUMOCOCCUS. II. Genetic Studies of Mutant Integrating All the Markers with a High Efficiency

Transformation of the pneumococcus mutant 401 by DNA's bearing the standard reference marker and several other markers belonging to two unlinked loci has shown that differences in the integration efficiencies of these markers were considerably reduced in this strain compared to the wild-type strain Cl(3). The sensitivities of mutant 401 to ultraviolet light and to X-ray irradiation are the same as those of Cl(3). However, in 401 all the markers tested are more resistant to inactivation as shown by transformation of 401 and Cl(3) by ultraviolet-irradiated DNA. The increase in resistance is greater for low efficiency (LE) markers than for high efficiency (HE) markers.-The decreased discrimination between LE and HE markers in strain 401 is not due to a mechanism related to modification of markers in the transforming DNA by the recipient cells, nor are the proteins inducing competence of the cells responsible for the differences in the integration efficiencies of various markers.-Genetic studies of the fate of recombinants as well as the measure of the amount of DNA taken up have shown that all the markers are integrated in strain 401 by the same recombination process, that specific to high efficiency markers.     

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.     

Repair of UV-irradiated plasmid DNA in Saccharomyces cerevisiae. Inability to complement mutational defects in excision repair by in vitro treatment with Micrococcus luteus UV endonuclease

Excision repair defects of Saccharomyces cerevisiae rad1-1, rad4-4, rad7-1 and rad14 mutants were examined. As previously found, transformation of such cells with UV-irradiated plasmid DNA is poor compared to wild-type yeast. Treatment of UV-irradiated YRp12 plasmid DNA with crude preparations of Micrococcus luteus UV endonuclease before introducing it into rad1-1 cells increased transformation efficiency to wild-type levels. This is consistent with earlier reports of rad1-1 mutants being defective in the incision step of excision repair. However, with purified UV endonuclease little or no rescue occurred when the UV-irradiated plasmid was incised before transformation into rad1-1 or rad4-4 cells. Furthermore, the purified UV endonuclease reduced transformation of rad7-1 and rad14 mutants to levels seen in rad1-1 and rad4-4 cells. In contrast such treatment caused only a small decrease in the transforming ability of UV-irradiated DNA in wild-type cells. These results show that yeast can normally process pre-incised, UV-irradiated DNA and that this activity is absent in rad1-1, rad4-4, rad7-1 and rad14 mutants. Thus, in addition to their previously reported roles in incision, the RAD1, 4, 7 and 14 gene products are also required for repair to continue after the incision of DNA lesions.     

Isolation of telomerelike sequences from Cryptococcus neoformans and their use in high-efficiency transformation.

Development of a transformation system for the fungal human pathogen Cryptococcus neoformans is an important prerequisite for the identification of genes involved in virulence. It has previously been reported that low-efficiency transformation can be achieved by using the cloned C. neoformans URA5 gene and ura5 mutants. The introduction of linearized URA5 vectors into C. neoformans resulted in unstable transformants which apparently harbored linear extrachromosomal DNA molecules. In this paper, the nature of these molecules is confirmed to be linear by exonuclease digestion. Recovery of the extrachromosomal DNA in Escherichia coli and sequence analysis demonstrates that repeats characteristic of telomeric DNA have been added to the ends of the introduced DNA. The recovered plasmids are capable of transforming at much higher efficiencies either in the supercoiled state (up to 200 transformants per microgram) or the linear state (up to 90,000 transformants per microgram).     

Molecular heterozygotes in Bacillus subtilis and their correction

Summary Data are presented on the probability of correction of molecular heterozygotes during the transformation of Bacillus subtilis. This value varies between 0 and 1 for different mutants in the same genetic locus. The correction of closely linked markers is simultaneous but it is independent for distant loci. The efficiency of integration of different genetic markers during transformation depends on their ability to be corrected towards the structure of the recipient strain.The linked correction of neighboring markers explains quantitatively the asymmetric phenomena in reciprocal crosses.UV-irradiation of transforming DNA inhibits strongly the correction of molecular heterozygotes and eliminates the asymmetry in reciprocal crosses. The same effect is found after chemical damage of DNA by nitrous acid.     

Molecular Events Accompanying the Fixation of Genetic Information in Haemophilus Heterospecific Transformation

Heterospecific transformation between Haemophilus influenzae and H. parainfluenzae was investigated by isopycnic analysis of deoxyribonucleic acid (DNA) extracts of (3)H-labeled transforming cells that had been exposed to (32)P-labeled, heavy transforming DNA. The density distribution of genetic markers from the resident DNA and from the donor DNA was determined by transformation assay of fractions from CsCl gradients, both species being used as recipients. About 50% of the (32)P atoms in H. parainfluenzae donor DNA taken up by H. influenzae cells were transferred to resident DNA, and only a small amount of the label was lost under conditions of little cell growth. There was less transfer in the reciprocal cross, and almost half of the donor label was lost. In both crosses, the transferred donor material transformed for the donor marker considerably more efficiently when assayed on the donor species than on the recipient species, indicating that at least some of the associated (32)P atoms are contained in relatively long stretches of donor DNA. When the transformed cultures were incubated under growth conditions, the donor marker associated with recipient DNA transformed the donor species with progressively decreasing efficiency. The data indicate that the low heterospecific transformation between H. influenzae and H. parainfluenzae may be due partly to events occurring before association of donor and resident DNA but results mostly from events that occur after the association of the two DNA preparations.     

Competence Mutants II. Physical and Biological Fate of Donor Transforming Deoxyribonucleic Acid

Transformation-deficient (com(-)) mutants, which are able to bind donor transforming deoxyribonucleic acid (DNA) without yielding a significant number of transformants, were studied with regard to the fate of donor DNA. In no case was there any detectable degradation into acid-soluble radioactivity after donor DNA uptake. Physical experiments showed that some of these mutants are deficient in their ability to associate donor DNA with the recipient's chromosome (dad(-) mutants, for donor association defective), whereas others are able to form what appear to be normal donor-recipient complexes. In spite of physical evidence for integration, none of the dad(-) mutants contains biologically active recombinant DNA, suggesting that they might be deficient in the recombination process (dab(-) mutants, for donor association biologically defective). Donor biological activity is not replicated in any of the mutant strains, and in some cases there is a 10-fold reduction of donor transforming DNA within 60 min after DNA uptake.     

DNA Repair and the Evolution of Transformation in Haemophilus Influenzae

Under certain environmental conditions, naturally transforming bacteria are induced to pick up DNA released into the environment by other cells of the same or closely related species and, by homologous recombination, integrate that DNA into their chromosome. The selective pressures responsible for the evolution and maintenance of this form of genetic outcrossing, or sex, in bacteria are not known. A prominent hypothesis is that transformation, and sex in general, evolved as a means of obtaining DNA templates to repair damaged regions of the chromosome. Previous results obtained with Bacillus subtilis were consistent with the repair hypothesis. In an effort to explore the generality of those results, I have tested the repair hypothesis with Haemophilus influenzae, a naturally transforming, gram-negative species of bacteria. The results of UV damage-survivorship experiments with H. influenzae were also consistent with that hypothesis. However, additional experiments demonstrate that the higher survival of transformed cultures cannot be accounted for by use of the transforming DNA as templates for repair. I consider alternative hypotheses for the means by which transformation can increase cell survival following UV exposure and discuss the implications of these results with respect to the DNA repair hypothesis and the evolution of transformation.     

Interspecies transformation in Bacillus: sequence heterology as the major barrier.

The relative contribution of DNA restriction and of sequence heterology as barriers to interspecies transfer of DNA was studied in the heterologous transformation of Bacillus subtilis recipients by DNA was studied in the heterologous transformation of Bacillus subtilis recipients by DNA isolated from B. globigii. Transformants were obtained at very low frequencies in the evolutionarily nonconserved aromatic region; high cotransfer of linked markers was observed. New mutations were introduced into the B. globigii intergenote sequence in the resulting hybrids; these markers could be transformed with high efficiency by both B. globigii and B. subtilis DNA, representing a 10(5)-fold increase in heterologous transforming efficiency. A restriction activity in B. globigii crude extracts inactivated the biological activity of B. subtilis and hybrid DNA but not B. globigii DNA in vitro, demonstrating different sites for restriction and modification between these species. In vivo, however, B. globigii and hybrid DNA transformed the B. globigii sequence in a hybrid recipient with the same efficiency. These results show that sequence heterology is the major barrier to interspecies transformation and that, in this system, enzymatic restriction does not prevent interspecies transformation.     

Transformation of Saccharomyces cerevisiae with UV-irradiated single-stranded plasmid.

UV-irradiated single-stranded replicative plasmids were used to transform different yeast strains. The low doses of UV used in this study (10-75 J/m2) caused a significant decrease in the transforming efficiency of plasmid DNA in the Rad+ strain, while they had no effect on transformation with double-stranded plasmids of comparable size. Neither the rev3 mutation, nor the rad18 or rad52 mutations influenced the efficiency of transformation with irradiated single-stranded plasmid. However, it was found to be decreased in the double rev3 rad52 mutant. Extracellular irradiation of plasmid that contains both URA3 and LEU2 genes (psLU) gave rise to up to 5% Leu- transformants among selected Ura+ ones in the repair-proficient strain. Induction of Leu- transformants was dose-dependent and only partially depressed in the rev3 mutant. These results suggest that both mutagenic and recombinational repair processes operate on UV-damaged single-stranded DNA in yeast.     

Seventeen Sxy-Dependent Cyclic AMP Receptor Protein Site-Regulated Genes Are Needed for Natural Transformation in Haemophilus influenzae

Natural competence is the ability of bacteria to actively take up extracellular DNA. This DNA can recombine with the host chromosome, transforming the host cell and altering its genotype. In Haemophilus influenzae, natural competence is induced by energy starvation and the depletion of nucleotide pools. This induces a 26-gene competence regulon (Sxy-dependent cyclic AMP receptor protein [CRP-S] regulon) whose expression is controlled by two regulators, CRP and Sxy. The role of most of the CRP-S genes in DNA uptake and transformation is not known. We have therefore created in-frame deletions of each CRP-S gene and studied their competence phenotypes. All but one gene (ssb) could be deleted. Although none of the remaining CRP-S genes were required for growth in rich medium or survival under starvation conditions, DNA uptake and transformation were abolished or reduced in most of the mutants. Seventeen genes were absolutely required for transformation, with 14 of these genes being specifically required for the assembly and function of the type IV pilus DNA uptake machinery. Only five genes were dispensable for both competence and transformation. This is the first competence regulon for which all genes have been mutationally characterized.     

Transformation of Escherichia coli by a specific DNA restriction fragment.

Summary Specific transformation of a rifampicin sensitive strain of Escherichia coli to rifampicin resistance has been performed by a single, defined DNA restriction fragment carrying the genetic information for the subunit of E. coli RNA polymerase. In this transformation the transforming genetic character has been substituted for the corresponding recipient gene locus by recombination. The value of the described transformation system for locating genetic markers on DNA restriction fragments is discussed in comparison to previously reported in vitro systems.