Uptake of plasmid deoxyribonucleic acid by Haemophilus

The uptake of circular and linear plasmid RSF0885 deoxyribonucleic acids, (DNAs) obtained from Haemophilus parainfluenzae 14, in both homologous and heterologous recipients was studied and compared with that of chromosomal DNA. High concentrations of divalent cations stimulated the uptake of either circular or linear plasmid DNA in H. parainfluenzae 14 competent cells but did not affect the uptake of chromosomal DNA. The biological activity of linear plasmid DNA was similar to that of circular DNA, and the transforming efficiencies for ampicillin resistance of both molecular forms were stimulated by divalent ions. Plasmid DNA was taken up efficiently either with or without the addition of divalent ions but was not biologically active in the heterologous Haemophilus influenzae Rd recipient. Our results suggest that in H. parainfluenzae 14 some of the steps for chromosomal and plasmid DNA uptake are different.     

Uptake of heterologous DNA by Haemophilus influenzae.

With the use of highly competent Haemophilus influenzae cells, it was possible to demonstrate the uptake of heterologous DNAs. However, these DNAs, as expected, were only 1% or less as effective when competing for uptake with Haemophilus DNA. Escherichia coli DNA was removed from solution by competent cells to the extent expected if all the E. coli DNA particles contained at least one uptake recognition signal. The data were consistent with a model in which there was one uptake signal per 20 X 10(6) to 30 X 10(6) daltons of E. coli DNA. Since H. influenzae DNA has many more recognition signals, approximately one per 2 X 10(6) daltons (Danner et al., Gene 77:311-318, 1980; K. Vogt and S. H. Goodgal, submitted for publication), it has been suggested that the slower rate of E. coli DNA binding and the so-called specificity of Haemophilus DNA binding are due to the number of recognition signals per molecule of DNA as well as the nature of the DNA receptor (Vogt and Goodgal, submitted for publication). The specificity of native H. influenzae DNA binding does not apply to the uptake of denatured DNA in the transforming system (low pH) for denatured DNA.     

EXTENSIVE VARIATION IN NATURAL COMPETENCE IN HAEMOPHILUS INFLUENZAE

The ability of some bacteria to take up and recombine DNA from the environment is an important evolutionary problem because its function is controversial; although populations may benefit in the long-term from the introduction of new alleles, cells also reap immediate benefits from the contribution of DNA to metabolism. To clarify how selection has acted, we have characterized competence in natural isolates of H. influenzae by measuring DNA uptake and transformation. Most of the 34 strains we tested became competent, but the amounts of DNA they took up and recombined varied more than 1000-fold. Differences in recombination were not due to sequence divergence and were only partly explained by differences in the amounts of DNA taken up. One strain was highly competent during log phase growth, unlike the reference strain Rd, but several strains did not develop competence under any of the tested conditions. Analysis of competence genes identified genetic defects in two poorly transformable strains. These results show that strains can differ considerably in the amount of DNA they take up and recombine, indicating that the benefit associated with competence is likely to vary in space and/or time.     

HP0333, a Member of the dprA Family, Is Involved in Natural Transformation in Helicobacter pylori

Helicobacter pylori is naturally competent for DNA transformation, but the mechanism by which transformation occurs is not known. For Haemophilus influenzae, dprA is required for transformation by chromosomal but not plasmid DNA, and the complete genomic sequence of H. pylori 26695 revealed a dprA homolog (HP0333). Examination of genetic databases indicates that DprA homologs are present in a wide variety of bacterial species. To examine whether HP0333 has a function similar to dprA of H. influenzae, HP0333, present in each of 11 strains studied, was disrupted in two H. pylori isolates. For both mutants, the frequency of transformation by H. pylori chromosomal DNA was markedly reduced, but not eliminated, compared to their wild-type parental strains. Mutation of HP0333 also resulted in a marked decrease in transformation frequency by a shuttle plasmid (pHP1), which differs from the phenotype described in H. influenzae. Complementation of the mutant with HP0333 inserted in trans in the chromosomal ureAB locus completely restored the frequency of transformation to that of the wild-type strain. Thus, while dprA is required for high-frequency transformation, transformation also may occur independently of DprA. The presence of DprA homologs in bacteria known not to be naturally competent suggests a broad function in DNA processing.     

Haemophilus influenzae polypeptides involved in deoxyribonucleic acid uptake detected by cellular surface protein iodination.

Polypeptides that appear to be involved in competence development and deoxyribonucleic acid (DNA) uptake by Haemophilus influenzae were detected with a surface-specific iodinating reagent 1,3,4,6,-tetrachloro-3 alpha, 6 alpha-diphenylglycoluril. As shown on electrophoretograms, a number of polypeptides became sensitive to 125I protein labeling with the ability of these cells to bind DNA. Of these polypeptides, nine were reduced in their ability to be labeled (ral polypeptides) extensively after the incubation of competent cells with homologous, but not with heterologous, DNA. Iodination of many of these ral polypeptides was reduced in competence-deficient mutants compared with wild-type competent cells. One 125I-labeled polypeptide corresponding to a molecular weight of 29,000 was present at reduced levels in mutants reduced in the ability to bind DNA. Our results suggest that the 29,000-molecular-weight polypeptide corresponds with the ability of H. influenzae to take up DNA and that a complex of proteins is involved in DNA uptake and transformation.     

Binding of Deoxyribonucleic Acid by Cell Walls of Transformable and Nontransformable Streptococci

Cell walls isolated from competent streptococci (group H strain Challis) were shown to bind more homologous and heterologous deoxyribonucleic acid (DNA) than noncompetent walls. Heat- and alkali-denatured DNA was not bound by either wall preparation. Pretreatment of cell walls with cetyltrimethylammonium bromide sharply increased the binding of DNA but did not increase transformation of whole cells. Pretreatment of the walls with either sodium dodecylsulfate, deoxyribonuclease and ribonuclease, or with crude competence-provoking factor did not affect the binding of DNA. Antiserum prepared against whole competent cells completely blocked transformation and also inhibited DNA binding to competent cell walls. Adsorption of this antiserum with competent Challis cells removed its blocking action for both binding and transformation. Pretreatment of walls with trypsin and Pronase destroyed their ability to bind DNA. Trypsin treatment also blocked transformation in whole cells. The transforming activity of DNA bound to cell walls was found to be protected from deoxyribonuclease action. Significant differences were observed in the arginine, proline, and phenylalanine content of competent and noncompetent walls. With few exceptions, the amino acids released from competent cell walls by trypsin were several-fold greater than from noncompetent walls. The results indicate that (i) two binding sites exist, one in competent cells only and essential for subsequent transformation, and a second, present in all cells, which is not involved in transformation; (ii) both sites are protein in nature; (iii) the transformation site is blocked by antibody; and (iv) the competent cell wall possesses tryptic-sensitive protein not present in the noncompetent wall.     

Natural transformation and DNA uptake signal sequences in Actinobacillus actinomycetemcomitans

Actinobacillus actinomycetemcomitans is a member of the family Pasteurellaceae and a major causative agent of periodontitis. While several genera from this family are known to be competent for transformation, A. actinomycetemcomitans has yet to be fully characterized. Here we show that the competence of A. actinomycetemcomitans is remarkably similar to that of Haemophilus influenzae. In addition to having a similar frequency of transformation as H. influenzae, A. actinomycetemcomitans competence could also be induced at least 100-fold by cyclic AMP, suggesting that, as in H. influenzae, at least some competence genes are regulated by catabolite repression. Even more intriguing was the discovery of a putative A. actinomycetemcomitans DNA uptake signal sequence (USS) virtually identical to the USS of H. influenzae. Moreover, we provide evidence that this sequence functions in the same capacity as that from H. influenzae; the sequence appears to be required and sufficient for DNA uptake in a variety of assays. Finally, we have taken advantage of this system to develop a simple, highly efficient competence-based method for generating site-directed mutations in the wild-type fimbriated A. actinomycetemcomitans.     

Transformation of Haemophilus influenzae by plasmid RSF0885.

Plasmid RSF0885, which conferred ampicillin resistance, transformed competent Haemophilus influenzae cells with low efficiency (maximum, less than 0.01%). As judged by competition experiments and uptake of radioactivity, plasmid RSF0885 deoxyribonucleic acid was taken up into competent H. influenzae cells several orders of magnitude less efficiently than H. influenzae chromosomal deoxyribonucleic acid. Plasmid RSF0885 transformed cells with even lower efficiency than could be accounted for by the low uptake. Transformation was not affected by rec-1 and rec-2 mutations in the recipient, and strains cured of the plasmid did not show increased transformation. Plasmid molecules cut once with a restriction enzyme that made blunt ends did not transform. Transformation was favored by the closed circular form of the plasmid.     

Deoxyribonucleic acid-binding properties and membrane protein composition of a competence-deficient mutant of Haemophilus influenzae.

A mutant of Haemophilus influenzae was isolated which was completely unable to take up double-stranded homologous deoxyribonucleic acid (DNA) at normal physiological conditions but which took up DNA equally as well as the wild type at low pH (pH 4.4). The properties of the mutant provide evidence for the existence of two different mechanisms for DNA entry in the H. influenzae transformation system. With the aid of the mutant the optimal conditions for entry of DNA by these two mechanisms were determined, and the dependence of entry and the specific transforming activity of the entered DNA on competence was examined. The mechanism of entry of DNA at neutral pH, which is not functioning in the mutant, effected entry of homologous DNA only, whereas the mechanism involved in entry of DNA at low pH also effected entry of heterologous DNA. This suggests that the mutant is lacking a protein which recognizes the specific base sequence(s) required for entry. Comparison of the protein composition of the membranes of mutant cells subjected to a growth regimen provoking competence in wild-type cells with that of competent wild-type cells revealed that the mutant is impaired in the synthesis of a protein with a molecular weight of 22,500.     

Electroporation of Haemophilus influenzae is effective for transformation of plasmid but not chromosomal DNA.

Electroporation of plasmid and chromosomal DNAs were tested in Haemophilus influenzae because of an interest in introducing DNA into mutants that are deficient in competence for transformation. The initial experiments were designed to investigate and optimize conditions for electroporation of H. influenzae. Plasmid DNA was introduced into the competence proficient strain Rd and its competence-deficient uptake mutants com-52, com-59, and com-88, and the recombination deficient mutant rec1. Plasmid DNA could also be electroporated into the non-transforming strains Ra, Rc, Re and Rf. Plasmid DNA without sequences that are involved in tight binding (uptake) of DNA by competent cells of H. influenzae Rd was electroporated into both competent and non-competent cells. Competent cells were several orders of magnitude less efficient than non-competent cells for electroporation of plasmid DNAs. Electroporation of H. influenzae chromosomal DNA was not successful. Low levels of integration of chromosomal markers were observed following electroporation and these could be ascribed to transformation. The treatment of cells with DNasel following electroporation separated the effects due to electroporation from those due to transformation. The DNasel treatment did not affect the efficiency of plasmid incorporation, but severely restricted effects due to natural DNA transformation.     

Mechanism of Inactivation of Transforming Deoxyribonucleic Acid by X Rays

Transforming deoxyribonucleic acid (DNA) from Haemophilus influenzae was exposed to X rays either in phosphate buffer or in 10% yeast extract. Relations between determinations of biological inactivation, DNA uptake by competent H. influenzae, integration of DNA into the competent cell genome, and induced single-and double-strand breaks indicate that transforming DNA is inactivated by the direct and the indirect effect of X radiation primarily because integration of DNA is prevented as a result of the production of double-strand breaks.     

Transformation in Streptococcus pneumoniae: formation of eclipse complex in a coiA mutant implicates CoiA in genetic recombination

CoiA is a transient protein expressed specifically during competence and required for genetic transformation in Streptococcus pneumoniae, but not for DNA uptake. It is widely conserved among Gram-positive bacteria but its function is unknown. Here we report that although the rate of DNA uptake was not affected in a coiA mutant, the internalized donor DNA did not recombine into the host chromosome to form a physical and genetic heteroduplex. Instead, DNA taken up by a coiA mutant accumulated in the form of a single-stranded (ss) DNA-protein complex indistinguishable from the eclipse complex formed as a recombination intermediate in wild-type competent cells. Internalized donor DNA in a dprA mutant did not accumulate either as ss DNA or as an eclipse complex. Together, these results establish that a coiA mutant exhibits a phenotype different from that of dprA or recA mutants, and that CoiA functions at a later step in promoting recombination during genetic transformation in Streptococcus pneumoniae.     

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.     

Genetic transformation of Streptococcus pneumoniae by heterologous plasmid deoxyribonucleic acid.

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

Specificity of DNA uptake in genetic transformation of gonococci

Genetic transformation of gonococci to streptomycin resistance was inhibited by homologous DNA or by DNA from related $\text{Neisseriae}$, but not by high concentrations of heterologous DNAs. Gonococci were capable of adsorbing large quantities (up to about 50 μg per 10⁸ cells) of both homologous and heterologous DNA, which could not be eluted by strong shearing forces. Treatment with externally added DNase removed virtually all the heterologous DNA while a small fraction of the homologous DNA, not influenced by the presence of excess heterologous DNA, remained cell-bound in a form resistant to nuclease treatment. Competing homologous DNA suppressed nuclease-resistant binding. These findings suggest that gonococci have two types of DNA binding components at their surface. Competence of gonococci for genetic transformation undergoes a rapid decay if the cells are incubated with homologous (but $\text{not}$ with heterologous) DNA.     

Role of the electrochemical proton gradient in genetic transformation of Haemophilus influenzae.

The uptake of homologous DNA by Haemophilus influenzae was studied as a function of the proton motive force in completely competent cultures in the pH range of 6 to 8. The composition and magnitude of the proton motive force were varied by using the ionophores valinomycin and nigericin (in the presence of various potassium ion concentrations) and by using protonophores. No interaction of the ionophores with the DNA transformation system itself was observed. Either component of the proton motive force, the electrical potential or the pH gradient, can drive the uptake of DNA, and the extent of the uptake of DNA is ultimately determined by the total proton motive force. The transformation frequency increases with the proton motive force, which reaches a maximum value at around -130 mV. These results are consistent with an electrogenic proton-DNA symport mechanism, but direct evidence for such a system is not available. The proton motive force was followed during competence development of H. influenzae at pH 8. In the initial phase (up to 50 min), the proton motive force remained constant at about -90 mV, whereas the transformation frequency rose steeply. In the second phase, the proton motive force increased. The transformation frequency in this phase increased with the proton motive force, as in completely competent cultures. These observations and the observed inhibition by NAD of both the proton motive force and the transformation frequency indicate that structural components of the competent state are formed in the initial phase of competence development, whereas the second phase is characterized by an increase of the proton motive force.     

Periodate inhibition of transformation and competence development in Haemophilus influenzae

Ranhand, Jon M. (University of Cincinnati, Cincinnati, Ohio), and Herman C. Lichstein. Periodate inhibition of transformation and competence development in Haemophilus influenzae. J. Bacteriol. 92:956-959. 1966.-Periodate treatment of competent cells reduced the frequency of transformation to streptomycin resistance about 90% while reducing cell viability about 30% or less. Moreover, when periodate was added to cells early in the competence-development phase, these, too, were unable to develop maximal competence. Periodate inhibition was dependent on time and concentration as well as on the composition of the suspending menstruum. Periodate had no effect on transforming deoxyribonucleic acid (DNA), nor did it prevent transformation when added to competent cells which had already reacted with DNA. Furthermore, the progeny from cells inactivated 90% could be made fully competent, showing that the inhibition was not genetic. It was concluded that the periodate-sensitive substrate may involve the DNA binding site(s).     

Further studies on the deoxyribonucleic acid helping effect during transformation

Summary Transformation studies of the Challis strain of the H group of streptococcus were performed to further investigate the molecular basis of the deoxyribonucleic acid helping effect. Studies in the efficiency of transformation in the presence of non-transforming DNA support the notion that bacterial cells are indiscriminate in their uptake of donor DNA and that the helping effect occurs at a time when both transforming (T) and helping (H) DNAs have jointly entered the recipients. Furthermore, the ability of H DNA to promote transformation by T DNA is not directly altered by exposure of the former DNA to either UV-irradiation or nitrous acid. Nor does 5-bromouracil incorporation affect the capacity of H DNA to assist T DNA to transform a Challis cell.Increasing the concentration of denatured H DNA to a level that saturates the Challis bacteria in reaction mixtures produces a significant increase in the efficiency of genetic transformation. This increase in transformation frequency is greater with single DNA strands than with the corresponding amount of double strands.The extent of the helping effect with the Challis H DNA remains constant within an average molecular weight range of 3.5–7.0x10⁶ daltons. In the case of heterologous E. coli DNA, however, the helping function in this range is more pronounced as a result of decreasing molecular weight, even though the net incorporation of T DNA remains unaffected. When the average M. W. is reduced below 2×10⁶ a significant decline in the helping effect occurs in both cases.The effect of H DNA on the genetic transfer of two nonallelic antibiotic markers demonstrates that a saturating amount of non-transforming H DNA present in cells does not enhance the likelihood of co-integration of nonallelic factors. Evidence concerning the physiology of the competent cells and their ability to be helped reveals that the physiological basis of transformabilities and the helping capabilities of a culture are not identical.     

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.     

Isolation and characterization of mutants of Haemophilus influenzae deficient in an adenosine 5''-triphosphate-dependent deoxyribonuclease activity.

By a direct assay approach, mutants of Haemophilus influenzae Rd that are deficient in adenosine 5'-triphosphate-dependent deoxyribonuclease activity (add-) were isolated and characterized. A large proportion (50 to 90%) of the cells in cultures of these mutants failed to produce visible colonies when plated. An extensive analysis of the recombination proficiency of these strains revealed that the transformation frequency (transformants per competent cell) in the mutants was similar to that found in the wild type, but that the transformation efficiency (transformants per microgram of irreversibly bound deoxyribonucleic acid [DNA]) was reduced approximately fourfold. Sensitivities of the mutants to gamma rays, ultraviolet radiation, and methyl methane sulfonate were only slightly greater than wild-type levels. The rate of degradation of host DNA after ultraviolet irradiation was significantly reduced in the mutants. It is suggested that the adenosine 5'-triphosphate-dependent deoxyribonuclease in H. influenzae plays a nonessential role in DNA recombination and repair.