tfoX (sxy)-dependent transformation of Aggregatibacter (Actinobacillus) actinomycetemcomitans

tfoX (sxy) is a regulatory gene needed to turn on competence genes. Aggregatibacter (Actinobacillus) actinomycetemcomitans has a tfoX gene that is important for transformation. We cloned this gene on an IncQ plasmid downstream of the inducible tac promoter. When this plasmid was resident in cells of A. actinomycetemcomitans and tfoX was induced, the cells became competent for transformation. Several strains of A. actinomycetemcomitans, including different serotypes, as well as rough (adherent) and isogenic smooth (nonadherent) forms were tested. Only our two serotype f strains failed to be transformed. With the other strains, we could easily get transformants with extrachromosomal plasmid DNA when closed circular, replicative plasmid carrying an uptake signal sequence (USS) was used. When a replicative plasmid carrying a USS and cloned DNA from the chromosome of A. actinomycetemcomitans was linearized by digestion with a restriction endonuclease or when genomic DNA was used directly, the outcome was allelic exchange. To facilitate allelic exchange, we constructed a suicide plasmid (pMB78) that does not replicate in A. actinomycetemcomitans and carries a region with two inverted copies of a USS. This vector gave allelic exchange in the presence of cloned and induced tfoX easily and without digestion. Using transposon insertions in cloned katA DNA, we found that as little as 78 bp of homology at one of the ends was sufficient for that end to participate in allelic exchange. The cloning and induction of tfoX makes it possible to transform nearly any strain of A. actinomycetemcomitans, and allelic exchange has proven to be important for site-directed mutagenesis.     

Evolution of competence and DNA uptake specificity in the Pasteurellaceae

Background  

Many bacteria can take up DNA, but the evolutionary history and function of natural competence and transformation remain obscure. The sporadic distribution of competence suggests it is frequently lost and/or gained, but this has not been examined in an explicitly phylogenetic context. Additional insight may come from the sequence specificity of uptake by species such as Haemophilus influenzae, where a 9 bp uptake signal sequence (USS) repeat is both highly overrepresented in the genome and needed for efficient DNA uptake. We used the distribution of competence genes and DNA uptake specificity in H. influenzae 's family, the Pasteurellaceae, to examine the ancestry of competence.     

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.     

DNA sequence and characterization of Haemophilus influenzae dprA+, a gene required for chromosomal but not plasmid DNA transformation.

Natural genetic transformation in Haemophilus influenzae involves DNA binding, uptake, translocation, and recombination. In this study, we cloned and sequenced a 3.8-kbp H. influenzae DNA segment capable of complementing in trans the transformation defect of an H. influenzae strain carrying the tfo-37 mutation. We used subcloning, deletion analysis, and in vivo protein labeling experiments to more precisely define the gene required for efficient DNA transformation on the cloned DNA. A novel gene, which we called dprA+, was shown to encode a 41.6-kDa polypeptide that was required for efficient chromosomal but not plasmid DNA transformation. Analysis of the deduced amino acid sequence of DprA suggested that it may be an inner membrane protein, which is consistent with its apparent role in DNA processing during transformation. Four other open reading frames (ORFs) on the cloned DNA segment were identified. Two ORFs were homologous to the phosphofructokinase A (pfkA) and alpha-isopropyl malate synthase (leuA) genes of Escherichia coli and Salmonella typhimurium, respectively. Homologs for the two other ORFs could not be identified.     

comH, a novel gene essential for natural transformation of Helicobacter pylori

Helicobacter pylori is naturally competent for transformation, but the DNA uptake system of this bacterium is only partially characterized, and nothing is known about the regulation of competence in H. pylori. To identify other components involved in transformation or competence regulation in this species, we screened a mutant library for competence-deficient mutants. This resulted in the identification of a novel, Helicobacter-specific competence gene (comH) whose function is essential for transformation of H. pylori with chromosomal DNA fragments as well as with plasmids. Complementation of comH mutants in trans completely restored competence. Unlike other transformation genes of H. pylori, comH does not belong to a known family of orthologous genes. Moreover, no significant homologs of comH were identified in currently available databases of bacterial genome sequences. The comH gene codes for a protein with an N-terminal leader sequence and is present in both highly competent and less-efficient transforming H. pylori strains. A comH homolog was found in Helicobacter acinonychis but not in Helicobacter felis and Helicobacter mustelae.     

Characterization of recognition sites on bacteriophage HP1c1 DNA which interact with the DNA uptake system of Haemophilus influenzae Rd

The 32.4-kb genome of the Haemophilus influenzae bacteriophage HP1c1 contains at least twelve sites, each conferring high affinity for the DNA uptake system of transformable H. influenzae Rd. Five of these high-affinity sites have been located and their nucleotide sequences determined. Three sites contained a contiguous 9-bp sequence identical to the first nine residues of the 11-bp site previously identified as conferring high affinity for the H. influenzae transformation receptor to DNA fragments. The remaining two sites contained complete 11-bp sequences. In contrast, an HP1c1 restriction fragment containing a sequence identical to the final nine residues of the 11-bp uptake site exhibits only a low affinity for the DNA uptake system. An 8-bp sequence consisting of the first eight residues of the 11-bp site was 1% as active as the longer, high-affinity sites. Thus the first 9-bp of the 11-bp site are sufficient to direct high-affinity uptake, while the first 8-bp or the distal 9-bp are not. These results provide an initial assessment of the relative contributions of the individual residues constituting the 11-bp site to the apparent affinity of DNA fragments for the receptor of Haemophilus transformation.     

Natural transformation of Gallibacterium anatis

Gallibacterium anatis is a pathogen of poultry. Very little is known about its genetics and pathogenesis. To enable the study of gene function in G. anatis, we have established methods for transformation and targeted mutagenesis. The genus Gallibacterium belongs to the Pasteurellaceae, a group with several naturally transformable members, including Haemophilus influenzae. Bioinformatics analysis identified G. anatis homologs of the H. influenzae competence genes, and natural competence was induced in G. anatis by the procedure established for H. influenzae: transfer from rich medium to the starvation medium M-IV. This procedure gave reproducibly high transformation frequencies with G. anatis chromosomal DNA and with linearized plasmid DNA carrying G. anatis sequences. Both DNA types integrated into the G. anatis chromosome by homologous recombination. Targeted mutagenesis gave transformation frequencies of >2 × 10(-4) transformants CFU(-1). Transformation was also efficient with circular plasmid containing no G. anatis DNA; this resulted in the establishment of a self-replicating plasmid. Nine diverse G. anatis strains were found to be naturally transformable by this procedure, suggesting that natural competence is common and the M-IV transformation procedure widely applicable for this species. The G. anatis genome is only slightly enriched for the uptake signal sequences identified in other pasteurellaceaen genomes, but G. anatis did preferentially take up its own DNA over that of Escherichia coli. Transformation by electroporation was not effective for chromosomal integration but could be used to introduce self-replicating plasmids. The findings described here provide important tools for the genetic manipulation of G. anatis.     

Point mutations in a peptidoglycan biosynthesis gene cause competence induction in Haemophilus influenzae

We have identified three new Haemophilus influenzae mutations causing cells to exhibit extreme hypercompetence at all stages of growth. The mutations are in murE, which encodes the meso-diaminopimelate-adding enzyme of peptidoglycan synthesis. All are point mutations causing nonconservative amino acid substitutions, two at a poorly conserved residue (G(435)-->R and G(435)-->W) and the third at a highly conserved leucine (L(361)-->S). The mutant strains have very similar phenotypes and do not exhibit any defects in cell growth, permeability, or sensitivity to peptidoglycan antibiotics. Cells retain the normal specificity of DNA uptake for the H. influenzae uptake signal sequence. The mutations do not bypass genes known to be needed for competence induction but do dramatically increase expression of genes required for the normal pathway of DNA uptake. We conclude that the mutations do not act by increasing cell permeability but by causing induction of the normal competence pathway via a previously unsuspected signal.     

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.     

Transposon mutagenesis, characterization, and cloning of transformation genes of Haemophilus influenzae Rd.

A plasmid library of PstI fragments of Haemophilus influenzae Rd genomic DNA was mutagenized in Escherichia coli with mini-Tn10kan. The mutagenized PstI fragments were introduced by transformation into the H. influenzae chromosome, and kanamycin-resistant transformants were screened for the transformation-deficient phenotype by a cyclic AMP-DNA plate method. Fifty-four mutant strains containing 24 unique insertions that mapped to 10 different PstI fragments were isolated. Strains carrying unique insertions were tested individually for DNA uptake, transformation efficiency, UV sensitivity, and growth rate. The transformation frequencies of these mutants were decreased by factors of 10(-2) to 10(-6). Five of the mutants had normal competence-induced DNA uptake, and the rest were variably deficient in competence development. Three strains were moderately UV sensitive. All strains but one had doubling times within 50% of that of the wild type. Mutated genes were cloned into an H. influenzae-E. coli shuttle vector, and wild-type loci were recovered by in vivo recombinational exchange. Hybridization of these clones to SmaI genomic fragments separated in pulsed-field gels showed that these insertions were not clustered in a particular region of the chromosome.     

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.     

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.     

The Haemophilus influenzae sxy-1 mutation is in a newly identified gene essential for competence.

The sxy-1 mutation of Haemophilus influenzae causes a 100- to 1,000-fold increase in spontaneous natural competence. We have used mapping and sequencing to identify this mutation as a G-to-A transition in an open reading frame adjacent to the rec-1 locus. This mutation substitutes valine for isoleucine at amino acid 19 of the protein specified by this gene (now named sxy). A multicopy plasmid containing the wild-type sxy gene confers constitutive competence on wild-type cells. Cells carrying this plasmid exhibit, in all stages of growth, DNA uptake levels and transformation frequencies as high those normally seen only after full induction of competence by starvation; deletion of part of the sxy gene from the plasmid abolishes this effect. In contrast, a transposon insertion in sxy entirely prevents both DNA uptake and transformation, indicating that sxy encodes a function essential for competence. These findings suggest that sxy may act as a positive regulator of competence. However, because cells carrying the transposon-inactivated sxy::Tn allele grow slowly under conditions that do not induce competence, sxy may also have a role in noncompetent cells.     

Identification and expression of the Actinobacillus actinomycetemcomitans leukotoxin gene

The leukotoxin produced by the oral bacterium Actinobacillus actinomycetemcomitans has been implicated in the pathogenesis of juvenile periodontitis. In order to elucidate the structure of the leukotoxin, molecular cloning of the leukotoxin gene was carried out. A DNA library of A. actinomycetemcomitans, strain JP2, was constructed by partial digestion of genomic DNA with Sau3AI and ligation of 0.5 to 5.0 kilobase pair fragments into the Bam HI site of the plasmid vector pENN-vrf. After transformation into E. coli RR1 (lambda cI857), the clones were screened for the production of A. actinomycetemcomitans leukotoxin with polyclonal antibody. Six immunoreactive clones were identified. The clones expressed proteins which ranged from 21-80 kilodaltons, and the clone designated pII-2, producing the largest protein was selected for further study. Antibodies eluted from immobilized pII-2 protein also recognized the native A. actinomycetemcomitans leukotoxin molecule indicating that both molecules shared at least one epitope. DNA sequence analysis demonstrated that there are regions of significant amino acid sequence homology between the cloned A. actinomycetemcomitans leukotoxin and two other cytolysins, Escherichia coli alpha-hemolysin and Pasteurella haemolytica leukotoxin, suggesting that a family of cytolysins may exist which share a common mechanism of killing but vary in their target cell specificity.     

Quorum sensing contributes to natural transformation of Vibrio cholerae in a species-specific manner

Although it is a human pathogen, Vibrio cholerae is a regular member of aquatic habitats, such as coastal regions and estuaries. Within these environments, V. cholerae often takes advantage of the abundance of zooplankton and their chitinous molts as a nutritious surface on which the bacteria can form biofilms. Chitin also induces the developmental program of natural competence for transformation in several species of the genus Vibrio. In this study, we show that V. cholerae does not distinguish between species-specific and non-species-specific DNA at the level of DNA uptake. This is in contrast to what has been shown for other Gram-negative bacteria, such as Neisseria gonorrhoeae and Haemophilus influenzae. However, species specificity with respect to natural transformation still occurs in V. cholerae. This is based on a positive correlation between quorum sensing and natural transformation. Using mutant-strain analysis, cross-feeding experiments, and synthetic cholera autoinducer-1 (CAI-1), we provide strong evidence that the species-specific signaling molecule CAI-1 plays a major role in natural competence for transformation. We suggest that CAI-1 can be considered a competence pheromone.     

Specificity in Deoxyribonucleic Acid Uptake by Transformable Haemophilus influenzae

Cells of Haemophilus influenzae strain Rd competent for genetic transformation irreversibly bound approximately five molecular fragments of H. influenzae deoxyribonucleic acid (DNA) per cell; under identical conditions, DNA derived from Escherichia coli B was not taken up (<1 molecule per 50 cells). Similarly, DNA from Xenopus laevis was not taken up by competent H. influenzae. Of the heterologous DNAs tested, only DNA from H. parainfluenzae interfered with the uptake of H. influenzae DNA, as judged by competition experiments employing either DNA binding or genetic transformation as the test system. The extracellular heterologous DNA did not suffer either single- or double-strand breakage upon exposure to competent H. influenzae.     

In vitro Tn7 mutagenesis of Haemophilus influenzae Rd and characterization of the role of atpA in transformation.

Haemophilus influenzae Rd is a gram-negative bacterium capable of natural DNA transformation. The competent state occurs naturally in late exponential growth or can be induced by a nutritional downshift or by transient anaerobiosis. The genes cya, crp, topA, and sxy (tfoX) are known to function in the regulation of competence development. The phosphoenolpyruvate:carbohydrate phosphotransferase system functions to maintain levels of cyclic AMP necessary for competence development but is not directly involved in regulation. The exact signal(s) for competence and the genes that mediate the signal(s) are still unknown. In an effort to find additional regulatory genes, H. influenzae Rd was mutated by using an in vitro Tn7 system and screened for mutants with a reduced ability to induce the competence-regulatory gene, comA. Insertions in atpA, a gene coding for the alpha subunit of the F1 cytoplasmic domain of the ATP synthase, reduce transformation frequencies about 20-fold and cause a significant reduction in expression of competence-regulatory genes, while the expression of constitutive competence genes is only minimally affected. In addition, we found that an insertion in atpB, which encodes the a subunit of the F0 membrane-spanning domain, has a similar effect on transformation frequencies.