Sequential action of factors involved in natural competence for transformation of Neisseria gonorrhoeae.

We previously identified and genetically characterized several factors essential for the natural competence of transformation in Neisseria gonorrhoeae. Here we analyse the sequential action of these factors and dissect the overall transformation process into three distinct steps, (i) the sequence-specific uptake of transforming DNA into a DNase-resistant state, (ii) the transfer of DNA to the cytosol and (iii) the processing and recombination of the incoming with the resident DNA. While two pilus-associated factors, PilE and PilC, were previously implicated in the early DNA uptake event, we show here that three competence factors unrelated to pilus biogenesis, ComA, ComL and Tpc, are not essential for DNA uptake and rather act in a subsequent step. The respective mutants, however, lack the characteristic nucleolytic processing observed with the incoming DNA in both wild-type and non-transformable RecA-deficient N. gonorrhoeae, indicating that they are blocked in the processing and/or the delivery of DNA to the cytoplasm. A hypothetical model proposing a sequential action of the known gonococcal competence factors is presented.

A novel peptidoglycan-linked lipoprotein (ComL) that functions in natural transformation competence of Neisseria gonorrhoeae.

A novel peptidoglycan-linked lipoprotein (ComL) has been identified which is required for efficient transformation of Neisseria gonorrhoeae by species-related DNA. Although most mutations in comL appear to be lethal, transposon shuttle mutagenesis was successful in generating a single viable comL mutant of N. gonorrhoeae strain MS11. This mutant, N457, exhibits a cratered and crinkled colony morphology and grows slower than wild-type MS11. However, as indicated by electron microscopy, this retardation is due to a small bacterial size rather than to a decreased generation time of the mutant bacteria. Complementation of N457 with an intact comL gene via the Hermes shuttle system fully reconstitutes bacterial size, colony morphology, and transformation competence of the wild-type strain. comL is a single-copy gene and maps downstream of the previously described comA gene. It is transcribed in the opposite direction, probably using the same transcriptional terminator. ComL has a predicted size of 29 kDa and is synthesized in Escherichia coli under the control of its native promoter, which is highly conserved with the E. coli promoter consensus sequence. The 5' end of the coding sequence reveals a lipoprotein secretion signal shown to be functional by gene fusion with alkaline phosphatase (phoA'). In E. coli, cloned ComL can be labelled with [3H]-palmitic acid, thus demonstrating its lipoproteinaceous nature. Palmitoylated ComL appears to be covalently bound to the murein sacculus of E. coli and N. gonorrhoeae since it resists boiling in 4% sodium dodecyl sulphate and is released only by lysozyme treatment. Homologous counterparts of the comL gene are found in Neisseria meningitidis as well as in several nonpathogenic Neisseria species.

Tetrapac (tpc), a novel genotype of Neisseria gonorrhoeae affecting epithelial cell invasion, natural transformation competence and cell separation.

We characterized a novel mutant phenotype (tetrapac, tpc) of Neisseria gonorrhoeae (Ngo) associated with a distinctive rough-colony morphology and bacterial growth in clusters of four. This phenotype, suggesting a defect in cell division, was isolated from a mutant library of Ngo MS11 generated with the phoA minitransposon TnMax4. The tpc mutant shows a 30% reduction in the overall murein hydrolase activity using Escherichia coli murein as substrate. Tetrapacs can be resolved by co-cultivation with wild-type Ngo, indicating that Tpc is a diffusible protein. Interestingly, Tpc is absolutely required for the natural transformation competence of piliated Ngo. Mutants in tpc grow normally, but show a approximately 10-fold reduction in their ability to invade human epithelial cells. The tpc sequence reveals an open reading frame of approximately 1 kb encoding a protein (Tpc) of 37 kDa. The primary gene product exhibits an N-terminal leader sequence typical of lipoproteins, but palmitoylation of Tpc could not be demonstrated. The ribosomal binding site of tpc is immediately downstream of the translational stop codon of the folC gene coding for an enzyme involved in folic acid biosynthesis and one-carbon metabolism. The tpc gene is probably co-transcribed from the folC promoter and a promoter located within the folC gene. The latter promoter sequence shares significant homology with E. coli gearbox consensus promoters. All three mutant phenotypes, i.e. the cell separation defect, the transformation deficiency and the defect in cell invasion can be restored by complementation of the mutant with an intact tpc gene. To some extent the tcp phenotype is reminiscent of iap in Listeria, lytA in Streptococcus pneumoniae and lyt in Bacillus subtilis, all of which are considered to represent murein hydrolase defects.

Role of pili and the phase-variable PilC protein in natural competence for transformation of Neisseria gonorrhoeae.

The Gram-negative bacterial pathogen Neisseria gonorrhoeae is naturally competent for transformation with species-related DNA. We show here that two phase-variable pilus-associated proteins, the major pilus subunit (pilin, or PilE) and PilC, a factor known to function in the assembly and adherence of gonococcal pili, are essential for transformation competence. The PilE and PilC proteins are necessary for the conversion of linearized plasmid DNA carrying the Neisseria-specific DNA uptake signal into a DNase-resistant form. The biogenesis of typical pilus fibers is neither essential nor sufficient for this process. DNA uptake deficiency of defined piliated pilC1,2 double mutants can be complemented by expression of a cloned pilC2 gene in trans. The PilC defect can also be restored by the addition of purified PilC protein, or better, pili containing PilC protein, to the mutant gonococci. Our data suggest that the two phase-variable Pil proteins act on the bacterial cell surface and cooperate in DNA recognition and/or outer membrane translocation.

Generalized transposon shuttle mutagenesis in Neisseria gonorrhoeae: a method for isolating epithelial cell invasion-defective mutants.

One requirement for the invasion of, and tight adherence to, human epithelial cells by Neisseria gonorrhoeae is the synthesis of distinct opacity (Opa) outer membrane proteins, encoded by a family of phase-variable chromosomal genes. However, cloning and surface expression of invasion-promoting Opas in Escherichia coli is not sufficient for the efficient invasion of epithelial cells: additional factors besides Opa may be involved in this process. Using the phoA mini-transposon TnMax4, a library of gonococcal mutants affected in the expression of genes encoding exported proteins was generated through shuttle mutagenesis. Of a total of 608 PhoA+ plasmid clones identified in E. coli E145 approximately 40% were used successfully in transforming N. gonorrhoeae and in activating the corresponding chromosomal genes. Gonococci producing the invasion-promoting Opa50 served as the genetic background to identify 51 mutants unable to enter Chang human epithelial cells. We expect some of these mutations affect the interaction of N. gonorrhoeae with epithelial cells directly, while other mutants may carry defects in general house-keeping, secretory and/or regulatory determinants. In some mutants the loss of invasiveness appears to be due to a negative dominant effect of the PhoA+ fusions produced in these mutants. Some of the identified genes display a phase-variation phenomenon in E. coli and several genes are found in multiple copies in N. gonorrhoeae and/or present only in pathogenic Neisseria species.

A novel determinant (comA) essential for natural transformation competence in Neisseria gonorrhoeae and the effect of a comA defect on pilin variation.

A novel genetic determinant (comA) has been identified and found to be required for the transformation of piliated Neisseria gonorrhoeae. Mutants in comA of strain MS11 grow normally and are DNA-uptake proficient but blocked in the translocation of DNA into the cytoplasm. Here we show by site-specific mutagenesis and genetic complementation that only one of two open reading frames identified in comA is essential for competence: it encodes a protein (ComA) with a predicted size of 74 kDa. The comA gene maps upstream of the iga locus and is transcribed in the opposite orientation, probably under the control of a putative sigma 54-type promoter. While DNA probes specific for the N. gonorrhoeae iga locus reveal only a little cross-reactivity with commensal Neisseria species, the neighbouring comA gene appears to be present in most of them. ComA fusion proteins were obtained by in vitro translation. The synthesized gene products migrated atypically in SDS gels indicating its strong hydrophobicity. Several transmembrane alpha-helices were predicted from the amino acid sequence of ComA which, in the context of an observed sequence similarity with other inner membrane proteins, suggests a location for the protein in the inner membrane. Using piliated and non-piliated comA mutants the consequences of transformation deficiency on pilin phase variation were assessed. We show that the comA defect affects some but not all types of DNA rearrangements associated with pilE variation. The results are in agreement with previous observations supporting the notion that multiple recombination pathways contribute to the variability of pilE.

TnMax--a versatile mini-transposon for the analysis of cloned genes and shuttle mutagenesis.

A series of Tn1721-based mini-transposons (TnMax) has been developed which are suitable for the targeting of cloned genes, shuttle mutagenesis, identification of protein export signals and the rescue of chromosomal markers. TnMax mini-Tn consist of two 38-bp inverted repeats (IR) flanking a resolution site (res), a suicide replication origin (orifd), and a gene conferring resistance to either chloramphenicol (TnMax1) or erythromycin (TnMax2). Other versions of TnMax (TnMax3 and TnMax4) carry a promoterless alkaline phosphatase-encoding gene (phoA') useful for the identification of protein export signals. The various mini-Tn cartridges are fused on the same plasmid with a common transposition control unit (TCU) comprising the tnpA (transposase) and tnpR (resolvase) genes under control of the inducible Ptrc promoter. This configuration causes a high frequency of transposition in Escherichia coli (approx. 10(-2) events/copy of target plasmid) and a minimum size of the mini-Tn. Like Tn1721, TnMax variants prefer random insertion into plasmids rather than into the E. coli chromosome, thus representing superb tools for the insertion mutagenesis of cloned genes. The TnMax-borne orifd simplifies the identification of targeted plasmids and facilitates shuttle mutagenesis, i.e., suicide delivery of a mutated gene with subsequent allelic replacement of a corresponding resident gene, in a variety of microorganisms. Rescue of such targeted chromosomal genes is easily accomplished by the excision of TnMax plus flanking segments using appropriate restriction endonucleases, ligation, and transformation of an E. coli host permissive for orifd-directed replication.