Shuttle mutagenesis: two mini-transposons for gene mapping and for lacZ transcriptional fusions in Neisseria gonorrhoeae

Genetic Manipulation of Neisseria gonorrhoeae

The sexually transmitted pathogen, Neisseria gonorrhoeae, undergoes natural transformation at high frequency. This property has led to the rapid dissemination of antibiotic resistance markers and to the panmictic structure of the gonococcal population. However, high-frequency transformation also makes N. gonorrhoeae one of the easiest bacterial species to manipulate genetically in the laboratory. Techniques have been developed that result in transformation frequencies >50%, allowing the identification of mutants by screening and without selection. Constructs have been created to take advantage of this high-frequency transformation, facilitating genetic mutation, complementation, and heterologous gene expression. Techniques are described for genetic manipulation of N. gonorrhoeae, as well as for growth of this fastidious organism.

Genetic manipulation of Neisseria gonorrhoeae

The sexually-transmitted pathogen, Neisseria gonorrhoeae, undergoes natural transformation at high frequency. This property has led to the rapid dissemination of antibiotic resistance markers and to the panmictic structure of the gonococcal population. However, high frequency transformation also makes N. gonorrhoeae one of the easiest bacterial species to manipulate genetically in the laboratory. Techniques have been developed that result in transformation frequencies >50%, allowing the identification of mutants by screening and without selection. Constructs have been created to take advantage of this high frequency transformation, facilitating genetic mutation, complementation, and heterologous gene expression. Techniques are described for genetic manipulation of N. gonorrhoeae, as well as for growth of this fastidious organism.

Neisseria gonorrhoeae secretes chromosomal DNA via a novel type IV secretion system

The process of DNA donation for natural transformation of bacteria is poorly understood and has been assumed to involve bacterial cell death. Recently in Neisseria gonorrhoeae we found that mutations in three genes in the gonococcal genetic island (GGI) reduced the ability of a strain to act as a donor in transformation and to release DNA into the culture. To better characterize the GGI and the process of DNA donation, the 57 kb genetic island was cloned, sequenced and subjected to insertional mutagenesis. DNA sequencing revealed that the GGI has characteristics of a horizontally acquired genomic island and encodes homologues of type IV secretion system proteins. The GGI was found to be incorporated near the chromosomal replication terminus at the dif site, a sequence targeted by the site-specific recombinase XerCD. Using a plasmid carrying a small region of the GGI and the associated dif site, we demonstrated that this model island could be integrated at the dif site in strains not carrying the GGI and was spontaneously excised from that site. Also, we were able to delete the entire 57 kb region by transformation with DNA from a strain lacking the GGI. Thus the GGI was likely acquired and integrated into the gonococcal chromosome by site-specific recombination and may be lost by site-specific recombination or natural transformation. We made mutations in six putative type IV secretion system genes and assayed these strains for the ability to secrete DNA. Five of the mutations greatly reduced or completely eliminated DNA secretion. Our data indicate that N. gonorrhoeae secretes DNA via a specific process. Donated DNA may be used in natural transformation, contributing to antigenic variation and the spread of antibiotic resistance, and it may modulate the host immune response.

Insertion-duplication mutagenesis of neisseria: use in characterization of DNA transfer genes in the gonococcal genetic island

We created plasmids for use in insertion-duplication mutagenesis (IDM) of Neisseria gonorrhoeae. This mutagenesis method has the advantage that it requires only a single cloning step prior to transformation into gonococci. Chromosomal DNA cloned into the plasmid directs insertion into the chromosome at the site of homology by a single-crossover (Campbell-type) recombination event. Two of the vectors contain an erythromycin resistance gene, ermC, with a strong promoter and in an orientation such that transcription will proceed into the cloned insert. Thus, these plasmids can be used to create insertions that are effectively nonpolar on the transcription of downstream genes. In addition to the improved ermC, the vector contains two copies of the neisserial DNA uptake sequence to facilitate high-frequency DNA uptake during transformation. Using various chromosomal DNA insert sizes, we have determined that even small inserts can target insertion mutation by this method and that the insertions are stably maintained in the gonococcal chromosome. We have used IDM to create knockouts in two genes in the gonococcal genetic island (GGI) and to clone additional regions of the GGI by a chromosome-walking procedure. Phenotypic characterization of traG and traH mutants suggests a role for the encoded proteins in DNA secretion by a novel type IV secretion system.

Modulation of gonococcal piliation by regulatable transcription of pilE

The gonococcal pilus, a member of the type IV family of pili, is composed of numerous monomers of the pilin protein and plays an important role in the initiation of disease by providing the primary attachment of the bacterial cell to human mucosal tissues. Piliation also correlates with efficient DNA transformation. To investigate the relationships between these pilus-related functions, the piliation state, and the availability of pilin, we constructed a derivative of MS11-C9 (DeltapilE1) in which the lacIOP regulatory sequences control pilE transcription. In this strain, MS11-C9.10, the steady-state levels of pilin mRNA and protein directly correlate with the concentration of IPTG (isopropyl-beta-D-thiogalactopyranoside) in the growth medium and can reach near-wild-type levels of expression. Transmission electron microscopy (TEM) demonstrated that the number of pili per cell correlated with the steady-state expression levels: at a low level of transcription, single long pili were observed; at a moderate expression level, many singular and bundled pili were expressed; and upon full gene expression, increased lateral association between pili was observed. Analysis of pilus assembly by TEM and epithelial cell adherence over a time course of induction demonstrated that pili were expressed as early as 1 h postinduction. Analysis at different steady-state levels of transcription demonstrated that DNA transformation efficiency and adherence of MS11-C9.10 to transformed and primary epithelial cells also correlated with the level of piliation. These data show that modulation of the level of pilE transcription, without a change in pilE sequence, can alter the number of pili expressed per cell, pilus bundling, DNA transformation competence, and epithelial cell adherence of the gonococcus.

Mutagenesis of Neisseria meningitidis by in vitro transposition of Himar1 mariner

Now that the meningococcal genome sequence has been completed, the lack of a suitable method for saturation mutagenesis remains a major obstacle to the unraveling of the pathogenic propensity of Neisseria meningitidis. Here, we demonstrate that in vitro Himar1 mariner transposition on chromosomal or PCR-amplified meningococcal DNA, which is subsequently reintroduced into N. meningitidis by natural transformation, is an extremely efficient mutagenesis method. Southern blot analysis, sequencing the Himar1 insertion point in numerous transposition mutants, and a limited screening of the mutant libraries for clones impaired in maltose catabolism confirmed that Himar1 transposed randomly in N. meningitidis. Taken together, these data demonstrate that Himar1 in vitro transposition can lead to the exhaustive mutagenesis of N. meningitidis, allowing for the first time a genomic-scale mutational analysis of this important human pathogen.

Molecular models accounting for the gene conversion reactions mediating gonococcal pilin antigenic variation

The pilus antigenic variation (Av) system of Neisseria gonorrhoeae is one of several high-frequency variation systems that utilize gene conversion to switch between numerous forms of an antigen on the cell surface. We have tested three predictions of the first models that explain the movement of DNA during pilin Av: (i) Av requires two recombinations at short regions of identity, (ii) circular intermediates exist that carry pilE/pilS hybrid loci and (iii) these pilE/pilS hybrid loci target the pilS sequences to a recipient pilE gene. We confirm that normal pilin Av utilizes recombination at very short regions of DNA sequence identity and that these recombination events can occur independent of homologous recombination functions. We have isolated covalently closed circular DNA molecules carrying hybrid pilin loci, but propose that an alternative hybrid molecule is the intermediate of pilin Av. Our most striking finding is that transformation of isolated pilE/pilS hybrid loci targets the pilS sequences of the hybrid to a recipient pilE at frequencies much higher than normal recombination frequencies. These results show that the different steps of a model that explains pilin Av can be separately tested to support the validity of these novel models that account for the high-frequency gene conversions that mediate pilin Av.

Neisseria gonorrhoeae PilA is an FtsY homolog

The pilA gene of Neisseria gonorrhoeae was initially identified in a screen for transcriptional regulators of pilE, the expression locus for pilin, the major structural component of gonococcal pili. The predicted protein sequence for PilA has significant homology to two GTPases of the mammalian signal recognition particle (SRP), SRP54 and SRalpha. Homologs of SRP54 and SRalpha were subsequently identified in bacteria (Ffh and FtsY, respectively) and appear to form an SRP-like apparatus in prokaryotes. Of the two proteins, PilA is the most similar to FtsY (47% identical and 67% similar at the amino acid level). Like FtsY, PilA is essential for viability and hydrolyzes GTP. The similarities between PilA and the bacterial FtsY led us to ask whether PilA might function as the gonococcal FtsY. In this work, we show that overproduction of PilA in Escherichia coli leads to an accumulation of pre-beta-lactamase, similar to previous observations with other bacterial SRP components. Low-level expression of pilA in an ftsY conditional mutant can complement the ftsY mutation and restore normal growth to this strain under nonpermissive conditions. In addition, purified PilA can replace FtsY in an in vitro translocation assay using purified E. coli SRP components. A PilA mutant that is severely affected in its GTPase activity cannot replace FtsY in vivo or in vitro. However, overexpression of the GTPase mutant leads to the accumulation of pre-beta-lactamase, suggesting that the mutant protein may interact with the SRP apparatus to affect protein maturation. Taken together, these results show that the gonococcal PilA is an FtsY homolog and that the GTPase activity is necessary for its function.

A shuttle mutagenesis system for tagging genes in the yeast Yarrowia lipolytica

A shuttle mutagenesis system was developed for the dimorphic yeast Yarrowia lipolytica. This system combines transposon insertions generated in Escherichia coli with the transformation of yeast with the Tn-mutagenized DNA. The mini-transposon mTn-3xHA/GFP, used in Saccharomyces cerevisiae for producing stable insertions, was adapted for use in the yeast Y. lipolytica. The mTnYl1 transposon (for mini-Tn of Y. lipolytica) confers resistance to tetracycline in E. coli. It also contains the Y. lipolytica URA3 gene for selection of yeast transformants, and the coding sequence for the S65T mutant form of GFP. The rare cutter endonuclease, I-SceI, restriction site, which enables identification of the chromosomal localization of mutagenized genes, was also incorporated. mTnYl1 was first tested on the ACO1 gene, which encodes an Acyl CoA oxidase isozyme. The mutagenesis system was further validated on a Y. lipolytica genomic DNA library constructed in a pHSS6 derivative vector. Mutants with a particular morphology or defective for alkane, fatty acids and oil degradation were obtained.

The pathogenic neisseriae contain an inactive rpoN gene and do not utilize the pilE sigma54 promoter

The sigma54 promoter (P3) upstream of the pilE gene in Neisseria gonorrhoeae was shown to be non-functional by transcriptional analysis of a PpilE::lacZ fusion containing only P3. A region on the chromosome of N. gonorrhoeae strain MS11-A was identified that potentially encodes a protein with a significant similarity to the Escherichia coli RpoN protein. However, this region (designated RLS for rpoN-like sequence) does not contain a single open reading frame (ORF) capable of encoding a functional RpoN protein. It appears that RLS may have arisen from an ancestral rpoN homologue that underwent a deletion removing the sequence encoding the essential helix-turn-helix (HTH) motif, and changing the subsequent reading frame. An RLS has been identified in several strains of N. gonorrhoeae and N. meningitidis. A 90-kDa gonococcal protein has previously been shown to react with a monoclonal antibody raised against the RpoN from Salmonella typhimurium. However, mutagenesis and Western blot analysis confirmed that the gene encoding this protein is not contained within RLS.

Insertionally inactivated and inducible recA alleles for use in Neisseria

Two classes of recA mutations have been constructed for use in Neisseria gonorrhoeae: three insertionally inactivated ('knockout') mutations and three LacI-regulatable constructs that can be shifted between Rec- and Rec+ by the removal or addition of IPTG. The effects of regulating recA expression on the processes of DNA transformation, DNA repair and pilin-phase variation are described. These regulatable cassettes can also be used to control the expression of any chromosomal gene.

Plasmids with erythromycin resistance and catechol 2,3-dioxygenase- or beta-galactosidase-encoding gene cassettes for use in Neisseria spp

Four new plasmids containing the ermC' (encoding a methyltransferase which confers resistance to erythromycin), xylE-ermC' (xylE, encoding catechol 2,3-dioxygenase) and lacZ-ermC' cassettes have been constructed. The 10-bp gonococcal uptake sequence has been placed downstream from ermC' to facilitate the delivery of these cassettes into pathogenic Neisseria spp. Several restriction sites have been placed to flank the cassettes to allow their excision and directional cloning. These plasmids will provide valuable tools for constructing insertional mutants and transcriptional fusions in Neisseria spp. or other bacteria.

An improved TnMax mini-transposon system suitable for sequencing, shuttle mutagenesis and gene fusions

A new collection of mini-transposons (mini-Tn) of the previously described TnMax series [Haas et al, Gene 130 (1993a) 23-31] has been constructed. The transposons (Tn) bear genes conferring resistance to either chloramphenicol (Cm) or kanamycin (Km). Each member of the new series (TnMax5-TnMax11) contains the general M13 forward (M13-FP) and reverse (M13-RP1) sequencing primers close to the inverted repeats (IR), facilitating the rapid and convenient determination of the DNA sequences flanking the transposon insertion site. Furthermore, the mini-Tn possess the infrequently occurring NotI sites, allowing the localization of genes on macro-restriction maps of bacterial species. Some derivatives contain promoterless trp-lacZ (TnMax11), xylE (TnMax10), phoA (TnMax6) or blaM (TnMax7, TnMax9) genes next to the IR, suitable for the generation of in vivo gene- and operon fusions to study gene regulation, protein export, or to determine the topology of proteins in bacterial membranes. A set of conjugative minimal plasmid vectors (pMin1, pMin2) are used to select for TnMax insertions into the cloned insert, rather than the vector sequences. Due to the small size of the mini-Tn, and a simple and efficient mutagenesis procedure, the TnMax system is a useful tool for targeting and sequencing of cloned genes in Escherichia coli, and especially for shuttle mutagenesis of bacterial species which cannot be targeted by direct transposition.

Direct transformation of Neisseria gonorrhoeae by gel-isolated DNA

The naturally competent organism, Neisseria gonorrhoeae, can efficiently transform a marker carried on DNA purified in low-melting-temperature agarose without prior purification or dilution. Neither the agarose or buffer components inhibit transformation frequencies, but exposure to UV irradiation completely abrogates transformation.

The pilE gene of Neisseria gonorrhoeae MS11 is transcribed from a sigma 70 promoter during growth in vitro

Type 4 pili are essential for virulence in Neisseria gonorrhoeae. The gonococcal pilin subunit is encoded by pilE, upstream of which three putative promoter sequences (P1, P2, and P3) have been identified. P1 and P2 are sigma 70-like promoters and are functional when a PpiE::cat transcriptional fusion is expressed in Escherichia coli DH5 alpha. P3 is sigma 54 dependent and overlaps the P1 sequence. Site-directed mutagenesis of the pilE promoters followed by transcriptional analysis in E. coli indicated that in the absence of an appropriate activator protein, binding of RNA polymerase-sigma 54 to P3 inhibits transcription from P1 on the order of 30-fold. Transcription from P3 was undetectable in E. coli. However, PilR-dependent, P3-associated expression was detected in Pseudomonas aeruginosa PAK containing a PpilE::cat fusion, with P3 the only intact promoter. A similar analysis was performed on gonococcal reporter strains containing wild-type and mutated PpilE::cat cassettes recombined into the chromosome. In such piliated gonococcal recombinants cultured in vitro, P1 was responsible for cat expression and almost certainly for transcription of pilE. Transcription from P2 and P3 was not detectable under these conditions. Inhibition of transcription from P1 by sigma 54 binding to P3 was not apparent in N. gonorrhoeae MS11-A, suggesting that sigma 54 was either absent or unable to bind to P3 in these cells.

Shuttle mutagenesis: a mini-transposon for producing PhoA fusions with exported proteins in Neisseria gonorrhoeae

Shuttle mutagenesis is a method for producing stable mini-transposon (mTn) insertions into the genome of Neisseria gonorrhoeae (gonococcus, Gc) and other microbes. Using an mTn3 derivative, we have produced an mTn (mTnCmPhoA) which contains a phoA' gene lacking its N-terminal signal sequence useful for isolating genes which encode exported proteins. mTnCmPhoA was characterized in Gc and Escherichia coli using a cloned target containing the Gc genes, opaE1, pilA and pilB. PhoA+ Gc containing pilB::mTnCmPhoA insertions confirm that PilB is an exported protein in Gc. This system will be useful for isolating and characterizing extracytoplasmic virulence factors from Gc and other bacterial pathogens.

A conserved DNA sequence is required for efficient gonococcal pilin antigenic variation

Antigenic variation of the Neisseria gonorrhoeae pilus occurs when a variant pilin sequence from a silent locus recombines into the expression locus by predominantly unidirectional, homologous recombination. At the 3' end of all pilin loci lies a conserved DNA sequence, called the Sma/Cla repeat, which has sequence similarity to several recombinase-binding sites, and therefore may be involved in pilin recombination. We have developed a novel reverse transcriptase/polymerase chain reaction (RT-PCR) assay for direct monitoring of pilin recombination, and both RT-PCR and phase variation were used to examine pilin recombination in a gonococcal strain that had had the pilE Sma/Cla repeat removed. Results from these experiments showed a decrease in pilin recombination when the Sma/Cla sequence was deleted from the expression locus, showing that a specialized site (Sma/Cla) is involved in efficient pilin recombination.