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.     

A genetic screen identifies genes and sites involved in pilin antigenic variation in Neisseria gonorrhoeae

It has previously been shown that the frequency of pilin antigenic variation in Neisseria gonorrhoeae (the gonococcus, Gc) is regulated by iron availability. To identify factors involved in pilin variation in an iron-dependent or an iron-independent manner, we conducted a genetic screen of transposon-mutated gonococci using a pilus-dependent colony morphology phenotype to detect antigenic variation deficient mutants. Forty-six total mutants representing insertions in 30 different genes were shown to have reduced colony morphology changes resulting from impaired pilin variation. Five mutants exhibited an iron-dependent decrease in pilin variation, while the remaining 41 displayed an iron-independent decrease in pilin variation. Based on the levels of antigenic variation impairment, we defined the genes as being essential for, important for, or involved in antigenic variation. DNA repair and DNA transformation frequencies of each mutant were measured to determine whether other recombination-based processes were also affected in the mutants. Each mutant was placed into one of six classes based on their pilin variation, DNA repair and DNA transformation phenotypes. Among the many genes identified, recR is shown to be an additional member of the gonococcal RecF-like recombination pathway. In addition, recG and ruvA represent the first evidence that the processing of Holliday junctions is required for pilin antigenic variation. Moreover, two independent insertions in a non-coding region upstream of the pilE gene suggest that cis-acting sequences important for pilin variation are found in that region. Finally, insertions that effect expression of the thrB and thrC genes suggest that molecules in the threonine biosynthetic pathway are important for pilin variation. Many of the other genes identified in this genetic screen do not have an obvious role in pilin variation, DNA repair, or DNA transformation.     

Analysis of protein binding to the Sma/Cla DNA repeat in pathogenic Neisseriae.

Antigenic variation of the pilus is an essential component of Neisseria gonorrhoeae pathogenesis. Unidirectional recombination of silent pilin DNA into an expressed pilin gene allows for substantial sequence variation of this highly immunogenic surface structure. While the RecA protein is required for pilin gene recombination, the factors which maintain the silent reservoir of pilin sequences and/or allow unidirectional recombination from silent to expression loci remain undefined. We have previously shown that a conserved sequence at the 3'end of all pilin loci (the Sma/Cla repeat) is required to be present at the expression locus for efficient recombination from the silent loci. In this study, the binding of gonococcal proteins to this DNA sequence was investigated. Gel mobility shift assays and competition experiments using deletion derivatives of the repeat, show that multiple activities bind to different regions of the Sma/Cla repeat and define the boundaries of the binding sequences. Moreover, only the pathogenic Neisseria harbor proteins which specifically bind to this repeat, suggesting a correlation between the expression of these DNA binding proteins and the potential to cause disease.     

Effects of recA Mutations on Pilus Antigenic Variation and Phase Transitions in Neisseria gonorrhoeae

Intragenic recombination between the single complete pilin gene (expression locus) and multiple, distinct, partial pilin gene copies (silent, storage loci) is thought to account for the generation of pilus antigenic diversity and piliation phase (on-off) changes exhibited by Neisseria gonorrhoeae. The mechanisms operating in the genomic rearrangements associated with these forms of pilus variation were investigated through the study of isogenic strains of gonococci bearing either wild-type or altered recA alleles. Examination of the rates of pilus phase variation and the genetic basis for changes in piliation status displayed by these strains show that recA mediated homologous recombination is required for these high frequency events and confirm that the nonpiliated state results from mutations in the expressed pilin gene. In a strain that is deficient in recA mediated homologous recombination, pilus phase variation occurs at a 100-1000-fold reduced rate and results predominantly from one class of spontaneous frameshift mutations within the pilin structural gene.     

L-pilin variants of Neisseria gonorrhoeae MS11

Phase- and antigenic variation of pilin expression in Neisseria gonorrhoeae is based on the genetic exchange between silent pilin genes (pilS) and the pilin expression locus (pilE). Similarly, the non-piliated L-variants of strain MS11, which show an increased resistance to certain antibiotics, are the result of recombination with the pilE locus. However, this recombination is atypical in that pilE(L) carries a tandem arrangement of a complete pilin gene and additional partial pilin genes under the control of the same pilE promoter. Since the two pilin gene copies are tandemly arranged and are often in the same translational frame, oversized pilin molecules are produced, which do not assemble into pili. The tandem gene copies introduced in a pilE(L) locus originate from silent loci where they are already joint. Upon reversion to the P+ phenotype the L-variants lose one pilin gene copy from the pilE(L) in a process reminiscent of the deletion events that otherwise lead to the formation of the non-revertible and non-piliated Pn mutants of MS11 gonococci. Thus deletion of pilin genes from pilE can be regarded as a third mechanism of pilin variation in gonococci.     

The size and position of heterologous insertions in a silent locus differentially affect pilin recombination in Neisseria gonorrhoeae

Gonococcal pilus antigenic and phase variation result from unidirectional, RecA-dependent recombination of DNA sequences from a silent pilin copy ( pilS  ) into the expressed pilin gene ( pilE  ). To develop a quantitative assay for pilin gene recombination that is independent of phase variation, a promoterless cat gene was inserted into pilS , and recombination of ' cat into pilE was detected by selection of chloramphenicol-resistant (Cm^R) variants expressing ' cat from the pilin promoter. Although RecA-dependent Cm^R variants occurred, none were generated by the simple transfer of ' cat into pilE . Instead, each Cm^R variant contained a new pilin locus that was a hybrid of sequences from the pilE and the pilS1 ::' cat loci in addition to the two starting loci. Therefore, this system could not be used to quantify antigenic variation. However, combined studies of these hybrid loci and of recombination products generated during additional pilS mutational analyses demonstrated that both the size and position of an insertion in pilS differentially affect pilin recombination. Also, the hybrid loci appear to be intermediates of antigenic variation. This enabled the creation of molecular models for the recombination reactions that result in pilin antigenic variation.     

Differential roles of homologous recombination pathways in Neisseria gonorrhoeae pilin antigenic variation, DNA transformation and DNA repair

Neisseria gonorrhoeae (Gc) pili undergo antigenic variation when the amino acid sequence of the pilin protein is changed, aiding in immune avoidance and altering pilus expression. Pilin antigenic variation occurs by RecA-dependent unidirectional transfer of DNA sequences from a silent pilin locus to the expressed pilin gene through high-frequency recombination events that occur at limited regions of homology. We show that the Gc recQ and recO genes are essential for pilin antigenic and phase variation and DNA repair but are not involved in natural DNA transformation. This suggests that a RecF-like pathway of recombination exists in Gc. In addition, mutations in the Gc recB, recC or recD genes revealed that a Gc RecBCD pathway also exists and is involved in DNA transformation and DNA repair but not in pilin antigenic variation.     

Insertion Mutations in pilE Differentially Alter Gonococcal Pilin Antigenic Variation

Pilus antigenic variation in Neisseria gonorrhoeae occurs by the high-frequency, unidirectional transfer of DNA sequences from one of several silent pilin loci (pilS) into the expressed pilin gene (pilE), resulting in a change in the primary pilin protein sequence. Previously, we investigated the effects of large or small heterologous insertions in conserved and variable portions of a pilS copy on antigenic variation. We observed differential effects on pilin recombination by the various insertions, and the severity of the defect correlated with the disruption or displacement of a conserved pilin DNA sequence called cys2. In this study, we show that disruption or displacement of the pilE cys2 sequence by the same insertions or a deletion also affects pilin recombination. However, in contrast to the insertions in pilS, the analogous insertions in pilE impaired, but did not block, recombination of the flanking pilin sequences. These results, the change in the spectrum of donor silent copies used during variation, and our previous results with pilS mutations show that the donor pilS and recipient pilE play different roles in antigenic variation. We conclude that when high-frequency recombination mechanisms are blocked, alternative mechanisms are operative.     

Silent pilin genes of Neisseria gonorrhoeae MS11 and the occurrence of related hypervariant sequences among other gonococcal isolates

Pilin variation in Neisseria gonorrhoeae depends on a family of variant genes that undergo homologous, intragenic recombination. This work focuses on the repertoire of silent variant pilin genes in strain MS11, which contribute to the extensive variation of the expressed gene copy. A total of 17 silent copies were identified, which are, to varying degrees, truncated at their 5' coding region and grouped in seven distinct pil loci. Most silent copies belong to loci pilS1, pilS2 and pilS6, which contain six, two and three silent copies, respectively, tandemly arranged. The pilS5 and pilS7 loci each contain only a single copy. In addition, two silent copies are associated with each of the two pilE loci. By comparison with sequences present in the expressed gene of other variants of the same strain, it is suggested that each silent locus is capable of donating variant sequences into the expression locus and, thus, each silent copy can contribute to the variability of pilin expression. Often, concomitant with changes in the expressed copy, the silent copies of the pilE1 locus undergo recombinations as well. Analyses of unrelated clinical isolates of N. gonorrhoeae reveal homologies of hypervariant pilin sequences with those present in strain MS11, suggesting a limited diversity of such sequences within the gonococcal population and the existence of substantial functional constraints on the variability of pilin and pili. The data further indicate that hypervariant pilin sequences are subject to horizontal exchange and interstrain recombination.     

Limited variation and maintenance of tight genetic linkage characterize heteroallelic pilE recombination following DNA transformation of Neisseria gonorrhoeae

Genetic recombination impacts on neisserial biology in two ways: (i) specific loci undergo rearrangement at high frequency leading to the formation of many different alleles; and (ii) Neisseria , being naturally competent for DNA transformation, provide a means to disseminate the novel alleles throughout a population. In this study pilE was used as a model system to examine heteroallelic recombination following DNA transformation. When gonococci were transformed with chromosomal donor DNA containing different pilE alleles, the majority of pilE recombinants arose through allelic replacement. Co-conversion analysis across pilE showed that in ∼ 85–90% of recombination events encompassing pilE and an adjacent opa locus, linkage was maintained (i.e. ∼ 10–15% of recombination events terminated within the ∼ 1000 base pair pilE/opaE interval). In addition to those recombinants that arose through allelic replacement, a large pilus-minus subpopulation was also observed (∼ 10% of all recombinants), indicating that many recombination events did not yield recombinant pilE s that could be assembled into functional pili. PilE mosaics increased following transformation with plasmid donor DNAs carrying pilE with limited flanking-sequence homology, suggesting a potential role for flanking-sequence homologies in mosaic formation. Overall, the data support the view that horizontal transmission of chromosomal DNA between gonococci will favour the spread of intact alleles, as opposed to expanding the allelic repertoire through the formation of gene mosaics.     

Actinomycetes--the test-organisms of genetic engineering

The paper contains a short review of the data on using the methods of genetic engineering in studies of genetics and molecular biology in Streptomyces. The techniques of DNA introduction into actinomycetes and wide-spread vectors are briefly described. The origin of the actinomycete plasmids as chromosomal segments capable of autonomous replication is discussed. In this view, it is suggested that genetic instability in actinomycetes is connected with excision of specific DNA sequences from the chromosome at frequencies characteristic of recombination events. Also, amplification of short DNA segments within the chromosome resulting in tandem repeats is a consequence of unequal crossing over between direct repeats flanking the amplifying DNA and, possibly, of induction of replication of this DNA. The data on molecular cloning of actinomycete genes for primary metabolism and those for resistance to and biosynthesis of antibiotics, on using actinomycetes as the hosts for foreign genes to be expressed, as well as on analysis of nucleotide sequences of actinomycete DNA, are presented.     

Questions about gonococcal pilus phase- and antigenic variation

Pathogenic organisms inhabit one of several defined locations within a host where temperature, pH, and nutrients are relatively constant. While the microorganism must adapt to different environments within the host, the host immune system is the most formidable predator that can limit the growth of a pathogen. Neisseria gonorrhoeae (the gonococcus, Gc) is the causative agent of gonorrhoea, and has evolved several systems for varying the antigenicity of different surface antigens, presumably to help evade the effects of the human immune system. The On/Off/On phase variation of surface structure expression also alters the antigenic characteristics of the bacterial cell surface. Antigenic variation of the major subunit of the pilus, pilin, occurs by unidirectional, homologous recombination between a silent locus and the expression locus. The silent loci lie from 1 to 900 kb from the expression locus in the chromosome yet all can donate their sequences to the expression locus. The genetic composition of the pilin loci of two Gc strains has been elucidated, and the types of changes that lead to altered forms of the pilus have been extensively characterized. However, little is known about the precise molecular mechanisms used to allow high-frequency, non-reciprocal, chromosomal recombination between pilin loci or about what regulates the process of maintaining chromosome fidelity.     

Genome plasticity in Neisseria gonorrhoeae

Abstract The pathogenic Neisseria have exploited the processes of horizontal DNA transfer and genetic recombination as mechanisms for the generation of extensive protein variation and modulation of gene expression. Localized recombinations have been well documented in members of multigene families as have alterations in short repetitive sequences. Here we report an analysis of the chromosomal structure of a defined lineage of Neisseria gonorrhoeae strain MS 11 pilin variants. This study reveals the occurrence of large rearrangements, including the amplification of a 26 kb region and an inversion involving more than a third of the chromosome. Additionally, a restriction site polymorphism that correlates with pilin expression has been observed. These findings highlight the flexibility of the gonococcal genome.     

Gene conversion involving the pilin structural gene correlates with pilus+ in equilibrium with pilus- changes in Neisseria gonorrhoeae

Gonococci (Gc) exhibit pilus+----pilus- "phase transitions" at high frequency, but only some of the pilus- Gc can revert to pilus+ phenotype. We examined reversible phase transitions between pilus+ Gc and a particular pilus- variant (P-rp+ phenotype) whose pilin mRNA carries a unique block of nucleotides encoding an "assembly missense" pilin polypeptide. The results show that Gc pilus+ in equilibrium with P-rp+ transitions can result from intragenic recombination in which there is nonreciprocal exchange of partially homologous DNA sequences from a partial pilin gene (in silent, storage form) into the expression locus' complete pilin gene. Hence Gc pilus phase variation, like pilus antigenic variation, can occur by gene conversion of the pilin structural gene expression locus.     

Analysis of the Piv recombinase-related gene family of Neisseria gonorrhoeae

Neisseria gonorrhoeae (the gonococcus) is an obligate human pathogen and the causative agent of the disease gonorrhea. The gonococcal pilus undergoes antigenic variation through high-frequency recombination events between unexpressed pilS silent copies and the pilin expression locus pilE. The machinery involved in pilin antigenic variation identified to date is composed primarily of genes involved in homologous recombination. However, a number of characteristics of antigenic variation suggest that one or more recombinases, in addition to the homologous recombination machinery, may be involved in mediating sequence changes at pilE. Previous work has identified several genes in the gonococcus with significant identity to the pilin inversion gene (piv) from Moraxella species and transposases of the IS110 family of insertion elements. These genes were candidates for a recombinase system involved in pilin antigenic variation. We have named these genes irg for invertase-related gene family. In this work, we characterize these genes and demonstrate that the irg genes do not complement for Moraxella lacunata Piv invertase or IS492 MooV transposase activities. Moreover, by inactivation of all eight gene copies and overexpression of one gene copy, we conclusively show that these recombinases are not involved in gonococcal pilin variation, DNA transformation, or DNA repair. We propose that the irg genes encode transposases for two different IS110-related elements given the names ISNgo2 and ISNgo3. ISNgo2 is located at multiple loci on the chromosome of N. gonorrhoeae, and ISNgo3 is found in single and duplicate copies in the N. gonorrhoeae and Neisseria meningitidis genomes, respectively.     

Transformation competence and type-4 pilus biogenesis in Neisseria gonorrhoeae – a review

In Neisseria gonorrhoea (Ngo), the processes of type-4 pilus biogenesis and DNA transformation are functionally linked and play a pivotal role in the life style of this strictly human pathogen. The assembly of pili from its main subunit pilin (PilE) is a prerequisite for gonococcal infection since it allows the first contact to epithelial cells in conjunction with the pilus tip-associated PilC protein. While the components of the pilus and its assembly machinery are either directly or indirectly involved in the transport of DNA across the outer membrane, other factors unrelated to pilus biogenesis appear to facilitate further DNA transfer across the murein layer (ComL, Tpc) and the inner membrane (ComA) before the transforming DNA is rescued in the recipient bacterial chromosome in a RecA-dependent manner. Interestingly, PilE is essential for the first step of transformation, i.e., DNA uptake, and is itself also subject to transformation-mediated phase and antigenic variation. This short-term adaptive mechanism allows Ngo to cope with changing micro-environments in the host as well as to escape the immune response during the course of infection. Given the fact that Ngo has no ecological niche other than man, horizontal genetic exchange is essential for a successful co-evolution with the host. Horizontal exchange gives rise to heterogeneous populations harboring clones which better withstand selective forces within the host. Such extended horizontal exchange is reflected by a high genome plasticity, the existence of mosaic genes and a low linkage disequilibrium of genetic loci within the neisserial population. This led to the concept that rather than regarding individual Neisseria species as independent traits, they comprise a collective of species interconnected via horizontal exchange and relying on a common gene pool.     

Nucleotide sequence of the structural gene for class I pilin from Neisseria meningitidis: homologies with the pilE locus of Neisseria gonorrhoeae

The nucleotide sequence has been determined for the expressed pilin (pilE) locus of Neisseria meningitidis strain C311 which produces class I pili that are antigenically and structurally similar to those of gonococci. The deduced amino acid sequence of the N. meningitidis pilE translation product contains a 7 amino acid N-terminal pre-pilin leader sequence which is identical to that found in gonococcal pilin and which is characteristic of N-methylphenylalanine pili in general. The succeeding N-terminal 53 amino acids are identical to those found in the equivalent position in antigenically variant gonococcal pilins and confirm direct peptide sequencing of the amino-terminus of at least one type of meningococcal pilin. Other regions that are conserved in variant pilin polypeptides from Neisseria gonorrhoeae are conserved at the amino acid level in the class I meningococcal pilin but the coding DNA contains numerous base substitutions when compared with the equivalent gonococcal pil sequence. Sequences extending downstream for about 140 bp on the 3' side of the coding region for both pilin genes are only about 85% homologous.     

Molecular principles of antigenic variation in Neisseria gonorrhoeae

The genome of Neisseria gonorrhoeae harbours many gene loci for the production of variant pili. Strain MS11 has two expression genes (pilE) with promoter and complete coding sequences. The remaining genes are silent (pilS) lacking the promoter and the conservative amino terminals coding sequences of pilin. The pilus genes consist of six variable minicassettes (mc's), that are flancked by strictly conserved sequences. Upon phase (P⁺ to P⁺) and antigenic (P⁺ to P^–, or vice versa) transitions minicassettes from silent loci are transferred from silent pilus gene copies to the expression gene by gene conversion. P^– variants resulting from such rearrangements still produce pilin mRNA as well as pilin, but only a few are found on the surface of those gonococci.