Dialects of the DNA Uptake Sequence in Neisseriaceae

In all sexual organisms, adaptations exist that secure the safe reassortment of homologous alleles and prevent the intrusion of potentially hazardous alien DNA. Some bacteria engage in a simple form of sex known as transformation. In the human pathogen Neisseria meningitidis and in related bacterial species, transformation by exogenous DNA is regulated by the presence of a specific DNA Uptake Sequence (DUS), which is present in thousands of copies in the respective genomes. DUS affects transformation by limiting DNA uptake and recombination in favour of homologous DNA. The specific mechanisms of DUS–dependent genetic transformation have remained elusive. Bioinformatic analyses of family Neisseriaceae genomes reveal eight distinct variants of DUS. These variants are here termed DUS dialects, and their effect on interspecies commutation is demonstrated. Each of the DUS dialects is remarkably conserved within each species and is distributed consistent with a robust Neisseriaceae phylogeny based on core genome sequences. The impact of individual single nucleotide transversions in DUS on meningococcal transformation and on DNA binding and uptake is analysed. The results show that a DUS core 5′-CTG-3′ is required for transformation and that transversions in this core reduce DNA uptake more than two orders of magnitude although the level of DNA binding remains less affected. Distinct DUS dialects are efficient barriers to interspecies recombination in N. meningitidis, N. elongata, Kingella denitrificans, and Eikenella corrodens, despite the presence of the core sequence. The degree of similarity between the DUS dialect of the recipient species and the donor DNA directly correlates with the level of transformation and DNA binding and uptake. Finally, DUS–dependent transformation is documented in the genera Eikenella and Kingella for the first time. The results presented here advance our understanding of the function and evolution of DUS and genetic transformation in bacteria, and define the phylogenetic relationships within the Neisseriaceae family.     

Biased distribution of DNA uptake sequences towards genome maintenance genes

Repeated sequence signatures are characteristic features of all genomic DNA. We have made a rigorous search for repeat genomic sequences in the human pathogens Neisseria meningitidis, Neisseria gonorrhoeae and Haemophilus influenzae and found that by far the most frequent 9–10mers residing within coding regions are the DNA uptake sequences (DUS) required for natural genetic transformation. More importantly, we found a significantly higher density of DUS within genes involved in DNA repair, recombination, restriction-modification and replication than in any other annotated gene group in these organisms. Pasteurella multocida also displayed high frequencies of a putative DUS identical to that previously identified in H.influenzae and with a skewed distribution towards genome maintenance genes, indicating that this bacterium might be transformation competent under certain conditions. These results imply that the high frequency of DUS in genome maintenance genes is conserved among phylogenetically divergent species and thus are of significant biological importance. Increased DUS density is expected to enhance DNA uptake and the over-representation of DUS in genome maintenance genes might reflect facilitated recovery of genome preserving functions. For example, transient and beneficial increase in genome instability can be allowed during pathogenesis simply through loss of antimutator genes, since these DUS-containing sequences will be preferentially recovered. Furthermore, uptake of such genes could provide a mechanism for facilitated recovery from DNA damage after genotoxic stress.     

Genetic Studies of Sulfadiazine-resistant and Methionine-requiring Neisseria Isolated From Clinical Material

Deoxyribonucleate (DNA) preparations were extracted from Neisseria meningitidis (four isolates from spinal fluid and blood) and N. gonorrhoeae strains, all of which were resistant to sulfadiazine upon primary isolation. These DNA preparations, together with others from in vitro mutants of N. meningitidis and N. perflava, were examined in transformation tests by using as recipient a drug-susceptible strain of N. meningitidis (Ne 15 Sul-s Met⁺) which was able to grow in a methionine-free defined medium. The sulfadiazine resistance typical of each donor was introduced into the uniform constitution of this recipient. Production of p-aminobenzoic acid was not significantly altered thereby. Transformants elicited by DNA from the N. meningitidis clinical isolates were resistant to at least 200 μg of sulfadiazine/ml, and did not show a requirement for methionine (Sul-r Met⁺). DNA from six strains of N. gonorrhoeae, which were isolated during the period of therapeutic use of sulfonamides, conveyed lower degrees of resistance and, invariably, a concurrent methionine requirement (Sul-r/Met⁻). The requirement of these transformants, and that of in vitro mutants selected on sulfadiazine-agar, was satisfied by methionine, but not by vitamin B₁₂, homocysteine, cystathionine, homoserine, or cysteine. Sul-r Met⁺ and Sul-r/Met⁻ loci could coexist in the same genome, but were segregated during transformation. On the other hand, the dual Sul-r/Met⁻ properties were not separated by recombination, but were eliminated together. DNA from various Sul-r/Met⁻ clones tested against recipients having nonidentical Sul-r/Met⁻ mutant sites yielded Sul-s Met⁺ transformants. The met locus involved is genetically complex, and will be a valuable tool for studies of genetic fine structure of members of Neisseria, and of genetic homology between species.     

Fatty Acid Composition of Neisseria Species as Determined by Gas Chromatography

Duplicate cultures of 53 strains representing 9 species of Neisseria were analyzed by gas-liquid chromatography for cellular fatty acids. N. sicca, N. mucosa, N. flava, N. flavescens, N. perflava, N. subflava, and the several serotypes of N. meningitidis examined were found to comprise a fairly homogeneous group on the basis of the percentages of individual fatty acids present. Lactose-fermenting Neisseria also were in this group. N. catarrhalis, however, contained decanoic acid in addition to the acids occurring in the other species. Moreover, the 18 C-saturated and monoenoic acids together constituted 36% of the total fatty acid composition for N. catarrhalis, while the comparable mean value for the other species was less than 13%.     

RecX Facilitates Homologous Recombination by Modulating RecA Activities

The Bacillus subtilis recH342 strain, which decreases interspecies recombination without significantly affecting the frequency of transformation with homogamic DNA, carried a point mutation in the putative recX (yfhG) gene, and the mutation was renamed as recX342. We show that RecX (264 residues long), which shares partial identity with the Proteobacterial RecX (<180 residues), is a genuine recombination protein, and its primary function is to modulate the SOS response and to facilitate RecA-mediated recombinational repair and genetic recombination. RecX-YFP formed discrete foci on the nucleoid, which were coincident in time with RecF, in response to DNA damage, and on the poles and/or the nucleoid upon stochastic induction of programmed natural competence. When DNA was damaged, the RecX foci co-localized with RecA threads that persisted for a longer time in the recX context. The absence of RecX severely impaired natural transformation both with plasmid and chromosomal DNA. We show that RecX suppresses the negative effect exerted by RecA during plasmid transformation, prevents RecA mis-sensing of single-stranded DNA tracts, and modulates DNA strand exchange. RecX, by modulating the “length or packing” of a RecA filament, facilitates the initiation of recombination and increases recombination across species.     

Natural Competence and the Evolution of DNA Uptake Specificity

Many bacteria are naturally competent, able to actively transport environmental DNA fragments across their cell envelope and into their cytoplasm. Because incoming DNA fragments can recombine with and replace homologous segments of the chromosome, competence provides cells with a potent mechanism of horizontal gene transfer as well as access to the nutrients in extracellular DNA. This review starts with an introductory overview of competence and continues with a detailed consideration of the DNA uptake specificity of competent proteobacteria in the Pasteurellaceae and Neisseriaceae. Species in these distantly related families exhibit strong preferences for genomic DNA from close relatives, a self-specificity arising from the combined effects of biases in the uptake machinery and genomic overrepresentation of the sequences this machinery prefers. Other competent species tested lack obvious uptake bias or uptake sequences, suggesting that strong convergent evolutionary forces have acted on these two families. Recent results show that uptake sequences have multiple “dialects,” with clades within each family preferring distinct sequence variants and having corresponding variants enriched in their genomes. Although the genomic consensus uptake sequences are 12 and 29 to 34 bp, uptake assays have found that only central cores of 3 to 4 bp, conserved across dialects, are crucial for uptake. The other bases, which differ between dialects, make weaker individual contributions but have important cooperative interactions. Together, these results make predictions about the mechanism of DNA uptake across the outer membrane, supporting a model for the evolutionary accumulation and stability of uptake sequences and suggesting that uptake biases may be more widespread than currently thought.     

Genome Sequencing Reveals Widespread Virulence Gene Exchange among Human Neisseria Species

Commensal bacteria comprise a large part of the microbial world, playing important roles in human development, health and disease. However, little is known about the genomic content of commensals or how related they are to their pathogenic counterparts. The genus Neisseria, containing both commensal and pathogenic species, provides an excellent opportunity to study these issues. We undertook a comprehensive sequencing and analysis of human commensal and pathogenic Neisseria genomes. Commensals have an extensive repertoire of virulence alleles, a large fraction of which has been exchanged among Neisseria species. Commensals also have the genetic capacity to donate DNA to, and take up DNA from, other Neisseria. Our findings strongly suggest that commensal Neisseria serve as reservoirs of virulence alleles, and that they engage extensively in genetic exchange.     

Characterization of DNA restriction and modification activities in Neisseria species

Type II restriction endonuclease activities detected in various Neisseria species were characterized for sequence specificity and precise site of cleavage. NsiCI isolated from N. sicca C351 cleaves the sequence 5′-GAT↓ATC-3′ (EcoRV isoschizomer); NmeCI from N. meningitidis C114 and NphI from N. pharyngis C245 cleave 5′-N↓GATCN-3′ (MboI isoschizomers); NgoPII and NgoPIII from N. gonorrhoeae P9-2 cleave at 5′-CC↓GCGG-3′ (SacII isoschizomer) and 5′-GG↓CC-3′ (HaeIII isoschizomer), respectively. Chromosomal DNA isolated from these strains and two other N. meningitidis strains (which lacked detectable endonuclease activities), was found to be refractive to cleavage by various restriction enzymes, implying the presence of methylase activities additional to those required for protection against the cellular endonucleases.     

Genomic Content of Neisseria Species

The physical properties of most bacterial genomes are largely unexplored. We have previously demonstrated that the strict human pathogen Neisseria gonorrhoeae is polyploid, carrying an average of three chromosome copies per cell and only maintaining one pair of replication forks per chromosome (D. M. Tobiason and H. S. Seifert, PLos Biol. 4:1069-1078, 2006). We are following up this initial report to test several predictions of the polyploidy model of gonococcal chromosome organization. We demonstrate that the N. gonorrhoeae chromosomes exist solely as monomers and not covalently linked dimers, and in agreement with the monomer status, we show that distinct nucleoid regions can be detected by electron microscopy. Two different approaches to isolate heterozygous N. gonorrhoeae resulted in the formation of merodiploids, showing that even with more than one chromosome copy, these bacteria are genetically haploid. We show that the closely related bacterium Neisseria meningitidis is also polyploid, while the commensal organism Neisseria lactamica maintains chromosomes in single copy. We conclude that the pathogenic Neisseria strains are homozygous diploids.Bacteria are unicellular organisms that exhibit a multitude of shapes and sizes and exist in a wide range of environments. Despite the extreme diversity of capabilities and physiology evidenced by different bacterial species, most bacteria are assumed to conform to the enteric model of genomic organization, chromosomal replication, and genomic segregation during cell division exemplified by Escherichia coli. In contradiction to this limited view of bacterial genome biology, some bacterial species have their genome divided between multiple DNA elements (10), and some possess linear chromosomes (2, 19). A few bacterial species have been reported to carry multiple genome copies per cell (members of the genera Azotobacter, Borrelia, Buchnera, Deinococcus, Neisseria, and Epulopiscium), with copy number estimates ranging from two copies to thousands of copies per cell (1, 7, 17, 23, 25, 26, 34, 35, 39, 46). The exact number of genomes per cell has not been determined for most of these organisms, and the mechanisms for organizing polyploid genomes and segregating them during cell division remain to be determined. An exception is Deinococcus radiodurans, which has been shown to possess four complete chromosomes during exponential growth and up to 16 genomes within the stationary phase. The polyploid genomes of D. radiodurans have been proposed to assemble into a toroidal mass in the cell (29), but the validity of this finding has been questioned (11, 13, 49). There are few obvious commonalities between these polyploid organisms, except that some Neisseria, Deinococcus, and Borrelia species utilize homologous recombination to mediate specialized processes essential for the survival of these species. In addition, members of the Azotobacter, Buchnera, and Epulopiscium genera are obligate symbionts that do not possess a free-living stage, but the reasons why obligate symbionts would possess polyploid chromosomes are unknown.Neisseria gonorrhoeae and Neisseria meningitidis are the two pathogenic members of the Neisseria genus. N. gonorrhoeae is the sole causative agent of the disease gonorrhea, and N. meningitidis is the most common cause of bacterial meningitis in adolescents and young adults. One attribute that these human-specific pathogens use to coexist and evolve within humans lies in their capacity to antigenically vary and phase vary several outer membrane structures, including pili, Opa proteins, and the lipooligosaccharide (LOS) (12, 21). Variation of the Opa and LOS antigens is mediated by polynucleotide repeat variation that modulates expression of biosynthetic genes (40, 48). These changes in polynucleotide repeat sequences are mediated through slipped-strand mispairing that occurs during normal DNA replication and therefore would not obviously benefit from polyploidy. In contrast, pilin antigenic variation is a RecA-mediated gene conversion event (27), which could be aided by having two copies of all the recombining pilin loci within a single cell to facilitate the nonreciprocal transfer of pilin sequences. Therefore, we postulated that the presence of multiple genome copies per gonococcal cell may be required to facilitate these high-frequency gene conversion events. Analysis of gonococcal genome content by flow cytometry and fluorescent microscopy indicated that there existed greater than one genome equivalent of gonococcal DNA content per cell (46). Additionally, quantitative real-time PCR and genome microarray analysis measured a marker frequency pinpointing a single DNA replication event per round of cell division. On average, each coccal unit had three genome copies per cell, and a population of cells with a single genome equivalent per cell was never observed, even under conditions of slower growth. These observations predicted a model for gonococcal replication (Fig. ​(Fig.1)1) in which each coccal unit has a minimum of two chromosomes that replicate in unison to produce four chromosomes prior to cell division and the conclusion that this species is diploid.Open in a separate windowFIG. 1.Model of gonococcal DNA replication and chromosome segregation in a monococcus. The gonococcal chromosome is indicated by a dotted line. An antibiotic resistance (Ab^R) marker recombined into a gonococcal chromosome (solid line). At time zero minutes, DNA replication begins, and after 35 min, DNA replication is complete. Gonococcal cell division occurs after 60 min. In scenario I, homozygous chromosomes are segregated together. In scenario II, heterozygous bacteria are produced.Though the analysis of the genomic content has only been reported for the gonococcus, the genus Neisseria encompasses a number of pathogenic and commensal bacteria. N. meningitidis is the leading cause of bacterial meningitis worldwide and is asymptomatically carried in the human nasopharynx (47). Most of the Neisseria species are commensal organisms that inhabit the nasopharynx and rarely cause disease (24). The most extensively studied commensal Neisseria species, N. lactamica, shares extensive homology with the pathogenic Neisseriae species and also predominately resides in the human nasopharynx (31). Only the pathogenic neisseriae, N. gonorrhoeae and N. meningitidis, have been shown to undergo pilin antigenic variation (43). Since the polyploid nature of N. gonorrhoeae has been proposed to be required for pilin antigenic variation, N. meningitidis may also have multiple genome copies per cell. The genomic copy number of other Neisseria species and the putative relationship between genomic content and pathogenesis remain to be determined.In this work, we tested several predictions or models resulting from the observation that the gonococcus is polyploid. We confirmed that the chromosomes exist as separate molecules and show that the gonococcal nucleoids reside in discrete cellular regions. We confirm that these bacteria are genetically haploid, suggesting that chromosomal segregation mechanisms ensure a homozygous population. Finally, we show that the other pathogenic Neisseria species, N. meningitidis, is also polyploid, while a commensal Neisseria species, N. lactamica, is not. These studies show that polyploidy is correlated with Neisseria pathogenesis and suggest that this property has evolved to allow diploid chromosomes while maintaining the haploid status of these obligate human pathogens.     

Variations in gene organization and DNA uptake signal sequence in the folP region between commensal and pathogenic Neisseria species

Background  

Horizontal gene transfer is an important source of genetic variation among Neisseria species and has contributed to the spread of resistance to penicillin and sulfonamide drugs in the pathogen Neisseria meningitidis. Sulfonamide resistance in Neisseria meningitidis is mediated by altered chromosomal folP genes. At least some folP alleles conferring resistance have been horizontally acquired from other species, presumably from commensal Neisseriae. In this work, the DNA sequence surrounding folP in commensal Neisseria species was determined and compared to corresponding regions in pathogenic Neisseriae, in order to elucidate the potential for inter-species DNA transfer within this region.     

Role of interspecies transfer of chromosomal genes in the evolution of penicillin resistance in pathogenic and commensal Neisseria species

Summary The two pathogenic species of Neisseria, N. meningitidis and N. gonorrhoeae, have evolved resistance to penicillin by alterations in chromosomal genes encoding the high molecular weight penicillin-binding proteins, or PBPs. The PBP 2 gene (penA) has been sequenced from over 20 Neisseria isolates, including susceptible and resistant strains of the two pathogenic species, and five human commensal species. The genes from penicillin-susceptible strains of N. meningitidis and N. gonorrhoeae are very uniform, whereas those from penicillin-resistant strains consist of a mosaic of regions resembling those in susceptible strains of the same species, interspersed with regions resembling those in one, or in some cases, two of the commensal species. The mosaic structure is interpreted as having arisen from the horizontal transfer, by genetic transformation, of blocks of DNA, usually of a few hundred base pairs. The commensal species identified as donors in these interspecies recombinational events (N. flavescens and N. cinerea) are intrinsically more resistant to penicillin than typical isolates of the pathogenic species. Transformation has apparently provided N. meningitidis and N. gonorrhoeae with a mechanism by which they can obtain increased resistance to penicillin by replacing their penA genes (or the relevant parts of them) with the penA genes of related species that fortuitously produce forms of PBP 2 that are less susceptible to inhibition by the antibiotic. The ends of the diverged blocks of DNA in the penA genes of different penicillin-resistant strains are located at the same position more often than would be the case if they represent independent crossovers at random points along the gene. Some of these common crossover points may represent common ancestry, but reasons are given for thinking that some may represent independent events occurring at recombinational hotspots. Offprint requests to: B.G. Spratt     

An in vitro strategy for the selective isolation of anomalous DNA from prokaryotic genomes

In sequenced genomes of prokaryotes, anomalous DNA (aDNA) can be recognized, among others, by atypical clustering of dinucleotides. We hypothesized that atypical clustering of hexameric endonuclease recognition sites in aDNA allows the specific isolation of anomalous sequences in vitro. Clustering of endonuclease recognition sites in aDNA regions of eight published prokaryotic genome sequences was demonstrated. In silico digestion of the Neisseria meningitidis MC58 genome, using four selected endonucleases, revealed that out of 27 of the small fragments predicted (<5 kb), 21 were located in known genomic islands. Of the 24 calculated fragments (>300 bp and <5 kb), 22 met our criteria for aDNA, i.e. a high dinucleotide dissimilarity and/or aberrant GC content. The four enzymes also allowed the identification of aDNA fragments from the related Z2491 strain. Similarly, the sequenced genomes of three strains of Escherichia coli assessed by in silico digestion using XbaI yielded strain-specific sets of fragments of anomalous composition. In vitro applicability of the method was demonstrated by using adaptor-linked PCR, yielding the predicted fragments from the N.meningitidis MC58 genome. In conclusion, this strategy allows the selective isolation of aDNA from prokaryotic genomes by a simple restriction digest–amplification–cloning–sequencing scheme.     

A New Family of Secreted Toxins in Pathogenic Neisseria Species

The genus Neisseria includes both commensal and pathogenic species which are genetically closely related. However, only meningococcus and gonococcus are important human pathogens. Very few toxins are known to be secreted by pathogenic Neisseria species. Recently, toxins secreted via type V secretion system and belonging to the widespread family of contact-dependent inhibition (CDI) toxins have been described in numerous species including meningococcus. In this study, we analyzed loci containing the maf genes in N. meningitidis and N. gonorrhoeae and proposed a novel uniform nomenclature for maf genomic islands (MGIs). We demonstrated that mafB genes encode secreted polymorphic toxins and that genes immediately downstream of mafB encode a specific immunity protein (MafI). We focused on a MafB toxin found in meningococcal strain NEM8013 and characterized its EndoU ribonuclease activity. maf genes represent 2% of the genome of pathogenic Neisseria, and are virtually absent from non-pathogenic species, thus arguing for an important biological role. Indeed, we showed that overexpression of one of the four MafB toxins of strain NEM8013 provides an advantage in competition assays, suggesting a role of maf loci in niche adaptation.     

Comparative and phylogenetic analyses of Swertia L. (Gentianaceae) medicinal plants (from Qinghai,China) based on complete chloroplast genomes

Swertia L. is a large genus in Swertiinae (Gentianaceae). In China, many Swertia species are used as traditional Tibetan medicines, known as “Zangyinchen” or “Dida”. However, the phylogenetic relationships among Swertia medicinal plants and their wild relatives have remained unclear. In this study, we sequenced and assembled 16 complete chloroplast (cp) genomes of 10 Swertia species, mainly distributed in Qinghai Province, China. The results showed that these species have typical structures and characteristics of plant cp genomes. The sizes of Swertia cp genomes are ranging from 149,488 bp to 154,097 bp. Most Swertia cp genomes presented 134 genes, including 85 protein coding genes, eight rRNA genes, 37 tRNA genes, and four pseudogenes. Furthermore, the GC contents and boundaries of cp genomes are similar among Swertia species. The phylogenetic analyses indicated that Swertia is a complex polyphyletic group. In addition, positive selection was found in psaI and petL genes, indicating the possible adaptation of Qinghai Swertia species to the light environment of the Qinghai-Tibet plateau. These new cp genome data could be further investigated to develop DNA barcodes for Swertia medicinal plants and for additional systematic studies of Swertia and Swertiinae species.     

DNA Methylation Assessed by SMRT Sequencing Is Linked to Mutations in Neisseria meningitidis Isolates

The Gram-negative bacterium Neisseria meningitidis features extensive genetic variability. To present, proposed virulence genotypes are also detected in isolates from asymptomatic carriers, indicating more complex mechanisms underlying variable colonization modes of N. meningitidis.We applied the Single Molecule, Real-Time (SMRT) sequencing method from Pacific Biosciences to assess the genome-wide DNA modification profiles of two genetically related N. meningitidis strains, both of serogroup A. The resulting DNA methylomes revealed clear divergences, represented by the detection of shared and of strain-specific DNA methylation target motifs. The positional distribution of these methylated target sites within the genomic sequences displayed clear biases, which suggest a functional role of DNA methylation related to the regulation of genes.DNA methylation in N. meningitidis has a likely underestimated potential for variability, as evidenced by a careful analysis of the ORF status of a panel of confirmed and predicted DNA methyltransferase genes in an extended collection of N. meningitidis strains of serogroup A. Based on high coverage short sequence reads, we find phase variability as a major contributor to the variability in DNA methylation. Taking into account the phase variable loci, the inferred functional status of DNA methyltransferase genes matched the observed methylation profiles.Towards an elucidation of presently incompletely characterized functional consequences of DNA methylation in N. meningitidis, we reveal a prominent colocalization of methylated bases with Single Nucleotide Polymorphisms (SNPs) detected within our genomic sequence collection. As a novel observation we report increased mutability also at 6mA methylated nucleotides, complementing mutational hotspots previously described at 5mC methylated nucleotides.These findings suggest a more diverse role of DNA methylation and Restriction-Modification (RM) systems in the evolution of prokaryotic genomes.     

The pilus colonization factor of pathogenic neisserial species: organelle biogenesis and structure/function relationships – a review

Type-IV pilus expression plays a critical role in the interactions between Neisseria gonorrhoeae, Neisseria meningitidis and their human host. We have focused on experiments designed to elucidate the mechanisms of organelle biogenesis as one means of understanding the complexities of pilus biology in these species. Employing a variety of approaches, genes and gene products essential to pilus biogenesis have been identified and characterized. The findings indicate that the neisserial type-IV pilus biogenesis machinery is most closely related to that operating in Pseudomonas aeruginosa and other pseudomonad species. This interrelatedness is documented at the levels of gene organization, DNA homologies and identities between the primary structures of the components. Despite these similarities, the biological correlates of pilus expression in the pathogenic Neisseria are quite unique. The current status of our embryonic understanding of the factors influencing organelle biogenesis is presented. In the context of this workshop, emphasis has been placed on specific contributions made through studies of gonococci and meningococci to the field as a whole.     

System Specificity of the TpsB Transporters of Coexpressed Two-Partner Secretion Systems of Neisseria meningitidis

The two-partner secretion (TPS) systems of Gram-negative bacteria consist of a large secreted exoprotein (TpsA) and a transporter protein (TpsB) located in the outer membrane. TpsA targets TpsB for transport across the membrane via its ∼30-kDa TPS domain located at its N terminus, and this domain is also the minimal secretory unit. Neisseria meningitidis genomes encode up to five TpsAs and two TpsBs. Sequence alignments of TPS domains suggested that these are organized into three systems, while there are two TpsBs, which raised questions on their system specificity. We show here that the TpsB2 transporter of Neisseria meningitidis is able to secrete all types of TPS domains encoded in N. meningitidis and the related species Neisseria lactamica but not domains of Haemophilus influenzae and Pseudomonas aeruginosa. In contrast, the TpsB1 transporter seemed to be specific for its cognate N. meningitidis system and did not secrete the TPS domains of other meningococcal systems. However, TpsB1 did secrete the TPS2b domain of N. lactamica, which is related to the meningococcal TPS2 domains. Apparently, the secretion depends on specific sequences within the TPS domain rather than the overall TPS domain structure.     

Bacterial DNA Uptake Sequences Can Accumulate by Molecular Drive Alone

Uptake signal sequences are DNA motifs that promote DNA uptake by competent bacteria in the family Pasteurellaceae and the genus Neisseria. The genomes of these bacteria contain many copies of their canonical uptake sequence (often >100-fold overrepresentation), so the bias of the uptake machinery causes cells to prefer DNA derived from close relatives over DNA from other sources. However, the molecular and evolutionary forces responsible for the abundance of uptake sequences in these genomes are not well understood, and their presence is not easily explained by any of the current models of the evolution of competence. Here we describe use of a computer simulation model to thoroughly evaluate the simplest explanation for uptake sequences, that they accumulate in genomes by a form of molecular drive generated by biased DNA uptake and evolutionarily neutral (i.e., unselected) recombination. In parallel we used an unbiased search algorithm to characterize genomic uptake sequences and DNA uptake assays to refine the Haemophilus influenzae uptake specificity. These analyses showed that biased uptake and neutral recombination are sufficient to drive uptake sequences to high densities, with the spacings, stabilities, and strong consensuses typical of uptake sequences in real genomes. This result greatly simplifies testing of hypotheses about the benefits of DNA uptake, because it explains how genomes could have passively accumulated sequences matching the bias of their uptake machineries.MANY bacteria are able to take up DNA fragments from their environment, a genetically specified trait called natural competence (Chen and Dubnau 2004; Johnsborg et al. 2007; Maughan et al. 2008). Many other species have homologs of competence genes, suggesting that although they are not competent under laboratory conditions, they may be competent under natural conditions (Claverys and Martin 2003; Kovacs et al. 2009). Such a widespread trait must be beneficial but the evolutionary function of DNA uptake remains controversial. Cells can use the nucleotides released by degradation of both incoming DNA and any strands displaced by its recombination, thus reducing demands on their nucleotide salvage and biosynthesis pathways (Redfield 1993; Palchevskiy and Finkel 2009). Cells may also benefit if recombination of the incoming DNA provides templates for DNA repair or introduces beneficial mutations, but may suffer if recombination introduces damage or harmful mutations (Redfield 1988; Michod et al. 2008).Although most bacteria that have been tested show no obvious preferences for specific DNA sources or sequences, bacteria in the family Pasteurellaceae and the genus Neisseria strongly prefer DNA fragments from close relatives. Two factors are responsible: First, the DNA uptake machineries of these bacteria are strongly biased toward certain short DNA sequence motifs. Second, the genomes of these bacteria contain hundreds of occurrences of the preferred sequences. The Pasteurellacean motif is called the uptake signal sequence (USS); its Neisseria counterpart is called the DNA uptake sequence (DUS). All Neisseria genomes contain the same consensus DUS [core GCCGTCTGAA (Treangen et al. 2008)], but divergence in the Pasteurellaceae has produced two subclades, one of species sharing the canonical Haemophilus influenzae 9-bp USS (Hin-USS core AAGTGCGGT) and the other of species with a variant USS that differs at three core positions (Apl-USS core: ACAAGCGGT) and has a longer flanking consensus (Redfield et al. 2006). Uptake sequence biases are strong but not absolute; for example, replacing the Hin-USS with the Apl-USS reduces H. influenzae DNA uptake only 10-fold (Redfield et al. 2006) and DNA from Escherichia coli is taken up in the absence of competing H. influenzae DNA (Goodgal and Mitchell 1984).Most studies of the distribution and consensus of uptake sequences in genomes have examined only those occurrences that perfectly match the above core DUS and USS sequences. Here we call these perfect matches “core-consensus” (cc) uptake sequences. These cc-uptake sequences occupy ∼1% of their genomes; they are equally frequent in the plus and minus orientations of the genome sequence but are underrepresented in coding sequences, with the noncoding 14% and 20% of their respective genomes containing 35% of cc-USSs and 65% of cc-DUSs (Smith et al. 1995). Although many of these intergenic cc-DUSs and cc-USSs occur in inverted-repeat pairs that function as terminators (Kingsford et al. 2007), most uptake sequences are too far apart or in genes or other locations where termination does not occur. Within coding regions uptake sequences occur more often in weakly conserved genes, in weakly conserved parts of genes, and in reading frames that encode common tripeptides (Findlay and Redfield 2009), all of which are consistent with selection acting mainly to eliminate mutations that improve uptake from genome regions constrained by coding or other functions.Analyses that focus on cc-uptake sequences effectively treat uptake sequences as replicative elements (Smith et al. 1995; Redfield et al. 2006; Ambur et al. 2007; Treangen et al. 2008). However, USS and DUS are known to originate in situ by normal mutational processes, mainly point mutations, and to spread between genomes mainly by homologous recombination (Redfield et al. 2006; Treangen et al. 2008). As they are not replicating elements, why are they up to 1000-fold more common in their genomes than expected for unselected sequences (e.g., H. influenzae, 1471 cc-USS vs. 8 expected by chance; N. gonorrheae, 1892 cc-DUS vs. 2 expected by chance)?The explanation for this abundance must lie with the specificity of the DNA uptake system, because the strong correspondence between the uptake bias and the uptake sequences in the genome is far too improbable to be a coincidence. However, uptake specificity is not easily accommodated by either of the hypothesized functions of DNA uptake. If bacteria take up DNA to get benefits from homologous genetic recombination, the combination of uptake bias and uptake sequences might serve as a mate-choice adaptation that maximizes these benefits by excluding foreign DNAs (Treangen et al. 2008). Although this explanation is appealing, it requires simultaneous evolution of bias in the uptake machinery and of genomic sequences matching this bias. Another problem is that the genomic sequences can be “selected” only after the cell carrying them is dead. On the other hand, if bacteria instead take up DNA as a source of nutrients, all DNAs should be equally useful, so uptake bias and uptake sequences would likely reduce rather than increase this benefit. Although the sequence bias could be explained as a consequence of mechanistic constraints on DNA uptake, this would not account for the high density of the preferred sequences in the genome.However, both hypotheses may be simplified by a process called molecular drive, under which uptake sequences would gradually accumulate over evolutionary time as a direct consequence of biased uptake and recombination (Danner et al. 1980; Bakkali et al. 2004; Bakkali 2007), without any need for natural selection. This drive is proposed to work as follows: First, random mutation continuously creates variation in DNA sequences that affects their probability of uptake, and random cell death allows DNA fragments containing preferred variants to be taken up by other cells. Second, repeated recombination of such preferred DNA sequences with their chromosomal homologs gradually increases their abundance in the genomes of competent cells'' descendants. Thus mutations that create matches to the bias of the uptake machinery are horizontally transmitted to other members of the same species more often than other mutations. Because some recombination may be inevitable even if DNA''s main benefit is nutritional, molecular drive could account for uptake sequence accumulation under both hypotheses, leaving only the biased uptake process to be explained by natural selection for either genetic variation or nutrients.Although drive is plausible, its ability to account for the observed properties of genomic uptake sequences has never been evaluated. To do this, we developed a realistic computer simulation model that includes only the processes thought to generate molecular drive. Below we first use this model to identify the conditions that determine whether uptake sequences will accumulate and then compare the properties of these simulated uptake sequences to those of the uptake sequences in the N. meningitidis and H. influenzae genomes. In parallel we use unbiased motif searches to better characterize genomic uptake sequences and DNA uptake assays to refine the H. influenzae uptake specificity.     

A novel metal transporter mediating manganese export (MntX) regulates the Mn to Fe intracellular ratio and Neisseria meningitidis virulence

Neisseria meningitidis (Nm) and N. gonorrhoeae (Ng) are adapted to different environments within their human host. If the basis of this difference has not yet been fully understood, previous studies (including our own data) have reported that, unlike Ng, Nm tolerates high manganese concentrations. As transition metals are essential regulators of cell growth and host pathogen interactions, we aimed to address mechanisms of Nm Mn²⁺ tolerance and its pathogenic consequences. Using bioinformatics, gene deletion and heterologous expression we identified a conserved bacterial manganese resistance factor MntX (formerly YebN). The predicted structure suggests that MntX represents a new family of transporters exporting Mn. In the Neisseria genus, this exporter is present and functional in all Nm isolates but it is mutated in a majority of Ng strains and commonly absent in nonpathogenic species. In Nm, Mn²⁺ export via MntX regulates the intracellular Mn/Fe ratio and protects against manganese toxicity that is exacerbated in low iron conditions. MntX is also important for N. meningitidis to resist killing by human serum and for survival in mice blood during septicemia. The present work thus points to new clues about Mn homeostasis, its interplay with Fe metabolism and the influence on N. meningitidis physiology and pathogenicity.