H-DNA formation by the coding repeat elements of neisserial opa genes

Characterization of the Neisseria gonorrhoeae Iron and Fur Regulatory Network

The Neisseria gonorrhoeae ferric uptake regulator (Fur) protein controls expression of iron homeostasis genes in response to intracellular iron levels. In this study, using transcriptome sequencing (RNA-seq) analysis of an N. gonorrhoeae fur strain, we defined the gonococcal Fur and iron regulons and characterized Fur-controlled expression of an ArsR-like DNA binding protein. We observed that 158 genes (8% of the genome) showed differential expression in response to iron in an N. gonorrhoeae wild-type or fur strain, while 54 genes exhibited differential expression in response to Fur. The Fur regulon was extended to additional regulators, including NrrF and 13 other small RNAs (sRNAs), and two transcriptional factors. One transcriptional factor, coding for an ArsR-like regulator (ArsR), exhibited increased expression under iron-replete conditions in the wild-type strain but showed decreased expression across iron conditions in the fur strain, an effect that was reversed in a fur-complemented strain. Fur was shown to bind to the promoter region of the arsR gene downstream of a predicted σ(70) promoter region. Electrophoretic mobility shift assay (EMSA) analysis confirmed binding of the ArsR protein to the norB promoter region, and sequence analysis identified two additional putative targets, NGO1411 and NGO1646. A gonococcal arsR strain demonstrated decreased survival in human endocervical epithelial cells compared to that of the wild-type and arsR-complemented strains, suggesting that the ArsR regulon includes genes required for survival in host cells. Collectively, these results demonstrate that the N. gonorrhoeae Fur functions as a global regulatory protein to repress or activate expression of a large repertoire of genes, including additional transcriptional regulatory proteins.

IMPORTANCE

Gene regulation in bacteria in response to environmental stimuli, including iron, is of paramount importance to both bacterial replication and, in the case of pathogenic bacteria, successful infection. Bacterial DNA binding proteins are a common mechanism utilized by pathogens to control gene expression under various environmental conditions. Here, we show that the DNA binding protein Fur, expressed by the human pathogen Neisseria gonorrhoeae, controls the expression of a large repertoire of genes and extends this regulon by controlling expression of additional DNA binding proteins. One of these proteins, an ArsR-like regulator, was required for N. gonorrhoeae survival within host cells. These results show that the Fur regulon extends to additional regulatory proteins, which together contribute to gonococcal mechanisms of pathogenesis.

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.

Differential gene expression activity among species-specific polypyrimidine/polypurine motifs in mu opioid receptor gene promoters

The mu opioid receptor (MOR) is the principle molecular target of opioid analgesics. An appropriate understanding of MOR gene expression across species is critical for understanding its analgesic functions in humans. Here, we undertake a cross-species analysis of the polymorphic polypyrimidine/polypurine (PPy/u) motif, a key enhancer of MOR gene expression. The mouse PPy/u motif is highly homologous to those of rat (67%) and human (83%), but drives reporter gene expression tenfold and fivefold more effectively than those of rat and human, respectively. Circular dichroism profiles of PPy/u oligonucleotides from different species showed that they are primarily different in structure. Conformational studies of reporter plasmids using confocal Raman spectra, S1 nuclease and restriction enzymes demonstrated that the structural difference is the result of changes in the phosphodiester backbone. Furthermore, these conformational disparities produce differences in torsional stress, as shown by topoisomerase II relaxation and activation of different levels of gene expression under hypertonic conditions. This study demonstrates that homologous PPy/u motifs adopt unique species-specific conformations with different mechanisms and activities for gene expression. We further discuss how structural aspects of transcription regulatory elements, rather than the sequence itself, are significant when studying functional gene expression regulatory elements.

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.

The role of phenotypic variation in rhizosphere Pseudomonas bacteria

Colony phase variation is a regulatory mechanism at the DNA level which usually results in high frequency, reversible switches between colonies with a different phenotype. A number of molecular mechanisms underlying phase variation are known: slipped-strand mispairing, genomic rearrangements, spontaneous mutations and epigenetic mechanisms such as differential methylation. Most examples of phenotypic variation or phase variation have been described in the context of host-pathogen interactions as mechanisms allowing pathogens to evade host immune responses. Recent reports indicate that phase variation is also relevant in competitive root colonization and biological control of phytopathogens. Many rhizospere Pseudomonas species show phenotypic variation, based on spontaneous mutation of the gacA and gacS genes. These morphological variants do not express secondary metabolites and have improved growth characteristics. The latter could contribute to efficient root colonization and success in competition, especially since (as shown for one strain) these variants were observed to revert to their wild-type form. The observation that these variants are present in rhizosphere-competent Pseudomonas bacteria suggests the existence of a conserved strategy to increase their success in the rhizosphere.

Meningococcal genome dynamics

Neisseria meningitidis (the meningococcus) is an important commensal, pathogen and model organism that faces up to the environment in its exclusive human host with a small but hyperdynamic genome. Compared with Escherichia coli, several DNA-repair genes are absent in N. meningitidis, whereas the gene products of others interact differently. Instead of responding to external stimuli, the meningococcus spontaneously produces a plethora of genetic variants. The frequent genomic alterations and polymorphisms have profound consequences for the interaction of this microorganism with its host, impacting structural and antigenic changes in crucial surface components that are relevant for adherence and invasion as well as antibiotic resistance and vaccine development.

Phase and antigenic variation in bacteria

Phase and antigenic variation result in a heterogenic phenotype of a clonal bacterial population, in which individual cells either express the phase-variable protein(s) or not, or express one of multiple antigenic forms of the protein, respectively. This form of regulation has been identified mainly, but by no means exclusively, for a wide variety of surface structures in animal pathogens and is implicated as a virulence strategy. This review provides an overview of the many bacterial proteins and structures that are under the control of phase or antigenic variation. The context is mainly within the role of the proteins and variation for pathogenesis, which reflects the main body of literature. The occurrence of phase variation in expression of genes not readily recognizable as virulence factors is highlighted as well, to illustrate that our current knowledge is incomplete. From recent genome sequence analysis, it has become clear that phase variation may be more widespread than is currently recognized, and a brief discussion is included to show how genome sequence analysis can provide novel information, as well as its limitations. The current state of knowledge of the molecular mechanisms leading to phase variation and antigenic variation are reviewed, and the way in which these mechanisms form part of the general regulatory network of the cell is addressed. Arguments both for and against a role of phase and antigenic variation in immune evasion are presented and put into new perspective by distinguishing between a role in bacterial persistence in a host and a role in facilitating evasion of cross-immunity. Finally, examples are presented to illustrate that phase-variable gene expression should be taken into account in the development of diagnostic assays and in the interpretation of experimental results and epidemiological studies.

Unique regulation of SclB - a novel collagen-like surface protein of Streptococcus pyogenes

Slipped-strand mispairing at sites containing so-called coding repeats (CRs) can lead to phase variation of surface proteins in Gram-negative bacteria. This mechanism, believed to contribute to virulence, has so far not been identified in a Gram-positive bacterium. In the genome of the Gram-positive human pathogen Streptococcus pyogenes, we identified pentanucleotide CRs within a putative signal sequence of an open reading frame (ORF) encoding a novel collagen-like surface protein, denoted SclB. In 12 S. pyogenes strains, the number of CRs in the sclB gene varied from three to 19, rendering the start codon in frame with the downstream ORF in four strains and out of frame in eight strains. A protein reacting with anti-SclB antibodies could only be solubilized from three strains, all containing an intact sclB gene. Variations in the number of CRs were observed within strains of the same M serotype and occurred during growth of S. pyogenes in fresh human blood, but not in medium. The SclB protein has a hypervariable N-terminal part, a collagen-like central part and a typical cell wall sorting sequence containing the LPXTGX motif. SclB is related to the collagen-like SclA and is, like SclA, involved in the adhesion of S. pyogenes bacteria to human cells. However, the Mga protein, known to upregulate sclA and several additional genes encoding virulence factors of S. pyogenes, downregulates sclB transcription. This observation and the potential of SclB to phase vary by slipped-strand mispairing emphasize the unique regulation of this novel S. pyogenes surface protein.

Environmentally constrained mutation and adaptive evolution in Salmonella

The relationship between environment and mutation is complex [1]. Claims of Lamarkian mutation [2] have proved unfounded [3-5]; it is apparent, however, that the external environment can influence the generation of heritable variation, through either direct effects on DNA sequence [6] or DNA maintenance and copying mechanisms [7-10], or as a consequence of evolutionary processes [11-16]. The spectrum of mutational events subject to environmental influence is unknown [6] and precisely how environmental signals modulate mutation is unclear. Evidence from bacteria suggests that a transient recombination-dependent hypermutational state can be induced by starvation [5]. It is also apparent that changes in the mutability of specific loci can be influenced by alterations in DNA topology [10,17]. Here we describe a remarkable instance of adaptive evolution in Salmonella which is caused by a mutation that occurs in intermediate-strength osmotic environments. We show that the mutation is not 'directed' and describe its genetic basis. We also present compelling evidence in support of the hypothesis that the mutational event is constrained by signals transmitted from the external environment via changes in the activity of DNA gyrase.

Occurrence and structure-function relationship of pentameric short sequence repeats in microbial genomes

It is suggested that genomes found in any form of cellular life contain potentially size-variable repetitive DNA moieties. In eukaryotes, large proportions of the multi-chromosomal genome consist of various classes of repetitive DNA. Also in archaeal genomes, repetitive DNA is encountered and, as is the case for the eukaryotes as well, little or no function is at present attributable to most of it. For prokaryotes, elegant experiments have highlighted so-called slipped strand nucleotide mispairing (SSM) as a basic and causal mechanism, giving rise to repeat unit number variation at a distinct locus. Illegitimate base pairing in regions of repetitive DNA during replication, in association with defective DNA repair and enhanced nuclease susceptibility of replication intermediates, in the end gives rise to deletion or addition of repeat units. Prokaryotic short sequence repeats (SSRs) harbour arrays of short repeat units, between one and approximately 20 nucleotides in length. SSRs are involved in various mechanisms of microbial gene expression regulation. Promoter strength can be affected by altering the spacing between important structural domains as can the integrity of open reading frames. In the present communication the literature on microbial SSRs harbouring repeat units that are five nucleotides in length will be briefly reviewed. Examples of these SSRs with discrete functionality are encountered in bacterial species such as Haemophilus influenzae, Neisseria gonorrhoeae, and Pasteurella haemolytica. In addition, several of the currently known bacterial and archaeal whole genome sequences were scanned for the presence of novel examples of potential five-nucleotide SSRs (and others) in order to gather additional knowledge on the propensity and putative functions of this type of potential genetic switch.

Molecular switches--the ON and OFF of bacterial phase variation

The expression of most bacterial genes is controlled at the level of transcription via promoter control mechanisms that permit a graded response. However, an increasing number of bacterial genes are found to exhibit an 'all-or-none' control mechanism that adapts the bacterium to more than one environment. One such mechanism is phase variation, traditionally defined as the high-frequency ON<-->OFF switching of phenotype expression. Phase variation events are usually random, but may be modulated by environmental conditions. The mechanisms of phase variation events and their significance within the microbial community are discussed here.

Variable expression of the Opc outer membrane protein in Neisseria meningitidis is caused by size variation of a promoter containing poly-cytidine

Opa proteins of Neisseria meningitidis exhibit translational phase variation via addition or deletion of repetitive coding repeat units within the DNA encoding the protein leader sequence. In contrast, Opc phase variation is the result of transcriptional regulation. Transcription starts 13 nucleotides after the -10 region of an unusual promoter sequence containing a variable number of contiguous cytidine residues and lacking a -35 region. Efficient expression of Opc occurred in strains with 12 to 13 cytidine residues, intermediate expression in strains with 11 or 14 residues and no expression with < or = 10 or > or = 15 residues. This unusual regulation may have evolved because the Opc protein enables meningococcal invasion and is immunogenic.

Adaptive evolution of highly mutable loci in pathogenic bacteria

Bacteria have specific loci that are highly mutable. We argue that the coexistence within bacterial genomes of such 'contingency' genes with high mutation rates, and 'housekeeping' genes with low mutation rates, is the result of adaptive evolution, and facilitates the efficient exploration of phenotypic solutions to unpredictable aspects of the host environment while minimizing deleterious effects on fitness.

Homopurine/homopyrimidine sequences as potential regulatory elements in eukaryotic cells

1. Homopurine/homopyrimidine (PuPy) repetitive duplex sequences can form intramolecular triplexes (H-DNA) or intermolecular triplexes with a third strand in a sequence-specific manner. 2. Such sequences are present in natural genomes within 5'- and 3'-flanking sequences and coding regions of genes. Triplex DNA structures have been detected in vitro and in vivo and have been immunolocalized to chromosomes by triplex-specific monoclonal antibody approaches. 3. Intermolecular triplex formation represses gene expression at the transcriptional level and is also useful in genomic mapping, gene cloning, sequence-specific drug delivery, and selective modulation of gene expression.

DNA topology and bacterial virulence gene regulation

The topology of bacterial DNA varies in response to extracellular environmental stimuli, providing a possible mechanism for environmental control of gene expression during bacterial pathogenesis. The contribution of DNA topology to the control of transcription is complex, but an appreciation of the distinction between local and global DNA topological effects is helping to clarify this complexity.

Variation and genetic control of surface antigen expression in mycoplasmas: the Vlp system of Mycoplasma hyorhinis

Surface antigenic diversity in the swine pathogen Mycoplasma hyorhinis is generated by random combinatorial expression and high-frequency phase variation of multiple, size-variant membrane surface lipoproteins (Vlps) which represent the major coat proteins of this wall-less procaryote. The distinctive structural basis for Vlp variation was revealed in a family of several related but divergent vlp genes. These occur in one cluster as single chromosomal copies, each encoding a conserved domain for membrane insertion and lipoprotein processing, and a divergent external domain that changes size by deletion or insertion of repetitive intragenic coding sequences while retaining a distinctive charge motif. Lack of detectable changes in restriction fragment patterns or DNA sequence of vlp structural genes during phase transitions between ON and OFF expression states ruled out long range genomic rearrangements and frameshift mutations as a means of controlling Vlp phase variation. However, highly homologous vlp promoter regions contain a homopolymeric tract of contiguous adenine residues [poly(A)] upstream of the transcriptional start site which is subject to frequent mutations altering its length. These mutations are the only sequence changes detected during phase transitions, and are highly correlated with the expression state of each vlp gene. This suggests a mechanism of transcriptional control regulating Vlp phase variation by critical changes within the poly(A) region affecting the spacing between the -10 and -35 hexamers or a putative regulator binding site. The multiple levels of structural and antigenic diversity embodied in the vlp gene family may provide essential adaptive capabilities for this wall-less microbial pathogen.

Neisserial surface variation: how and why?

Neisseria gonorrhoeae exhibits striking variability in several of its surface components (pili, Opa proteins and lipooligosaccharide) in vivo and in vitro. Such flagrant variation of this mucosal pathogen's surface components contrasts sharply with changes in single surface components of blood-borne trypanosomes and borreliae. Despite these differences, similar molecular events are sometimes involved.

The interplay of microbes and their hosts

Microbes and their hosts exert considerable evolutionary pressure on one another. This brief report of a recent meeting describes the strategies and tactics, and highlights some of the key molecules involved in the complex host-parasite relationship.

Genetic variation in pathogenic bacteria

In contrast to textbook ideas of pure cultures and defined strains, genetic variation is a fact of life in the microbial world. It not only allows pathogens to establish themselves in their chosen host, but also allows them to resist that host's subsequent attempts to evict them. Here we review some of the mechanisms that bring about this variation, and some of the functional consequences that result from it.