A Listeria-like strain isolated in Austria from pre-cut lettuce fitted with the description of the genus Listeria although it could not be assigned to any of the known species. Comparison of the rrs gene (coding 16S rRNA) sequence and gene content by DNA-array indicates affiliation to the genus Listeria. Phylogenetic distance with known Listeria species indicates it represents a new species. Since it can be differentiated from all other known species of Listeria by using phenotypic tests, the name Listeria rocourtiae is proposed for the new species. The type strain is CIP 109804(T)(= DSM 22097(T), Allerberger 700284/02(T)). The type strain is avirulent as assessed by cell culture assays and inoculation of mice.

The bacterial pathogen Legionella pneumophila responds to environmental changes by differentiation. At least two forms are well described: replicative bacteria are avirulent, in contrast transmissive bacteria express virulence traits and flagella. Phenotypic analysis, Western blot and electron microscopy of regulatory mutants in the genes encoding RpoN, FleQ, FleR and FliA demonstrated that flagellin expression is strongly repressed and that the mutants are non-flagellated in transmissive phase. Transcriptome analyses elucidated that RpoN, together with FleQ enhances transcription of 14 out of 31 flagellar class II genes, which code for the basal body, hook, and regulatory proteins. Unexpectedly, FleQ independent of RpoN enhances the transcription of fliA encoding sigma 28. Expression analysis of a fliA mutant showed that FliA activates three out of five remaining flagellar class III genes and the flagellar class IV genes. Surprisingly, FleR does not induce but inhibit expression of at least 14 flagellar class III genes on transcriptional level. Thus we propose that flagellar class II genes are controlled by FleQ and RpoN, whereas the transcription of the class III gene fliA is controlled in a FleQ-dependent but RpoN-independent manner. However, RpoN and FleR might influence flagellin synthesis on post-transcriptional level. In contrast to the commonly accepted view that enhancer binding proteins as FleQ always interact with RpoN to fullfill their regulatory functions, our results strongly indicate that FleQ regulates gene expression RpoN-dependent and RpoN-independent. Finaly, FliA induces expression of flagellar class III and IV genes leading to the complete synthesis of the flagellum.

Riboswitches are RNA elements acting in cis, controlling expression of their downstream genes through a metabolite-induced alteration of their secondary structure. Here, we demonstrate that two S-adenosylmethionine (SAM) riboswitches, SreA and SreB, can also function in trans and act as noncoding RNAs in Listeria monocytogenes. SreA and SreB control expression of the virulence regulator PrfA by binding to the 5'-untranslated region of its mRNA. Absence of the SAM riboswitches SreA and SreB increases the level of PrfA and virulence gene expression in L. monocytogenes. Thus, the impact of the SAM riboswitches on PrfA expression highlights a link between bacterial virulence and nutrient availability. Together, our results uncover an unexpected role for riboswitches and a distinct class of regulatory noncoding RNAs in bacteria.

ABSTRACT: BACKGROUND: Genome sequences, now available for most pathogens, hold promises for the rational design of new therapies. However, biological resources for genome-scale identification of gene function (notably genes involved in pathogenesis) and/or genes essential for cell viability, which are necessary to achieve this goal, are often sorely lacking. This holds true for Neisseria meningitidis, one of the most feared human bacterial pathogens that causes meningitis and septicaemia. RESULTS: By determining and annotating manually the complete genome sequence of a serogroup C clinical isolate of N. meningitidis (strain 8013) and assembling a library of defined mutants in up to 60% of its non-essential genes, we have created NeMeSys a biological resource for Neisseria meningitidis systematic functional analysis. To further enhance the versatility of this toolbox, we have manually (re)annotated 8 publicly available Neisseria genome sequences and stored all these data in a publicly accessible online database. The potential of NeMeSys for narrowing the gap between sequence and function is illustrated in several ways, notably by performing a functional genomics analysis of the biogenesis of type IV pili, one of the most widespread virulence factors in bacteria, and by identifying through comparative genomics a complete biochemical pathway (for sulfur metabolism) that may potentially be important for nasopharyngeal colonization. CONCLUSIONS: By improving our capacity to understand gene function in an important human pathogen, NeMeSys is expected to contribute to the ongoing efforts aimed at understanding a prokaryotic cell comprehensively and eventually to the design of new therapies.

Legionella pneumophila is the etiological agent of Legionnaires' disease and of the less acute disease Pontiac fever. It is a Gram-negative bacterium present in fresh and artificial water environments that replicates in protozoan hosts and is also found in biofilms. Replication within protozoa is essential for the survival of the bacterium. The last years have seen a giant step forward in the genomics of L. pneumophila. The establishment and publication of the complete genome sequences of three clinical L. pneumophila isolates in 2004 and a fourth in 2007 has paved the way for major breakthroughs in understanding the biology of L. pneumophila in particular and Legionella in general. Sequence analysis identified several specific features of Legionella:(i) an extraordinary genetic diversity among the different isolates and (ii) the presence of an unexpected high number and variety of eukaryotic-like proteins, predicted to be involved in the exploitation of the host cellular processes by mimicking specific eukaryotic functions. In this chapter, we will first discuss the insights gained from genomics by highlighting the characteristic features and common traits of the four L. pneumophila genomes obtained through genome analysis and comparison and then we will focus on the newest results obtained by functional analysis of different eukaryotic-like proteins and describe their involvementin the pathogenicity of L. pneumophila.

It is 32 years since Legionella pneumophila was identified and recognized as a human pathogen, causing the severe form of pneumonia termed Legionnaires' disease, or legionellosis. This bacterium is found in freshwater reservoirs where it replicates in aquatic protozoa and can invade man-made water distribution systems. Although the disease can be treated by antibiotherapy and prevented through surveillance and control measures, reported cases of Legionnaires' disease continue to rise across Europe and outbreaks of major public health significance still occur. Genome sequencing and analyses led to a giant step forward by suggesting new ways by which this intracellular bacterium might subvert host functions. One particular feature revealed was the presence of many eukaryotic-like proteins, possibly mimicking host proteins to allow intracellular replication of Legionella. Here, we describe the identification and analysis of these proteins and report on recent advances detailing the mechanisms by which these proteins function. Finally, comparative and evolutionary genomic aspects regarding the eukaryotic-like proteins are presented. Collectively, these data have shed new light on the virulence strategies of L. pneumophila, a major aspect of which is molecular mimicry.

Cell wall-deficient bacteria referred to as L-forms have lost the ability to maintain or build a rigid peptidoglycan envelope. We have generated stable, non-reverting L-form variants of the Gram-positive pathogen Listeria monocytogenes, and studied the cellular and molecular changes associated with this transition. Stable L-form cells can occur as small protoplast-like vesicles and as multi-nucleated, large bodies. They have lost the thick, multilayered murein sacculus and are surrounded by a cytoplasmic membrane only, although peptidoglycan precursors are still produced. While they lack murein-associated molecules including Internalin A, membrane-anchored proteins such as Internalin B are retained. Surprisingly, L-forms were found to be able to divide and propagate indefinitely without a wall. Time-lapse microscopy of fluorescently labeled L-forms indicated a switch to a novel form of cell division, where genome-containing membrane vesicles are first formed within enlarged L-forms, and subsequently released by collapse of the mother cell. Array-based transcriptomics of parent and L-form cells revealed manifold differences in expression of genes associated with morphological and physiological functions. The L-forms feature downregulated metabolic functions correlating with the dramatic shift in surface to volume ratio, whereas upregulation of stress genes reflects the difficulties in adapting to this unusual, cell-wall deficient lifestyle.

Listeria monocytogenes is a human intracellular pathogen able to colonize host tissues after ingestion of contaminated food, causing severe invasive infections. In order to gain a better understanding of the nature of host-pathogen interactions, we studied the L. monocytogenes genome expression during mouse infection. In the spleen of infected mice, approximately 20% of the Listeria genome is differentially expressed, essentially through gene activation, as compared to exponential growth in rich broth medium. Data presented here show that, during infection, Listeria is in an active multiplication phase, as revealed by the high expression of genes involved in replication, cell division and multiplication. In vivo bacterial growth requires increased expression of genes involved in adaptation of the bacterial metabolism and stress responses, in particular to oxidative stress. Listeria interaction with its host induces cell wall metabolism and surface expression of virulence factors. During infection, L. monocytogenes also activates subversion mechanisms of host defenses, including resistance to cationic peptides, peptidoglycan modifications and release of muramyl peptides. We show that the in vivo differential expression of the Listeria genome is coordinated by a complex regulatory network, with a central role for the PrfA-SigB interplay. In particular, L. monocytogenes up regulates in vivo the two major virulence regulators, PrfA and VirR, and their downstream effectors. Mutagenesis of in vivo induced genes allowed the identification of novel L. monocytogenes virulence factors, including an LPXTG surface protein, suggesting a role for S-layer glycoproteins and for cadmium efflux system in Listeria virulence.