Bianca Colonna

Thermoregulation of Shigella and Escherichia coli EIEC pathogenicity. A temperature-dependent structural transition of DNA modulates accessibility of virF promoter to transcriptional repressor H-NS

The expression of plasmid‐borne virF of Shigella encoding a transcriptional regulator of the AraC family, is required to initiate a cascade of events resulting in activation of several operons encoding invasion functions. H‐NS, one of the main nucleoid‐associated proteins, controls the temperature‐dependent expression of the virulence genes by repressing the in vivo transcription of virF only below a critical temperature (∼32°C). This temperature‐dependent transcriptional regulation has been reproduced in vitro and the targets of H‐NS on the virF promoter were identified as two sites centred around −250 and −1 separated by an intrinsic DNA curvature. H‐NS bound cooperatively to these two sites below 32°C, but not at 37°C. DNA supercoiling within the virF promoter region did not influence H‐NS binding but was necessary for the H‐NS‐mediated transcriptional repression. Electrophoretic analysis between 4 and 60°C showed that the virF promoter fragment, comprising the two H‐NS sites, undergoes a specific and temperature‐dependent conformational transition at ∼32°C. Our results suggest that this modification of the DNA target may modulate a cooperative interaction between H‐NS molecules bound at two distant sites in the virF promoter region and thus represents the physical basis for the H‐NS‐dependent thermoregulation of virulence gene expression.

The virF promoter in Shigella: more than just a curved DNA stretch

In the human enteropathogen Shigella transcription of virF, the primary regulator of the invasion functions, is strictly temperature‐dependent and is antagonistically mediated by H‐NS and FIS, which bind to specific sites on the virF promoter. Here we report on the relevance of DNA geometry to the themoregulation of virF and demonstrate that the virF promoter hosts a major DNA bend halfway between two H‐NS sites. The bent region has been mutagenized in vitro to mimic temperature‐induced changes of DNA curvature. Functional analysis of curvature mutants and of promoter constructs in which the two H‐NS sites are phased‐out by a half–helix turn reveals that modifying the spatial relationships between these sites severely affects the interaction of H‐NS with the virF promoter, as well as its in vivo and in vitro temperature‐dependent activity. The role of promoter curvature as thermosensor is also compatible with the present observation that, with increasing temperature, the virF bending centre moves downstream at a rate having its maximum around the transition temperature, abruptly unmasking a binding site for the transcriptional activator FIS.

Involvement of FIS in the H‐NS‐mediated regulation of virF gene of Shigella and enteroinvasive Escherichia coli

The mechanism of pathogenicity in Shigella and enteroinvasive Escherichia coli (EIEC) requires the co‐ordinated expression of several genes located on both the virulence plasmid and the chromosome. We found that cells lacking a functional FIS protein (factor for inversion stimulation) are partially impaired in expressing the virulence genes and that full expression is totally restored when Shigella wild‐type fis gene is offered in trans. We also identified virF, among the virulence genes, as a target of FIS‐mediated activation and showed that FIS binds to four specific sites in the promoter region of virF. Previous studies have demonstrated that the expression of VirF, the first positive activator of a multistep regulatory cascade, is subject to temperature‐dependent regulation by H‐NS, one of the main nucleoid‐associated proteins. We now demonstrate that two of the four FIS sites overlap one of the two H‐NS sites responsible for thermoregulation (H‐NS site I). FIS was found to exercise a direct positive transcriptional control at permissive temperature (37°C), when H‐NS fails to repress virF, as well as an indirect effect by partially counteracting H‐NS inhibition at the transition temperature (32°C). Our data indicate that FIS may be relevant for the rapid increase in virF expression after penetration of bacteria into the host.

A role for H-NS in the regulation of the virF gene of Shigella and enteroinvasive Escherichia coli.

We have investigated the role of H-NS, one of the major components of the bacterial nucleoid, in the expression of the virF gene present on the large virulence plasmid of Shigella and enteroinvasive Escherichia coli in response to different environmental conditions. VirF is an AraC-like protein which activates at least two promoters, virB and virG, both repressed by H-NS. Band shift experiments reveal that the affinity of H-NS for the virF and virB promoters is comparable, while the affinity for the virG promoter is higher. Polyacrylamide gel electrophoresis of three DNA fragments containing the virF, the virB and the VirG promoters demonstrates, in agreement with computer predictions, that they have an intrinsically curved structure, confirming the preference of H-NS for bent DNA. In vivo transcriptional analysis of virF mRNA shows that H-NS negatively controls the expression of virF at 30 degrees C. The expression of a virF-lacZ translational fusion in E.coli wild type and in an hns-defective derivative grown at 30 degrees or 37 degrees C and at pH 6.0 or 7.0 indicates that, in the absence of H-NS, virF expression becomes insensitive to temperature and to limited pH changes. Our results strongly suggest that H-NS controls virF expression by binding to the virF promoter and by repressing its expression at low temperature and at low pH.

A novel antisense RNA regulates at transcriptional level the virulence gene icsA of Shigella flexneri

The virulence gene icsA of Shigella flexneri encodes an invasion protein crucial for host colonization by pathogenic bacteria. Within the intergenic region virA-icsA, we have discovered a new gene that encodes a non-translated antisense RNA (named RnaG), transcribed in cis on the complementary strand of icsA. In vitro transcription assays show that RnaG promotes premature termination of transcription of icsA mRNA. Transcriptional inhibition is also observed in vivo by monitoring the expression profile in Shigella by real-time polymerase chain reaction and when RnaG is provided in trans. Chemical and enzymatic probing of the leader region of icsA mRNA either free or bound to RnaG indicate that upon hetero-duplex formation an intrinsic terminator, leading to transcription block, is generated on the nascent icsA mRNA. Mutations in the hairpin structure of the proposed terminator impair the RnaG mediated-regulation of icsA transcription. This study represents the first evidence of transcriptional attenuation mechanism caused by a small RNA in Gram-negative bacteria. We also present data on the secondary structure of the antisense region of RnaG. In addition, alternatively silencing icsA and RnaG promoters, we find that transcription from the strong RnaG promoter reduces the activity of the weak convergent icsA promoter through the transcriptional interference regulation.

Polyamines: emerging players in bacteria-host interactions.

Polyamines are small polycationic molecules found in almost all cells and associated with a wide variety of physiological processes. In recent years it has become increasingly clear that, in addition to core physiological functions, polyamines play a crucial role in bacterial pathogenesis. Considerable evidence has built up that bacteria have evolved mechanisms to turn these molecules to their own advantage and a novel standpoint to look at host-bacterium interactions emerges from the interplay among polyamines, host cells and infecting bacteria. In this review, we highlight how human bacterial pathogens have developed their own resourceful strategies to exploit polyamines or manipulate polyamine-related processes to optimize their fitness within the host. Besides contributing to a better understanding of the complex relationship between a pathogen and its host, acquisitions in this field have a significant potential towards the development of novel antibacterial therapeutic approaches.

A two-year study of enteric infections associated with diarrhoeal diseases in children in urban Somalia.

A hospital-based systematic sample of 1667 children with severe diarrhoeal disease was studied in Mogadishu, Somalia, throughout 1983 and 1984. One or more enteric pathogens were found in 61% of the patients. Rotavirus (25%), enterotoxigenic Escherichia coli (11%), Shigella spp. (9%), Aeromonas hydrophila (9%), Giardia lamblia trophozoites (8%), Campylobacter jejuni (8%), and Vibrio cholerae non-O1 (6%) were the most frequently identified pathogens. Age-specific detection rates of enteric pathogens and helminths, seasonal patterns, and relationship of some specific infections with feeding status and main clinical features have been defined for all the sample examined.

A multifactor regulatory circuit involving H-NS, VirF and an antisense RNA modulates transcription of the virulence gene icsA of Shigella flexneri

The icsA gene of Shigella encodes a structural protein involved in colonization of the intestinal mucosa by bacteria. This gene is expressed upon invasion of the host and is controlled by a complex regulatory circuit involving the nucleoid protein H-NS, the AraC-like transcriptional activator VirF, and a 450 nt antisense RNA (RnaG) acting as transcriptional attenuator. We investigated on the interplay of these factors at the molecular level. DNase I footprints reveal that both H-NS and VirF bind to a region including the icsA and RnaG promoters. H-NS is shown to repress icsA transcription at 30°C but not at 37°C, suggesting a significant involvement of this protein in the temperature-regulated expression of icsA. We also demonstrate that VirF directly stimulates icsA transcription and is able to alleviate H-NS repression in vitro. According to these results, icsA expression is derepressed in hns- background and overexpressed when VirF is provided in trans. Moreover, we find that RnaG-mediated transcription attenuation depends on 80 nt at its 5′-end, a stretch carrying the antisense region. Bases engaged in the initial contact leading to sense–antisense pairing have been identified using synthetic RNA and DNA oligonucleotides designed to rebuild and mutagenize the two stem–loop motifs of the antisense region.

CadC Is the Preferential Target of a Convergent Evolution Driving Enteroinvasive Escherichia coli toward a Lysine Decarboxylase-Defective Phenotype

ABSTRACT Enteroinvasive E. coli (EIEC), like Shigella, is the etiological agent of bacillary dysentery, a particularly severe syndrome in children in developing countries. All EIEC strains share with Shigella the inability to synthesize lysine decarboxylase (the LDC phenotype). The lack of this function is considered a pathoadaptive mutation whose emergence was necessary to obtain the full expression of invasiveness. Cadaverine, the product of lysine decarboxylation, is a small polyamine which interferes mainly with the inflammatory process induced by dysenteric bacteria. Genes coding for lysine decarboxylase and its transporter constitute a single operon (cadBA) and are expressed at low pH under the positive control of CadC. This regulator is an inner membrane protein that is able to sense pH variation and to respond by transcriptionally activating the cadBA genes. In this study we show that, unlike in Shigella, mutations affecting the cad locus in the EIEC strains we have analyzed are not followed by a novel gene arrangement and that the LCD− phenotype is dependent mainly on inactivation of the cadC gene. Introduction of a functional CadC restores cadaverine expression in all EIEC strains harboring either an IS2 element or a defective cadC promoter. Comparative analysis between the cad regions of S. flexneri and EIEC suggests that the LDC− phenotype has been attained by different strategies within the E. coli species.

Molecular characterization of virulence determinants of Stenotrophomonas maltophilia strains isolated from patients affected by cystic fibrosis

Stenotrophomonas maltophilia is an emerging nosocomial bacterial pathogen which is currently isolated with increasing frequency from the airways of cystic fibrosis (CF) patients. In this study 13 S. maltophilia strains (11 isolated from the airways of independent CF patients, and two non-CF respiratory reference strains) have been characterized for the expression of several virulence-associated factors. In particular, the ability to form biofilm on abiotic surfaces has been determined and correlated with different features, such as motility, adherence and the ability to invade A549 respiratory epithelial cells. Moreover, the presence of a flagellum-associated gene as well as that of the StmPr1 gene, which encodes an extra-cellular protease, have been determined by Southern blot hybridization. Our data indicate that the different degree of biofilm formation exhibited by the 11 CF isolates does not correlate with motility, ability to adhere to and invade A549 cells, or with the presence of flagella. On the other hand, among the CF isolates the StmPr1 gene was found only in two strains, both able to establish chronic lung infections in CF patients. Moreover, only four of the strains analyzed show a temperature-independent antibiotic-resistance profile, suggesting either a different origin of these strains or an intervening adaptation to host tissues.