François Lépine

Active Starvation Responses Mediate Antibiotic Tolerance in Biofilms and Nutrient-Limited Bacteria

During growth arrest, bacteria tolerate the presence of antibiotics, thanks to mechanisms that protect against oxidant stress. Bacteria become highly tolerant to antibiotics when nutrients are limited. The inactivity of antibiotic targets caused by starvation-induced growth arrest is thought to be a key mechanism producing tolerance. Here we show that the antibiotic tolerance of nutrient-limited and biofilm Pseudomonas aeruginosa is mediated by active responses to starvation, rather than by the passive effects of growth arrest. The protective mechanism is controlled by the starvation-signaling stringent response (SR), and our experiments link SR-mediated tolerance to reduced levels of oxidant stress in bacterial cells. Furthermore, inactivating this protective mechanism sensitized biofilms by several orders of magnitude to four different classes of antibiotics and markedly enhanced the efficacy of antibiotic treatment in experimental infections.

Rhamnolipids: diversity of structures, microbial origins and roles

Rhamnolipids are glycolipidic biosurfactants produced by various bacterial species. They were initially found as exoproducts of the opportunistic pathogen Pseudomonas aeruginosa and described as a mixture of four congeners: α-L-rhamnopyranosyl-α-L-rhamnopyranosyl-β-hydroxydecanoyl-β-hydroxydecanoate (Rha-Rha-C10-C10), α-L-rhamnopyranosyl-α-L-rhamnopyranosyl-β-hydroxydecanoate (Rha-Rha-C10), as well as their mono-rhamnolipid congeners Rha-C10-C10 and Rha-C10. The development of more sensitive analytical techniques has lead to the further discovery of a wide diversity of rhamnolipid congeners and homologues (about 60) that are produced at different concentrations by various Pseudomonas species and by bacteria belonging to other families, classes, or even phyla. For example, various Burkholderia species have been shown to produce rhamnolipids that have longer alkyl chains than those produced by P. aeruginosa. In P. aeruginosa, three genes, carried on two distinct operons, code for the enzymes responsible for the final steps of rhamnolipid synthesis: one operon carries the rhlAB genes and the other rhlC. Genes highly similar to rhlA, rhlB, and rhlC have also been found in various Burkholderia species but grouped within one putative operon, and they have been shown to be required for rhamnolipid production as well. The exact physiological function of these secondary metabolites is still unclear. Most identified activities are derived from the surface activity, wetting ability, detergency, and other amphipathic-related properties of these molecules. Indeed, rhamnolipids promote the uptake and biodegradation of poorly soluble substrates, act as immune modulators and virulence factors, have antimicrobial activities, and are involved in surface motility and in bacterial biofilm development.

Production of rhamnolipids by Pseudomonas aeruginosa.

Pseudomonas aeruginosa produces glycolipidic surface-active molecules (rhamnolipids) which have potential biotechnological applications. Rhamnolipids are produced by P. aeruginosa in a concerted manner with different virulence-associated traits. Here, we review the rhamnolipids biosynthetic pathway, showing that it has metabolic links with numerous bacterial products such as alginate, lipopolysaccharide, polyhydroxyalkanoates, and 4-hydroxy-2-alkylquinolines (HAQs). We also discuss the factors controlling the production of rhamnolipids and the proposed roles this biosurfactant plays in P. aeruginosa lifestyle.

The contribution of MvfR to Pseudomonas aeruginosa pathogenesis and quorum sensing circuitry regulation: multiple quorum sensing-regulated genes are modulated without affecting lasRI, rhlRI or the production of N-acyl-L-homoserine lactones

The transcriptional regulator MvfR is required for full Pseudomonas aeruginosa virulence, the function of multiple quorum sensing (QS)‐regulated virulence factors and the synthesis of 4‐hydroxy‐2‐alkylquinolines (HAQs), including the Pseudomonas quinolone signal (PQS). Here we investigate the role of MvfR in the QS circuitry and P. aeruginosa pathogenesis. We demonstrate using a combination of biochemical and molecular approaches, including transcription profiling, that MvfR is involved in the regulation of multiple P. aeruginosa QS‐controlled genes without altering the expression of lasRI/rhlRI or the production of N‐acyl‐ l‐homoserine lactone (AHL) signals. Dissection of how mvfR is interwoven into the P. aeruginosa QS circuitry reveals that the MvfR system, through the essential contribution of PqsE, positively regulates a subset of genes dependant on both LasR and RhlR. Animal studies show that MvfR contributes to P. aeruginosa virulence by controlling the transcription of genes not under RhlR regulation, and that reduced virulence of a mvfR mutant is caused by the loss of pqsE expression and not only a deficiency in HAQs/PQS production. This study provides novel insights into the unique role of the MvfR system in AHL‐mediated QS and further supports its importance in P. aeruginosa pathogenesis.

Selection for Staphylococcus aureus small-colony variants due to growth in the presence of Pseudomonas aeruginosa

Opportunistic infections are often polymicrobial. Two of the most important bacterial opportunistic pathogens of humans, Pseudomonas aeruginosa and Staphylococcus aureus, frequently are coisolated from infections of catheters, endotracheal tubes, skin, eyes, and the respiratory tract, including the airways of people with cystic fibrosis (CF). Here, we show that suppression of S. aureus respiration by a P. aeruginosa exoproduct, 4-hydroxy-2-heptylquinoline-N-oxide (HQNO), protects S. aureus during coculture from killing by commonly used aminoglycoside antibiotics such as tobramycin. Furthermore, prolonged growth of S. aureus with either P. aeruginosa or with physiological concentrations of pure HQNO selects for typical S. aureus small-colony variants (SCVs), well known for stable aminoglycoside resistance and persistence in chronic infections, including those found in CF. We detected HQNO in the sputum of CF patients infected with P. aeruginosa, but not in uninfected patients, suggesting that this HQNO-mediated interspecies interaction occurs in CF airways. Thus, in all coinfections with P. aeruginosa, S. aureus may be underappreciated as a pathogen because of the formation of antibiotic-resistant and difficult to detect small-colony variants. Interspecies microbial interactions, analogous to those mediated by HQNO, commonly may alter not only the course of disease and the response to therapy, but also the population structure of bacterial communities that promote the health of host animals, plants, and ecosystems.

Liquid chromatography/mass spectrometry analysis of mixtures of rhamnolipids produced by Pseudomonas aeruginosa strain 57RP grown on mannitol or naphthalene

Liquid chromatography/mass spectrometry using electrospray ionisation was used to analyse rhamnolipids produced by a Pseudomonas aeruginosa strain with mannitol or naphthalene as carbon source. Identification and quantification of 28 different rhamnolipid congeners was accomplished using a reverse-phase C(18) column and a 30 min chromatographic run. Isomeric rhamnolipids that were not chromatographically resolved could be identified by interpretation of their mass spectra and their relative proportions estimated. The most abundant rhamnolipid produced on mannitol contained two rhamnoses and two 3-hydroxydecanoic acid groups. The most abundant rhamnolipid produced from naphthalene contained two rhamnoses and one 3-hydroxydecanoic acid group.

MvfR, a key Pseudomonas aeruginosa pathogenicity LTTR‐class regulatory protein, has dual ligands

MvfR (PqsR), a Pseudomonas aeruginosa LysR‐type transcriptional regulator, plays a critical role in the virulence of this pathogen. MvfR modulates the expression of multiple quorum sensing (QS)‐regulated virulence factors; and the expression of the phnAB and pqsA‐E genes that encode functions mediating 4‐hydroxy‐2‐alkylquinolines (HAQs) signalling compounds biosynthesis, including 3,4‐dihydroxy‐2‐heptylquinoline (PQS) and its precursor 4‐hydroxy‐2‐heptylquinoline (HHQ). PQS enhances the in vitro DNA‐binding affinity of MvfR to the pqsA‐E promoter, to suggest it might function as the in vivo MvfR ligand. Here we identify a novel MvfR ligand, as we show that HHQ binds to the MvfR ligand‐binding‐domain and potentiates MvfR binding to the pqsA‐E promoter leading to transcriptional activation of pqsA‐E genes. We show that HHQ is highly produced in vivo, where it is not fully converted into PQS, and demonstrate that it is required for MvfR‐dependent gene expression and pathogenicity; PQS is fully dispensable, as pqsH– mutant cells, which produce HHQ but completely lack PQS, display normal MvfR‐dependent gene expression and virulence. Conversely, PQS is required for full production of pyocyanin. These results uncover a novel biological role for HHQ; and provide novel insights on MvfR activation that may aid in the development of therapies that prevent or treat P. aeruginosa infections in humans.

Isolation and characterization of Desulfitobacterium frappieri sp. nov., an anaerobic bacterium which reductively dechlorinates pentachlorophenol to 3-chlorophenol

An anaerobic bacterium, strain PCP-1T (T = type strain), which dechlorinates pentachlorophenol (PCP) to 3-chlorophenol, was isolated from a methanogenic consortium. This organism is a spore-forming rod-shaped bacterium that is nonmotile, asaccharolytic, and Gram stain negative but Gram type positive as determined by electron microscopic observations. Inorganic electron acceptors, such as sulfite, thiosulfate, and nitrate (but not sulfate), stimulate growth in the presence of pyruvate and yeast extract. The optimum pH and optimum temperature for growth are 7.5 and 38 degrees C, respectively. The dechlorination pathway is: PCP-->2,3,4,5-tetrachlorophenol -->3,4,5-trichlorophenol-->3,5-dichlorophenol-->3-chlorophenol. This bacterium dechlorinates several different chlorophenols at ortho, meta, and para positions; exceptions to this are 2,3-dichlorophenol, 2,5-dichlorophenol, 3,4-dichlorophenol, and the monochlorophenols. The time course of PCP dechlorination suggests that two enzyme systems are involved in dehalogenation in strain PCP-1T. One system is inducible for ortho dechlorination, and the second system is inducible for meta and para dechlorinations. A 16S rRNA analysis revealed that strain PCP-1T exhibits 95% homology with Desulfitobacterium dehalogenans JW/IU-DC1, an anaerobic bacterium which can dehalogenate chlorophenols only in ortho positions. These results suggest that strain PCP-1T is a member of a new species and belongs to the recently proposed genus Desulfitobacterium. Strain PCP-1T differs from D. dehalogenans JW/IU-DC1 by its broader range of chlorophenol dechlorination. Strain PCP-1 is the type strain of the new species, Desulfitobacterium frappieri.

Mass spectrometry monitoring of rhamnolipids from a growing culture of Pseudomonas aeruginosa strain 57RP

Two rapid and simple methods for the characterisation and quantification of rhamnolipids produced by a growing culture of the Pseudomonas aeruginosa strain 57RP were developed. Two rhamnolipids were purified and their response factors determined. The various rhamnolipids produced were then measured using liquid chromatography/mass spectrometry. The culture supernatants were injected directly, without prior purification, in a HPLC equipped with a C(18) reverse-phase column. The complete profile of rhamnolipid congeners produced during a 2 week cultivation period was monitored. In order to shorten the analysis time, another method was developed which did not require chromatographic separation of the rhamnolipids prior to their detection. Quantification of rhamnolipids using the direct infusion method gave results very similar to those obtained with HPLC separation. These two methods were very well correlated with the standard colorimetric orcinol method. The rhamnolipid profiles obtained show that the various rhamnolipid congeners are secreted simultaneously, and that their relative proportion remained unchanged throughout the cultivation period.

Red death in Caenorhabditis elegans caused by Pseudomonas aeruginosa PAO1

During host injury, Pseudomonas aeruginosa can be cued to express a lethal phenotype within the intestinal tract reservoir—a hostile, nutrient scarce environment depleted of inorganic phosphate. Here we determined if phosphate depletion activates a lethal phenotype in P. aeruginosa during intestinal colonization. To test this, we allowed Caenorhabditis elegans to feed on lawns of P. aeruginosa PAO1 grown on high and low phosphate media. Phosphate depletion caused PAO1 to kill 60% of nematodes whereas no worms died on high phosphate media. Unexpectedly, intense redness was observed in digestive tubes of worms before death. Using a combination of transcriptome analyses, mutants, and reporter constructs, we identified 3 global virulence systems that were involved in the “red death” response of P. aeruginosa during phosphate depletion; they included phosphate signaling (PhoB), the MvfR–PQS pathway of quorum sensing, and the pyoverdin iron acquisition system. Activation of all 3 systems was required to form a red colored PQS+Fe3+ complex which conferred a lethal phenotype in this model. When pyoverdin production was inhibited in P. aeruginosa by providing excess iron, red death was attenuated in C. elegans and mortality was decreased in mice intestinally inoculated with P. aeruginosa. Introduction of the red colored PQS+Fe3+ complex into the digestive tube of C. elegans or mouse intestine caused mortality associated with epithelial disruption and apoptosis. In summary, red death in C. elegans reveals a triangulated response between PhoB, MvfR–PQS, and pyoverdin in response to phosphate depletion that activates a lethal phenotype in P. aeruginosa.