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. 2016 Jul 8;16(1):137.
doi: 10.1186/s12866-016-0756-x.

Tryptophan catabolism in Pseudomonas aeruginosa and potential for inter-kingdom relationship

Perrine Bortolotti  1 Benjamin Hennart  2 Camille Thieffry  1 Guillaume Jausions  1 Emmanuel Faure  1 Teddy Grandjean  3 Marion Thepaut  3 Rodrigue Dessein  3 Delphine Allorge  2 Benoit P Guery  4 Karine Faure  3 Eric Kipnis  3 Bertrand Toussaint  5   6 Audrey Le Gouellec  7   8
Affiliations

Tryptophan catabolism in Pseudomonas aeruginosa and potential for inter-kingdom relationship

Perrine Bortolotti et al. BMC Microbiol. .

Abstract

Background: Pseudomonas aeruginosa (Pa) is a Gram-negative bacteria frequently involved in healthcare-associated pneumonia with poor clinical outcome. To face the announced post-antibiotic era due to increasing resistance and lack of new antibiotics, new treatment strategies have to be developed. Immunomodulation of the host response involved in outcome could be an alternative therapeutic target in Pa-induced lung infection. Kynurenines are metabolites resulting from tryptophan catabolism and are known for their immunomodulatory properties. Pa catabolizes tryptophan through the kynurenine pathway. Interestingly, many host cells also possess the kynurenine pathway, whose metabolites are known to control immune system homeostasis. Thus, bacterial metabolites may interfere with the host's immune response. However, the kynurenine pathway in Pa, including functional enzymes, types and amounts of secreted metabolites remains poorly known. Using liquid chromatography coupled to mass spectrometry and different strains of Pa, we determined types and levels of metabolites produced by Pa ex vivo in growth medium, and the relevance of this production in vivo in a murine model of acute lung injury.

Results: Ex vivo, Pa secretes clinically relevant kynurenine levels (μM to mM). Pa also secretes kynurenic acid and 3-OH-kynurenine, suggesting that the bacteria possess both a functional kynurenine aminotransferase and kynurenine monooxygenase. The bacterial kynurenine pathway is the major pathway leading to anthranilate production both ex vivo and in vivo. In the absence of the anthranilate pathway, the kynurenine pathway leads to kynurenic acid production.

Conclusion: Pa produces and secretes several metabolites of the kynurenine pathway. Here, we demonstrate the existence of new metabolic pathways leading to synthesis of bioactive molecules, kynurenic acid and 3-OH-kynurenine in Pa. The kynurenine pathway in Pa is critical to produce anthranilate, a crucial precursor of some Pa virulence factors. Metabolites (anthranilate, kynurenine, kynurenic acid) are produced at sustained levels both ex vivo and in vivo leading to a possible immunomodulatory interplay between bacteria and host. These data may imply that pulmonary infection with bacteria highly expressing the kynurenine pathway enzymes could influence the equilibrium of the host's tryptophan metabolic pathway, known to be involved in the immune response to infection. Further studies are needed to explore the effects of these metabolic changes on the pathophysiology of Pa infection.

Keywords: Anthranilate; Kynurenic acid; Kynurenine; Pseudomonas aeruginosa; Tryptophan.

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Figures

Fig. 1
Fig. 1
The kynurenine pathway in Pa. This figure shows the metabolites resulting from tryptophan catabolism through the kynurenine pathway in P. aeruginosa, the three enzymes involved in this metabolic pathway and their related genes
Fig. 2
Fig. 2
Tryptophan, anthranilate, and L-kynurenine concentrations ex vivo. Tryptophan, anthranilate, and L-kynurenine concentrations in growth medium supernatants of CHA strain (black), CHA∆kynA strain (dark gray) and CHA∆kynU strain (light gray) as determined by UPLC-MS-MS. All data from two experiments in duplicates. Error bars represent means +/− SD
Fig. 3
Fig. 3
Kynurenic acid concentrations ex vivo and hypothetical metabolic pathway. a Kynurenic acid concentrations in CHA (black), CHA∆kynA (dark gray) and CHA∆kynU (light gray) strains growth medium supernatants. All data from two experiments in duplicates. Error bars represent means +/− SD. b Hypothetical metabolic pathway responsible for bacterial synthesis of kynurenic acid
Fig. 4
Fig. 4
3-OH-kynurenine concentrations ex vivo and hypothetical metabolic pathway. a 3-OH-kynurenine concentrations in CHA (black), CHA∆kynA (dark gray) and CHA∆kynU (light gray) strains growth medium supernatants. Representative data from two experiments in duplicates. Error bars represent means +/− SD. b Hypothetical metabolic pathway responsible for bacterial synthesis of 3-OH-kynurenine
Fig 5
Fig 5
3-OH-anthranilate concentrations in vivo. 3-OH-anthranilate concentrations in BAL of infected mice in a 12-hour and a 24-hour infection models with CHA (black), CHA∆kynA and CHA∆kynU strains. All experiments, n = 5 mice per group, in duplicates. *p < 0.05. Error bars represent means +/− SEM. Symbols correspond to each sample. Dotted line represents the detection threshold
Fig. 6
Fig. 6
Kynurenic acid concentrations in vivo. Kynurenic acid concentrations in BAL of infected mice in 12-hour and 24-hour infection models with CHA (black), CHA∆kynA (dark gray) and CHA∆kynU (light gray) strains. All experiments, n = 5 mice per group, in duplicates. *p < 0.05. Error bars represent means +/− SEM
Fig. 7
Fig. 7
Impact of the bacterial kynurenine pathway on mice survival. Survival of mice infected with lethal inoculum of either CHA (in black), CHA∆kynA (in dash grey), or CHA∆kynU (in light grey) strains. There is a trend toward better survival in mice infected with CHA∆kynA compared with CHA∆kynU strain infection (p = 0063). There is no statistically significant difference in survival between mice infected with lethal inoculum of either CHA (in black) and CHA∆kynA (in dash grey), or CHA and CHA∆kynU (in grey) strains. 3 pooled experiments, n = 18 per group. Statistic analysis performed with log-rank test
Fig. 8
Fig. 8
Overview of the proposed enzymatic pathways for tryptophan catabolism in Pa. Summary of the proven (dark arrows) and hypothetical (grey arrows) enzymatic reactions composing the kynurenine pathway of Pa. Hypothetical enzymes are highlighted in red. TDO: tryptophan-2,3-dioxygenase, KYNF: kynurenine formamidase, KYNU: kynureninase, KAT: kynurenine aminotransferase, KMO: kynurenine monooxygenase
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