Tularemia treatment: experimental and clinical data

Tularemia is a zoonosis caused by the Gram negative, facultative intracellular bacterium Francisella tularensis. This disease has multiple clinical presentations according to the route of infection, the virulence of the infecting bacterial strain, and the underlying medical condition of infected persons. Systemic infections (e.g., pneumonic and typhoidal form) and complications are rare but may be life threatening. Most people suffer from local infection (e.g., skin ulcer, conjunctivitis, or pharyngitis) with regional lymphadenopathy, which evolve to suppuration in about 30% of patients and a chronic course of infection. Current treatment recommendations have been established to manage acute infections in the context of a biological threat and do not consider the great variability of clinical situations. This review summarizes literature data on antibiotic efficacy against F. tularensis in vitro, in animal models, and in humans. Empirical treatment with beta-lactams, most macrolides, or anti-tuberculosis agents is usually ineffective. The aminoglycosides gentamicin and streptomycin remain the gold standard for severe infections, and the fluoroquinolones and doxycycline for infections of mild severity, although current data indicate the former are usually more effective. However, the antibiotic treatments reported in the literature are highly variable in their composition and duration depending on the clinical manifestations, the age and health status of the patient, the presence of complications, and the evolution of the disease. Many patients received several antibiotics in combination or successively. Whatever the antibiotic treatment administered, variable but high rates of treatment failures and relapses are still observed, especially in patients treated more then 2–3 weeks after disease onset. In these patients, surgical treatment is often necessary for cure, including drainage or removal of suppurative lymph nodes or other infectious foci. It is currently difficult to establish therapeutic recommendations, particularly due to lack of comparative randomized studies. However, we have attempted to summarize current knowledge through proposals for improving tularemia treatment which will have to be discussed by a group of experts. A major factor in improving the prognosis of patients with tularemia is the early administration of appropriate treatment, which requires better medical knowledge and diagnostic strategy of this disease

Phylogeography and Genetic Diversity of Francisella tularensis subsp. holarctica in France (1947-2018)

In France, tularemia is caused by Francisella tularensis subsp. holarctica and is a sporadic disease affecting mainly wildlife animals and humans. F. tularensis species presents low genetic diversity that remains poorly described in France, as only a few genomes of isolates from the country are available so far. The objective of this study was to characterize the genetic diversity of F. tularensis in France and describe the phylogenetic distribution of isolates through whole-genome sequencing and molecular typing. Whole genomes of 350 strains of human or animal origin, collected from 1947 to 2018 in France and neighboring countries, were sequenced. A preliminary classification using the established canonical single nucleotide polymorphism (canSNP) nomenclature was performed. All isolates from France (except four) belonged to clade B.44, previously described in Western Europe. To increase the resolution power, a whole-genome SNP analysis was carried out. We were able to accurately reconstruct the population structure according to the global phylogenetic framework, and highlight numerous novel subclades. Whole-genome SNP analysis identified 87 new canSNPs specific to these subclades, among which 82 belonged to clade B.44. Identifying genomic features that are specific to sublineages is highly relevant in epidemiology and public health. We highlighted a large number of clusters among a single clade (B.44), which shows for the first time some genetic diversity among F. tularensis isolates from France, and the star phylogeny observed in clade B.44-subclades revealed that F. tularensis biodiversity in the country is relatively recent and resulted from clonal expansion of a single population. No association between clades and hosts or clinical forms of the disease was detected, but spatiotemporal clusters were identified for the first time in France. This is consistent with the hypothesis of persistence of F. tularensis strains found in Western Europe in the environment, associated with slow replication rates. Moreover, the presence of identical genotypes across long periods of time, and across long distances, supports this hypothesis but also suggests long-distance dispersal of the bacterium.This work was supported by the French National Research Agency (ANR) and the Direction Générale de l’Armement (DGA) (No. ANR-15-ASTR-0021-01). MK is a Ph.D. student co-supported by Université Paris-Est and DGA grants

Recherche de nouvelles stratégies thérapeutiques pour le traitement de la tularémie : résistances bactériennes chez Francisella tularensis et développement de nouveaux antibiotiques bis-indoliques de synthèse

Tularemia is a zoonosis caused by the highly pathogenic bacterium Francisella tularensis. The most virulent subspecies, F. tularensis subsp. tularensis, is found only in North America while the subspecies F. tularensis subsp. holarctica is present in the whole Northern hemisphere. In France, all strains belong to the biovar I of the subspecies holarctica and more specifically to the phylogenetic subclade B.FTNF002-00. Although tularemia is usually not a severe disease in France, many patients suffer from therapeutic failures despite receiving an appropriate treatment. These treatments failures are observed in up to 25% of patients treated with ciprofloxacin or gentamicin, and up to 35% if patients treated with doxycycline. The causes of those therapeutic failures remain poorly elucidated. Analysis of the literature and determination of the susceptibility of 59 French F. tularensis subsp. holarctica strains to 18 antibiotics confirmed that to date, no strain with acquired resistance to any of the first-line antibiotics used for treatment of tularemia have been isolated. The fluoroquinolones (in particular ciprofloxacin and levofloxacin) exhibit the lowest minimal inhibitory concentrations, compared to gentamicin and doxycycline. Data obtained in vitro and in animal models are concordant with human data concerning the efficacy of antibiotics and therapeutic failure rates. Thus, we advocate the use of ciprofloxacin as first-line treatment for mild form of tularemia, and the use of doxycyclin only as a second-line treatment in patients with contraindications to fluoroquinolones. Azithromycin and telithromycin may also be considered as potential therapeutic alternatives for tularemia cases caused by biovar I strains of the susbspecies holarctica, but only for patients with contraindications to first-line antibiotics. Further data in animal models are however required to consolidate our in vitro data. The in vitro selection of fluoroquinolone-resistant strains of F. tularensis has been reported. This suggests that the in vivo selection of such resistant mutants may occur. In vitro, the main fluoroquinolone resistance mutations occur in the gyrA and gyrB genes that encode type II topoisomerases of F. tularensis. We have characterized the functional impact of such mutations in avirulent F. novicida strains, taken as a surrogate of F. tularensis. Supercoiling and DNA cleavage activity of GyrA/GyrB complexes reconstituted in vitro have been determined in the presence of fluoroquinolones. Fluoroquinolone resistance level was the highest in strains with a D87G/D87Y mutation in the GyrA subunit or +P466 mutation in the GyrB subunit. The mutation P43H located outside the GyrA Quinolone-Resistance-Determining-Region (QRDR) confered significant but lower fluoroquinolone resistance. The mutation D487R-∆K488 also outside GyrB QRDR did not cause fluoroquinolone resistance by itself, but increased the resistance level in case of concomitant D87G mutation. No mutation could be identified in vivo in the QRDR of gyrA and gyrB genes amplified from clinical samples collected in patients treated with a fluoroquinolone, although some of them experienced therapeutic failure. Finally, while searching for new antibiotic compounds, we identified new synthetic bis-indolic derivatives with antibacterial activity. Lead compounds were only bacteriostatic against F. tularensis but bactericidal against staphylococci including against multi-drug-resistant Staphylococcus aureus. MIC90 were measured at 2mg/L for F. tularensis and S. aureus strains for the most active compound. However, many developments are still required to improve their solubility in water, decrease their plasma proteins binding and elucidate their original mechanism of action.La tularémie est une zoonose liée à la bactérie Francisella tularensis, hautement pathogène pour l’homme. La sous espèce la plus virulente, F. tularensis subsp. tularensis, est retrouvée uniquement en Amérique du Nord, alors que la sous-espèce F. tularensis subsp. holarctica est présente dans tout l’hémisphère Nord. En France toutes les souches appartiennent au biovar I de la sous-espèce holarctica et plus précisément au groupe phylogénétique B.FTNF002-00. Bien que rarement grave en France, la tularémie pose le problème de taux d’échecs thérapeutiques élevés, jusqu’à 25% en cas de traitement par ciprofloxacine ou gentamicine, et 35% pour la doxycycline. Les causes de ces échecs ne sont pas bien élucidées à l’heure actuelle. L’analyse de la littérature ainsi que la détermination de la sensibilité de 59 souches françaises de F. tularensis subsp. holarctica à 18 antibiotiques, confirment qu’aucune souche isolée à ce jour ne présente de résistance acquise à ces trois familles d’antibiotiques, qui représentent le traitement de première ligne de la tularémie. Les fluoroquinolones (en particulier la ciprofloxacine et la lévofloxacine) présentent concentrations minimales inhibitrices les plus basses, devant la gentamicine et la doxycycline. Les données disponibles in vitro et en modèle animal étant corrélées aux données humaines en termes d’efficacité et de taux d’échecs thérapeutiques, il semble néanmoins préférable de positionner la ciprofloxacine en première ligne pour le traitement des formes modérées de tularémie et de limiter l’utilisation de la doxycycline aux cas de contre-indication aux fluoroquinolones. L’azithromycine et la télithromycine ont été identifiées comme des alternatives thérapeutiques envisageables en cas d’infection par une souche de biovar I de F. tularensis subsp. holarctica lorsqu’existe une contre-indication aux traitements de première ligne. Des études en modèles animaux restent néanmoins nécessaires pour conforter ces dernières observations. La sélection in vitro de souches résistantes aux fluoroquinolones est possible, ce qui suggère la possibilité d’émergence de mutants résistants in vivo pour expliquer les taux d’échec thérapeutiques. Les principales mutations de résistance aux fluoroquinolones chez F. tularensis sont observées au niveau des gènes gyrA et gyrB codant pour les topoisomérases de type II. L’impact fonctionnel de mutations de résistances aux fluoroquinolones a été caractérisé in vitro chez F. novicida, pris comme modèle de bactérie avirulente proche de F. tularensis. L’activité de superenroulement et de clivage de l’ADN en présence de fluoroquinolones a été déterminée suite à la reconstruction in vitro de complexes GyrA/GyrB fonctionnels. La résistance aux fluoroquinolones était la plus forte en cas de mutation D87G/D87Y pour la sous-unité GyrA ou +P466 pour la sous-unité GyrB. La mutation P43H située en dehors du QRDR de GyrA est à l’origine d’un plus faible niveau de résistance. La mutation D487R-∆K488 en dehors du QRDR de GyrB ne confère pas de résistance intrinsèque mais potentialise l’effet d’une mutation D87G concomitante. En revanche, l’identification de mutations de résistance in vivo au sein des QRDR des gènes gyrA et gyrB chez des patients en situation d’échec thérapeutique traités par une fluoroquinolone est demeurée négative. Enfin, notre recherche a permis d’identifier de nouveaux composés de synthèse de structure bis-indolique possédant des activités antibactériennes. Ces composés sont bactériostatiques vis-à-vis de F. tularensis mais bactéricides vis-à-vis des staphylocoques y compris vis-à-vis de souches multi-résistantes de Staphylococcus aureus avec des CMI90 évaluées à 2mg/L chez F. tularensis et S. aureus pour le composé le plus actif. La faible solubilité de ces composés en milieu aqueux, leur forte liaison aux protéines plasmatiques ainsi que la recherche de leur mécanisme d’action original appellent néanmoins de nombreux développements futurs

Search for new therapeutic strategies for the treatment of tularemia : antibiotic resistances of Francisella tularensis and development of new synthetic bis-indolic antibiotics.

La tularémie est une zoonose liée à la bactérie Francisella tularensis, hautement pathogène pour l’homme. La sous espèce la plus virulente, F. tularensis subsp. tularensis, est retrouvée uniquement en Amérique du Nord, alors que la sous-espèce F. tularensis subsp. holarctica est présente dans tout l’hémisphère Nord. En France toutes les souches appartiennent au biovar I de la sous-espèce holarctica et plus précisément au groupe phylogénétique B.FTNF002-00. Bien que rarement grave en France, la tularémie pose le problème de taux d’échecs thérapeutiques élevés, jusqu’à 25% en cas de traitement par ciprofloxacine ou gentamicine, et 35% pour la doxycycline. Les causes de ces échecs ne sont pas bien élucidées à l’heure actuelle. L’analyse de la littérature ainsi que la détermination de la sensibilité de 59 souches françaises de F. tularensis subsp. holarctica à 18 antibiotiques, confirment qu’aucune souche isolée à ce jour ne présente de résistance acquise à ces trois familles d’antibiotiques, qui représentent le traitement de première ligne de la tularémie. Les fluoroquinolones (en particulier la ciprofloxacine et la lévofloxacine) présentent concentrations minimales inhibitrices les plus basses, devant la gentamicine et la doxycycline. Les données disponibles in vitro et en modèle animal étant corrélées aux données humaines en termes d’efficacité et de taux d’échecs thérapeutiques, il semble néanmoins préférable de positionner la ciprofloxacine en première ligne pour le traitement des formes modérées de tularémie et de limiter l’utilisation de la doxycycline aux cas de contre-indication aux fluoroquinolones. L’azithromycine et la télithromycine ont été identifiées comme des alternatives thérapeutiques envisageables en cas d’infection par une souche de biovar I de F. tularensis subsp. holarctica lorsqu’existe une contre-indication aux traitements de première ligne. Des études en modèles animaux restent néanmoins nécessaires pour conforter ces dernières observations. La sélection in vitro de souches résistantes aux fluoroquinolones est possible, ce qui suggère la possibilité d’émergence de mutants résistants in vivo pour expliquer les taux d’échec thérapeutiques. Les principales mutations de résistance aux fluoroquinolones chez F. tularensis sont observées au niveau des gènes gyrA et gyrB codant pour les topoisomérases de type II. L’impact fonctionnel de mutations de résistances aux fluoroquinolones a été caractérisé in vitro chez F. novicida, pris comme modèle de bactérie avirulente proche de F. tularensis. L’activité de superenroulement et de clivage de l’ADN en présence de fluoroquinolones a été déterminée suite à la reconstruction in vitro de complexes GyrA/GyrB fonctionnels. La résistance aux fluoroquinolones était la plus forte en cas de mutation D87G/D87Y pour la sous-unité GyrA ou +P466 pour la sous-unité GyrB. La mutation P43H située en dehors du QRDR de GyrA est à l’origine d’un plus faible niveau de résistance. La mutation D487R-∆K488 en dehors du QRDR de GyrB ne confère pas de résistance intrinsèque mais potentialise l’effet d’une mutation D87G concomitante. En revanche, l’identification de mutations de résistance in vivo au sein des QRDR des gènes gyrA et gyrB chez des patients en situation d’échec thérapeutique traités par une fluoroquinolone est demeurée négative. Enfin, notre recherche a permis d’identifier de nouveaux composés de synthèse de structure bis-indolique possédant des activités antibactériennes. Ces composés sont bactériostatiques vis-à-vis de F. tularensis mais bactéricides vis-à-vis des staphylocoques y compris vis-à-vis de souches multi-résistantes de Staphylococcus aureus avec des CMI90 évaluées à 2mg/L chez F. tularensis et S. aureus pour le composé le plus actif. La faible solubilité de ces composés en milieu aqueux, leur forte liaison aux protéines plasmatiques ainsi que la recherche de leur mécanisme d’action original appellent néanmoins de nombreux développements futurs.Tularemia is a zoonosis caused by the highly pathogenic bacterium Francisella tularensis. The most virulent subspecies, F. tularensis subsp. tularensis, is found only in North America while the subspecies F. tularensis subsp. holarctica is present in the whole Northern hemisphere. In France, all strains belong to the biovar I of the subspecies holarctica and more specifically to the phylogenetic subclade B.FTNF002-00. Although tularemia is usually not a severe disease in France, many patients suffer from therapeutic failures despite receiving an appropriate treatment. These treatments failures are observed in up to 25% of patients treated with ciprofloxacin or gentamicin, and up to 35% if patients treated with doxycycline. The causes of those therapeutic failures remain poorly elucidated. Analysis of the literature and determination of the susceptibility of 59 French F. tularensis subsp. holarctica strains to 18 antibiotics confirmed that to date, no strain with acquired resistance to any of the first-line antibiotics used for treatment of tularemia have been isolated. The fluoroquinolones (in particular ciprofloxacin and levofloxacin) exhibit the lowest minimal inhibitory concentrations, compared to gentamicin and doxycycline. Data obtained in vitro and in animal models are concordant with human data concerning the efficacy of antibiotics and therapeutic failure rates. Thus, we advocate the use of ciprofloxacin as first-line treatment for mild form of tularemia, and the use of doxycyclin only as a second-line treatment in patients with contraindications to fluoroquinolones. Azithromycin and telithromycin may also be considered as potential therapeutic alternatives for tularemia cases caused by biovar I strains of the susbspecies holarctica, but only for patients with contraindications to first-line antibiotics. Further data in animal models are however required to consolidate our in vitro data. The in vitro selection of fluoroquinolone-resistant strains of F. tularensis has been reported. This suggests that the in vivo selection of such resistant mutants may occur. In vitro, the main fluoroquinolone resistance mutations occur in the gyrA and gyrB genes that encode type II topoisomerases of F. tularensis. We have characterized the functional impact of such mutations in avirulent F. novicida strains, taken as a surrogate of F. tularensis. Supercoiling and DNA cleavage activity of GyrA/GyrB complexes reconstituted in vitro have been determined in the presence of fluoroquinolones. Fluoroquinolone resistance level was the highest in strains with a D87G/D87Y mutation in the GyrA subunit or +P466 mutation in the GyrB subunit. The mutation P43H located outside the GyrA Quinolone-Resistance-Determining-Region (QRDR) confered significant but lower fluoroquinolone resistance. The mutation D487R-∆K488 also outside GyrB QRDR did not cause fluoroquinolone resistance by itself, but increased the resistance level in case of concomitant D87G mutation. No mutation could be identified in vivo in the QRDR of gyrA and gyrB genes amplified from clinical samples collected in patients treated with a fluoroquinolone, although some of them experienced therapeutic failure. Finally, while searching for new antibiotic compounds, we identified new synthetic bis-indolic derivatives with antibacterial activity. Lead compounds were only bacteriostatic against F. tularensis but bactericidal against staphylococci including against multi-drug-resistant Staphylococcus aureus. MIC90 were measured at 2mg/L for F. tularensis and S. aureus strains for the most active compound. However, many developments are still required to improve their solubility in water, decrease their plasma proteins binding and elucidate their original mechanism of action

Évaluation de l activité antibactérienne de nouveaux composés bis-indoliques de synthèse, de structure proche de celles d alcaloïdes d origine marine

Le développement de nouvelles voies de synthèse d alcaloïdes bis-indoliques isolés d éponges marines appartenant aux familles des spongotines, des topsentines et des hamacanthines nous a permis d accéder à de nouveaux composés bis-indoliques de structure originale. Au final, 24 composés bis-indoliques comportant deux noyaux indoliques reliés par un espaceur central de type amide ou a-céto-amide ont été synthétisés et évalués quant à leur activité antibactérienne. Parmi eux, nous avons identifié des dérivés d action anti-staphylococcique propre et des inhibiteurs de la pompe à efflux NorA de Staphylococcus aureus. Ces inhibiteurs permettent de restaurer l activité des fluoroquinolones chez les souches de S. aureus résistantes à ces antibiotiques par surexpression de NorA. Les composés présentant une activité antibactérienne propre sont actifs à la fois sur S. aureus et sur les espèces de staphylocoques à coagulase négative, avec des concentrations minimales inhibitrices (CMI) variant de 1 à 4 g/mL pour les molécules les plus actives. Ces composés n ont pas d activité bactéricide. Leur activité est cependant conservée vis-à-vis des souches multi-résistantes de S. aureus, notamment celles résistantes à la méticilline (SARM) et/ou intermédiaires à la vancomycine (VISA). La cible bactérienne de ces composés bis-indoliques semble donc différente de celles des antibiotiques anti-staphylococciques disponibles actuellement. Son identification pourrait conduire à la synthèse d une ou plusieurs nouvelles familles d antibiotiques. Ces données préliminaires encourageantes nous incitent donc à poursuivre l optimisation structurale de ces composés bis-indoliques afin d augmenter leur activité vis-à-vis des staphylocoques, de réduire leur cytotoxicité, de tenter d élargir leur spectre antibactérien et d obtenir un effet bactéricide.Development of new ways of synthesis of marine bis-indole alkaloids belonging to the spongotin, topsentin and hamacanthin classes led to an original library of bis-indolic derivatives with either an amide or an a-keto-amide central linker. Here we report the synthesis, antibacterial activity and cytotoxicity of twenty four of those original compounds. Determination of minimal inhibitory concentrations (MIC) against 22 Grampositive and 7 Gram-negative bacterial strains revealed an antibacterial spectrum restricted to Staphylococcus species. Lead compounds were active against both Staphylococcus aureus and coagulase-negative Staphylococcus species, with MICs between 1 and 4 g/ml. Importantly, this antibacterial activity was maintained against methicillin-resistant and vancomycin-intermediate S. aureus strains, with unchanged MIC values. Determination of the minimal bactericidal concentrations and time-kill studies revealed no bactericidal activity of the bis-indole compounds. One-step mutation experiments did not allow us to isolate bis-indole resistant mutants despite using bacterial inocula as high as 1010 cfu/ml. Four bis-indole compounds with no proper antibacterial activity were inhibitors of S. aureus NorA efflux pump, which is involved in resistance to fluoroquinolones. The most effective compound led to a four-fold reduction of ciprofloxacin MIC against S. aureus strain SA1199B, which overexpresses NorA efflux pump, when used at 0.5 g/ml. In conclusion, the bis-indole derivatives are promising candidates for the development of new antistaphylococcal treatments, including drugs active against multi-drug resistant S. aureus strains.GRENOBLE1-BU Médecine pharm. (385162101) / SudocSudocFranceF

Francisella tularensis Susceptibility to Antibiotics: A Comprehensive Review of the Data Obtained In vitro and in Animal Models

The antibiotic classes that are recommended for tularaemia treatment are the aminoglycosides, the fluoroquinolones and the tetracyclines. However, cure rates vary between 60 and 100% depending on the antibiotic used, the time to appropriate antibiotic therapy setup and its duration, and the presence of complications, such as lymph node suppuration. Thus, antibiotic susceptibility testing (AST) of F. tularensis strains remains of primary importance for detection of the emergence of antibiotic resistances to first-line drugs, and to test new therapeutic alternatives. However, the AST methods reported in the literature were poorly standardized between studies and AST data have not been previously evaluated in a comprehensive and comparative way. The aim of the present review was to summarize experimental data on antibiotic susceptibilities of F. tularensis obtained in acellular media, cell models and animal models since the introduction of fluoroquinolones in the treatment of tularaemia in 1989. We compiled MIC data of 33 antibiotics (including aminoglycosides, fluoroquinolones, tetracyclines, macrolides, β-lactams, chloramphenicol, rifampicin, and linezolid) against 900 F. tularensis strains (504 human strains), including 107 subsp. tularensis (type A), 789 subsp. holarctica (type B) and four subsp. mediasiatica strains, using various AST methods. Specific culture media were identified or confirmed as unsuitable for AST of F. tularensis. Overall, MICs were the lowest for ciprofloxacin (≤ 0.002–0.125 mg/L) and levofloxacin, and ranged from ≤ 0.016 to 2 mg/L for gentamicin, and 0.064 to 4 mg/L for doxycycline. No resistant strain to any of these antibiotics was reported. Fluoroquinolones also exhibited a bactericidal activity against intracellular F. tularensis and lower relapse rates in animal models when compared with the bacteriostatic compound doxycycline. As expected, lower MIC values were found for macrolides against type A and biovar I type B strains, compared to biovar II type B strains. The macrolides were more effective against F. tularensis grown in phagocytic cells than in acellular media

Antibiotic susceptibility of Francisella tularensis subsp. holarctica strains isolated from tularaemia patients in France between 2006 and 2016

International audienceObjectives: To determine the in vitro susceptibility to 18 antibiotics of human strains of Francisella tularensis isolated in France between 2006 and 2016, to check the absence of acquired resistance and to evaluate potential therapeutic alternatives.Methods: Fifty-nine clinically unrelated F. tularensis subsp. holarctica strains identified at the French National Reference Centre for Francisella as belonging to the phylogenetic subclade B.FTNF002-00 were used. MICs were determined in CAMHB medium supplemented with 2% PolyViteX V R , using the CLSI broth microdilution method.Results: All strains were susceptible to fluoroquinolones (ofloxacin, ciprofloxacin, levofloxacin and moxifloxacin; MIC range: 0.016-0.25 mg/L), aminoglycosides (gentamicin and tobramycin; MIC range: 0.03-0.25 mg/L), doxycycline (MIC range: 0.125-0.25 mg/L) and chloramphenicol (MIC range: 0.5-2 mg/L). The erythromycin MIC range (0.5-2 mg/L) confirmed that all isolates belonged to biovar I of F. tularensis subsp. holarctica. Azithromycin and telithromycin displayed lower MIC ranges (0.25-1 and 0.03-0.5 mg/L, respectively). The tigecycline MIC range (0.25-1 mg/L) was slightly higher than that of doxycycline. All strains were resistant to ampicillin, meropenem, daptomycin, clindamycin and linezolid.Conclusions: F. tularensis strains isolated in France remain susceptible to antibiotic classes recommended for tularaemia treatment. Because fluoroquinolones display the lowest MIC 90 , have bactericidal activity and have lower therapeutic failure rates compared with doxycycline, they may be advocated as first-line treatment of mild cases of tularaemia, predominant in Europe. MIC data also indicate that azithromycin or telithromycin may be possible therapeutic options against biovar I strains from Western Europe in case of contraindication to first-line antibiotics

Phenotypic and genetic resistance traits of Pseudomonas aeruginosa strains infecting cystic fibrosis patients: A French cohort study

International audienc

A new dye uptake assay to test the activity of antibiotics against intracellular Francisella tularensis.

International audienceFrancisella tularensis, a facultative intracellular bacterium, is the aetiological agent of tularaemia. Antibiotic treatment of this zoonosis is based on the administration of a fluoroquinolone or a tetracycline for cases with mild to moderate severity, whereas an aminoglycoside (streptomycin or gentamicin) is advocated for severe cases. However, treatment failures and relapses remain frequent, especially in patients suffering from chronic lymph node suppuration. Therefore, new treatment alternatives are needed. We have developed a dye uptake assay for determination of minimal inhibitory extracellular concentrations (MIECs) of antibiotics against intracellular F. tularensis, and validated the method by comparing the results obtained using a CFU-enumerating method. We also compared MIECs with MICs of the same compounds determined using a CLSI broth microdilution method. We tested the activity of 11 antibiotics against two clinical strains of F. tularensis subsp. holarctica isolated in France. Both strains displayed low MICs (≤1 μg/mL) to fluoroquinolones (ciprofloxacin, levofloxacin and moxifloxacin), gentamicin, doxycycline and rifampicin. Higher MICs (≥8 μg/mL) were found for carbapenems (imipenem and meropenem), daptomycin and linezolid. Erythromycin MICs were 4.0 and 16.0 μg/mL, respectively, for the two clinical strains. MIECs were almost the same with the two methods used. They were concordant with MICs, except for erythromycin and linezolid (respectively, four and eight times more active against intracellular F. tularensis) and gentamicin (four to eight times less active against intracellular F. tularensis). This study validated the dye uptake assay as a new tool for determination of the activity of a large panel of antibiotics against intracellular F. tularensis. This test confirmed the intracellular activity of first-line antibiotics used for tularaemia treatment, but also revealed significant activity of linezolid against intracellular F. tularensis