The sources and the reservoirs of Mycobacterium ulcerans, the causative agent of Buruli ulcer

L'ulcère de Buruli, maladie négligée, pouvant entraîner déformations et incapacités permanentes, causée par Mycobacterium ulcerans, une mycobactérie associée aux écosystèmes aquatiques. Les sources et réservoirs de M. ulcerans ne sont pas précisément connus limitant la prophylaxie. Ma thèse contribue à démasquer les sources de contamination par M. ulcerans. Ma revue de la littérature répertoriant les sources potentielles, met en exergue les pièces manquantes pour la compréhension de l’épidémiologie de l’ulcère de Buruli. Mon étude de coculture M. ulcerans-Acanthamoeba griffini indique que cette amibe n’est pas un réservoir de M. ulcerans. Ensuite, mon étude du métabolisme des substrats carbonés indique que les bactéries, champignons, algues et mollusques peuvent combiner des sources carbonées au profit de M. ulcerans dans l’environnement. Capitalisant sur ce résultat, mon étude de l’effet des mycolactones secrétées par M. ulcerans sur les champignons, montre une attraction sur Mucor circinelloides. Ces observations démasquent une nouvelle activité de la mycolactone d’attraction d’organismes fungiques. Le mode de transmission de M. ulcerans à l’homme reste également un mystère. Dans ce sens, j’ai détecté des séquences d'ADN spécifiques de M. ulcerans sur la peau saine d’individus asymptomatiques en zones d’endémie. Ces données pourraient aider à promouvoir une prophylaxie fondée sur le port des habits de protection au contact des environnements à risques. En perspective à mon travail de thèse, une collaboration est mise en place avec le PNLUB et l’Institut Pasteur de Côte d’Ivoire pour étudier les réservoirs de M. ulcerans en Côte d'Ivoire.Buruli ulcer is a dermis, epidermis and sometimes bone infection leading to deformities and permanent disabilities. It is caused by Mycobacterium ulcerans, a mycobacterium associated to the aquatic ecosystems but its sources and reservoirs are not yet defined. Therefore, no prophylaxis is established. This thesis contribute to unmask the sources of contamination of M. ulcerans. My review has identified potential sources of M. ulcerans in the environment and highlighted the missing pieces for understanding the epidemiology of Buruli ulcer. My study on the role of amoeba in the survival of M. ulcerans in the environment, install M. ulcerans as susceptible to amoeba rendering amoeba an unlikely host of M. ulcerans. Hereafter, i studied carbon substrates metabolized by M. ulcerans strains. Literature survey indicated that the environmental sources of carbon substrates metabolized by M. ulcerans were bacteria, fungi, algae and mollusks. I therefore studied the interactions of M. ulcerans with fungi by testing the effect of mycolactones on fungi. Mycolactones showed an attraction effect on Mucor circinelloides. This observation suggest a novel role for mycolactones as chemoatractants to fungi. The mode of transmission of M. ulcerans to humans remains unknown. I showed that M. ulcerans DNA can be detected on the healthy skin of asymptomatic persons, suggesting an asymptomatic carriage. These data could help promote prophylaxis based on wearing protective clothing in contact with risky environments. In perspective to my thesis work, we set up a collaboration with the Buruli Ulcer Program (PNLUB) and Institut Pasteur Côte d'Ivoire to study the reservoirs of M. ulcerans

Intra-amoebal killing of Mycobacterium ulcerans by Acanthamoeba griffini: A co-culture model

International audienceMycobacterium ulcerans, a decaying Mycobacterium marinwn derivative is responsible for Buruli ulcer, a notifiable non-contagious disabling infection highly prevalent in some West African countries. Aquatic environments are suspected to host M. ulcerans, however, the exact reservoirs remain unknown. While M. marinum was found to resist amoebal microbicidal activities, this remains unknown for M. ulcerans. In this study M. ulcerans was co-cultured with the moderately halophile Acanthamoeba griffin at 30 degrees C to probe this tropical amoeba as a potential reservoir for M. ulcerans. In triplicate experiments, we observed engulfment of M. ulcerans by A. griffini trophozoites, followed by an unexpected significant difference of 98.4% (day 1), 99.5% (day 2), 99.5% (day 3) and 99.9% (day 7) between the number of intra-amoebal mycobacteria detected by PCR and the number of viable intra-amoebal mycobacteria measured by 10-week culture. Further encystment revealed only one Mycobacterium organism for 150 A. griffini cysts observed by electron microscopy and the culture of excysted amoebae remained sterile. In conclusion, these data install M. ulcerans as susceptible to A. griffini microbicidal activities rendering this amoeba species an unlikely host of M. ulcerans in natural environments

Draft Genome Sequence of Mycobacterium setense CSUR47

International audienceMycobacterium setense CSUR47 is a rapidly growing Mycobacterium species strain isolated from pus collected from a left maxillary sinus in Marseille, France. Here, we report the complete 6,278,097-bp genome sequence of M. setense CSUR47, which exhibits a 66.40% GC content and encodes 5,863 protein-coding genes, 48 tRNAs, and 9 rRNAs

High-Throughput Carbon Substrate Profiling of Mycobacterium ulcerans Suggests Potential Environmental Reservoirs

International audienceBackground Mycobacterium ulcerans is a close derivative of Mycobacterium marinum and the agent of Buruli ulcer in some tropical countries. Epidemiological and environmental studies pointed towards stagnant water ecosystems as potential sources of M. ulcerans, yet the ultimate reservoirs remain elusive. We hypothesized that carbon substrate determination may help elucidating the spectrum of potential reservoirs. Methodology/Principal findings In a first step, high-throughput phenotype microarray Biolog was used to profile carbon substrates in one M. marinum and five M. ulcerans strains. A total of 131/190 (69%) carbon substrates were metabolized by at least one M. ulcerans strain, including 28/190 (15%) carbon substrates metabolized by all five M. ulcerans strains of which 21 substrates were also metabolized by M. marinum. In a second step, 131 carbon substrates were investigated, through a bibliographical search, for their known environmental sources including plants, fruits and vegetables, bacteria, algae, fungi, nematodes, mollusks, mammals, insects and the inanimate environment. This analysis yielded significant association of M. ulcerans with bacteria (p = 0.000), fungi (p = 0.001), algae (p = 0.003) and mollusks (p = 0.007). In a third step, the Medline database was cross-searched for bacteria, fungi, mollusks and algae as potential sources of carbon substrates metabolized by all tested M. ulcerans; it indicated that 57% of M. ulcerans substrates were associated with bacteria, 18% with alga, 11% with mollusks and 7% with fungi. Conclusions This first report of high-throughput carbon substrate utilization by M. ulcerans would help designing media to isolate and grow this pathogen. Furthermore, the presented data suggest that potential M. ulcerans environmental reservoirs might be related to micro-habitats where bacteria, fungi, algae and mollusks are abundant. This should be followed by targeted investigations in Buruli ulcer endemic regions

Screening anti-infectious molecules against Mycobacterium ulcerans: A step towards decontaminating environmental specimens

International audienceMycobacterium ulcerans, a non-tuberculous mycobacterium responsible for Buruli ulcer, resides in poorly defined environmental niches in the vicinity of stagnant water. Very few isolates have been confirmed. With a view to culturingM.ulceransfrom such contaminated environmental specimens, we tested thein vitrosusceptibility of theM.ulceransCU001 strain co-cultivated with XTC cells to anti-infectious molecules registered in the French pharmacopoeia. We used a standardised concentration to identify molecules that were inactive againstM.ulceransand which could be incorporated into a decontaminating solution. Of 116 tested molecules, 64 (55.1%) molecules were ineffective against M. ulcerans CU001. These included 34 (29.3%) antibiotics, 14 (12%) antivirals, eight (6.8%) antiparasitics, and eight (6.8%) antifungals. This left 52 molecules which were active againstM.ulceransCU001. Three of the inactive antimicrobial molecules (oxytetracycline, polymyxin E and voriconazole) were then selected to prepare a decontamination solution which was shown to respectM.ulceransCU001 viability. These three antimicrobials could be incorporated into a decontamination solution to potentially isolate and cultureM.ulceransfrom environmental samples

Buruli Ulcer, a Prototype for Ecosystem-Related Infection, Caused by Mycobacterium ulcerans

International audienceBuruli ulcer is a noncontagious disabling cutaneous and subcutaneous mycobacteriosis reported by 33 countries in Africa, Asia, Oceania, and South America. The causative agent, Mycobacterium ulcerans, derives from Mycobacterium marinum by genomic reduction and acquisition of a plasmid-borne, nonribosomal cytotoxin mycolactone, the major virulence factor. M. ulcerans-specific sequences have been readily detected in aquatic environments in food chains involving small mammals. Skin contamination combined with any type of puncture, including insect bites, is the most plausible route of transmission, and skin temperature of <30 degrees C significantly correlates with the topography of lesions. After 30 years of emergence and increasing prevalence between 1970 and 2010, mainly in Africa, factors related to ongoing decreasing prevalence in the same countries remain unexplained. Rapid diagnosis, including laboratory confirmation at the point of care, is mandatory in order to reduce delays in effective treatment. Parenteral and potentially toxic streptomycinrifampin is to be replaced by oral clarithromycin or fluoroquinolone combined with rifampin. In the absence of proven effective primary prevention, avoiding skin contamination by means of clothing can be implemented in areas of endemicity. Buruli ulcer is a prototype of ecosystem pathology, illustrating the impact of human activities on the environment as a source for emerging tropical infectious diseases

Translocating Mycobacterium ulcerans: An experimental model

Mycobacterium ulcerans is a non-tuberculous environmental mycobacterium responsible for extensive cutaneous and subcutaneous ulcers in mammals, known as Buruli ulcer in humans. M. ulcerans has seldom been detected in the faeces of mammals and has not been detected in human faeces. Nevertheless, the detection and isolation of M. ulcerans in animal faeces does not fit with the current epidemiological schemes for the disease. Here, using an experimental model in which rats were fed with 10(9) colony-forming units of M. ulcerans, we detected M. ulcerans DNA in the faeces of challenged rats for two weeks and along their digestive tract for 10 days. M. ulcerans DNA was further detected in the lymphatic system including in the cervical and axillary lymph nodes and the spleen, but not in any other tissue including healthy and broken skin, 10 days post-challenge. These observations indicate that in some herbivorous mammals, M. ulcerans contamination by the digestive route may precede translocation and limited contamination of the lymphatic tissues without systemic infection. These herbivorous mammals may be sources of M. ulcerans for exposed populations but are unlikely to be reservoirs for the pathogen

Mycobacterium ulcerans mycolactones-fungi crosstalking

Abstract The opportunistic pathogen Mycobacterium ulcerans, which is responsible for Buruli ulcer, synthesizes a series of plasmid-encoded macrolide exotoxins termed mycolactones. These toxins destabilize cell membranes and induce apoptosis-associated pleiotropic effects including tissue destruction, analgesic and anti-inflammatory effects. Despite its medical interest, M. ulcerans is primarily an environmental mycobacterium and the primary functions of mycolactones in the natural ecosystems are unknown. High throughput biochemical profiling findings suggested that M. ulcerans may interact with fungi. Here, we report that semi-purified and purified mycolactones significantly enhance spore germination of Scedosporium apiospermum, Fusarium equiseti and Mucor circinelloides; and that M. ulcerans mycolactones significantly attract colonies of M. circinelloides whereas no significant effect was observed on S. apiospermum and F. equiseti. These experimental results suggest that mycolactones exhibit a chemoattractant activity independent of their cytotoxicity. In natural ecosystems, M. ulcerans mycolactones may act as spore germination inducers and chemoattractants for some fungi, suggesting a novel role for this unique class of mycobacterial toxins in natural ecosystems

Confirming Autochthonous Buruli Ulcer Cases in Burkina Faso, West Africa

International audienceEnvironmental Mycobacterium ulcerans causes a disabling skin disease called Buruli ulcer. Recent studies completed the knowledge of the evolving geographic extension and epidemiology of Buruli ulcer in West Africa, where Côte d’Ivoire is reporting the highest number of cases. We report seven polymerase chain reaction-documented patients in Burkina Faso, a neighboring country of Côte d’Ivoire, where previously Buruli ulcer cases were confirmed primarily using clinical arguments

Recipe for 1x PM inoculating fluids from stock solutions.

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