Mycobacterium liflandii infection in European colony of Silurana tropicalis.Mycobacterium liflandii causes a fatal frog disease in captive anurans. Here we report, to our knowledge, the first epizootie of mycobacteriosis in a European colony of clawed frogs (Silurana tropicalis), previously imported from a United States biologic supply company. Our findings suggest the emerging potential of this infection through international trade. ********** Many species of nontuberculous mycobacteria inhabit the environment. Mycobacterium fortuitum, M. chelonae, M. marinum, and M. xenopi are some of the mycobacteria mycobacteria members of the genus Mycobacterium. anonymous mycobacteria see opportunist (atypical) mycobacteria (below). nontubercular mycobacteria see opportunist (atypical) mycobacteria (below). that infect amphibians amphibians members of the animal class Amphibia. Includes frogs, toads, newts, salamanders and cecilians all capable of living on land or in water. , causing subcutaneous nodules Nodules A small mass of tissue in the form of a protuberance or a knot that is solid and can be detected by touch. Mentioned in: Leprosy , edema edema (ĭdē`mə), abnormal accumulation of fluid in the body tissues or in the body cavities causing swelling or distention of the affected parts. , and chronic wasting (1). The aquatic, pipid frog, Silurana tropicalis, is an emerging laboratory model for genetic and embryologic/ ontogenetic on·to·ge·net·ic adj. Of or relating to ontogeny. research. Although smaller than the related Xenopus laevis, S. tropicalis has research advantages: diploidy dip·loi·dy n. The state or condition of being diploid. diploidy the state of being diploid. diploidy A DNA complement double the haploid number, n–ie, 2n. See Haploid. Cf Aneuploidy. and brief maturation time make this species ideal for genetic analyses over multiple generations (2). In 2004, Trott et al. characterized a new mycobacterial mycobacterial emanating from or pertaining to mycobacterium. mycobacterial granuloma may be caused by Mycobacterium tuberculosis (see cutaneous tuberculosis), M. pathogen in pipid frog colonies (3), now named M. liflandii (4). On Middlebrook 7H11 agar supplemented with oleic acid, albumin, dextrose dextrose: see glucose. , and catalase catalase /cat·a·lase/ (kat´ah-las) a hemoprotein enzyme that catalyzes the decomposition of hydrogen peroxide to water and oxygen, protecting cells. , M. liflandii form rough, nonpigmented, slightly buff-colored colonies. Visible colonies develop after 30 to 35 days at 28[degrees]C on Lowenstein-Jensen (LJ) medium (3). This M. ulcerans-like mycobacterium mycobacterium Any of the rod-shaped bacteria that make up the genus Mycobacterium. The two most important species cause tuberculosis and leprosy in humans; another species causes tuberculosis in both cattle and humans. produces a plasmid-encoded toxin, mycolactone E, which is less cytopathogenic cytopathogenic /cy·to·path·o·gen·ic/ (-jen´ik) capable of producing pathologic changes in cells. cy·to·path·o·gen·ic adj. Of, relating to, or producing pathological changes in cells. than mycolactone A/B A/B Airborne A/B Afterburner (jet engines) A/B Air Blast A/B Answerback A/B Auto-brake A/B Air Bus A/B Afterburning , produced by African M. ulcerans (4). M. liflandii infection in frogs manifests as cutaneous lesions, coelomitis, and bloating bloating Vox populi A lay term for post-prandial abdominal fullness or swelling , with a high death rate (3). We investigated an epizootic ep·i·zo·ot·ic adj. Affecting a large number of animals at the same time within a particular region or geographic area. Used of a disease. ep of M. liflandii in a colony of African tropical clawed frogs (S. tropicalis) in a European research laboratory. With the rising popularity of this vertebrate laboratory model and the foreseen establishment of stock centers for mutant or transgenic animals, the epizootiology of this emerging disease must be defined so that preventive measures may be instituted. The Study In November 2004, we began to study an epizootic mycobacteriosis in a colony of imported captive S. tropicalis, the African tropical clawed frog. The Department of Molecular Biomedical Research, Flanders Interuniversity Institute for Biotechnology of Ghent University, Belgium, had imported S. tropicalis frogs from a supplier in the United States in September 2004. Within 5 weeks, some animals became lethargic with signs similar to those described by Trott et al.: loss of diving reflex, bloating, and ulcerative ulcerative /ul·cer·a·tive/ (ul´se-ra?tiv) (ul´ser-ah-tiv) pertaining to or characterized by ulceration. ulcerative pertaining to or characterized by ulceration. skin lesions (3). An average number of 2 deaths each week were reported in a colony of 300 specimens. Preliminary examination of 2 affected animals did not show chytridiomycosis; iridoviral infection; common bacterial infections of liver, lungs and kidneys; chlamydophila infection; or intestinal parasites. From November 2004 through April 2005, 19 visually affected and visually unaffected specimens of S. tropicalis, 2 tadpoles, and 4 tank water samples were selected for detailed examination for mycobacteria. The frogs were euthanized and dissected, and selected organs and fluid were removed aseptically (liver, lungs, gallbladder, gastrointestinal tract, spleen, kidneys, fat body, ovary, oviduct oviduct: see fallopian tube. , tibia tibia: see leg. , and coelomic fluid). Each of the specimens was divided into 2 equal parts, half for histopathologic analysis and half for preparation of decontaminated suspensions for culture and microscopic examination (3,5-7). Water samples were concentrated by filtration as described by Iivanainen et al. (7), and suspensions were made from the complete tadpoles (6). Further analyses were performed as described for the decontaminated frog suspensions. DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. for genetic analyses was extracted from the suspensions and pure cultures as described previously (6,8). M. liflandii was identified by IS2404 nested PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) and sequence analysis of 16S rRNA gene (9,10). A combination of 4 genetic typing assays (including 3 previously investigated in M. ulcerans) was used to type M. liflandii (3,9,11,12). A flowchart of the performed tests is shown in Figure 1. [FIGURE 1 OMITTED] All visually affected specimens showed positive results for at least 1 organ and for at least 2 of the following tests: microscopy (Ziehl-Neelsen staining), in vitro cultivation (LJ medium and charcoal medium), IS2404 nested PCR, and histopathologic examination. Of note, all ovarian tissue of the 11 visually affected specimens showed positive results for at least 2 tests. Three of 8 visually unaffected specimens showed positive results for at least 1 organ (including the ovary) and for 1 test. All tadpoles and water samples showed negative results for all tests. Histopathologic evaluation showed many acid-fast bacilli (AFB AFB abbr. acid-fast bacillus AFB Acid-fast bacillus, also 1. Aflatoxin B 2. Aorto-femoral bypass ) in the oviduct lumen (Figure 2). Numerous AFB were found in the kidney tubules, on the surface epithelium, and in the lumens of the gallbladder, stomach, intestine, and oviduct. Papillary papillary /pap·il·lary/ (pap´i-lar?e) pertaining to or resembling a papilla, or nipple. papillary, adj similar to a small, nipple-shaped elevation or projection. hyperplasia of the gallbladder mucosa was marked, and the lamina propria was expanded by heterophils and many AFB (Figure 2). Lung parenchyma Parenchyma A ground tissue of plants chiefly concerned with the manufacture and storage of food. The primary functions of plants, such as photosynthesis, assimilation, respiration, storage, secretion, and excretion—those associated with living , liver, femur, and tibia were normal and free of AFB. [FIGURE 2 OMITTED] We identified the causative pathogen as M. liflandii in all frogs: by growth on charcoal medium, by restriction fragment length polymorphism restriction fragment length polymorphism n. Abbr. RFLP Intraspecies variations in the length of DNA fragments generated by the action of restriction enzymes and caused by mutations that alter the sites at which these enzymes act, changing , or by sequence analysis. Isolate M05-0456 had a similarity value of 100% with M. liflandii (GenBank accession no. AY845224.1). Growth on charcoal medium can be considered as an additional identification criterion for M. liflandii because growth on charcoal is better than on LJ medium (3), differentiating M. liflandii from M. ulcerans. Clinical isolates of M. ulcerans are grown readily on LJ medium but never on charcoal medium. The antibiogram of strain M04-2878 showed resistance to isoniazid isoniazid (ī'sōnī`əzĭd), drug used to treat tuberculosis. Also known as isonicotinic acid hydrazide, isoniazid is the most effective antituberculosis drug currently available. , ethambutol ethambutol /etham·bu·tol/ (e-tham´bu-tol) an antibacterial, specifically effective against Mycobacterium; used with one or more other antituberculous drugs in the treatment of pulmonary tuberculosis, administered as the , rifampin rifampin (rĭfăm`pĭn), antibiotic used in the treatment of tuberculosis. It is also used to eliminate the meningococcus microorganism from carriers and to treat leprosy, or Hansen's disease. , clarithromycin, and ethionamide. In each of the genotyping assays, M. liflandii produced profiles that were distinct from those of M. ulcerans (data not shown). None of the laboratory staff who handled the anurans exhibited any signs of a mycobacterial disease. Conclusions The first epizootic of M. liflandii infection was reported by Trott et al. in 2004 in pipid frog colonies in the United States (3). To our knowledge, our report is the first account of M. liflandii disease in a colony of captive S. tropicalis frogs in Europe. We do not know the prevalence of M. liflandii infection in the colony, but we believe it was very high because 3 of 8 clinically healthy frogs were positive for M. liflandii by at least 1 test. The genetic and phenotypic identification of M. liflandii as causative agent of the epizootic, the fact that cases of M. liflandii infection have not been reported in Europe to date, the strikingly similar signs and disease progress (3), and the probability that the frogs were imported from the same supplier (3) all suggest that some members of the imported S. tropicalis colony were infected with M. liflandii before arrival in Europe. Crowding and stress associated with captivity may have contributed to spread of infection within the colony. How and where the imported frogs became infected remains unknown (3). Additionally, during an extensive study in the Democratic Republic of Congo, Portaels (13) isolated 956 mycobacterial strains from the environment from Buruli ulcer-endemic regions. Among the unknown species, none was characterized as a M. ulcerans--like mycobacterium. To our knowledge, no M. liflandii infection, in humans or wild anurans, has been reported from Africa. We have confirmed that all isolates from Buruli ulcer patients and environmental samples analyzed by our laboratory were true M. ulcerans infections and not IS2404 PCR-positive M. ulcerans--like mycobacteria (unpub. data). The apparently enzootic en·zo·ot·ic adj. Prevalent among or restricted to animals of a specific geographic area. Used of a disease. n. An enzootic disease. enzootic peculiar to or present constantly in a location. See also endemic. character of M. liflandii infection in different S. tropicalis breeding companies in the United States (3,4) and the exchange of transgenic or mutant S. tropicalis lines between research laboratories, may pose a serious threat for the international research community working with this emerging laboratory model. Difficulties in detecting the pathogen in visually unaffected specimens and the high infection rate call for urgent efforts in the management of this epizootic disease. Thus far, no preventive measures or treatment for this amphibian mycobacteriosis are known (3,4,14). Resistance to antimycobacterial agents by environmental mycobacteria is not unusual and has been reported previously (15). We propose examining the oocytes of newly imported frogs as an intervening noninvasive screening method on a regular basis, noting that all affected frogs reported in both intercontinental epizootics were females (3), oocytes from living adult S. tropicalis are easily obtained for research purposes (2), and ovarian tissue was positive for all visually affected specimens and for 1 of 3 positive visually unaffected specimens. However, further studies are needed to determine the role of oocytes in the epizootics of this emerging frog disease, especially in the evaluation of our proposed screening method. To prevent the infection of existing stocks with wild-caught frogs of unknown origin, we further recommend the importation of only certified pathogen-free laboratory-bred specimens from recognized biologic suppliers. Recently, Tarigo et al. reported a frog mycobacteriosis in an adult female, albino South African clawed frog (X. laevis) in a research colony at North Carolina State University History
1. originating in the same area in which it is found. 2. denoting a tissue graft to a new site on the same individual. frogs. Further investigation is required to establish this. Acknowledgments We thank K. Fissette, C. Uwizeye, P. De Rijk, and M. Claes for their excellent technical assistance. This work was supported by the Damien Foundation (Brussels, Belgium) and by a grant from the Flemish Interuniversity Council (VLIR) (grant no. NDOC NDOC National Defense Operations Center 2005UA0006). P.S. is currently supported by a PhD grant (no. NDOC 2005UA0006) of the Flemish Interuniversity Council (VLIR). References (1.) Bercovier H, Vincent V. Mycobacterial infections in domestic and wild animals due to Mycobacterium marinum, M. fortuitum, M. chelonae, M. porcinum, M. farcinogenes, M. smegmatis, M. scrofulaceum, M. xenopi, M. kansasii, M. simiae and M. genavense. In: Collins MT, Manning B. Mycobacterial infections in domestic and wild animals. Paris: Office International de Epizooties; 2001. p. 265-90. (2.) Hirsch N, Zimmerman LB, Grainger RM. Xenopus, the next generation: X. tropicalis genetics and genomics. Dev Dyn. 2002;225: 422-33. (3.) Trott KA, Stacy BA, Lifland BD, Diggs HE, Harland RM, Khokha MK, et al. Characterization of a Mycobacterium ulcerans--like infection in a colony of African tropical clawed frogs (Xenopus tropicalis). Comp Med. 2004;54:309-17. (4.) Mve-Obiang A, Lee RE, Umstot ES, Trott K.A, Grammer TC, Parker JM, et al. A newly discovered mycobacterial pathogen isolated from laboratories of Xenopus species with lethal infections produces a novel form of mycolactone, the Mycobacterium ulcerans macrolide toxin. Infect Immun. 2005;73:3307-12. (5.) Realini L, de Ridder K, Hirschel B, Portaels F. Blood and charcoal added to acidified acidified /acid·i·fied/ (ah-sid´i-fid) having been made acid. agar media promote the growth of Mycobacterium genavense. Diagn Microbiol Infect Dis. 1999;34:45-50. (6.) Kotlowski R, Martin A, Ablordey A, Chemlal K, Fonteyne PA, Portaels F. One-tube cell lysis and DNA extraction procedure for PCR-based detection of Mycobacterium ulcerans in aquatic insects, molluscs and fish. J Med Microbiol. 2004;53:927-33. (7.) Iivanainen EK, Martikainen PJ, Vaananen PK, Katila ML. Environmental factors affecting the occurrence of mycobacteria in brook waters. Appl Environ Microbiol. 1993;59:398-404. (8.) Stragier P, Ablordey A, Bayonne LM, Lugor YL, Sindani IS, Suykerbuyk P, et al. Heterogeneity among Mycobacterium ulcerans isolates from Africa. Emerg Infect Dis. 2006; 12:844-7. (9.) Ablordey A, Kotlowski R, Swings J, Portaels F. PCR amplification with primers based on IS2404 and GC-rich repeated sequence reveals polymorphism in Mycobacterium ulcerans. J Clin Microbiol. 2005;43:448-51. (10.) Rhodes MW, Kator H, McNabb A, Deshayes C, Reyrat JM, Brown-Elliott BA, et al. Mycobacterium pseudoshottsii sp. nov., a slowly growing chromogenic chro·mo·gen·ic adj. Of or relating to a chromogen or to chromogenesis. chromogenic (krō´mōjen´ik), adj pertaining to color production. species isolated from Chesapeake Bay striped bass (Morone saratilis). Int J Syst Evol Microbiol. 2005;55: 1139-47. (11.) Ablordey A, Swings J, Hubans C, Chemlal K, Locht C, Portaels F, et al. Multilocus variable-number tandem repeat typing of Mycobacterium ulcerans. J Clin Microbiol. 2005;43:1546-51. (12.) Stragier P, Ablordey A, Meyers WM, Portaels F. Genotyping Mycobacterium ulcerans and M. marinum by using mycobacterial interspersed repetitive units. J Bacteriol. 2005; 187:1639-47. (13.) Portaels F. Epidemiology ofmycobacterial diseases. Clin Dermatol. 1995;13:207-22. (14.) Tarigo J, Linder K, Neel J, Harvey S, Remick A, Grindem C. Reluctant to dive: coelomic effusion effusion /ef·fu·sion/ (e-fu´zhun) 1. escape of a fluid into a part; exudation or transudation. 2. effused material; an exudate or transudate. in a frog. Vet Clin Pathol. 2006;35:341-4. (15.) Rastogi N, Legrand E, Sola C. The mycobacteria: an introduction to nomenclature and pathogenesis. In: Collins MT, Manning B. Mycobacterial infections in domestic and wild animals. Paris: Office International de Epizooties; 2001. p. 21-54. Mr Suykerbuyk is a doctoral student at the Mycobacteriology Unit, Institute of Tropical Medicine in Antwerp, Belgium. His research interests include microbiology and ecology of M. ulcerans, herpetology, and geographic information systems. Address for correspondence: Francoise Portaels, Department of Microbiology, Mycobacteriology Unit, Institute of Tropical Medicine, Nationalestraat 155, 2000 Antwerp, Belgium; email: portaels@itg.be Patrick Suykerbuyk, * Kris Vleminckx, ([dagger]) ([double dagger]) Frank Pasmans, ([double dagger]) Pieter Stragier, * Anthony Ablordey, * ([section]) Hong Thi Tran, ([dagger]) ([double dagger]) Katleen Herrnans, ([double dagger]) Michelle Fleetwood, ([paragraph]) Wayne M. Meyers, ([paragraph]) and Francoise Portaels * * Institute of Tropical Medicine, Antwerp, Belgium; ([dagger]) Flanders Interuniversity Institute for Biotechnology of Ghent University, Zwijnaarde, Belgium; ([double dagger]) Ghent University, Merelbeke, Belgium; ([section]) Noguchi Memorial Institute for Medical Research, Legon, Ghana; and ([paragraph]) Armed Forces Institute of Pathology Armed Forces Institute of Pathology A section of the US military which provides consultations, reference atlases and educational programs for pathologists , Washington, DC, USA |
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