Mycobacterium genavense infection in two species of captive snakes

Ullmann, Leila Sabrina; Dias, Ramiro das Neves; Cagnini, Didier Quevedo; Yamatogi, Ricardo Seiti; Oliveira, Jose Paes; Nemer, Viviane; Teixeira, Rodrigo Hidalgo Friciello; Biondo, Alexander Welker; Araújo, João Pessoa

doi:10.1186/s40409-016-0082-7

Abstract

Background:

Mycobacterium is an important zoonotic agent with companion, livestock and wildlife animals reportedly playing a role as reservoirs. Although its association with reptiles has been described, the disease cycle remains to be fully established, particularly in snakes. Accordingly, this study aimed to report the occurrence of mycobacteriosis with clinical pneumonia in one exotic python snake (Python molurus) and one native green snake (Philodryas olfersii) from the Sorocaba Zoo, São Paulo state, Brazil.

Methods:

Diagnosis was based on necropsy, histopathological examination, Ziehl-Neelsen stain and immunohistochemistry.

Results:

Using a nested PCR followed by DNA sequencing and bioinformatics analysis, the causative Mycobacterium species was identified as Mycobacterium genavense.

Conclusion:

Mycobacterium genavense is an infectious zoonotic agent of animal and public health concerns.

Keywords:
Captive snakes; Mycobacterium; Public health

Background

Mycobacteriosis is a generic term for many diseases with different pathogenicities caused by about 85 bacterial species of the genus Mycobacterium [¹1. Miller MA. Current Diagnostic Methods for Tuberculosis in Zoo Animals. In: Miller MEFE, editor. Zoo and Wild Animal Medicine. 6th ed. Saint Louis: W.B. Saunders; 2008. p. 10-9.]. Mycobacteria are gram-positive, aerobic, alcohol-acid-resistant bacteria and share the same morphological characteristics among different species, which are currently classified into M. tuberculosis and nontuberculous mycobacteria (NTM) [²2. Soldati G, Lu ZH, Vaughan L, Polkinghorne A, Zimmermann DR, Huder JB, et al. Detection of mycobacteria and chlamydiae in granulomatous inflammation of reptiles: a retrospective study. Vet Pathol. 2004;41(4)388-97., ³3. Dias-Baptista IMF, Usó SMRS, Marcondes-Machado J. Trends in multidrug-resistant tuberculosis. J Venom Anim Toxins incl Trop Dis. 2008;14(2):203-23.].

Cold-blooded animals may carry a wide variety of zoonotic pathogens; in particular, reptiles may pose a health risk to professionals with whom they have contact. Although mostly described in mammals, reptiles may also be affected by mycobacteriosis, presenting clinical signs related to the affected organs and characterized by diffuse and granulomatous lesions [⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.]. Diagnosis is usually postmortem, wherein necropsy findings when visible include greyish-white nodules due to the granulomatous inflammatory infiltrate with multinucleated giant cells; differently from mammals, mineralized nodules are not observed in reptiles [²2. Soldati G, Lu ZH, Vaughan L, Polkinghorne A, Zimmermann DR, Huder JB, et al. Detection of mycobacteria and chlamydiae in granulomatous inflammation of reptiles: a retrospective study. Vet Pathol. 2004;41(4)388-97., ⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.].

Mycobacterium infection has been reported in reptiles and attributed to several species such as M. avium, M. chelonae, M. fortuitum, M. intracellulare, M. marinum, M. phlei, M. smegmatis and M. ulcerans, with a single case of M. tuberculosis complex infection [²2. Soldati G, Lu ZH, Vaughan L, Polkinghorne A, Zimmermann DR, Huder JB, et al. Detection of mycobacteria and chlamydiae in granulomatous inflammation of reptiles: a retrospective study. Vet Pathol. 2004;41(4)388-97., ⁵5. Divers SJ, Mader DR. Reptile Medicine and Surgery. Elsevier Health Sciences. 2005. https://books.google.com.br/books/about/Reptile_Medicine_and_Surgery.html?id=7Ai4BKhi0VUC&redir_esc=y
https://books.google.com.br/books/about/... , ⁶6. Hernandez-Divers SJ, Shearer D. Pulmonary mycobacteriosis caused by Mycobacterium haemophilum and M marinum in a royal python. J Am Vet Med Assoc. 2002;220(11):1661-3.]. Only five cases of Mycobacterium infection have been described in snakes between 1928 and 2002, including the species Boa constrictor, Elaphe quadrivitta and Python regius [⁶6. Hernandez-Divers SJ, Shearer D. Pulmonary mycobacteriosis caused by Mycobacterium haemophilum and M marinum in a royal python. J Am Vet Med Assoc. 2002;220(11):1661-3.–¹⁰10. Quesenberry KE, Jacobson ER, Allen JL, Cooley AJ. Ulcerative Stomatitis and Subcutaneous Granulomas Caused by Mycobacterium-Chelonei in a Boa Constrictor. J Am Vet Med Assoc. 1986;189(9):1131-2.]. Nonetheless, mycobacteriosis transmission has been poorly reported and remains to be fully established in reptiles [⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.]. Cutaneous lesions and/or ingestion may represent the main pathogenic pathways to susceptible and more likely immunosuppressed animals; impaired immune status may be triggered by chronic diseases, stress, poor nutrition and captivity [⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.]. Illness may be accompanied by non-specific signs such as anorexia, lethargy and weight loss, while the main lesions found in snakes with mycobacteria may include skin alteration, stomatitis, and respiratory tract infection in animals with chronic disease [¹¹11. Mitchell MA. Mycobacterial infections in reptiles. Vet Clin North Am Exot Anim Pract. 2012;15(1):101-11. vii., ¹²12. Pasmans F, Blahak S, Martel A, Pantchev N. Introducing reptiles into a captive collection: the role of the veterinarian. Vet J. 2008;175(1):53-68.].

Snakes have become a growing market as pets, sharing household spaces and increasing the owners' risks of bacterial infection. Mycobacterium fortuitum and M. fortuitum-like were isolated from domestic reptiles, ball pythons (Python regius), either in private owners' residences or in pet shops. Pet reptiles, including snakes, can act as possible reservoirs of pathogens and represent a serious public health risk to humans, in particular immune-compromised patients, and other domestic animals. Also, regular cage sanitation and personal hygiene after animal handling are important to avoid pathogen transmission [⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.].

Although individually maintained, captive snakes may share common handling, carrying and food, exposing immunosuppressed native snake species to exotic Mycobacterium spp. infection or vice versa. Regardless, such information may provide important data for future improvement of sanitary conditions and disease prevention among captive snake species worldwide. Accordingly, the aim of this study was to report the occurrence of mycobacteriosis in one exotic and one native snake species at the Sorocaba Zoo, São Paulo state, southeastern Brazil.

Methods

One four-month-old male zoo-born python (Python molurus) and one adult female wild-caught green snake (Philodryas olfersii) kept at Sorocaba Zoo, São Paulo state, Brazil, were presented at the veterinary section with similar clinical signs, including lethargy, mild anorexia and weight loss. Despite immediate and intensive therapy for pneumonia, both snakes died after 2 days and were submitted to necropsy as part of zoo routinely protocol. Prior to these two cases, no other snake in the zoo had shown any clinical sign of death without known cause.

Both snake carcasses were separately kept under refrigeration until individual necropsies were performed at different times to avoid cross-contamination of samples. Representative tissue samples were collected from lung, trachea, heart, kidneys, esophagus, and small intestine, preserved in 10 % neutral buffered formalin, and submitted to histopathological examination. Unstained slides were prepared for prospective evaluation by Ziehl-Neelsen staining and immunohistochemistry (IHC). A careful search for Mycobacterium was performed on all tissue areas with granulomatous inflammation.

Tissues for IHC were sectioned (3-μm thick), deparaffinized, rehydrated, and immersed in 3 % hydrogen peroxide solution in methanol for 20 min. Antigen retrieval was performed by heat treatment in 10 mM citrate buffer, pH 6.0, for the primary antibodies. The sections were digested with proteinase K (25 μg/mL in TE buffer, pH 8.0) for 15 min at 37 °C. Non-specific binding was blocked with 3 % skim milk in phosphate-buffered saline for one hour. The primary antibody utilized was the anti-bacillus Calmette-Guérin (BCG-Mycobacterium bovis) by means of a standard streptavidin-biotin-peroxidase technique. A positive case of human tuberculosis was used as positive control.

Total DNA was isolated from paraffin-embedded samples using a commercial tissue kit (QIAamp DNA FFPE, Qiagen, USA) following the manufacturer's protocol, and stored at −20 °C until processing. All handling, extraction, and amplification procedures were performed in separate laboratories using disposable tips with barrier protection. DNA purity and concentration were obtained using a commercial spectrophotometer (NanoDrop, Thermo Scienfic, USA), in which A260/280 and A260/230 values greater than 1.8 were considered suitable for analysis. The nested PCR (nPCR) was performed using a set of primers to a 16S region of ribosomal RNA of the Mycobacterium genus. The first-round primer sets used in nPCR, amplifying 590 base pairs (bp), were forward 246 (5′-AGAGTTTGATCCTGGCTCAG-3′) and reverse 247 (5′-TTTCACG AACAAGCCCAGAA3′). Second-round primers set (amplifying 455 bp) were forward M1 (5′-AGTGGCGAA CGGGTGAGTAAC-3′) and reverse R7 (5′-TTACG CCC AGTAATTCCGGACAA-3′) [¹³13. Hughes MS, James G, Ball N, Scally M, Malik R, Wigney DI, et al. Identification by 16S rRNA gene analyses of a potential novel mycobacterial species as an etiological agent of canine leproid granuloma syndrome. J Clin Microbiol. 2000;38(3):953-9.]. The nested PCR conditions were performed as previously described [¹⁴14. Oliveira-Filho JP, Monteiro LN, Delfiol DJ, Sequeira JL, Amorim RM, Fabris VE, et al. Mycobacterium DNA detection in liver and skin of a horse with generalized sarcoidosis. J Vet Diagn Invest. 2012;24(3):596–600.].

The PCR products were analyzed by 1.5 % agarose gel electrophoresis and visualized using GelRed™ (Biotium, USA). The molecular weights were estimated by comparison with a known marker (100 bp ladder) and gels documented with a commercial imaging capture system (ImageQuant System, GE Healthcare, USA).

The amplified products were purified using an available commercial kit (Invisorb Fragment CleanUp, Invitrogen, USA). The sequencing reactions were performed with the ABI 3500 Sequence Detection System (Applied Biosystems, USA). The sequences homologies were verified using the software Geneious R6 (Geneious Company, New Zealand).

Results and discussion

Whitish nodules a few millimeters in diameter found in the trachea, lung and liver (Fig. 1), hyperemic intestines and pale kidneys during the python necropsy examination led to suspicion of Mycobacterium spp. infection. Similar whitish, multifocal nodules were observed in the green snake; however, randomly spread only in lung and liver tissue.

Fig. 1
Mycobacteriosis in Python molurus. Liver with whitish, multifocal nodules, randomly spread, indicating a granulomatous inflammatory process

Microscopic examination of python samples revealed pneumonia (Fig. 2) which was characterized by mild heterophilic inflammatory interstitial infiltration and necrotic areas surrounded by heterophils, macrophages and giant cells. Similar lesions were found in the esophagus, trachea and liver. Mild heterophilic inflammatory infiltration was observed in the heart tissue. The green snake presented pneumonia lesions similar to those observed in the python.

Fig. 2
Mycobacteriosis in Python molurus. Lung with innumerous Ziehl-Neelsen-positive bacilli in a necrotic area (magnification 40×)

Due to nonspecific macroscopic lesions observed at necropsy and granulomatous inflammation generally associated with infectious agents resistant to phagocytosis, mycobacterial infection was included in the differential diagnosis. Bacilli, stained positively by Ziehl-Neelsen, suggested the presence of Mycobacterium infection [¹⁵15. LÉCu A, Ball R. Mycobacterial infections in zoo animals: relevance, diagnosis and management*. Int Zoo Yearb. 2011;45(1):183–202.].

Besides the inflammatory alterations and the presence of acid-alcohol-resistant bacilli stained by Ziehl-Neelsen, samples were also positive for Mycobacterium genus on immunohistochemistry. As previously described, both immunohistochemistry and molecular techniques should be used in suspected Mycobacterium cases [¹1. Miller MA. Current Diagnostic Methods for Tuberculosis in Zoo Animals. In: Miller MEFE, editor. Zoo and Wild Animal Medicine. 6th ed. Saint Louis: W.B. Saunders; 2008. p. 10-9.].

Nested PCR followed by DNA sequencing was applied to ascertain the particular mycobacterial species. The amplified product sequences were blasted, resulting in a 100 % match with M. genavense based on Linnaeus Blast tool (Geneious R6 software, Geneious, New Zealand) and NCBI nucleotide Blast. The sequences were submitted to GenBank (KJ614669 and KJ614670).

No ante-mortem test has been considered 100 % reliable for the detection of mycobacteriosis in wild animals, but the presence of Mycobacterium genus in snakes has been reported in live animals [¹1. Miller MA. Current Diagnostic Methods for Tuberculosis in Zoo Animals. In: Miller MEFE, editor. Zoo and Wild Animal Medicine. 6th ed. Saint Louis: W.B. Saunders; 2008. p. 10-9.]. Bacteria of the genus Mycobacterium were isolated in 13/18 (72.2 %) snakes, 13/134 (9.7 %) lizards, and 11/71 (15.5 %) turtles, all clinically healthy animals bred in captivity. Mycobacteria were classified as M. fortuitum (14; 37.8 %), M. fortuitum-like (17; 45.9 %), M. peregrinum (4; 10.8 %), or M. chelonae (1; 10.8 %). M. fortuitum was isolated from seven pythons and M. fortuitum-like from six pythons, demonstrating that clinically healthy animals may harbor and transmit the agent, acting as reservoirs of public health concern to owners, handlers and veterinarians [⁴4. Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.].

The mycobacteriosis infection was first diagnosed by positive Ziehl-Neelsen reaction (Fig. 2). As Nocardia bacterial infection may also be positively stained by Ziehl-Neelsen, immunohistochemistry test based on specific antigen-antibody reaction was used to confirm the presence of mycobacteria [¹⁵15. LÉCu A, Ball R. Mycobacterial infections in zoo animals: relevance, diagnosis and management*. Int Zoo Yearb. 2011;45(1):183–202.].

Mycobacterial infection was confirmed by the histological, histochemical, immunohistochemistry and molecular techniques. After sequencing, bioinformatics tools were able to identify M. genavense as the species implicated in the infection in both cases.

Snakes were kept in individual enclosures with restricted contact with other utensils or environmental sources so that aerosol was considered an unlikely source of transmission. Snakes were regularly fed healthy newborn mice maintained elsewhere, with no historical signs of disease or infection. Enclosure contamination or oral infection has been attributed as the probable source of infection but no consistent evidence was found.

The identification of M. genavense as the etiological agent may serve as a warning for potential zoonotic risk, since immunocompromised people are considered susceptible to infection [¹⁶16. Hoefsloot W, van Ingen J, Peters EJ, Magis-Escurra C, Dekhuijzen PN, Boeree MJ, et al. Mycobacterium genavense in the Netherlands: an opportunistic pathogen in HIV and non-HIV immunocompromised patients. An observational study in 14 cases. Clin Microbiol Infect. 2013;19(5):432–7., ¹⁷17. Rammaert B, Couderc LJ, Rivaud E, Honderlick P, Zucman D, Mamzer MF, et al. Mycobacterium genavense as a cause of subacute pneumonia in patients with severe cellular immunodeficiency. BMC Infect Dis. 2011;11:311.]. More studied should be conducted on mycobacterial infection to establish the role of reptiles as potential reservoirs for human or other animal pathogen transmission.

Conclusions

Since mycobacteriosis is usually a chronic disease with non-specific findings and a complex diagnosis, few reports of mycobacterium infection in reptiles have been reported to date. The combination of immunological and molecular techniques provided general and specific mycobacterial diagnosis, with M. genavense implicated as the causative agent, usually considered an environmental bacterium identified in oral and cutaneous lesions of reptiles.

Funding

This work was supported in part by a State of São Paulo Research Foundation (FAPESP) grant (to LSU). Studies were conducted in partnership with the Sorocaba Zoo, the Federal University of Paraná and the UNESP -Univ Estadual Paulista.

Acknowledgements

We gratefully acknowledge the Sorocaba Zoo staff for their help with the sample collection and storage.

References

¹
Miller MA. Current Diagnostic Methods for Tuberculosis in Zoo Animals. In: Miller MEFE, editor. Zoo and Wild Animal Medicine. 6th ed. Saint Louis: W.B. Saunders; 2008. p. 10-9.
²
Soldati G, Lu ZH, Vaughan L, Polkinghorne A, Zimmermann DR, Huder JB, et al. Detection of mycobacteria and chlamydiae in granulomatous inflammation of reptiles: a retrospective study. Vet Pathol. 2004;41(4)388-97.
³
Dias-Baptista IMF, Usó SMRS, Marcondes-Machado J. Trends in multidrug-resistant tuberculosis. J Venom Anim Toxins incl Trop Dis. 2008;14(2):203-23.
⁴
Ebani VV, Fratini F, Bertelloni F, Cerri D, Tortoli E. Isolation and identification of mycobacteria from captive reptiles. Res Vet Sci. 2012;93(3):1136-8.
⁵
Divers SJ, Mader DR. Reptile Medicine and Surgery. Elsevier Health Sciences. 2005. https://books.google.com.br/books/about/Reptile_Medicine_and_Surgery.html?id=7Ai4BKhi0VUC&redir_esc=y
» https://books.google.com.br/books/about/Reptile_Medicine_and_Surgery.html?id=7Ai4BKhi0VUC&redir_esc=y
⁶
Hernandez-Divers SJ, Shearer D. Pulmonary mycobacteriosis caused by Mycobacterium haemophilum and M marinum in a royal python. J Am Vet Med Assoc. 2002;220(11):1661-3.
⁷
Aronson JD. Spontaneous tuberculosis in snakes: N. Sp. Mycobacterium thamnopheos. J Infect Dis. 1929;44(3):215-23.
⁸
Kiel JL. Reptilian Tuberculosis in a Boa Constrictor. J Zoo Anim Med. 1977;8: 9-11.
⁹
Olsen GH, Hodgin C, Pechman R. Infectious stomatitis associated with Mycobacterium Sp. in a Boa Constrictor. Comp Anim Pract. 1987;8:47-9.
¹⁰
Quesenberry KE, Jacobson ER, Allen JL, Cooley AJ. Ulcerative Stomatitis and Subcutaneous Granulomas Caused by Mycobacterium-Chelonei in a Boa Constrictor. J Am Vet Med Assoc. 1986;189(9):1131-2.
¹¹
Mitchell MA. Mycobacterial infections in reptiles. Vet Clin North Am Exot Anim Pract. 2012;15(1):101-11. vii.
¹²
Pasmans F, Blahak S, Martel A, Pantchev N. Introducing reptiles into a captive collection: the role of the veterinarian. Vet J. 2008;175(1):53-68.
¹³
Hughes MS, James G, Ball N, Scally M, Malik R, Wigney DI, et al. Identification by 16S rRNA gene analyses of a potential novel mycobacterial species as an etiological agent of canine leproid granuloma syndrome. J Clin Microbiol. 2000;38(3):953-9.
¹⁴
Oliveira-Filho JP, Monteiro LN, Delfiol DJ, Sequeira JL, Amorim RM, Fabris VE, et al. Mycobacterium DNA detection in liver and skin of a horse with generalized sarcoidosis. J Vet Diagn Invest. 2012;24(3):596–600.
¹⁵
LÉCu A, Ball R. Mycobacterial infections in zoo animals: relevance, diagnosis and management*. Int Zoo Yearb. 2011;45(1):183–202.
¹⁶
Hoefsloot W, van Ingen J, Peters EJ, Magis-Escurra C, Dekhuijzen PN, Boeree MJ, et al. Mycobacterium genavense in the Netherlands: an opportunistic pathogen in HIV and non-HIV immunocompromised patients. An observational study in 14 cases. Clin Microbiol Infect. 2013;19(5):432–7.
¹⁷
Rammaert B, Couderc LJ, Rivaud E, Honderlick P, Zucman D, Mamzer MF, et al. Mycobacterium genavense as a cause of subacute pneumonia in patients with severe cellular immunodeficiency. BMC Infect Dis. 2011;11:311.

Publication Dates

Publication in this collection
2016

History

Received
03 Feb 2016
Accepted
10 Sept 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution 4.0 international License, which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the creative commons license, and indicate if change were made.

[1] Funding

This work was supported in part by a State of São Paulo Research Foundation (FAPESP) grant (to LSU). Studies were conducted in partnership with the Sorocaba Zoo, the Federal University of Paraná and the UNESP -Univ Estadual Paulista.

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