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Mycobacteria causing human cervical lymphadenitis in pastoral communities in the Karamoja region of Uganda

Published online by Cambridge University Press:  29 June 2007

J. OLOYA
Affiliation:
Department of Veterinary Public Health and Preventive Medicine, Makerere University, Kampala, Uganda Department of Food Safety and Infection Biology, Norwegian School of Veterinary Science, Oslo, Norway
J. OPUDA-ASIBO
Affiliation:
Department of Veterinary Public Health and Preventive Medicine, Makerere University, Kampala, Uganda
R. KAZWALA
Affiliation:
Sokoine University of Agriculture, Morogoro, Tanzania
A. B. DEMELASH
Affiliation:
Department of Epidemiology, Microbiology and Veterinary Public Health, Debub University, Awassa, Ethiopia
E. SKJERVE*
Affiliation:
Department of Food Safety and Infection Biology, Norwegian School of Veterinary Science, Oslo, Norway
A. LUND
Affiliation:
Department of Animal Health, National Veterinary Institute, Oslo, Norway
T. B. JOHANSEN
Affiliation:
Department of Animal Health, National Veterinary Institute, Oslo, Norway
B. DJONNE
Affiliation:
Department of Animal Health, National Veterinary Institute, Oslo, Norway
*
*Author for correspondence: Dr E. Skjerve, The Norwegian School of Veterinary Science, Oslo, Norway. (Email: [email protected])
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Summary

Mycobacteria from lymph node biopsies of patients with cervical lymphadenitis reporting for tuberculosis treatment in Matany and Moroto Hospitals in the transhumant areas of Karamoja, Uganda were isolated and characterized. The AccuProbe® culture identification kits for Mycobacterium tuberculosis complex (MTC), M. avium complex (MAC) and M. avium were used to identify the isolates. Spoligotyping, IS901 PCR and IS1311 and IS1245 restriction fragment length polymorphism (RFLP) were used to characterize the isolates. Of the 43 biopsies, ten M. avium, seven M. tuberculosis, three M. bovis, and two M. intracellulare were isolated. Two isolates could not be identified with AccuProbe® and from 19 samples no mycobacteria could be isolated. Three isolates with the Beijing spoligotype were identified from the seven M. tuberculosis isolates. The spoligopatterns of the M. bovis isolates had previously been detected in cattle in Uganda. Isolation of members of the MAC group reflects the complex interaction between the transhumant communities, water sources and their cattle. None of the M. avium isolates harboured IS901, and all showed several bands on IS1311 and IS1245 RFLP, in accordance with M. avium subsp. hominissuis. Composite dendrograms of IS1311 and IS1245 RFLP showed that the isolates were similar and identical patterns were found. The isolation of M. bovis confirms the human infection with zoonotic mycobacteria in areas where consumption of raw milk and meat is routine. Isolation of environmental mycobacteria also confirms their increasing role in human disease and the occupational risk of infection in the transhumant ecosystem in the absence of safe drinking water and environmental contamination.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2007

INTRODUCTION

Tuberculosis (TB), one of the most widespread infectious diseases, is a leading cause of death from a single infectious agent among adults in the world [Reference De Cock1]. After decades of decline, incidence rates of TB are increasing worldwide. In 2004, 2·6 million (29%) of the 8·9 million cases of worldwide TB reported to the Global Tuberculosis Programme of WHO were from Africa. This figure is considered low because many African countries, especially those with few resources, are unable to report all TB cases because of difficulties in identifying suspected cases, establishing proper diagnostic procedures, and poor recording and reporting systems [Reference Cosivi2].

Surveillance reports on Uganda [3] suggest an increase in TB incidence and decline in case detection rate. In 2004, Uganda ranked 15th in Africa on estimated number of incident cases (all forms), with an incidence of 402/100 000 persons per year and a prevalence of 646/100 000 people respectively. New notification rates of 13 extra-pulmonary TB cases/100 000 persons per year were also reported. While the information on causative agents of human TB in developed countries may be available, the relative contribution of Mycobacterium tuberculosis complex (MTC) and mycobacteria outside the MTC (MOT) to the human mycobacterial syndromes in developing countries, including Uganda, is still scarce. This is attributed to weak laboratory infrastructure and inadequate financial and human resources [3]. As reported, these results were based on smears, and no information was available on the identity of the species of mycobacteria isolated in the patients.

A review of zoonotic TB [Reference Cosivi2] estimates the proportion of human cases due to M. bovis to account for 3·1% of all forms of TB; 2·1% of pulmonary and 9·4% of extra-pulmonary forms. The incidence of mycobacterial cervical lymphadenitis has increased in parallel with the increase in the incidence of mycobacterial infection worldwide and may be a manifestation of a systemic tuberculous disease or a unique clinical entity localized to the neck [Reference Bayazit, Bayazit and Namiduru4]. Bovine tuberculosis (BTB) has been reported in cattle in Karamoja [Reference Oloya5] and M. bovis has been confirmed present in other pastoral areas as well [Reference Acen6]. The impact of high herd level prevalence of BTB in cattle herds in Karamoja region [Reference Oloya5] on the health of transhumant communities continuously in close contact and highly dependent on cattle as source of food has not been investigated, but studies done in similar pastoral communities in the neighbouring Tanzania isolated M. bovis from 21% [Reference Kazwala7] and 10·8% [Reference Mfinanga8] of culture-positive cases of tuberculous cervical lymphadenitis.

Consumption of raw milk, fresh blood and uninspected meat, documented in various studies as routes of M. bovis transmission to humans [Reference de la Rua-Domenech9Reference Ayele11] are traditional practices rampant in pastoral communities. Milk-borne infection is the principal cause of cervical lymphadenopathy (scrofula) and abdominal and other forms of non-pulmonary TB [Reference Acha and Szyfres12]. In the more profoundly immunosuppressed individuals, M. bovis infections tend to be disseminated [Reference van Soolingen13].

Like zoonotic M. bovis, the emergence of MOT as a classical opportunistic or true pathogen in human and animal infections is also becoming increasingly important [Reference Biet14Reference Pavlik17]. In the absence of M. tuberculosis, MOT are increasingly being isolated in HIV-positive patients. M. avium-intracellulare (MAC) have been isolated in 82·8% of non-tuberculous mycobacterial infections [Reference Sakatani18]. Members of MOT are saprophytic and are normal residents in natural waters rich in organic matter [Reference Dailloux19Reference Primm, Lucero and Falkinham22]. Moreover, water has been documented as a source of infection for mycobacteria causing cervical lymphadenitis and disseminated infections in humans [Reference Biet14, Reference Primm, Lucero and Falkinham22Reference Pierre-Audigier24]. In children, one study has shown a predominance of M. scrofulaceum (60%) followed by M. avium (40%) as causes of cervical lymphadenitis [Reference Jindal, Devi and Aggarwal25] while another report [Reference Primm, Lucero and Falkinham26] documented a predominance of MAC to M. scrofulaceum.

The occurrence of BTB in cattle and the existence of suitable biotopes for MOT in the water sources in transhumant or pastoral areas could increase the risk of infection with MTC and MOT to livestock and cervical lymphadenitis syndromes in communities. Against this backdrop, there was a need to investigate the possible impact of zoonotic and environmental mycobacteria in human disease in high-risk transhumant communities of Karamoja, Uganda. The main objective of this study was, therefore, to isolate and characterize the mycobacteria causing cervical lymphadenitis in patients in the transhumant areas of Karamoja, Uganda.

MATERIALS AND METHODS

Collection of samples

Routine lymph node biopsies from 43 human patients with cervical lymphadenitis reporting to the TB units of Moroto and Matany hospitals were aseptically collected and frozen at −20°C. Data on age, sex, occupation and origin were collected for each patient. Samples were transported in cooling boxes containing icepacks to the National Tuberculosis referral laboratory at Wandegeya, Kampala, where they were processed.

Tissue preparation and bacteriological examination

Fat and connective tissue were removed from the samples and about 3–10 g were placed in sterile Stomacher bags containing 30 ml physiological buffered saline and homogenized in a Stomacher machine for 7–10 min. The homogenates were transferred to sterile screw-cap tubes and decontaminated by the NaOH–NALC method [Reference Collins, Grange and Yates27]. After vortexing, the samples were left at room temperature for 15 min. Subsequently 5 ml of sterile 0·067 m phosphate buffer (pH 6·8) was added and the mixture was centrifuged at 3660 g for 15 min. The supernatant was discarded and the sediment was inoculated on Lowenstein–Jensen (Difco Laboratories, Detroit, MI, USA) media with and without pyruvate (0·6%) and incubated at 37°C for 12 weeks. Tubes were read weekly, and typical or suspect colonies were harvested into cryotubes containing 1·5 ml Middlebrook 7H9 media (Difco) and stored at −70°C at the National TB referral laboratory, Uganda. Samples were then transported to the National Veterinary Institute, Oslo and subsequently subcultured on Middlebrook 7H10 and Stonebrink media (Difco).

Identification of mycobacterial isolates

All acid-fast bacteria, determined by the Ziehl–Nielsen (ZN) staining technique, were examined by AccuProbe®Mycobacterium tuberculosis complex (MTC) identification kit (Gen-Probe Inc., San Diego, CA, USA) according to the manufacturer's protocol. Results were considered positive when relative light units (RLU) were >30 000, repeat range 20 000–29 000, and negative <20 000. Samples negative on the MTC kit were examined further on the AccuProbe®M. avium complex (MAC) and AccuProbe®M. avium culture identification kits. Final results were interpreted as follows; cultures positive on the M. avium and MAC culture identification kits were considered as M. avium and cultures negative on the M. avium kit and positive on the MAC kit were identified as M. intracellulare. Samples negative on all AccuProbe® culture identification kits were grouped as unidentified mycobacteria.

Spoligotyping

Cultures belonging to the MTC were submitted for further differentiation by the spoligotyping kit according to the manufacturer's instructions (Isogen, Life Science, The Netherlands). DNA isolation was done according to the protocol for DNA extraction for cell cultures (Qiagen™, Oslo, Norway), and PCR and hybridization were performed as previously described [Reference Kamerbeck28]. Amplified DNA was hybridized to a membrane containing 43 oligonucleotides in a miniblotter (MN45, Immunetics, Cambridge, MA, USA). Bound fragments were revealed by chemiluminescence after incubation with horseradish peroxidase-streptavidin (Boehringer, Mannheim, Germany) for 45 min at 45°C and exposure of the membrane to X-ray film (Hyperfilm, Amersham, Bucks., UK) for 10–12 min. The M. tuberculosis H37Rv and M. bovis BCG were included as controls.

The results were analysed using the BioNumerics program version 3.5 (Applied Maths, Kortrijk, Belgium). The BioNumerics software was used to calculate Dice coefficients of similarity and to cluster the isolates and generate dendrograms by the unweighted-pair group method using average linkage. The optimization and tolerance settings were both set at 2·00%.

Examination by IS1311 and IS1245 restriction fragment length polymorphism (RFLP)

Cultures identified as M. avium were further examined for the insertion sequence IS901 [Reference Johansen29] and characterized by IS1245 and IS1311 RFLP. The DNA extraction, RFLP analysis and interpretation of results were performed as previously described [Reference Johansen29], using the recommended probes for IS1245 and IS1311 RFLP.

RESULTS

The 43 biopsies from patients with lymphadenitis were cultured and different mycobacteria were isolated and characterized M. avium were found in 23·3% (n=10), M. tuberculosis in 16·3% (n=7), M. bovis in 7·0% (n=3) and M. intracellulare in 4·7% (n=2) of the samples. Two isolates (4·8%) were negative on all three AccuProbe® kits, and from 19 samples (45·2%) no mycobacteria could be detected. Patient data and data on mycobacterial isolates are presented in the Table.

Table. Patient occupation, sex, district of origin, age quartile and mycobacteria isolated from human cervical lymphadenitis in Uganda

M.a., M. avium; M.b., M. bovis; M.i., M. intracellulare; M.t., M. tuberculosis; Un., unidentified.

Spoligotyping was performed on 10 isolates positive on the AccuProbe® MTC culture identification test; three isolates were identified as M. bovis (lacking spacers 39–43) and seven as M. tuberculosis (Fig. 1). Four spoligotypes of M. tuberculosis were identified; the Beijing genotype, lacking spacers 1–34, from three patients, one type that lacked spacers 1–24 and 33–36 and two types closely related to M. tuberculosis H37Rv. Two spoligotypes of M. bovis were identified from the three isolates

Fig. 1. A dendrogram showing spoligotypes detected in three Mycobacterium bovis and seven Mycobacterium tuberculosis isolates from human patients with cervical lymphadenitis in Uganda. For M. bovis, only spacers 1–38 are shown.

Nine of the ten M. avium isolates were characterized, the last isolate could not be typed due to culturing problems. None of the isolates harboured the IS901 element, and all but one isolate showed four identical bands on IS1311 RFLP. The last isolate showed five bands. More bands were observed on IS1245 RFLP. The composite dendrograms of IS1311 and IS1245 RFLPs yielded five different profiles (Fig. 2). The lack of IS901 and the multibanded profile observed on IS1311 and IS1245 RLFP were compatible with M. avium subsp. hominissuis [Reference Matlova30].

Fig. 2. A dendrogram showing the IS1311 and IS1245 RFLP of nine Mycobacterium avium isolates from human cervical lymphadenitis in Uganda.

DISCUSSION

The study documented that M. avium, M. tuberculosis and M. bovis caused cervical lymphadenitis in humans in pastoral communities in the Karamoja region of Uganda. To our knowledge, this is the first report of M. avium as an important causative agent of these lesions in regions of Uganda where BTB is present and uncontrolled, a fact that is contrary to the previously held opinion that M. bovis was the most important cause of these infections [Reference Cosivi2]. However, no mycobacteria could be isolated or identified on ZN stain in 45·2% of patients' samples in this study.

M. bovis was the causative agent of cervical lymphadenitis in 12·5% of the cases where mycobacteria could be isolated, in accordance with what has been found in Tanzania [Reference Mfinanga8, Reference Kazwala31]. As documented elsewhere in Africa [Reference Cosivi2], cattle are an integral part of pastoralists' social life. Raw milk, fresh blood and meat form the main diet during transhumance. Ingestion of raw milk is the most probable route of extra-pulmonary M. bovis infections [Reference Cosivi2, Reference Haddad, Masselot and Durand32, Reference Kazwala33], although inhalation of the agent might also lead to infections [Reference Kazwala31, Reference Grange34, Reference Kazwala35]. The fact that M. bovis were detected from nomads aged >25 years might point to their leading roles in herding and privileged access to milk that is usually consumed raw and commonly mixed with cows' urine or fresh blood. M. bovis was not detected in children as reported previously [Reference Wedlock36]. However, the limited sample size might have affected this observation. The occurrence of M. bovis mainly in one district seems to point to the host factor-occupation type risk of transmission; although the limited patient catchment areas of the hospitals might have distorted our results. The two different spoligotypes detected in humans have previously been detected in cattle in Uganda (J. Oloya et al., unpublished observations). The isolation of the same spoligotypes both in cattle (although from another location) and humans suggests cross-species transmission and might reflect the occupational risks that pastoralists face. These spoligotypes have not been detected in other African countries, and comparison of these spoligotypes with those in the database (http://www.mbovis.org) did not show any similarities, indicating that these strains might be unique.

M. tuberculosis was detected in 29·2% of the cases where mycobacteria could be isolated. In Tanzania, M. tuberculosis was found in 41·5% [Reference Mfinanga8] to 70·5% [Reference Kazwala31] of human lymphadenitis cases. The isolation of M. tuberculosis did not seem to be localized to a particular occupation, sex, age or district, indicating its communicability and infectiousness. Four spoligotypes of M. tuberculosis were identified in the seven isolates. One of the spoligotypes (Hu-4 and Hu-5 in Fig. 1) is labelled LAM 3/S in the spoligotyping database SpolDB4, and has been isolated in 118 countries including Kenya [Reference Brudey37], Tanzania [Reference Eldholm38] and Uganda [Reference Niemann39]. This spoligotype is very similar to M. africanum II, the only difference being the presence of spacer 40 which is lacking in M. africanum II. Isolation of the M. tuberculosis Beijing spoligotype from Uganda confirms its widespread nature (a total 3758 isolates identified in 61 countries with highest isolation frequency in the Asian countries) and probably its selective advantage over other TB genotypes [Reference Van Soolingen40]. The two last spoligotypes detected, Hu-6 and Hu-7, have been isolated in six and 26 countries respectively. However, they have not been isolated in the East African region until now.

Isolation of MOT in 58·3% of the cases of cervical lymphadenitis where mycobacteria could be isolated corroborates other studies [Reference Jindal, Devi and Aggarwal25, Reference Kazwala31, Reference Kirschner, Parker and Falkinham41]. Although the data are limited, M. avium seems to be a problem in children in pastoral areas as previously reported [Reference Primm, Lucero and Falkinham22, Reference Bayazit, Bayazit and Namiduru42, Reference Vu, Daniel and Quach43]. In some countries, there may be of a shift in the frequency of isolation of previously predominant M. scrofulaceum to bacteria in MAC from children with cervical lymphadenitis [Reference Wolinsky44, Reference Falkinham45]. This shift could be attributed to their low immune status or other immunocompromising infections [Reference Murcia-Aranguren46, Reference Biet47], a not surprising situation in a region where 18·7% of the children are reportedly malnourished [48]. MOT was more often isolated from patients in Moroto district, probably as a result of many patients from within that district seeking medical assistance. Many MOT are found in the environment, where they are able to grow, persist and survive [Reference Falkinham45]. In absence of documented evidence of person-to-person spread of these mycobacteria [Reference Biet14, Reference Carbonne49], biotopes become very important in maintaining human and animal infection. Our earlier studies in pastoral cattle in the same areas detected many avian and doubtful reactors on the tuberculin test [Reference Oloya5], suggesting sensitization to avian tuberculin due to mycobacteria in the environment. The patients were not screened for HIV due to lack of facilities at the health centres, therefore its role can not be ruled out.

The predominance of males in this study may point to the poor social conditions of women in this highly patriarchal community. Women have less access to medical facilities than men due to customary restrictions, poverty, distance to health facilities and insecurity. Transhumant societies rarely assign women major responsibilities for large stock, while males move with the animals from place to place in the dry season in search of water and pastures. An alternative explanation is that men drink water directly from the same stagnant water sources as their animals and wild birds. As documented, water high in organic matter or animal dejections enhances growth of environmental mycobacteria [Reference Kirschner, Parker and Falkinham21, Reference Biet47], and studies have found high MAC numbers correlated with high temperature, low pH, low dissolved oxygen and high soluble zinc [Reference Kirschner, Parker and Falkinham21, Reference Kirschner, Parker and Falkinham41]. These findings show that water in heavily soiled swamps, as seen in the grazing areas of Karamoja, may represent major sources of mycobacterial infections, possibly connected with the higher incidence of human and animal infection in this region. The absence of safe water sources for domestic use is also a health issue in homesteads. On average, the distance to clean water sources is 5 km, often leading to families using rain surface run-off water trapped in open ponds for domestic use. Ponds in communities where 84–90% of homesteads lack toilets [50], could easily get contaminated with organic plant, animal and human matter. MAC has been recovered from water samples from ponds in several countries [Reference Kirschner, Parker and Falkinham21, Reference Falkinham45, Reference Dailloux51, Reference Eaton52], and soil in these ponds could be a natural habitat for MAC where water acts as vehicle for transmission [Reference Falkinham45, Reference Biet47, Reference Dailloux51, Reference Eaton52].

Results from IS1311 RFLP showed only two genotypes, while IS1245 RFLP gave a better separation of strains by generating 9–12 bands in their patterns. This low discriminatory power of IS1311 RFLP correlates well with earlier study [Reference Johansen29]. The different isolates showed similar patterns, and none of the isolates had the RFLP pattern earlier described as the ‘bird pattern’ [Reference Mfinanga8] or as M. avium subsp. avium [Reference Matlova30]. However, the lack of IS901 and the observed multi-banded RFLP patterns were compatible with M. avium subsp. hominissuis [Reference Matlova30], an environmental mycobacteria that has been implicated as a cause of infection in humans [Reference Mijs53]. However, more data on M. avium in humans, animals and the environment in Uganda are necessary in order to further elucidate the importance of this opportunistic pathogen.

In conclusion, this study has given an insight into the mycobacteria causing cervical lymphadenitis in pastoral communities in Uganda. The isolation of M. bovis with the same spoligopatterns from cattle and humans has once more highlighted a need for coordination of veterinary and medical policies geared towards the control of TB in developing countries [Reference Kazwala33]. The isolation of MOT from a high proportion of human cases of lymphadenitis shows the importance of bacterial culture in TB diagnostics. The isolation of the Beijing strain of M. tuberculosis indicates the widespread nature of this strain and potential risk associated with its resistance to drugs. The complexity of human–animal–environment interaction in pastoral production systems poses enormous challenges in control and prevention of mycobacterial pathogens.

ACKNOWLEDGEMENTS

We are grateful to the Norwegian Council for Higher Education (NUFU), Norway, for financial support through the North-South Collaboration between the Norwegian School of Veterinary Science and Makerere University. Also special thanks go to Merete R. Jensen and Vivi Myrann, Section of Bacteriology, National Veterinary Institute of Norway and Dr Francis Adatu-Engwau, Director, and Mr Elisha Hatanga, Supervisor, of the Wandegeya National Tuberculosis and Leprosy Programme (NTLP) Laboratory, Kampala, Uganda.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. De Cock, KM. HIV infection, tuberculosis and World AIDS Day, 2006. International Journal of Tuberculosis and Lung Disease 2006; 10: 1305.Google Scholar
2. Cosivi, O, et al. Zoonotic tuberculosis due to Mycobacterium bovis in developing countries. Emerging Infectious Diseases 1998; 4: 5970.CrossRefGoogle Scholar
3. Anon. Global Tuberculosis Database: country profile on tuberculosis – Uganda. In: Global Project on Anti-Tuberculosis Drug Resistance Surveillance, WHO/IUATLD, 2004.Google Scholar
4. Bayazit, YA, Bayazit, N, Namiduru, M. Mycobacterial cervical lymphadenitis. ORL – Head and Neck Nursing 2004; 66: 275280.Google Scholar
5. Oloya, J, et al. Responses to tuberculin among Zebu cattle in the transhumance regions of Karamoja and Nakasongola district of Uganda. Tropical Animal Health and Production 2006; 38: 275283.Google Scholar
6. Acen, F. Pre- and Post-slaughter diagnosis of tuberculosis in cattle in Kampala abattoir [M.Sc. Thesis Monograph]. Makerere, 1991.Google Scholar
7. Kazwala, RR, et al. Risk factors associated with the occurrence of bovine tuberculosis in cattle in the southern highlands of Tanzania. Veterinary Research Communications 2001; 25: 609614.CrossRefGoogle Scholar
8. Mfinanga, SGM, et al. Mycobacterial adenitis: role of Mycobacterium bovis, non-tuberculous mycobacteria, HIV infection, and risk factors in Arusha, Tanzania. East African Medical Journal 2004; 81: 171178.Google Scholar
9. de la Rua-Domenech, R. Human Mycobacterium bovis infection in the United Kingdom: Incidence, risks, control measures and review of the zoonotic aspects of bovine tuberculosis. Tuberculosis (Edinburgh, Scotland) 2006; 86: 77109.Google Scholar
10. Thoen, C, Lobue, P, de Kantor, I. The importance of Mycobacterium bovis as a zoonosis. Veterinary Microbiology 2006; 112: 339345.CrossRefGoogle Scholar
11. Ayele, WY, et al. Bovine tuberculosis: an old disease but a new threat to Africa. International Journal of Tuberculosis and Lung Disease 2004; 8: 924937.Google Scholar
12. Acha, PN, Szyfres, B. Zoonoses and Communicable Diseases Common to Man and Animals, 2nd edn.Washington: Pan American Health Organization, Pan American Sanitary Bureau, Regional Office of the World Health Organization, 2001.Google Scholar
13. van Soolingen, D, et al. Molecular epidemiology of tuberculosis in the Netherlands: a nationwide study from 1993 through 1997. Journal of Infectious Diseases 1999; 180: 726736.Google Scholar
14. Biet, F, et al. Zoonotic aspects of Mycobacterium bovis and Mycobacterium avium-intracellulare complex (MAC). Veterinary Research 2005; 36: 411436.Google Scholar
15. Falkinham, JO 3rd. Epidemiology of infection by nontuberculous mycobacteria. Clinical Microbiology Reviews 1996; 9: 177215.Google Scholar
16. Falkinham, JO 3rd. Nontuberculous mycobacteria in the environment. Clinical Chest Medicine 2002; 23: 529551.Google Scholar
17. Pavlik, I, et al. Relationship between IS901 in the Mycobacterium avium complex strains isolated from birds, animals, humans, and the environment and virulence for poultry. Clinical and Diagnostic Laboratory Immunology 2000; 7: 212217.Google Scholar
18. Sakatani, M. The non-tuberculous mycobacteriosis. Kekkaku 2005; 80: 2530.Google Scholar
19. Dailloux, M, et al. Water and nontuberculous mycobacteria. Water Research 1999; 33: 22192228.Google Scholar
20. Iivanainen, E, et al. Environmental factors affecting the occurrence of mycobacteria in brook sediments. Journal of Applied Microbiology 1999; 86: 673681.Google Scholar
21. Kirschner, RA, Parker, BC, Falkinham, JO. Humic and fulvic acids stimulate the growth of Mycobacterium avium. FEMS Microbiology Ecology 1999; 30: 327332.Google Scholar
22. Primm, TP, Lucero, CA, Falkinham, JO 3rd. Health impacts of environmental mycobacteria. Clinical Microbiology Reviews 2004; 17: 98106.CrossRefGoogle Scholar
23. Nigg, AP, et al. Recurring disseminated Mycobacterium avium infections in an HIV-negative patient [in German]. Deutsche Medizinische Wochenschrift 2005; 130: 13691372.Google Scholar
24. Pierre-Audigier, C, et al. Age-related prevalence and distribution of nontuberculous mycobacterial species among patients with cystic fibrosis. Journal of Clinical Microbiology 2005; 43: 34673470.Google Scholar
25. Jindal, N, Devi, B, Aggarwal, A. Mycobacterial cervical lymphadenitis in childhood. Indian Journal of Medical Sciences 2003; 57: 1215.Google Scholar
26. Primm, TP, Lucero, CA, Falkinham, JO. Health impacts of environmental mycobacteria. Clinical Microbiology Reviews 2004; 17: 98106.Google Scholar
27. Collins, CH, Grange, JM, Yates, MD. Tuberculosis: Bacteriology, Organization and Practice, 2nd edn.Oxford, UK: Butterworth-Heinemann, 1997.Google Scholar
28. Kamerbeck, J, et al. Simultaneous detection and strain differentiation of Mycobacterium tuberculosis for diagnosis and epidemiology. Journal of Clinical Microbiology 1997; 35: 907914.Google Scholar
29. Johansen, TB, et al. Distribution of IS1311 and IS1245 in Mycobacterium avium subspecies revisited. Journal of Clinical Microbiology 2005; 43: 25002502.Google Scholar
30. Matlova, L, et al. Distribution of Mycobacterium avium complex isolates in tissue samples of pigs fed peat naturally contaminated with mycobacteria as a supplement. Journal of Clinical Microbiology 2005; 43: 12611268.Google Scholar
31. Kazwala, RR, et al. Isolation of Mycobacterium bovis from human cases of cervical adenitis in Tanzania: a cause for concern? International Journal of Tuberculosis and Lung Disease 2001; 5: 8791.Google Scholar
32. Haddad, N, Masselot, M, Durand, B. Molecular differentiation of Mycobacterium bovis isolates. Review of main techniques and applications. Research in Veterinary Science 2004; 76: 118.Google Scholar
33. Kazwala, RR, et al. The molecular epidemiology of Mycobacterium bovis infections in Tanzania. Veterinary Microbiology 2006; 112: 201210.Google Scholar
34. Grange, JM. Mycobacterium bovis infection in human beings. Tuberculosis (Edinburgh) 2001; 81: 7177.Google Scholar
35. Kazwala, RR, et al. Isolation of Mycobacterium species from raw milk of pastoral cattle of the southern highlands of Tanzania. Tropical Animal Health and Production 1998; 30: 233239.Google Scholar
36. Wedlock, DN, et al. Control of Mycobacterium bovis infections and the risk to human populations. Microbes and Infection 2002; 4: 471480.Google Scholar
37. Brudey, K, et al. Mycobacterium tuberculosis complex genetic diversity: mining the fourth international spoligotyping database (SpolDB4) for classification, population genetics and epidemiology. BMC Microbiology 2006; 6: 23.Google Scholar
38. Eldholm, V, et al. A first insight into the genetic diversity of Mycobacterium tuberculosis in Dar es Salaam, Tanzania, assessed by spoligotyping. BMC Microbiology 2006; 6: 76.Google Scholar
39. Niemann, S, et al. Mycobacterium africanum subtype II is associated with two distinct genotypes and is a major cause of human tuberculosis in Kampala, Uganda. Journal of Clinical Microbiology 2002; 40: 33983405.Google Scholar
40. Van Soolingen, D. Molecular epidemiology of tuberculosis and other mycobacterial infections: main methodologies and achievements. Journal of Internal Medicine 2001; 249: 126.Google Scholar
41. Kirschner, RA, Parker, BC, Falkinham, JO. Epidemiology of infection by nontuberculous mycobacteria – Mycobacterium avium, Mycobacterium intracellulare, and mycobacterium scrofulaceum in acid, brown water swamps of the southeastern United-States and their association with environmental variables. American Review of Respiratory Diseases 1992; 145: 271275.Google Scholar
42. Bayazit, YA, Bayazit, N, Namiduru, M. Mycobacterial cervical lymphadenitis. ORL: Journal of Oto-Rhino-Laryngology and its Related Specialties 2004; 66: 275280.Google Scholar
43. Vu, TT, Daniel, SJ, Quach, C. Nontuberculous mycobacteria in children: a changing pattern. Journal of Otolaryngology 2005; 34 (Suppl. 1): S4044.Google Scholar
44. Wolinsky, E. Mycobacterial lymphadenitis in children: a prospective study of 105 nontuberculous cases with long-term follow-up. Clinical Infectious Diseases 1995; 20: 954963.Google Scholar
45. Falkinham, JOI. Epidemiology of infection by nontuberculous mycobacteria. Clinical Microbiology Reviews 1996; 9: 177215.Google Scholar
46. Murcia-Aranguren, IM, et al. Frequency of tuberculous and non-tuberculous mycobacteria in HIV infected patients from Bogota, Colombia. BMC Infectious Diseases 2001; 1(21).Google Scholar
47. Biet, F, et al. Zoonotic aspects of Mycobacterium bovis and Mycobacterium avium-intracellulare complex (MAC). Veterinary Research 2005; 36: 411436.Google Scholar
48. Anon. World Food Programme assists drought hit Karamoja highest malnutrition in Uganda. WFP News Press release, 16 March 2005.Google Scholar
49. Carbonne, A, et al. Mycobacterium avium complex common-source or cross-infection in AIDS patients attending the same day-care facility. Infection Control and Hospital Epidemiology 1998; 19: 784786.Google Scholar
50. Anon. Challenges and Prospects for Poverty Reduction in Northern Uganda: Discussion Paper 5. Kampala, 2002.Google Scholar
51. Dailloux, M, et al. Water and nontuberculous mycobacteria. Water Research 1999; 33: 22192228.CrossRefGoogle Scholar
52. Eaton, T, et al. Isolation and characteristics of Mycobacterium avium complex from water and soil samples in Uganda. Tubercle and Lung Disease 1995; 76: 570574.Google Scholar
53. Mijs, W, et al. Molecular evidence to support a proposal to reserve the designation Mycobacterium avium subsp. avium for bird-type isolates and ‘M. avium subsp. hominissuis’ for the human/porcine type of M. avium. International Journal of Systematic and Evolutionary Microbiology 2002; 52: 15051518.Google Scholar
Figure 0

Table. Patient occupation, sex, district of origin, age quartile and mycobacteria isolated from human cervical lymphadenitis in Uganda

Figure 1

Fig. 1. A dendrogram showing spoligotypes detected in three Mycobacterium bovis and seven Mycobacterium tuberculosis isolates from human patients with cervical lymphadenitis in Uganda. For M. bovis, only spacers 1–38 are shown.

Figure 2

Fig. 2. A dendrogram showing the IS1311 and IS1245 RFLP of nine Mycobacterium avium isolates from human cervical lymphadenitis in Uganda.