Emerging Infectious Diseases
[Volume 6 No.2 / March - April 2000]

Dispatches

Bovine Tuberculosis and the Endangered Iberian Lynx

Victor Briones* Lucía de Juan,* Celia Sánchez,† Ana-Isabel
Vela,* Margarita Galka,‡ Natalia Montero,* Joaquín Goyache,*
Alicia Aranaz,* Ana Mateos,* and Lucas Domínguez*
*Facultad de Veterinaria, Universidad Complutense de Madrid,
Spain; †Parque Nacional de Doñana, Huelva, Spain; ‡Parque
Natural de Doñana, Huelva, Spain

We report the first case of bovine tuberculosis in a free-living
Iberian lynx (Lynx pardina), an extremely endangered feline, from
Doñana National Park in Spain. The isolate (Mycobacterium bovis)
correlates by molecular characterization with other isolates from
wild ungulates in the park, strongly suggesting an epidemiologic
link. Mycobacterium bovis infects many animal species, with wild
and free-ranging domestic ungulates being the main reservoirs in
nature (1).


Carnivores generally acquire the infection by eating infected food
(2,3), but reports of tuberculosis (TB) in wild carnivores are rare
(2-6). However, TB monitoring in free-living carnivores has
provided increased reports of the disease (7). TB does not pose a
serious threat to most wild carnivore populations but could have a
devastating effect in a small and divided population such as the
Iberian lynx. This species is the most endangered feline in the
world (8), with a declining number of animals living in reduced
and isolated areas in Spain and Portugal.

An adult male Iberian lynx, seen limping in August 1998, died in
October 1998. We could perform only direct and radiologic
examinations of the empty carcass. The right elbow joint was
enlarged, with fistulization. On X-ray, the lesion was diagnosed as
septic arthritis on the basis of radiolucent areas and sclerosis, along
with bony excrescences. A fragment from the right elbow joint, a
small fecal sample, and a nasal swab were collected and routinely
processed for detection of mycobacteria by auramine acid-fast
staining, culture, and polymerase chain reaction (PCR) (9-11).

Auramine staining of a smear from the elbow lesion was performed
by the method of Smithwick (9), and transmission fluorescence
microscopy at x400 showed acid-fast bacilli. Samples were
simultaneously processed for culture following standard
procedures: a suspension was obtained from a nasal swab, and the
other samples were homogenized in sterile distilled water in a
tissue homogenizer. The homogenates and suspension were then
decontaminated with hexadecylpyridinium chloride and
centrifuged, and sediments were inoculated onto Coletsos and
Löwenstein-Jensen media for mycobacteria; they were incubated at
37°C and inspected weekly for growth (10). Colonies were
examined for acid-fast bacilli by the Ziehl-Neelsen technique (9).
Identification procedures were performed as described elsewhere,
by means of direct PCR either on the processed samples or on
isolated colonies (10), and specific mycobacterial molecular
characterization was done by spoligotyping (11). The only positive
sample was the elbow joint: direct PCR was positive for M.
tuberculosis complex. An isolate consisting of acid-fast bacilli on
selective media was identified as M. bovis. Additionally, molecular
characterization by spoligotyping showed that the lynx isolate was
identical to other isolates from samples of wild ungulates living in
the park, including nine wild boars (Sus scrofa) and four fallow
deer (Dama dama) studied during the past 3 years.

Once TB has been confirmed in a free-living lynx, it is important
to determine whether a single animal has been affected or the
infection has spread within the population. From 1993, postmortem
examinations have been performed on 21 lynxes in conditions that
permitted reliable interpretation of pathologic findings. Any
granulomatous lesions found during necropsy, as well as fecal
samples taken regularly from temporarily or permanently captive
animals, were tested by acid-fast staining, direct PCR, and culture.
Radiologic screening has also been performed on captive and live-
captured animals. TB had never been diagnosed in lynxes before
this case. However, because of the insidious nature of the infection,
this case will not be the last; other lynxes could already be infected.
The prevalence of the infection in the species is extremely difficult
to determine because the number of lynxes is low and very few
animals can be monitored, since captures are limited to a
minimum. In addition, rapid, specific, and accurate in vivo
diagnosis of TB in lynxes is difficult. A reliable, rapid technique
for diagnosis is urgently needed to ensure that any captured animal
will be correctly diagnosed and treated.

Another important consideration is the role of wild ungulates and
domestic livestock as reservoirs. Populations of red deer (Cervus
elaphus), fallow deer, and wild boar live in the National Park.
Traditional farming in the area means that many domestic animals
(mainly free-ranging cattle) coexist with wild species. All these
species are susceptible to TB and could act as reservoirs (1).
Carnivore populations are generally considered spill-over hosts that
become incidentally infected and therefore are unlikely to maintain
the disease without an external source of infection (3,6,7). Because
eradication campaigns are conducted in domestic cattle, the
prevalence of bovine TB is low, but cattle are not TB free. Wild
ungulates have been monitored over the last 11 years; a few
isolated cases were detected before 1993, although the number of
cases has increased dramatically in recent years. This observation
may represent a real increase in prevalence or a higher intensity of
surveillance. Therefore, surveys of the prevalence of TB among
wild ungulates in the Park need to be enhanced to allow a more
accurate assessment of the problem. The isolate of M. bovis from
the lynx correlates exactly by spoligotyping with isolates obtained
recently from wild boars and fallow deer living in the same area,
suggesting a common source of infection. As fallow deer are
known to be part of the lynx's diet (12), these results are not
surprising and strongly suggest interspecies infection. However,
since no cultures from cattle are available, the molecular
comparison of strains isolated from wild and domestic animals is
not possible and a potential epidemiologic link among them cannot
be demonstrated. Nevertheless, TB transmission between domestic
cattle and wild ungulates sharing the same pastures has been
described (13). The different patterns of lesions in red and fallow
deer (mainly respiratory) and wild boars (digestive) suggest the
probable routes of infection, but the modes of transmission need to
be elucidated.

Infectious diseases affecting both domestic and wild animals
become a problem for both conservationists and farmers. In this
case, the concern is not only transmission between cattle and wild
ungulates, but transmission to the Iberian lynx, an endangered
species protected by strict conservation policies. Thus, health
requirements for domestic animals entering the park should be
strengthened to prevent TB, and livestock populations must be
managed and controlled, as a total ban seems unfeasible. The role
of lagomorphs in this case is speculative, as TB has not been
diagnosed in these species at the park. Although naturally acquired
TB seems to be extremely rare in rabbits, it is not uncommon in
hares (14). Since these animals are a basic item of the lynx's diet
(12), monitoring TB in lagomorphs must be included in a
prevention program so that a potential source of infection should
not be overlooked.

The detection of bovine TB in an Iberian lynx leads to another
question: what should be done with a free-living lynx with a
positive TB diagnosis? Intraspecies transmission seems quite
unlikely because of the rare contact between lynxes except during
mating season. However, basic rules of animal health dictate that
infected animals should be isolated to interrupt the transmission
cycle of many infectious diseases, including TB.

Anti-TB therapy in animals is controversial, and euthanasia is the
most commonly accepted option. However, the critical situation of
the Iberian lynx, with a declining population of under 1,000, makes
every animal essential. Multidrug, long-term, daily therapy has
been used in domestic cats (2,3), but extrapolating this treatment to
lynxes maintained in captivity would be difficult. Although therapy
must be the choice, adequate facilities and containment and
preventive measures must be in place to ensure that disease will
not spread during treatment. In addition, the likelihood of success
of treatment, which depends on the severity of the disease and the
general condition of the animal, must be evaluated in light of the
well-known collateral effects of antimycobacterial drugs (2,3).
Finally, even if treatment is successful, the animals will probably
not be able to live in the wild again because of possible physical or
behavioral changes.

In conclusion, survival of many species already depends on human
management of populations (15); in this case, every measure must
be adopted to ensure that bovine TB will not threaten the
endangered Iberian lynx. Dr. Briones is associate professor,
Departamento de Sanidad Animal, Facultad de Veterinaria,
Universidad Complutense de Madrid. His responsibilities include
clinical microbiology and infectious diseases (research and
teaching). His research interests focus on bacterial diseases of
wildlife and exotic pets in Spain.

Address for correspondence: Lucas Domínguez, Departamento de
Sanidad Animal, Facultad de Veterinaria, Universidad
Complutense de Madrid, 28040-Madrid, Spain; fax: 34-91- 394-
3908; e-mail: vbriones@eucmax.sim.ucm.es.

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Emerging Infectious Diseases
National Center for Infectious Diseases
Centers for Disease Control and Prevention
Atlanta, GA

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