KalemaZ_145-151.qxd


INTRODUCTION

Bovine tuberculosis (BTB) caused by Mycobacteri-
um bovis in African buffaloes (Syncerus caffer) in
the Queen Elizabeth National Park (QENP) was first
detected in the early 1960s (Thurlbeck, Butas, Man-
kiewicz & Laws 1965). The first tuberculosis survey

was performed in the QENP buffaloes in 1967. In
this survey BTB was found in 38 % of 64 buffaloes
selected because of poor body condition and 10 %
of 52 buffaloes that were randomly selected (Wood-
ford 1982a). In this study it was concluded that BTB
in the buffaloes had originated from cattle, because
this disease had been documented in cattle close
to or bordering the park and infected buffaloes were
only found in those sectors with a buffalo/cattle
interface. The Maramagambo forest was thought to
have been an adequate barrier to prevent the spread
of BTB into sector A of the park, which is without a
buffalo/cattle interface (Woodford 1982a). It was
also concluded that BTB had spilled over from the
buffaloes into warthogs since 9 % of a sample of 90
warthogs in sectors D and E were found to be pos-
itive (Woodford 1982b). Bovine tuberculosis in the

145

Onderstepoort Journal of Veterinary Research, 72:145–151 (2005)

A preliminary investigation of tuberculosis and
other diseases in African buffalo (Syncerus caffer)
in Queen Elizabeth National Park, Uganda

G. KALEMA-ZIKUSOKA1, R.G. BENGIS2, A.L. MICHEL3 and M.H. WOODFORD4

ABSTRACT

KALEMA-ZIKUSOKA, G., BENGIS, R.G., MICHEL, A.L. & WOODFORD, M.H. 2005. A survey of
tuberculosis and other diseases in African buffalo (Syncerus caffer) in Queen Elizabeth National
Park, Uganda. Onderstepoort Journal of Veterinary Research, 72:145–151

A survey to determine the prevalence of bovine tuberculosis caused by Mycobacterium bovis and
certain other infectious diseases was conducted on 42 free-ranging African buffaloes, (Syncerus caf-
fer) from May to June 1997 in the Queen Elizabeth National Park, Uganda. Using the gamma inter-
feron test, exposure to M. bovis was detected in 21.6 % of the buffaloes. One dead buffalo and an
emaciated warthog (Phacochoerus aethiopicus) that was euthanased, were necropsied; both had
miliary granulomas from which M. bovis was isolated. None of the buffaloes sampled in Sector A of
the park, which has no cattle interface, tested positive for bovine tuberculosis (BTB) exposure. The
prevalence and distribution of BTB does not appear to have changed significantly since the 1960s,
but this may be due to fluxes in the buffalo population. Serological testing for foot-and-mouth dis-
ease (FMD) demonstrated positive exposure of 57.1 % of the buffaloes sampled, with types A, O and
SAT 1–3, which is the first known report of FMD antibodies to A and O types in free ranging African
buffaloes. Foot-and-mouth disease virus types SAT 1 and SAT  3 were isolated from buffalo probang
samples. Two percent of the buffaloes had been exposed to brucellosis. None of the buffaloes tested
had antibodies to rinderpest, leptospirosis or Q fever. 

Keywords: African buffalo, bovine tuberculosis, foot-and-mouth disease, Syncerus caffer

1 Conservation Through Public Health, Plot 39, Babiiha Avenue,
P.O. Box 10950, Kampala, Uganda 

2 Directorate of Animal Health, P.O. Box 12, Skukuza, 1350
South Africa 

3 Onderstepoort Veterinary Institute, Private Bag X05, Onder-
stepoort, 0110 South Africa 

4 IUCN Veterinary Specialist Group

Accepted for publication 31 March 2005—Editor



Kruger National Park (KNP) in South Africa is also
believed to have originated from cattle (De Vos,
Bengis, Kriek, Michel, Keet, Raath & Huchzermeyer
2001; Bengis, Kock & Fischer 2002) and the dis-
ease in buffaloes has subsequently been reported
to have spilled over into lions, leopards, kudus,
baboons and other species (Keet, Kriek, Penrith,
Michel & Huchzermeyer 1996; Bengis 1999; Keet,
Kriek, Bengis, Grobler & Michel 2000; Keet, Kriek,
Bengis & Michel 2001).

In the 1970s and 1980s, a 76.7 % reduction of the
QENP buffalo population occurred as a result of
severe poaching during the civil wars (Eltringham &
Woodford 1973; Anon. 1996). 

This study was initiated to determine whether the re-
duction in buffalo numbers in the 1970s and 1980s
had any effect on the BTB prevalence reported in
the earlier study, which took place in the late 1960s
(Woodford 1982a). In the present study in the buf-
faloes, foot-and-mouth disease (FMD), rinderpest,
brucellosis, leptospirosis and Q fever, which are
important infectious diseases of livestock, were also
investigated.

MATERIALS AND METHODS

Study site

Queen Elizabeth National Park is a protected area
bordering Lakes George and Edward and contains
the Kazinga channel that connects the two lakes
(Fig. 1). The park is unfenced and surrounding
reserves have village enclaves in which there are
cattle. The northern and southern parts are sepa-
rated by the Maramagambo Forest of 320 km2,
which appears to form a barrier for migration of buf-
faloes between the northern and southern sectors
of the park (Woodford 1982a). The northern part is
separated further into sectors B, C, D, E and F (Fig.
2). Sector A is separated from sector B by the
incomplete barrier of the Maramagambo Forest,
sector B is separated from sector C by the complete
barrier of the Kazinga Channel, sector C is sepa-
rated from sector D incompletely by the settlement
at Katwe village and by the crater area. 

Immobilization techniques and sampling
locations

The buffaloes were darted from a four-wheel drive
vehicle using a Daninject dart gun firing 1.5 ml Dan-
inject darts. The anesthetic cocktail contained 7–
8 mg etorphine (Kyron, South Africa) plus 60–70 mg
xylazine (Kyron, South Africa). After sampling, the

sedative effects of the cocktail on the buffaloes were
reversed by the intravenous administration of 14–
18 mg diprenorphine (Kyron, South Africa) and 60–
70 mg yohimbine (Kyron, South Africa), respectively.
Forty-two buffaloes were sampled from 18 different
breeding herds and several bull groups. 

Sampling was randomized in that the first animal in
the herd that offered a clear shot was darted, two to
three animals were sampled in each herd. There
was some bias towards older animals since calves
and yearlings were rarely sampled. Sampled buffa-
lo herds were spatially distributed north and south
of the Kazinga Channel in sectors D and B, respec-
tively, and also from sector A (Ishasha) south of the
Maramagambo Forest. 

Samples

Blood and oesophageal-pharyngeal probang sam-
ples were collected from 42 buffaloes. The blood
was collected from the jugular vein or tail vein in
heparinized and clot tubes. The probang samples
were placed in sterile phosphate buffered saline
(PBS) and stored in liquid nitrogen until further anal-
ysis at the Onderstepoort Veterinary Institute (OVI),
South Africa. Blood in the heparinized tubes was
divided into three 1.5 ml aliquots and each aliquot
was incubated within 8 h of collection in three dif-
ferent reagents. The first aliquot was incubated in
30 µl of bovine tuberculin purified protein derivative
(PPD) (ID-Lelystad, The Netherlands), the second
aliquot in 60 µl of avian tuberculin PPD (ID-Lelystad,
The Netherlands) and the third aliquot in a control
of 30 µl of phosphate buffered saline (PBS) (Onder-
stepoort Veterinary Institute, South Africa) for 20–
28 h. After incubation, plasma was collected in cry-
ovails and stored in liquid nitrogen until further
analysis at the OVI tuberculosis laboratory in South
Africa. 

Gamma interferon (IFN) assay for tuberculosis

The commercially available Bovigam assay (CSL,
Australia) was used according to the manufactur-
er’s instructions for the execution of this test. A
sandwich enzyme-linked immunosorbent assay
(ELISA) was performed as described by Rothel,
Jones, Corner, Cox & Wood (1990). Unbound mate-
rial was removed by washing after incubation. Horse-
radish peroxidase labeled anti-bovine IFN gamma
was added. Unreacted conjugate was removed by
washing after incubation. An enzyme substrate was
added. The rate of conversion of this enzyme sub-
strate was proportional to the amount of bound inter-

146

Tuberculosis and other diseases in African buffalo (Syncerus caffer) in Uganda



feron (IFN)-gamma. The amount of colour develop-
ment was estimated spectrophotometrically after
termination of the reaction.

Test for foot-and-mouth disease 

The oesophageal-pharyngeal probang sample from
each buffalo was prepared for the isolation of FMD
virus by grinding it in a mortar with a pestle and
adding sufficient phosphate buffered saline to make

a 10 % tissue suspension. This was inoculated in
1 ml amounts into ten tubes containing cultures of
primary porcine kidney cells, which were then incu-
bated at 37 °C for 48 h. Cultures were observed
daily for cytopathic effects. Cultures not showing
cytopathic effects after 48 h were incubated for a
further 48 h. Supernatants from affected cultures
were used to type the viral isolate by antigen cap-
ture ELISA using the method described by Roeder
& Le Blanc Smith (1987). 

147

G. KALEMA-ZIKUSOKA et al.

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Serology

A competitive antibody ELISA test and a liquid phase
blocking ELISA test were used to test for exposure
to rinderpest (Anderson, Barrett & Scott 1997) and
FMD (Hamblin, Barnett & Hedger 1986), respective-
ly. An indirect immunofluoresence assay (IFA) (To,
Htwe, Kako, Kim, Yamaguchi, Fukushi & Hirai 1998)
was used to detect antibodies to Coxiella burnetii
(Q fever). 

Serum agglutination (Adesiyun & Cazabon 1996)
and complement fixation tests (Jones, Hendricks &

Berman 1963) were used to detect antibodies to
Brucella abortus. Microscopic agglutination tests
(MAT) and serum neutralization tests as described
by Leighton & Kuiken (2001) were used to deter-
mine exposure to Leptospira serotypes. 

Postmortem examinations

Permission was also obtained to euthanase three
emaciated animals for study. A female warthog, one
buffalo cow and one male baboon were euthanased
using suxamethonium chloride (Scoline, Kyron,

148

Tuberculosis and other diseases in African buffalo (Syncerus caffer) in Uganda

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South Africa). A dead buffalo cow found intact,
which was estimated to have been dead for less
than 12 h, was also necropsied. Samples of lesions
in these animals were collected and frozen for myco-
bacterial culture as described previously (Bengis,
Kriek, Keet, Raath, De Vos & Huchzermeyer 1996)
and additional samples were placed in 10 % formal-
dehyde for histopathological examination at the
OVI. 

RESULTS

All the darted buffaloes were in good bodily condi-
tion with no overt clinical signs of BTB. No ungu-
lates with overt clinical signs suggestive of rinder-
pest were observed in the park during this study.
Buffalo sampling was restricted to sectors A, B and
D because buffalo herds living in the vicinity of
human communities in sectors C and E were diffi-
cult to approach within darting range as a result of
poaching, which occurs on a significant scale. 

Eight (21.6 %) out of 38 buffaloes were positive re-
actors to M. bovis on the gamma IFN test, which
took into consideration M. avium and the positive
control. Four of the samples were not interpretable.
The dead buffalo and the warthog that was euthan-
ased had diffuse miliary granulomas present in many
lymph nodes, liver and lungs from which M. bovis
was isolated. The emaciated buffalo was not suffer-
ing from tuberculosis and the loss of bodily con-
dition was attributable to severe dental attrition. The
emaciated baboon that was euthanased and
necropsied had granulomatous lung lesions, but M.
bovis was not isolated from them. Histopathologi-
cally, the lung lesions were shown to be caused by
a trematode, probably a Paragonimus sp. (Georgi
1985).

The prevalence of FMD antibody was 57.14 %. Pos-
itive animals had antibodies to one or more of the
viral types. Of these positive buffaloes, 83.3 % had
antibodies to SAT 1, 29.2 % to SAT 2, 33.3 % to
SAT 3, 20.8 % to type A and 58.3 % to type O. A
SAT 1 type virus was isolated from two probang
samples, and SAT 3 type virus from another. One
of the 42 buffaloes reacted positive in the serum
agglutination and complement fixation tests for B.
abortus. A second buffalo was a weak positive
reactor in these two tests and was considered sus-
pect. The remaining 40 animals tested negative for
brucellosis. 

All the buffaloes tested were serologically negative
for rinderpest, Q fever and Leptospira serotypes. 

DISCUSSION

When comparing the results of the current BTB sur-
vey with the survey conducted in the 1960s, it is
important to note that the results of the earlier sur-
vey were based on lesions found at post-mortem
examinations and histopathology with culture of a
certain percentage of samples (Woodford 1982a).
Mycobacterium bovis was responsible for 12 out of
14 infections typed from buffaloes and for two out of
six typed from warthogs. Atypical mycobacteria
were responsible for the balance of infections typed
and was thought to be from fish, frogs or birds
(Woodford 1982a, 1982b). Therefore, the 1960 study
results are rough approximations of the actual BTB
prevalence. Recent studies, however, have found
an excellent correlation between necropsy and cul-
ture findings of culled buffaloes and the blood-based
gamma IFN test used in this survey (Grobler, Michel,
De Klerk & Bengis 2002). In both buffalo surveys
conducted in the 1960s and this current one mainly
mature buffaloes were sampled to increase the like-
lihood of detecting infected animals (Bengis 1999,
De Vos et al. 2001). 

The current survey demonstrated that the BTB
prevalence in QENP buffaloes has not changed
significantly over 30 years, and that spillover infec-
tion from buffaloes into warthogs is still occurring.
However, this study did not investigate the possibil-
ity of warthogs being maintenance hosts of BTB.
One of the reasons why the TB prevalence may not
have changed significantly over 30 years is that
extensive poaching of buffaloes and other large
mammals, including elephants, occurred during the
period of Ugandan civil wars in the 1970s and
1980s. The buffalo numbers decreased by 76.7 %,
i.e. from 18 000 to 4 200 (Eltringham & Woodford
1973, Anonymous 1996). If it is assumed that BTB
transmission is density dependent, then this popu-
lation decrease may have reduced the rate of spa-
tial spread of the disease within and between the
buffalo herds. The population has now grown to
over 10 000 animals (Richard Lamprey, personal
communication 2002) and, although the prevalence
appears to have remained the same, it may have
been tracking the population densities, and is now
increasing progressively, as has been reported
from the KNP (De Vos et al. 2001). 

The African buffalo, being a wild bovid with similar
habits to cattle, as well as filling a similar ecological
niche, may be a good indicator species for monitor-
ing certain cattle associated diseases such as BTB
and rinderpest. Cattle, in turn, may be considered
sentinels for detecting certain Afro-endemic dis-

149

G. KALEMA-ZIKUSOKA et al.



eases in buffaloes. Cattle still graze illegally in the
park and use water holes in the interior and the
periphery of QENP, creating a diffuse interface for
them to mix with buffaloes, with the potential of bi-
directional transmission of infectious diseases.
Bovine tuberculosis is a chronic erosive disease,
but because it does not have a high clinical profile
in cattle, it is not considered to be as important in
Uganda as the epidemic viral diseases of ruminant
cattle such as FMD and rinderpest which may cause
severe morbidity and mortality in cattle (Bengis et
al. 2002). 

In Africa, buffaloes are known maintenance hosts of
FMD viral types SAT 1, SAT 2 and SAT 3 (Hedger
1972; Sutmoller, Thomson, Hargreaves, Foggin &
Anderson 2000). The results of this survey show
that the QENP buffaloes are no exception regarding
these types. However, the finding of antibodies to
types A and O was surprising, as this has not been
previously recorded in free-ranging African buffalo
populations (Thomson, Vosloo & Bastos 2003). The
buffalo pharyngeo-oesophageal probang samples,
however, only yielded SAT 1 and SAT 3 types.
There remains a possibility that some of the QENP
buffaloes sampled had cross-reactions to the FMD
A and O types (Vosloo, personal communication
2003). Genome sequencing studies on these buffa-
lo isolates demonstrated that the Uganda SAT 1
buffalo strain from this survey was distinct from
SAT 1 strains of buffaloes in Zambia, Malawi, Nam-
ibia, Zimbabwe, Botswana, Swaziland, KNP and
other parts of South Africa (Thomson et al. 2003). 

Cattle in the village enclaves around QENP suffer
from sporadic FMD outbreaks, almost on a yearly
basis (Joram Tumushabe, personal communication
2002), causing morbidity, and in some instances,
mortality. Molecular epidemiological studies to
characterize the strains infecting the cattle and to
compare them with buffalo strains would help to
identify FMD vaccine candidates, which could be
used to protect these cattle. Cattle and buffalo iso-
lates may possibly even one day yield one of the
Afro-alien types (A, O, C and Asia 1). 

The low prevalence of brucellosis reactors in the
QENP buffaloes could indicate that they are not
maintaining the disease, or possibly have limited
exposure from a low prevalence cattle source. How-
ever, it has been reported that if brucellosis cannot
be maintained in bovidae populations, another Bru-
cella species other than Brucella abortus may be
involved, emphasizing the importance of brucellosis
bacteriology and ruling out contact with other Bru-
cella spp. infected domestic livestock. The preva-

lence of brucellosis in the cattle at the interface
needs to be examined further, because, as with
BTB, brucellosis is also of public health significance
and humans can get infected through consumption
of raw milk. The low prevalence of brucellosis reac-
tors could also be attributed to the lack of sensitivi-
ty of the serum agglutination and complement fixa-
tion tests (CFT) employed in the survey. When the
tests were performed in 1997, the CFT was the
most sensitive test and recommended as the con-
firmatory test for brucellosis. However, a more
recent indirect ELISA test appears to be more sen-
sitive than the CFT (Paweska et al. 2002) and would
be good to use for future surveys. 

The absence of antibodies to rinderpest in the
QENP buffaloes sampled is in agreement with pre-
vious findings. Rinderpest has not been reported
from this part of Uganda since the 1930s (Plowright,
Laws & Rampton 1964). There are also no pub-
lished reports to date of outbreaks of leptospirosis
or Q fever in livestock or humans, even though the
causative organisms are rather ubiquitous in nature.

Unfortunately, buffaloes at the periphery of the park
that were more likely to mix with cattle could not be
sampled in this survey. This area has been subject
to severe poaching and the buffaloes were conse-
quently nervous and difficult to approach with a
vehicle. Follow-up studies are necessary to investi-
gate the prevalence of significant ruminant dis-
eases at this buffalo/livestock interface, and to com-
pare results with cattle that live further away from
the park in order to determine the direction of dis-
ease transmission between these two closely relat-
ed species. Education of cattle keepers and park
staff on the risks of disease transmission between
buffaloes and livestock could potentially reduce the
historical resentment of cattle keepers to not being
allowed to legally graze their animals in this park
since it was gazetted in 1952. 

ACKNOWLEDGEMENTS

We thank the Uganda Wildlife Authority and the
South African National Directorate of Animal Health
for permission and logistical assistance to carry out
this study, the Food and Agricultural Organization,
Care For The Wild, Makerere University Faculty of
Veterinary Medicine (MUK/FVM) and Uganda Gov-
ernment Veterinary Services for funds and logistical
assistance, Dr Eric Edroma (UWA executive direc-
tor), Dr Ludwig Siefert (senior lecturer from MUK/
FVM), Abdullah Latiff (chief park warden of QENP),
Marcello Onen, Tom Friday and Joseph Machati

150

Tuberculosis and other diseases in African buffalo (Syncerus caffer) in Uganda



(field assistants and ranger from QENP) for logisti-
cal and technical assistance, and Dr Suzanne Ken-
nedy-Stoskopf from North Carolina State University
for editorial assistance and comments on the man-
uscript. 

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