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Human–carnivore conflict over livestock in the eastern part of the Serengeti ecosystem, with a particular focus on the African wild dog Lycaon pictus

Published online by Cambridge University Press:  30 January 2014

R. D. Lyamuya
Affiliation:
Department of Biology, Norwegian University of Science and Technology, Realfagbygget, NO-7491 Trondheim, Norway.
E. H. Masenga
Affiliation:
Tanzania Wildlife Research Institute, Arusha, Tanzania
R. D. Fyumagwa
Affiliation:
Tanzania Wildlife Research Institute, Arusha, Tanzania
E. Røskaft*
Affiliation:
Department of Biology, Norwegian University of Science and Technology, Realfagbygget, NO-7491 Trondheim, Norway.
*
(Corresponding author) E-mail [email protected]
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Abstract

During 2007–2009 we conducted a survey of attacks by wild carnivores on the livestock of the Maasai and Sonjo tribes in the eastern Serengeti ecosystem of northern Tanzania. Local enumerators systematically recorded incidents of carnivore predation on livestock and their data were quantified by us, with the aid of District Game Officers or trusted local people. The annual rate of attack by African wild dogs Lycaon pictus was significantly higher (1.42 animals per 1,000 livestock) in the Sonjo tribal area than in the Maasai tribal area (0.72 animals per 1,000 livestock). In the Maasai tribal area there was a significant amount of predation by leopards Panthera pardus and spotted hyaenas Crocuta crocuta. In both tribal areas sheep Ovis aries and goats Capra aegagrus hircus were subject to predation more frequently than cattle. Attacks on livestock by wild dogs occurred most frequently in the afternoon and evening, whereas other carnivores generally attacked livestock at night. Sheep and goats were most frequently attacked by most carnivores during the long rainy season. Cattle Bos primigenius were most frequently attacked by wild dogs and leopards during the long dry season and by lions Panthera leo during the long rainy season, whereas spotted hyaenas killed cattle most frequently during the short rainy season.

Type
Papers
Copyright
Copyright © Fauna & Flora International 2014 

Introduction

Human–carnivore conflict over livestock presents a challenge for both wildlife conservationists and farmers (Diamond, Reference Diamond1997; Chen et al., Reference Chen, Baxter, Muir, Groenen and Schook2007; Kissui, Reference Kissui2008; Driscoll et al., Reference Driscoll, Macdonald and Brien2009). It is a global problem (Ciucci & Boitani, Reference Ciucci and Boitani1998; Røskaft et al., Reference Røskaft, Bjerke, Kaltenborn, Linnell and Andersen2003, Reference Røskaft, Händel, Bjerke and Kaltenborn2007; Treves & Karanth, Reference Treves and Karanth2003; Rodney & Rinchen, Reference Rodney and Rinchen2004; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005) and the decline of many large wild carnivore species is at least partly attributable to revenge killing as a result of predation on livestock (Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005). The African wild dog Lycaon pictus is one of the species that has declined because of such conflicts (Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005). It has disappeared from much of its former range (Rasmussen, Reference Rasmussen1999) and there are only c. 8,000 individuals remaining in the wild (Swarner, Reference Swarner2004; Masenga & Mentzel, Reference Masenga and Mentzel2005; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005).

Wild dogs were declared locally extinct in the Serengeti National Park in 1991 (Gascoyne et al., Reference Gascoyne, King, Laurenson, Borner, Schildger and Barrat1993; Creel et al., Reference Creel, Creel and Monfort1997; Stearns & Stearns, Reference Stearns and Stearns1999; Carbone et al., Reference Carbone, Frame, Frame, Malcolm, Fanshawe and Fitzgibbon2005). However, c. eight packs of wild dogs were reported in the Park during 2008–2009. These packs, with fewer than 100 adults in total, inhabited the north-eastern part of the ecosystem (Masenga, Reference Masenga2011). Attacks on livestock by wild dogs have been reported in this area since 2000, when packs began to reappear there (Masenga & Mentzel, Reference Masenga and Mentzel2005).

Wild dogs have been reported to prey on livestock near human communities (Rasmussen, Reference Rasmussen1999; Swarner, Reference Swarner2004). Experience in East Africa shows that conflict between humans and wild dogs occurs in human-dominated landscapes when the contact between wild dogs and livestock increases (Thomas, Reference Thomas2000; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005). In southern Africa most conflict with wild dogs occurs outside protected areas; e.g. on communal lands and outside fenced areas (Lindsey et al., Reference Lindsey, Alexander, Du Toit and Mills2005). Other large carnivore species also come into conflict with humans as a result of habitat loss caused by human population growth (Kolowski & Holekamp, Reference Kolowski and Holekamp2006; Kissui, Reference Kissui2008). The aim of this study was to assess the patterns of attack related to such conflict, and their magnitude, in the eastern part of the Serengeti ecosystem. We focused on the African wild dog and, for comparison, on other large carnivore species in the area (lions Panthera leo, leopards Panthera pardus, spotted hyaenas Crocuta crocuta, striped hyaenas Hyaena hyaena and cheetahs Acinonyx jubatus).

Study area

The study was conducted in the eastern part of the Serengeti ecosystem, which covers the Loliondo Game Controlled Area and a small portion of the Ngorongoro Conservation Area (Fig. 1). The Maasai and Sonjo tribes inhabit these areas. The Maasai are nomadic pastoralists and live near the Serengeti National Park. The Sonjo are agro-pastoralists and live in permanent settlements some distance from the Park (Fig. 1; Maddox, Reference Maddox2003; Masenga & Mentzel, Reference Masenga and Mentzel2005).

Fig. 1. The location of the two study areas, Loliondo and Ngorongoro, in the north-east of the Serengeti National Park, Tanzania. The rectangle on the inset shows the location of the Serengeti ecosystem in Africa.

The Loliondo Game Controlled Area is located in the Maasai ancestral lands in the northern part of Tanzania and covers c. 4,500 km2. It is a multiple land-use area and forms the eastern boundary of the Serengeti ecosystem (Fig. 1). The human population increases gradually from south to north, with the highest densities found around Wasso, the town of Loliondo and the area near the Kenyan border. In the south the human population mainly comprises nomadic Maasai, who inhabit the area at a low density. The density of resident wild herbivores in the area is also low, as a result of overgrazing and trophy hunting (Holdo et al., Reference Holdo, Galvin, Knapp, Polasky, Hilborn and Holt2010). Rainfall is bimodal, with peaks in December and April and an annual total of 400–1,200 mm (Jaeger, Reference Jaeger1982; Maddox, Reference Maddox2003; Masenga & Mentzel, Reference Masenga and Mentzel2005). The area is dominated by open woodland and grassland (Sinclair et al., Reference Sinclair, Mduma and Arcese2002). Open woodland is mostly found in the northern part of the area on rolling hills, interspersed with rocky outcrops. In the central part there are mountains with steep slopes and densely vegetated gullies. The open areas in the lowlands are either cultivated land or open woodlands (Sinclair et al., Reference Sinclair, Mduma and Arcese2002). The southern part of the area includes short grasslands (Masenga & Mentzel, Reference Masenga and Mentzel2005).

Methods

Data collection

Between July 2007 and June 2009 information on carnivore attacks on livestock was gathered by eight enumerators trained to collect data for wildlife research. Prior to training the enumerators we informed them, and all local people, that there was no compensation scheme for livestock losses to predators in mainland Tanzania. This information was supplied to ensure that the livestock keepers provided valid responses to the management authority. The enumerators were educated at least to primary level and were chosen randomly from local communities, and based on interviews to evaluate their knowledge and research skills. Before beginning the fieldwork the enumerators received training from us, including instruction on the use of a global positioning system unit and on the completion of the standard form developed to record incidences of carnivore conflict. The form was divided into three sections: herder information, carnivore species involved in the attack, and information on the livestock attacked (goats, sheep, cattle or donkeys Equus africanus asinus). The enumerators were also trained to ensure that information was collected as soon as possible and not more than 24 hours after an attack. We normally visited villages on a monthly basis. With the aid of village officers or other trusted members of the community we revisited all bomas where incidences of conflict had been reported by enumerators. We used a checklist of carnivore species to cross-check the information reported by the enumerators. Data that were considered incorrect were rejected. We also followed ground tracks of wild dogs attacking livestock and recorded all sightings of wild dogs. The enumerators used photographic ID to identify the packs responsible for attacks in the region, identifying eight packs in total, six in the Maasai tribal area and two in the Sonjo tribal area. In total 591 incidences of human–carnivore conflict were recorded and confirmed. In addition, secondary data were obtained from the employees of the wildlife department, community representatives and people with experience of conflicts with carnivores. These data included the total number of livestock and the number of households in the area, based on census data from 2008–2009. The livestock population included 246,786 sheep and goats and 149,614 cattle. The Maasai tribe owned 318,209 animals and the Sonjo tribe owned 78,191 animals, giving a total livestock population of 396,400.

Data analyses

The data on carnivore predation on livestock were summarized and analysed using SPSS v.17 (SPSS, Chicago, USA). We performed nonparametric tests for all analyses. The carnivore species responsible for livestock loss were wild dogs, lions, spotted hyaenas, striped hyaenas, leopards and cheetahs (Table 1). Hereafter, we refer to two groups of prey: sheep and goats, and cattle. Few donkeys were attacked, and therefore we excluded them from our analysis. All statistical tests were two-tailed and the significance level was set at P ⩽ 0.05.

Table 1 Number of attacks by carnivores on livestock on the Maasai and Sonjo tribal lands (Fig. 1) in the eastern Serengeti ecosystem during 2007–2009.

Results

Livestock attacks by carnivores

African wild dogs were the most common livestock predator in both tribal areas, responsible for 47.8% of attacks on livestock in the Maasai tribal area and 99.1% of attacks in the Sonjo tribal area (Table 1). Approximately 20% of the attacks in the Maasai tribal area were carried out by leopards and spotted hyaenas, compared to 0.9% (hyaenas) in the Sonjo tribal area. Lions were responsible for 5.8% of attacks in the Maasai tribal area, where cheetahs and striped hyaenas were together responsible for a further 5.8% of attacks (Table 1). There was a significant difference in the frequency of attacks by the different carnivores between the two areas (χ2 = 97.8, df = 8, P < 0.001; Table 1). The annual rate of attack per 1,000 livestock differed between the two tribes. The Maasai tribe lost 0.72 animals per 1,000 per year, whereas the Sonjo lost 1.42 animals per 1,000 per year. This difference was highly significant (χ2 = 100.5, df = 1, P < 0.001). Although the absolute number of attacks by wild dogs was higher in the Maasai tribal area, the rate of attack was significantly higher in the Sonjo tribal area. The rate of attack by other carnivores (combined) was significantly higher in the Maasai tribal area (0.81 per 1,000 livestock per year) than in the Sonjo tribal area (0.01 per 1,000 livestock per year; χ2 = 97.8, df = 1, P < 0.001).

Most attacks on cattle, sheep and goats were by African wild dogs, although they killed more sheep and goats than cattle. Leopards and spotted hyaenas were also reported to kill more sheep and goats than cattle (18.3% and 16.7%, respectively; Table 2), whereas lions were the only carnivore species that killed more cattle than sheep and goats (Table 2). The rates of predation on sheep and goats and on cattle differed significantly between the different carnivore species (χ2 = 155.9, P < 0.0001; Table 2). Striped hyaenas and cheetahs killed only sheep and goats (Table 2).

Table 2 Total number of attacks by carnivores on cattle Bos primigenius and on sheep Ovis aries and goats Capra aegagrus hircus in the two study areas (Fig. 1) during 2007–2009.

* The total numbers are higher than the sum of cattle, sheep and goats because they include donkeys.

The rates of attack on sheep and goats differed significantly between the two tribal areas (χ2 = 93.9, df = 8, P < 0.001; Table 2). African wild dogs were responsible for all of the attacks on sheep and goats in the Sonjo tribal area but only 38% of the killings in the Maasai tribal area (Table 2). Lions were responsible for 31.3% of the attacks on cattle in the Maasai tribal area but did not kill any cattle in the Sonjo tribal area (Table 2).

A similar (but not statistically significant) difference between the two tribal areas was found for the rates of attacks on cattle, with lions responsible for 31.3% of the attacks on cattle in the Maasai area (Wilcoxon W, z = −1.101, df = 2, P = 0.271; Table 2; leopards, hyaenas and other carnivores were pooled).

Season

Attacks occurred during all seasons of the year. Attacks on sheep and goats by most predators were significantly more frequent during the long rainy season (χ2 = 112.1, df = 8, P < 0.001), whereas most cattle were killed by wild dogs during the long rainy season and by lions and leopards during the dry season (χ2 = 26.95, df = 6, P < 0.001; Table 3). Striped hyaenas killed sheep and goats during the short rainy season (November–December), whereas cheetahs killed sheep and goats during the long rainy season (March–May; Table 3). Spotted hyaenas killed cattle most frequently during the short rainy season (Table 3).

Table 3 Total number of attacks by carnivores on cattle and on sheep and goats in the two study areas (Fig. 1) in different seasons during 2007–2009.

Time of day

Carnivore attacks were reported to occur at any time during the day or night. The patterns of attacks differed significantly between species, depending on the time of day (sheep, goats and cattle pooled; χ2 = 249.1, P < 0.001; Table 4). Attacks by wild dogs were reported to occur primarily in the evening (87.2% for cattle and 41.8% for sheep and goats; Table 4). However, most other carnivores attacked sheep and goats most frequently during the late evening and night (Table 4). Cattle were only killed by spotted hyaenas during the night but were killed by all carnivores during the day (Table 4). Very few attacks by other carnivores occurred during the early morning.

Table 4 The percentage of attacks that occurred at different times of the day, by wild dogs, lions, leopards, hyaenas and other carnivores on sheep and goats and on cattle in the north-eastern Serengeti ecosystem (Fig. 1) during 2007–2009.

Discussion

Incidences of attack by wild dogs and other carnivores

African wild dogs are probably the most serious predator in both the Maasai and Sonjo tribal areas following their reappearance in the eastern part of the Serengeti National Park (Marsden et al., Reference Marsden, Wayne and Mable2012). As a result of their large home range and their social lifestyle African wild dogs can consume large amounts of food relative to other carnivores (Rasmussen, Reference Rasmussen1999; Creel & Creel, Reference Creel and Creel2002). Woodroffe et al. (Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005) pointed out that wild dogs attack more sheep and goats in northern Kenya and our findings are consistent with this.

Wildlife population densities tend to be lower outside the Serengeti National Park than inside the Park and to decrease with increasing distance from the Park (Setsaas et al., Reference Setsaas, Holmern, Mwakalebe, Stokke and Røskaft2007), because of legal and illegal hunting, human encroachment and human activities in general (Holmern et al., Reference Holmern, Nyahongo and Røskaft2007; Nyahongo & Røskaft, Reference Nyahongo, Røskaft and Kaswamila2011). Normally, the densities and behaviour of wild dogs are negatively affected by the presence of other carnivore species in the Serengeti National Park (Estes & Goddard, Reference Estes and Goddard1967). Lions may directly cause pup mortality in wild dogs (Creel & Creel, Reference Creel and Creel1996), and spotted hyaenas follow wild dogs hunting and steal their kills (Estes & Goddard, Reference Estes and Goddard1967; Creel & Creel, Reference Creel and Creel1996; Carbone et al., Reference Carbone, Du Toit and Gordon1997, Reference Carbone, Frame, Frame, Malcolm, Fanshawe and Fitzgibbon2005). For these reasons wild dogs are normally found in areas with low densities of other carnivores (Creel & Creel, Reference Creel and Creel1996; Vucetich & Creel, Reference Vucetich and Creel1999). The relative absence of other carnivore species is probably the main reason that wild dogs are the most common predator of livestock in this area.

Wild dogs and most of the other carnivores, except lions, preyed more frequently on sheep and goats than on cattle. This is because wild dogs, as well as leopards and both species of hyaenas, prefer medium-sized prey, within a bimodal body mass range of 16–32 kg to 120–140 kg (Estes & Goddard, Reference Estes and Goddard1967; Hayward et al., Reference Hayward, O'Brien, Hofmeyr and Kerley2006; Woodroffe et al., Reference Woodroffe, Frank, Lindsey, Ranah and Romanach2007). They also prefer abundant prey species that have a relatively low probability of injuring the attacking predator (Hayward et al., Reference Hayward, O'Brien, Hofmeyr and Kerley2006). However, lions prefer larger prey, including cattle (Kissui, Reference Kissui2008).

Season

Attacks on sheep and goats by most carnivores are more frequent during the long rainy season, although lions attack cattle more frequently during the long rainy season. The increased frequency of attacks on sheep and goats during the long rainy season is probably because wildebeest Connochaetes taurinus have migrated to the plains in the Ngorongoro area, south of the normal range of the wild dogs, in search of high-nutrient pastures (Fig. 1; McNaughton, Reference Mcnaughton1985; Wilmshurst et al., Reference Wilmshurst, Fryxell, Farm, Sinclair and Henschel1999; Maddox, Reference Maddox2003; Musiega & Kazadi, Reference Musiega and Kazadi2004). The livestock remain and are available as prey to the carnivores that continue to hunt in the area.

Wild prey species are abundant on the plains during the long rainy season. Nevertheless, more predation on livestock occurred in our study area during this season. The increase in attacks on livestock is probably associated with the annual calving of the wildebeest, which generally occurs during February and March (Ndibalema, Reference Ndibalema2009). During this period the wildebeest transmit malignant catarrhal fever, which causes many livestock fatalities (Bourn & Blench, Reference Bourn and Blench1999; Fyumagwa, Reference Fyumagwa, Gereta and Røskaft2010). To avoid exposure to this disease the Maasai usually move their animals from areas with favourable pastures on the plains to the highlands and hills but this increases the contact between livestock and wild dogs, which den in these areas (Masenga, unpubl. data). The rate of predation on livestock increases because wild dogs and the other carnivores are forced to prey on livestock if there are few or no wild prey species available (Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005).

Attacks on cattle by wild dogs and leopards were most frequent during the dry season, when livestock herders move into forested mountain regions in search of pasture and water. These new pastures are especially important for cattle, which require more food than sheep and goats. The movement of both predators and livestock to these areas during the dry season increases the probability of contact between livestock and wild dogs.

Time of day

Wild dogs attack livestock at different times of the day compared to other carnivores. These differences are related to the activity patterns of the wild carnivores in the area. For example, lions, spotted hyaenas and leopards are more active during the night, whereas wild dogs are only active during the day (Frank et al., Reference Frank, Woodroffe, Ogada, Woodroffe, Thirgood and Rabinowitz2005).

As a result of these activity patterns wild dogs attacked more livestock during the late afternoon and evening than at any other time of the day. Sheep and goats were attacked more than cattle during this time. The same pattern has been observed by other surveys (Creel & Creel, Reference Creel and Creel2002; Frank et al., Reference Frank, Woodroffe, Ogada, Woodroffe, Thirgood and Rabinowitz2005; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005, Reference Woodroffe, Frank, Lindsey, Ranah and Romanach2007; Fuller & Kat, Reference Fuller and Kat2008). There are reports that wild dogs are usually active from 05.00 onwards (Estes & Goddard, Reference Estes and Goddard1967; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005) but we recorded few attacks on livestock during the early morning. This is because the Maasai and Sonjo tribes do not start to herd their livestock until later in the day, and wild dogs have rarely been found to prey on livestock inside or near bomas (Frank et al., Reference Frank, Woodroffe, Ogada, Woodroffe, Thirgood and Rabinowitz2005; Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005). We found that wild dogs began to prey on livestock from 09.00 onwards, when most herders began to take their livestock out to graze. Before 09.00 wild dogs tend to attack wild prey rather than livestock (Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005). After 09.00 they switch to livestock if they have been unsuccessful in hunting wild animals. Such prey switching has been found to increase in the study area and elsewhere from 10.00 onwards, reaching a peak at c. 16.00 (Woodroffe et al., Reference Woodroffe, Lindsey, Romanach, Stein and Ranah2005).

Conclusions

We conclude that losses of livestock to wild dogs and other carnivores are not critical in the study area. The approximate annual rate of loss is one animal per 1,000 livestock. However, every animal has a cultural and sentimental value to the Maasai and Sonjo tribes. For this reason any occurrence of predation causes a great outcry. We therefore recommend that the intensity of herding should be increased at all times, especially during the afternoon and evening as well as during seasonally sensitive periods.

Acknowledgements

We acknowledge the Tanzania Wildlife Research Institute and Frankfurt Zoological Society, both of which provided financial support and helped with field equipment. We are indebted to the staff of the Serengeti Wildlife Research Centre for their help during data collection, and we thank all those who participated in making this project possible. This work is part of a larger Serengeti Wild Dog Conservation Project financially supported by Frankfurt Zoological Society, Vodacom Tanzania Ltd and Ngorongoro District Council in the Serengeti Ecosystem.

Biographical sketches

R. D. Lyamuya and E. H. Masenga are involved in the Serengeti Wild Dog Conservation Project, monitoring African wild dogs outside the Serengeti National Park in northern Tanzania. R. D. Fyumagwa is a wildlife veterinarian interested in conservation biology and the transmission of diseases. E. Røskaft is interested in a wide range of bird and mammal species in Europe, North America, Asia and Africa, and in human–wildlife conflict over the use of limited land and resources.

References

Bourn, D. & Blench, R. (1999) Can Livestock and Wildlife Co-exist? An Interdisciplinary Approach. Overseas Development Institute, London, UK. Google Scholar
Carbone, C., Du Toit, J.T. & Gordon, I.J. (1997) Feeding success in African wild dogs: does kleptoparasitism by spotted hyaenas influence hunting group size? Journal of Animal Ecology, 66, 318326.CrossRefGoogle Scholar
Carbone, C., Frame, L., Frame, G., Malcolm, J., Fanshawe, J., Fitzgibbon, C. et al. (2005) Feeding success of African wild dogs (Lycaon pictus) in the Serengeti: the effects of group size and kleptoparasitis. Journal of Zoology, 266, 153161.CrossRefGoogle Scholar
Chen, K., Baxter, T., Muir, M.W., Groenen, A.M. & Schook, B.L. (2007) Genetic resources, genome mapping and evolutionary genomics of the pig (Sus scrofa). International Journal of Biological Sciences, 3, 153165.CrossRefGoogle ScholarPubMed
Ciucci, P. & Boitani, L. (1998) Wolf and dog depredation on livestock in central Italy. Wildlife Society Bulletin, 26, 504514.Google Scholar
Creel, S. & Creel, N.M. (1996) Limitation of African wild dogs by competition with large carnivores. Conservation Biology, 10, 526538.CrossRefGoogle Scholar
Creel, S. & Creel, N.M. (2002) The African Wild Dog: Behaviour, Ecology and Conservation. Princeton University Press, Princeton, USA.CrossRefGoogle Scholar
Creel, S., Creel, M.N. & Monfort, S.L. (1997) Radio collaring and stress hormones in African wild dogs. Conservation Biology, 11, 544548.CrossRefGoogle Scholar
Diamond, J. (1997) Guns, Germs and Steel: The Fates of Human Societies. W.W. Norton, New York, USA and London, UK.Google Scholar
Driscoll, A.C., Macdonald, W.D. & Brien, J.S. (2009) From wild animals to domestic pets, an evolutionary view of domestication. Proceedings of the National Academy of Sciences of the United States of America, 106, 99719978.CrossRefGoogle ScholarPubMed
Estes, R.D. & Goddard, J. (1967) Prey selection and hunting behavior of the African wild dog. Journal of Wildlife Management, 31, 5270.CrossRefGoogle Scholar
Frank, L.G., Woodroffe, R. & Ogada, M.O. (2005) People and predators in Laikipia District, Kenya. In People and Wildlife: Conflict or Coexistence? (eds Woodroffe, R., Thirgood, S. & Rabinowitz, A.), pp. 286304. Cambridge University Press, Cambridge, UK.CrossRefGoogle Scholar
Fuller, T.K. & Kat, P.W. (2008) Movements, activity, and prey relationships of African wild dogs (Lycaon pictus) near Aitong, southwestern Kenya. African Journal of Ecology, 28, 330350.CrossRefGoogle Scholar
Fyumagwa, R.D. (2010) Diseases of economic and conservation significance in the livestock–wildlife interface in Tanzania. In Conservation of Natural Resources: Some African & Asian Examples (eds Gereta, E. & Røskaft, E.), pp. 419444. Tapir Academic Press, Trondheim, Norway.Google Scholar
Gascoyne, S.C., King, A.A., Laurenson, M.K., Borner, M., Schildger, B. & Barrat, J. (1993) Aspects of rabies infection and control in the conservation of the African wild dog (Lycaon pictus) in the Serengeti region, Tanzania. Onderstepoort Journal of Veterinary Research, 60, 415420.Google ScholarPubMed
Hayward, M.W., O'Brien, J., Hofmeyr, M. & Kerley, G.I.H. (2006) Prey preferences of the African wild dog Lycaon pictus (Canidae: Carnivora): ecological requirements for conservation. Journal of Mammalogy, 87, 11221131.CrossRefGoogle Scholar
Holdo, R.M., Galvin, K.A., Knapp, E., Polasky, S., Hilborn, R. & Holt, R.D. (2010) Responses to alternative rainfall regimes and antipoaching in a migratory system. Ecological Applications, 20, 381397.CrossRefGoogle Scholar
Holmern, T., Nyahongo, J.W. & Røskaft, E. (2007) Livestock loss caused by predators outside the Serengeti National Park, Tanzania. Biological Conservation, 135, 534542.CrossRefGoogle Scholar
Jaeger, T. (1982) Soils of the Serengeti woodlands, Tanzania. PhD thesis. Agricultural University, Wageningen, Holland.Google Scholar
Kissui, B.M. (2008) Livestock predation by lions, leopards, spotted hyaenas, and their vulnerability to retaliatory killing in the Massai Steppe, Tanzania. Animal Conservation, 11, 422432.CrossRefGoogle Scholar
Kolowski, J.M. & Holekamp, K.E. (2006) Spatial, temporal, and physical characteristics of livestock depredations by large carnivores along a Kenyan reserve border. Biological Conservation, 128, 529541.CrossRefGoogle Scholar
Lindsey, P.A., Alexander, R., Du Toit, J.T. & Mills, M.G.L. (2005) The cost efficiency of wild dog conservation in South Africa. Conservation Biology, 19, 12051214.CrossRefGoogle Scholar
Maddox, T.M. (2003) The ecology of cheetahs and other large carnivores in a pastoralist-dominated buffer zone. PhD thesis. University College, London & Institute of Zoology, London, UK.Google Scholar
Marsden, C.D., Wayne, R.K. & Mable, B.K. (2012) Inferring the ancestry of African wild dogs that returned to the Serengeti-Mara. Conservation Genetics, 13, 525533.CrossRefGoogle Scholar
Masenga, H.E. (2011) Abundance, distribution and conservation threats of African wild dogs (Lycaon pictus) in the Loliondo Game Controlled Area, Tanzania. MSc thesis. Sokoine University of Agriculture, Morogoro, Tanzania.Google Scholar
Masenga, H.E. & Mentzel, C. (2005) Preliminary results from a newly established population of African wild dogs (Lycaon pictus) in the Serengeti–Ngorongoro ecosystem, northern Tanzania. In Proceedings of the 5th Annual Conference of the Tanzanian Wildlife Research Institute. Tanzanian Wildlife Research Institute, Arusha, Tanzania.Google Scholar
Mcnaughton, S.J. (1985) Ecology of a grazing ecosystem: the Serengeti. Ecological Monographs, 55, 259294.CrossRefGoogle Scholar
Musiega, D.E. & Kazadi, S.N. (2004) Simulating the East African wildebeest migration patterns using GIS and remote sensing. African Journal of Ecology, 42, 355362.CrossRefGoogle Scholar
Ndibalema, V.G. (2009) A comparison of sex ratio, birth periods and calf survival among Serengeti wildebeest sub-populations, Tanzania. African Journal of Ecology, 47, 574582.CrossRefGoogle Scholar
Nyahongo, J.W. & Røskaft, E. (2011) Assessment of livestock loss factors in the Western Serengeti, Tanzania. In Sustainable Natural Resources Management (ed. Kaswamila, A.), 155163. InTech, Rijeka, Croatia.Google Scholar
Rasmussen, G.S.A. (1999) Livestock predation by the painted hunting dog Lycaon pictus in a cattle ranching region of Zimbabwe: a case study. Biological Conservation, 88, 133139.CrossRefGoogle Scholar
Rodney, M.J. & Rinchen, W. (2004) A community-based approach to mitigating livestock depredation by snow leopards. Human Dimensions of Wildlife, 9, 307315.Google Scholar
Røskaft, E., Bjerke, T., Kaltenborn, B.P., Linnell, J.D.C. & Andersen, R. (2003) Patterns of self-reported fear towards large carnivores among the Norwegian public. Evolution & Human Behavior, 24, 184198.CrossRefGoogle Scholar
Røskaft, E., Händel, B., Bjerke, T. & Kaltenborn, B.J. (2007) Human attitudes towards large carnivores in Norway. Wildlife Biology, 13, 114.CrossRefGoogle Scholar
Setsaas, T.H., Holmern, T., Mwakalebe, G.G., Stokke, S. & Røskaft, E. (2007) How does human exploitation affect impala populations in protected and partially protected areas?—a case study from the Serengeti ecosystem, Tanzania. Biological Conservation, 136, 563570.CrossRefGoogle Scholar
Sinclair, A.R.E., Mduma, S.A.R. & Arcese, P. (2002) Protected areas as biodiversity benchmarks for human impact: agriculture and the Serengeti avifauna. Proceedings of the Royal Society of London Series B, 269, 24012405.CrossRefGoogle ScholarPubMed
Stearns, P.B. & Stearns, S.C. (1999) Watching, from the Edge of Extinction, Yale University Press, New Haven, USA.Google Scholar
Swarner, M. (2004) Human–carnivore conflict over livestock: the African wild dog in central Botswana. In Breslauer Symposium on Natural Resource Issues in Africa. Center for African Studies, University of California, Berkeley, USA.Google Scholar
Thomas, C.D. (2000) Dispersal and extinction in fragmented landscapes. Proceedings of the Royal Society of London Series B, 267, 139145.CrossRefGoogle ScholarPubMed
Treves, A. & Karanth, K.U. (2003) Human–carnivore conflict and perspectives on carnivore management worldwide. Conservation Biology, 17, 14911499.CrossRefGoogle Scholar
Vucetich, J.A. & Creel, S. (1999) Ecological interactions, social organization, and extinction risk in African wild dogs. Conservation Biology, 13, 11721182.CrossRefGoogle Scholar
Wilmshurst, J.F., Fryxell, J.M., Farm, B.P., Sinclair, A.R.E. & Henschel, C.P. (1999) Spatial distribution of Serengeti wildebeest in relation to resources. Canadian Journal of Zoology, 77, 12231232.CrossRefGoogle Scholar
Woodroffe, R., Frank, L., Lindsey, P., Ranah, M.K.S. & Romanach, S. (2007) Livestock husbandry as a tool for carnivore conservation in Africa's community rangelands: a case-control study. Biodiversity and Conservation, 16, 12451260.CrossRefGoogle Scholar
Woodroffe, R., Lindsey, P., Romanach, S., Stein, A. & Ranah, S.M.K.O. (2005) Livestock predation by endangered African wild dogs (Lycaon pictus) in northern Kenya. Biological Conservation, 124, 225234.CrossRefGoogle Scholar
Figure 0

Fig. 1. The location of the two study areas, Loliondo and Ngorongoro, in the north-east of the Serengeti National Park, Tanzania. The rectangle on the inset shows the location of the Serengeti ecosystem in Africa.

Figure 1

Table 1 Number of attacks by carnivores on livestock on the Maasai and Sonjo tribal lands (Fig. 1) in the eastern Serengeti ecosystem during 2007–2009.

Figure 2

Table 2 Total number of attacks by carnivores on cattle Bos primigenius and on sheep Ovis aries and goats Capra aegagrus hircus in the two study areas (Fig. 1) during 2007–2009.

Figure 3

Table 3 Total number of attacks by carnivores on cattle and on sheep and goats in the two study areas (Fig. 1) in different seasons during 2007–2009.

Figure 4

Table 4 The percentage of attacks that occurred at different times of the day, by wild dogs, lions, leopards, hyaenas and other carnivores on sheep and goats and on cattle in the north-eastern Serengeti ecosystem (Fig. 1) during 2007–2009.