Hostname: page-component-78c5997874-t5tsf Total loading time: 0 Render date: 2024-11-10T07:45:08.620Z Has data issue: false hasContentIssue false
  • English
  • Français

Population size and habitat preference of the Vulnerable Bale monkey Chlorocebus djamdjamensis in Odobullu Forest and its distribution across the Bale Mountains, Ethiopia

Published online by Cambridge University Press:  14 October 2010

Addisu Mekonnen ,
Afework Bekele ,
Graham Hemson ,
Eyob Teshome  and
Anagaw Atickem
Addisu Mekonnen*
Affiliation:
Department of Biology, Addis Ababa University, P.O. Box 1176, Addis Ababa, Ethiopia
Afework Bekele
Affiliation:
Department of Biology, Addis Ababa University, P.O. Box 1176, Addis Ababa, Ethiopia
Graham Hemson
Affiliation:
Ethiopian Wolf Conservation Programme, Robe, Ethiopia
Eyob Teshome
Affiliation:
Frankfurt Zoological Society, Robe, Ethiopia
Anagaw Atickem
Affiliation:
Centre for Ecological and Evolutionary Synthesis, University of Oslo, Oslo, Norway
*
*Department of Biology, Addis Ababa University, P.O. Box 1176, Addis Ababa, Ethiopia. E-mail addisumk@yahoo.com
Rights & Permissions [Opens in a new window]

Abstract

The Bale monkey Chlorocebus djamdjamensis is a little-known primate endemic to the south-eastern highlands of Ethiopia. From August 2007 to May 2008 we surveyed to determine the species' habitat preferences and population size in the Odobullu Forest and its range across the Bale Mountains. In Odobullu Forest a total of 136 transects of 1.8–3.0 km were surveyed over a total distance of 280 km. Bale monkey groups were encountered only in bamboo forest, suggesting that the species is a bamboo forest specialist. The density and population size of the Bale monkey in the bamboo forest of Odobullu Forest were estimated to be 121–141 km-2 and 1,718–2,002, respectively. At a larger scale, we assessed the distribution of the Bale monkey in 40% of the bamboo forest across the Bale Mountains within the species’ altitudinal range of 2,400–3,250 m. We identified the areas to be surveyed using a 200 m digital elevation model and a 10-m resolution satellite image. We found the Bale monkey in five areas, three of which are previously unrecorded locations for the species. The Bale monkey is now categorized as Vulnerable on the IUCN Red List, partly based on the results of our surveys. Although extensive, our surveys did not cover all of the species’ potential habitat and further surveys are required across all of the bamboo forest of the Bale Mountains and Sidamo region (the western extension of the Bale Mountains).

Keywords

Bale monkeybambooChlorocebus djamdjamensisdistributionEthiopiahabitat preferenceOdobullu Forestpopulation size
Type
Papers
Information
Oryx , Volume 44 , Issue 4 , October 2010 , pp. 558 - 563
Copyright
Copyright © Fauna & Flora International 2010

Introduction

Savannah monkeys Chlorocebus spp. are the most widely distributed non-human primates in Africa, occurring from Senegal to Ethiopia and southwards to South Africa. Although the taxonomy of savannah monkeys has been the subject of debate (Grubb et al., Reference Grubb, Butynski, Oates, Bearder, Disotell, Groves and Struhsaker2003), Groves (Reference Groves, Wilson and Reeder2005) divides Chlorocebus into six species. The least known and most range-restricted of these is the Bale monkey Chlorocebus djamdjamensis, endemic to the southern Ethiopian highlands.

Other savannah monkeys, such as the grivet Chlorocebus aethiops and vervet monkey Chlorocebus pygerythrus are habitat generalists, inhabiting a wide range of habitat types including savannah, woodland, forest, grassland and riverine and gallery forests (Kingdon, Reference Kingdon1997; Zinner et al., Reference Zinner, Pelaez and Torkler2002; Barrett, Reference Barrett2005). The occurrence of Bale monkeys has been documented in the Bale Mountains National Park, Harenna Forest, Kacha and Rirra areas (Carpaneto & Gippoliti, Reference Carpaneto and Gippoliti1994; Kingdon, Reference Kingdon1997; Butynski et al., in press), and in Odobullu Forest (Butynski et al., in press; Mekonnen et al., Reference Butynski, Atickem, De Jong, Butynski, Kingdon and Kalina2010). In addition, Bale monkeys have been recorded in bamboo forest 23 km north-west of Dodolla and in the Djam-Djam Mountains near Abera, east of Lake Abaya at c. 3,000 m (Carpaneto & Gippoliti, Reference Carpaneto and Gippoliti1994; Butynski et al., in press). However, the distribution of the species has not previously been adequately documented.

The Bale Mountains, which harbour a diverse range of endemic fauna and flora, are part of the Eastern Afromontane Biodiversity Hotspot (Myers et al., Reference Myers, Mittermeier, Mittermeier, Fonseca and Kent2000). Despite this diversity, however, habitat loss and fragmentation are intensifying because of the increasing human population and associated agricultural expansion (Philip et al., 2001; WWF, 2001). The Bale Mountains National Park, which was established in 1970 to conserve the endemic mammals of the region, currently provides limited protection because of lack of law enforcement. Studies of the distribution patterns and habitat preferences of wildlife in this human-modified landscape are thus crucial to focus conservation efforts in the region.

The Bale monkey is one of Africa’s least known primates. At the time of our study it was categorized as Data Deficient on the IUCN Red List but has now been categorized as Vulnerable (Butynski et al., Reference Butynski, Gippoliti, Kingdon and De Jong2008). The combination of the species’ thickly forested mountainous habitat, a tendency to flee rapidly upon encountering humans, and quiet behaviour may explain why no detailed field study of the species has previously been undertaken.

The objectives of the study described here were to determine the population size and habitat preferences of the Bale monkey in one of its known strongholds, Odobullu Forest, and to conduct surveys across the Bale Mountains to document further the species’ distribution.

Study area

The study of habitat preferences and population size was carried out in the 71 km2 Odobullu Forest, south-eastern Ethiopia (Fig. 1). Odobullu Forest is controlled by a private organization, Rift Valley Hunting Safaris. The area is protected from livestock grazing and tree cutting but bamboo harvesting is allowed. Hunting of wildlife is allowed based on quota-managed trophy hunting but hunting of the Bale monkey is not permitted. The topography of the area is mountainous, with cliffs and valleys intersected by streams at altitudes of 2,250–3,022 m. The broader distribution survey was conducted across the Bale Mountains in an area of 5,551 km2 over altitudes of 2,400–3,250 m, in the bamboo forest (Fig. 1).

Fig. 1 The study area in the Bale Mountains, with the five areas of bamboo forest in which we located the Bale monkey Chlorocebus djamdjamensis, and known historical records of the species.

Methods

Habitat classification and vegetation mapping

We classified the vegetation of Odobullu Forest into four types (tree-dominated forest, bamboo forest, bushland and grassland). We used the supervised classification method in Erdas Imagine v. 8.6 (ERDAS, Norcross, USA) to analyse 10-m resolution Spot images of 160 randomly selected locations (Dean & Smith, Reference Dean and Smith2003; Irwin et al., Reference Irwin, Johnson and Wright2005). To calibrate the image we surveyed vegetation composition within a 4 × 5 m quadrat at each of the 160 points, located with a global positioning system (GPS), recording plant species and their frequency, and canopy cover. Quadrats that contained trees > 30 cm diameter at breast height with dominant canopy cover were classified as tree-dominated forest. Quadrats with > 60% cover of Euphorbiaceae (Erythrococca spp.) and/or other shrubs were classified as bushland. Quadrats with > 50% cover of bamboo Arundinaria alpina were classified as bamboo forest. Quadrats with primarily grass species were classified as grassland. Following classification, the areas of each of the four habitat types were calculated using the geographical information system (GIS) ArcGIS v. 9.1 (ESRI, Redlands, USA).

Habitat preference and population estimate

In Odobullu Forest transect sampling (Peres, Reference Peres1999) was used to determine the habitat preference of the Bale monkey and to estimate the species’ population size. Transects were established based on a stratified random sampling approach within each habitat type (Chapman et al., Reference Chapman, Fedigan and Fedigan1988; Plumptre, Reference Plumptre2000; Lacher, Reference Lacher2003). A total of nine transects of 1.8–3.0 km in length were censused in bamboo forest, tree-dominated forest and bushland using both existing and newly established trails. We did not survey grassland because we found that it comprises only 7% of the area and is distributed in many discontinuous patches. Each transect was censused 12–16 times in total, during both the wet (September–October 2007) and dry seasons (December 2007–January 2008). Censuses were conducted on foot by AM and a field assistant, together with villagers who were familiar with the area, from 06.30–06.45 to 10.30–10.45 and 14.00–18.00 (Peres, Reference Peres1999; Timmuck & Vaughan, Reference Timmuck and Vaughan2002) at an average speed of 1 km h-1 in forest and 2 km h-1 in bushland (Wallace et al., 1998; Peres, Reference Peres1999; Chapman et al., Reference Chapman, Gillespie, Skorupa and Struhsaker2000).

When Bale monkeys were encountered the dominant habitat type was noted (Wallace et al., 1998), along with location (with a GPS), group size, distance from observer and sighting angle (Chiarello, Reference Chiarello2000; Fashing & Cords, Reference Fashing and Cords2000; Bennet et al., Reference Bennet, Leonard and Carter2001; Anderson et al., Reference Anderson, Rowcliffe and Cowlishaw2007). Distance was estimated visually by AM, who previously practiced estimating distance, and sighting angle was measured with a compass.

Encounter rates of groups per km were calculated by habitat type (Wallace et al., 1998; Bobadilla & Ferrari, Reference Bobadilla and Ferrari2000), and sightings were summarized as the total number of groups and individuals observed in each habitat type (Anderson et al., Reference Anderson, Rowcliffe and Cowlishaw2007). We estimated density using the animal–observer distance method to the first animal seen (Chapman et al., Reference Chapman, Fedigan and Fedigan1988; Chapman et al., Reference Chapman, Gillespie, Skorupa and Struhsaker2000; Fashing & Cords, Reference Fashing and Cords2000; Marshall et al., Reference Marshall, Lovett and White2008). We created a histogram of all animal–observer distances, in 10-m interval classes (Müller et al., Reference Müller, Velo, Raheliarisoa, Zaramody and Curtis2000). The fall-off distance or maximum reliable sighting distance was determined by applying the 50% cut-off rule, i.e. the point at which sighting frequency decreased by at least 50% from the previous sighting class interval (Fashing & Cords, Reference Fashing and Cords2000; Chapman & Chapman, Reference Chapman and Chapman2002; Teelen, Reference Teelen2007; Weghorst, Reference Weghorst2007). Group sightings lying beyond the fall-off distance were excluded from density estimation (Twinomugisha & Chapman, Reference Twinomugisha and Chapman2006).

Group density was calculated as the total number of groups sighted within the fall-off sighting distance divided by the total transect length multiplied by transect width. Population density was estimated by multiplying group density estimates with the observed mean group size (Rosenbaum et al., Reference Rosenbaum, O’Brien, Kinnaird and Supriatna1998; Fashing & Cords, Reference Fashing and Cords2000). Sightings of solitary individuals were excluded from calculations of group density estimates and encounter rates (Fashing & Cords, Reference Fashing and Cords2000; Worman & Chapman, Reference Worman and Chapman2006). The total population was estimated by multiplying the average group density estimates by the total area of suitable habitat (Chiarello, Reference Chiarello2000).

Distribution across the Bale Mountains

Based on the altitudinal preference of Bale monkeys, (2,400–3,250 m; Mekonnen, Reference Mekonnen2008), the species’ potential range was demarcated using a 200-m digital elevation model in ArcGIS. This area was then classified into three habitat types (agriculture and human settlement, tree-dominated forest and bamboo forest) using a 10-m resolution satellite image with Erdas Imagine (Rappole et al., Reference Rappole, King and Leimgruber2000; Irwin et al., Reference Irwin, Johnson and Wright2005).

Based on the results of the habitat preference survey, the bamboo forest of the Bale Mountains was then surveyed, from east to west, covering c. 40% of the total area of this forest, during January–April 2008. We surveyed by walking along existing paths, besides rivers and on trails that we cut. When Bale monkeys were sighted we noted the location, with a GPS, group size, altitude and habitat type (Lehman, Reference Lehman2004; Isbell & Chism, Reference Isbell and Chism2007). Locations of the species recorded during our surveys and locations obtained from the literature (Butynski et al., in press) were incorporated into ArcGIS to create a map of the species’ distribution (Baumgarten, Reference Baumgarten2006). This survey was supplemented with informal interviews (Iwanaga & Ferrari, Reference Iwanaga and Ferrari2002) of the people who were familiar with, and reside in the vicinity of, the bamboo forest, during which we showed photographs of the Bale monkey.

Results

Tree-dominated forest, bamboo forest and bushland accounted for 56, 20 and 17% of the area of Odobullu Forest, respectively. A total of 136 transect censuses were conducted over a cumulative distance of 280 km in the three habitat types. Bale monkey groups were sighted on 43 occasions, all in bamboo forest (Table 1).

Table 1 Sightings of Bale monkey Chlorocebus djamdjamensis groups along transects in bamboo forest, tree-dominated forest and bushland in Odobullu Forest (Fig. 1).

The mean group size of Bale monkeys encountered along the two transects in bamboo forest was 19.1 ± SD 5.43 (range 13–41). The fall-off distance was 40 m and not significantly different between transects (Mann-Whitney U test, P > 0.05). Of the sightings, 41 were used to estimate density (two were beyond the fall-off distance). The mean group encounter rate was 0.58 ± SD 0.08 km-1, mean group density was 7.0 ± SD 1.3 km-2 (range 6.0–7.8) and mean individual density 132 ± SD 14 km-2 (range 121–141). Based on the range of mean individual density we estimated that the total population size of the Bale monkey in the bamboo forest of Odobullu is 1,718–2,002.

We sighted the Bale monkey in bamboo forest at five localities across the Bale Mountains (Fig. 1), of which Shedem, Woge and Gamma are newly discovered locations for the species. The highest altitude at which we observed the species was 3,200 m, in the Woge area. The Odobullu and Shedem populations were not in the vicinity of villages but rather surrounded by tree-dominated forest in mountainous terrain, whereas the Woge and Gamma populations were within the vicinity of people. In the Shedem population we observed two groups, of c. 18 and 32 each, but local people estimated that > 10 groups occur in the area. In the Woge and Gamma populations group sizes were 15–30 and we estimate that there are > 300 Bale monkeys in each locality.

Discussion

The results of our study suggest that the Bale monkey exclusively inhabits bamboo forest, irrespective of season, and avoids tree-dominated forest and bushland. As with the golden monkey Cercopithecus mitis kandti at Mgahinga Gorilla National Park, Uganda (Twinomugisha & Chapman, Reference Twinomugisha and Chapman2006) the habitat preference of the Bale monkey is almost certainly because of its dietary specialization on bamboo, which accounts for 77% of its diet at Odobullu (Mekonnen, Reference Mekonnen2008; Mekonnen et al., Reference Mekonnen, Bekele, Fashing, Hemson and Atickem2010). The Bale monkey is thus a specialist compared to its close relatives the grivet C. aethiops and vervet C. pygerythrus, both of which are habitat generalists (Kingdon, Reference Kingdon1997; Zinner et al., Reference Zinner, Pelaez and Torkler2002; Barrett, Reference Barrett2005). Species with a narrow ecological niche are particularly susceptible to extinction because of habitat destruction (Yu & Dobson, Reference Yu and Dobson2000; Harcourt, Reference Harcourt2006). The legal harvesting of bamboo by local people for commercial purposes could pose a serious future threat to the Bale monkey, and needs to be either discouraged or closely managed. The survival of the species clearly depends on planning and implementing conservation strategies for the management of the bamboo forest.

Our density estimates depend on the encounter rates and group size, and the method used to estimate transect width (Shah, Reference Shah2003; Weghorst, Reference Weghorst2007). To reduce errors in group size estimation, group sizes were always recounted by the accompanying assistants during transect walks. The maximum reliable sighting distance was used for estimation of transect width, a technique that has proven effective for density estimation in many forested sites (Chapman et al., Reference Chapman, Fedigan and Fedigan1988; Chapman et al., Reference Chapman, Gillespie, Skorupa and Struhsaker2000; Fashing & Cords, Reference Fashing and Cords2000; Shah, Reference Shah2003; Irwin et al., Reference Irwin, Johnson and Wright2005; Marshall et al., Reference Marshall, Lovett and White2008). We therefore believe that our estimate of the total population size of the Bale monkey in the bamboo forest of Odobullu is reasonably accurate.

The density and biomass of many primates are primarily related to food quality and availability (Chapman & Chapman, Reference Chapman and Chapman2002; Fashing et al., Reference Fashing, Dierenfeld and Mowry2007). The relatively high density of Bale monkeys in Odobullu Forest may be related to the high abundance and productivity of their main food source, bamboo (Mekonnen, Reference Mekonnen2008). It is likely, however, that other features, such as soil quality, climate, forest history, competition, predation and disease (Oates et al., Reference Oates, Whitesides, Davies and Mole1990) also influence the density of the Bale monkey at Odobullu.

Surveys in c. 40% of the bamboo forest in the Bale Mountains located the Bale monkey in three new localities. These discoveries suggest that the range of the species is broader than suggested in previous reports (Carpaneto & Gippoliti, Reference Carpaneto and Gippoliti1994; Kingdon, Reference Kingdon1997; Butynski et al., in press). The Bale monkey is now categorized as Vulnerable on the IUCN Red List (Butynski et al., Reference Butynski, Gippoliti, Kingdon and De Jong2008), partly based on the results of our surveys. This is the first time the species has received a designation other than Data Deficient. Although extensive, our surveys did not cover all of the species’ potential habitat and therefore the Vulnerable categorization should remain, pending the results of further surveys, which we plan to conduct, across all the bamboo forest of the Bale Mountains and Sidamo region (the western extension of the Bale Mountains).

Acknowledgements

This research was funded by the Ethiopian Wolf Conservation Programme, Primate Conservation, Inc. and Pittsburgh Zoo and PPG Aquarium. Satellite imagery was provided by FARM-Africa and SOS Sahel Ethiopia. We thank Addis Ababa University (Department of Biology) and Frankfurt Zoological Society for logistical support, the Federal Ethiopian Wildlife Conservation Authority and Oromia Region Wildlife Department for permission to conduct this research, and Peter Fashing, Nga Nguyen, Colin Groves, Tom Butynski and two anonymous reviewers for their helpful comments and for providing access to relevant literature. We are also grateful to our field assistants and camp attendants and to the local villagers across the region.

Biographical sketches

Addisu Mekonnen’s research interests include the ecology, conservation and taxonomy of the Bale monkey and other primates and large mammals. Afework Bekele is working on a wide range of wildlife species in Ethiopia in collaboration with students, in particular in the general area of mammal ecology. Eyob Teshome is working on land-use cover change in the Bale Mountains in relation to wildlife conservation and is also interested in GIS and remote sensing. Graham Hemson is working on the conservation of the Ethiopian wolf and is also interested in the conservation and ecology of carnivores and other wildlife. Anagaw Atickem is working on the ecological genetics of mountain nyala and Bale monkey and is interested in GIS-based ecological studies and the use of population genetics in wildlife research.

References

Anderson, J., Rowcliffe, J.M. & Cowlishaw, G. (2007) The Angola black-and-white colobus (Colobus angolensis palliatus) in Kenya: historical range contraction and current conservation status. American Journal of Primatology, 69, 664680.Google Scholar
Barrett, A.S. (2005) Foraging ecology of the vervet monkey (Chlorocebus aethiops) in mixed lowveld bushveld and sour lowveld bushveld of the Blydeberg Conservancy, Northern Province, South Africa. PhD thesis, University of South Africa, Pretoria, South Africa.Google Scholar
Baumgarten, A. (2006) Distribution and biogeography of central American howling monkey (Alouatta pigra and A. palliata). MSc thesis, Louisiana State University, Baton Rouge, USA.Google Scholar
Bennet, C.L., Leonard, S. & Carter, S. (2001) Abundance, diversity and patterns of distributions of primates on the Tapiche River in Amazonian Peru. American Journal of Primatology, 54, 119126.Google Scholar
Bobadilla, U.L. & Ferrari, S.F. (2000) Habitat use by Chiropotes satanas utahicki and syntopic Platyrrhines in Eastern Amazonia. American Journal of Primatology, 50, 215224.Google Scholar
Butynski, T.M., Atickem, A. & De Jong, Y.A. (in press) Bale monkey (Chlorocebus djamdjamensis). In The Mammals of Africa. Vol. 2. Primates (eds Butynski, T.M., Kingdon, J.S. & Kalina, J.). Academic Press, Amsterdam, The Netherlands.Google Scholar
Butynski, T.M., Gippoliti, S., Kingdon, J. & De Jong, Y. (2008) Chlorocebus djamdjamensis. In IUCN Red List of Threatened Species v. 2009.1. Http://www.iucnredlist.org [accessed 19 September 2009].Google Scholar
Carpaneto, G.M. & Gippoliti, S. (1994) Primates of the Harenna Forest, Ethiopia. Primate Conservation, 11, 1214.Google Scholar
Chapman, C.A. & Chapman, L.J. (2002) Foraging challenges of red colobus monkeys: influence of nutrients and secondary compounds. Comparative Biochemistry and Physiology, 133, 861875.Google Scholar
Chapman, C.A., Fedigan, L.M. & Fedigan, L. (1988) A comparison of transect methods of estimating population densities of Costa Rican primates. Brenesia, 30, 6780.Google Scholar
Chapman, C.A., Gillespie, T.R., Skorupa, J.P. & Struhsaker, T.T. (2000) Long term effect of logging on African primate communities: a 28-year comparison from Kibale National Park, Uganda. Conservation Biology, 14, 208216.Google Scholar
Chiarello, A.G. (2000) Density and population size of mammals in remnants of Brazilian Atlantic Forest. Conservation Biology, 14, 16491657.Google Scholar
Dean, A.M. & Smith, G.M. (2003) An evaluation of per-parcel land cover mapping using maximum likelihood class probabilities. International Journal of Remote Sensing, 24, 29052920.Google Scholar
Fashing, P.J. & Cords, M. (2000) Diurnal primate densities and biomass in the Kakamega Forest: an evaluation of census methods and a comparison with other forests. American Journal of Primatology, 50, 139152.Google Scholar
Fashing, P.J., Dierenfeld, E.S. & Mowry, C.B. (2007) Influence of plant and soil chemistry on food selection, ranging patterns and biomass of Colobus guereza in Kakamega Forest, Kenya. International Journal of Primatology, 28, 673703.Google Scholar
Groves, C.P. (2005) Order Primates. In Mammal Species of the World. A Taxonomic and Geographic Reference, 3rd edition (eds Wilson, D.E. & Reeder, D.M.), pp. 111184. Johns Hopkins University Press, Baltimore, USA.Google Scholar
Grubb, P., Butynski, T.M., Oates, J.F., Bearder, S.K., Disotell, T.R., Groves, C.P. & Struhsaker, T.T. (2003) Assessment of the diversity of African primates. International Journal of Primatology, 24, 13011357.Google Scholar
Harcourt, A.H. (2006) Rarity in the tropics: biogeography and macroecology of the primates. Journal of Biogeography, 33, 20772087.Google Scholar
Irwin, M.T., Johnson, S.E. & Wright, P.C. (2005) The state of lemur conservation in south-eastern Madagascar: population and habitat assessments for diurnal and cathemeral lemurs using surveys, satellite imagery and GIS. Oryx, 39, 204218.Google Scholar
Isbell, L.A. & Chism, J. (2007) Distribution and abundance of patas monkeys (Erythrocebus patas) in Laikipia, Kenya, 1979–2004. American Journal of Primatology, 69, 12231235.Google Scholar
Iwanaga, S. & Ferrari, S.F. (2002) Geographic distribution and abundance of woolly (Lagothrix cana) and spider (Ateles chamek) monkeys in southwestern Brazilian Amazonia. American Journal of Primatology, 56, 5764.Google Scholar
Kingdon, J. (1997) The Kingdon Field Guide to African Mammals. Academic Press, London, UK.Google Scholar
Lacher, T.E. (2003) Tropical Ecology, Assessment and Monitoring (TEAM) Initiative: Primate Monitoring Protocol. Unpublished Report to the Center for Applied Biodiversity Science, Conservation International, Washington, DC, USA.Google Scholar
Lehman, S.M. (2004) Distribution and diversity of primates in Guyana: species-area relationships and riverine barriers. International Journal of Primatology, 25, 7395.Google Scholar
Marshall, A.R., Lovett, J.C. & White, P.C.L. (2008) Selection of line-transect method for estimating the density of group-living animals: lessons from the primates. American Journal of Primatology, 70, 111.CrossRefGoogle Scholar
Mekonnen, A. (2008) Distribution of the Bale monkey (Chlorocebus djamdjamensis) in the Bale Mountains and its ecology in the Odobullu Forest, Ethiopia—a study of habitat preference, population size, feeding behaviour, activity and ranging patterns. MSc thesis, Addis Ababa University, Addis Ababa, Ethiopia.Google Scholar
Mekonnen, A., Bekele, A., Fashing, P.J., Hemson, G. & Atickem, A. (2010) Diet, activity patterns, and ranging ecology of the Bale monkey (Chlorocebus djamdjamensis) in Odobullu Forest, Ethiopia. International Journal of Primatology, 31, 339362.Google Scholar
Müller, P., Velo, A., Raheliarisoa, E., Zaramody, A. & Curtis, D.J. (2000) Surveys of sympatric lemurs at Anjamena, north-west Madagascar. African Journal of Ecology, 38, 248257.Google Scholar
Myers, N., Mittermeier, R.A., Mittermeier, C.G., Fonseca, da G.A.B. & Kent, J. (2000) Biodiversity hotspots for conservation priorities. Nature, 403, 853858.Google Scholar
Oates, J.F., Whitesides, G.H., Davies, A.G. & Mole, S. (1990) Determinants of variation in tropical forest primate biomass: new evidence from West Africa. Ecology, 71, 328343.Google Scholar
Peres, C.A. (1999) General guidelines for standardizing line-transect surveys of tropical forest primates. Neotropical Primates, 7, 1116.CrossRefGoogle Scholar
Plumptre, A.J. (2000) Monitoring mammal populations with line transect techniques in African forests. Journal of Applied Ecology, 37, 356368.Google Scholar
Rappole, J.H., King, D.I. & Leimgruber, P. (2000) Winter habitat and distribution of the endangered golden-cheeked warbler (Dendroica chrysoparia). Animal Conservation, 2, 4559.Google Scholar
Rosenbaum, B., O’Brien, T.G., Kinnaird, M. & Supriatna, J. (1998) Population densities of Sulawesi crested black macaques (Macaca nigra) on Bacan and Sulawesi, Indonesia: effects of habitat disturbance and hunting. American Journal of Primatology, 44, 89106.Google Scholar
Shah, N.F. (2003) Foraging strategies in the two sympatric mangabey species (Cercocebus agilis and Lophocebus albigena). PhD thesis, Stony Brook University, Stony Brook, USA.Google Scholar
Stephens, P.A., Candy, A.d’Sa, Sillero-Zubiri, C. & Leader-Williams, N. (2001) Impact of livestock and settlement on the large mammalian wildlife on Bale Mountains National Park, southern Ethiopia. Biological Conservation, 100, 307322.Google Scholar
Teelen, S. (2007) Primate abundance along five transect lines at Ngogo, Kibale National Park, Uganda. American Journal of Primatology, 69, 10301044.Google Scholar
Timmuck, J. & Vaughan, C. (2002) A census of mammal populations in Punta Leona Private Wildlife Refuge, Costa Rica. Revista de Biologia Tropical, 50, 112.Google Scholar
Twinomugisha, D. & Chapman, C.A. (2006) Golden monkey populations decline despite improved protection in Mgahinga Gorilla National Park, Uganda. African Journal of Ecology, 45, 220224.Google Scholar
Weghorst, J.A. (2007) High population density of black-handed spider monkeys (Ateles geoffroyi) in Costa Rican lowland wet forest. Primates, 48, 108116.Google Scholar
Worman, C.O. & Chapman, C.A. (2006) Densities of two frugivorous primates with respect to forest and fragment tree species composition and fruit availability. International Journal of Primatology, 27, 203225.Google Scholar
WWF (2001) Ethiopian Montane Grasslands and Woodlands. Http://www.worldwildlife.org/wildworld/profiles/terrestrial/at/at1007_full.html [accessed 4 June 2008].Google Scholar
Yu, J. & Dobson, F. (2000) Seven forms of rarity in mammals. Journal of Biogeography, 27, 131139.Google Scholar
Zinner, D., Pelaez, F. & Torkler, F. (2002) Distribution and habitat of grivet monkeys (Cercopithecus aethiops aethiops) in eastern and central Eritrea. African Journal of Ecology, 40, 151158.Google Scholar
Figure 0

Fig. 1 The study area in the Bale Mountains, with the five areas of bamboo forest in which we located the Bale monkey Chlorocebus djamdjamensis, and known historical records of the species.

Figure 1

Table 1 Sightings of Bale monkey Chlorocebus djamdjamensis groups along transects in bamboo forest, tree-dominated forest and bushland in Odobullu Forest (Fig. 1).