Summary
Populations of baboon (Papio sp.) at geographic and climatic extremes for the genus show a tendency to one-male organization, whereas most baboons live in multimale social groups; this effect has been attributed largely to limitation of food supply, but baboons' complex diet has hindered proper nutritional analyses. To test these optimal-diet explanations of social variation, we quantified intake and used phytochemical analysis of foods to compare the nutrition, during seasonal changes, of two groups of mountain baboons (P. ursinus) living at different altitudes of a continuous grassland habitat. The majority of plant foods were eaten uniquely by one or other group, though their altitudinal separation was only 400 m, and the time budget of feeding choices varied with age-sex class as well as season. Converting to a common currency of nutrients reveals that baboons gained the same yield from a unit time spent foraging (whether this is measured in edible dry weight, or simply protein) in both groups, despite their differing mean altitude, whereas seasonal variation was large and statistically significant. Increased feeding time at the winter “bottleneck” made no effective compensation for the poorer food yields: in late winter there was a minimum for daily nutrient gain at both altitudes. Apparently this population is already at an extreme for the time animals devote to foraging in winter, when they rely on inconspicuous and slow-to-harvest swollen shoot bases and underground plant storage organs. Since an individual's nutrient yield does not vary with altitude, we conclude that socioecological parameters are effectively optimized for feeding. Since contest competition is absent, this adjustment of foraging efficiency is largely through the effect of differential density on scramble competition. Differences in social structure are considered to be a secondray consequence of optimal foraging, mediated through altitudinal variation in either population density or in day range limits.
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References
Allen SE, Grimshaw HM, Parkinson JA, Quarnby C (1974) Chemical analysis of ecological materials. Blackwell Scientific, Oxford
Altmann SA (1974) Baboons, space, time and energy. In: Sussman RW (ed) Primate ecology: problem-oriented field studies. John Wiley, New York, pp 243–280
Altmann SA (1991) Diets of yearling female primates (Papio cynocephalus) predict lifetime fitness. Proc Natl Acad Sci USA 88:420–423
Anderson CM (1982) Baboons below the tropic of Capricorn. J Hum Evol 11:205–217
Anderson CM (1983) Levels of social organization and male-female bonding in the genusPapio. Am J Phys Anthropol 60:15–22
Barton RA (1989) Foraging strategies, diet and competition in olive baboons. Unpublished PhD thesis, University of St Andrews
Barton RA (1992) Allometry of food intake in free-ranging primates. Folia Primatol 58: 56–59
Byrne RW, Whiten A, Henzi SP (1987) One-male groups and intergroup interactions of mountain baboons (Papio ursinus). Int J Primatol 8:615–633
Byrne RW, Whiten A, Henzi SP (1990) Social relationships in mountain baboons: leadership and affiliation in a non-female-bonded monkey. Am J Primatol 20:313–329
Belovski GE (1984) Herbivore optimal foraging: a comparative test of three models. Am Nat 124:97–115
Crook JH, Gartlan JS (1966) Evolution of primate societies. Nature 210: 1200–1203
Dunbar RIM (1988) Primate social systems. Croom Helm, London
Dunbar RIM (1992) Time: a hidden constraint on the behavioral ecology of baboons. Behav Ecol Sociobiol 31:35–49
Gill FB, Wolf LL (1975) Economics of feeding territoriality in the golden-winged sunbird. Ecology 56:333–345
Goering HK, Soest PJ van (1970) Forage fibre analysis: apparatus, reagents, procedures and some applications (US Department of Agriculture Handbook No. 379). ARS, USDA, Washington DC
Henzi SP, Dyson ML, Deenik A (1990) On the relationship between group size and altitude in mountain baboons (Papio ursinus). Int J Primatol 11:319–325
Henzi SP, Byrne RW, Whiten A (1992) Patterns of movement by baboons in the Drakensberg Mountains: Primary responses to the environment. Int J Primatol 13:601–628
Hladik CM (1973) Alimentation et activité d'un groupe de chimpanzés reintroduit en forêt gabonaise. Terre Vie 27:343–413
Hladik CM (1977) A comparative study of the feeding strategies of two sympatric species of leaf monkey:Presbytis senex andPresbytis entellus. In: Clutton-Brock TH (ed) Primate ecology. Academic, London, pp 324–353
Janson CH, Schaik CP van (1988) Recognizing the many faces of food competition in primates: methods. Behaviour 105:165–186
Jarman PJ (1974) The social organisation of antelope in relation to their ecology. Behaviour 48, 21–267
Kacelnik A (1984) Central place foraging in starlings (Sturnus vulgaris). I Patch residence time. J Anim Ecol 53:283–299
Kummer H (1968) Social organization of hamadryas baboons. University of Chicago Press, Chicago
Kummer H (1984) From laboratory to desert and back: a social system of hamadryas baboons. Anim Behav 32:965–971
Milinski M, Heller R (1978) Influence of a predator on the optimal foraging behaviour of sticklebacks (Gasterosteus aculeatus). Nature 275:642–644
Mole S, Waterman PG (1987) A critical analysis of techniques for measuring tannins in ecological studies, I. Techniques for chemically defining tannins. Oecologia 72:137–147
Nishida T, Uehara S (1983) Natural diet of chimpanzees (Pan troglodytes schweinfurthii): long-term record from the Mahale Mountains, Tanzania. Afr Stud Monogr 3:109–130
Norton GW, Rhine RJ, Wyn GW, Wynn RD (1987) Baboon diet: a five-year study of stability and variability in the plant feeding and habitat of Mikumi National Park, Tanzania. Folia Primatol 48:78–120
Peters RH (1983) The ecological implications of body size. Cambridge University Press, Cambridge
Schmid-Hempel P, Kacelnik A, Houston AI (1985) Honeybees maximise efficiency by not filling their crop. Behav Ecol Sociobiol 17:61–66
Scotcher JSB (1982) Interrelations of vegetation and eland (Taurotragus oryx Pallas) in Giant's Castle Game Reserve, Natal. PhD Thesis, Witwatersrand University
Watts DP (1984) Composition and variability of mountain gorilla diets in the Central Virungas. Am J Primatol 7:323–356
Whiten A, Byrne RW, Henzi SP (1987) The behavioural ecology of mountain baboons. Int J Primatol 8:367–388
Whiten A, Byrne RW, Waterman P, Henzi SP, McCulloch FM (1990) Specifying the rules underlying selective foraging in wild mountain baboons,P. ursinus. In: Mello MT de, Whiten A, Byrne RW (eds) Baboons: behaviour and ecology, use and care. Brasilia University Press, Brasilia, pp 5–22
Whiten A, Byrne RW, Barton RA, Waterman PG, Henzi SP (1991) Dietary and foraging strategies of baboons. Philos Trans R Soc London B 334:187–197
Wrangham RW (1979) On the evolution of ape social systems. Soc Sci Inform 18:335–368
Wrangham RW (1980) An ecological model of female-bonded primate groups. Behaviour 75: 262–300
Wrangham RW (1987) The evolution of social structure. In: Smuts BB, Cheney DL, Seyfarth RM, Wrangham RW, Struhsaker TT (eds) Primate societies. Chicago University Press, Chicago, pp 282–296
Wrangham RW, Conklin NL, Chapman CA, Hunt K (1991) The significance of fibrous foods for Kibale Forest chimpanzees. In: Whiten A, Widdowson EM (eds) Foraging strategies and natural diet of monkeys, apes and humans. Clarendon, Oxford, pp 11–18
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Byrne, R.W., Whiten, A., Henzi, S.P. et al. Nutritional constraints on mountain baboons (Papio ursinus): Implications for baboon socioecology. Behav Ecol Sociobiol 33, 233–246 (1993). https://doi.org/10.1007/BF02027120
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DOI: https://doi.org/10.1007/BF02027120