Dispersal Status Influences Hormones and Behavior in the Male Spotted Hyena

Male spotted hyenas (Crocuta crocuta) reach puberty at 24 months of age and then invariably emigrate from their natal clans 1 to 38 months later. Thus there are two classes of reproductively mature males in everyCrocutaclan: adult natal males born in the clan and adult immigrant males born elsewhere. In one free-living hyena population in Kenya, these two groups of males were compared with respect to measures of aggression, social dominance, sexual behavior, and circulating hormone levels. Adult natal males engaged in higher hourly rates of aggression than did immigrants, won all fights with immigrants, and were socially dominant to immigrants. In addition, adult natal males engaged in far lower hourly rates of sexual behavior with resident females than did immigrants, and natal males were never observed to copulate with natal females. Mean basal plasma cortisol values did not differ between the two groups of adult males, but cortisol concentrations in immigrants were positively correlated with tenure in the clan and with immigrant male social rank. Adult natal males had plasma testosterone levels significantly lower than those of immigrants. Social rank and plasma testosterone values were positively correlated among immigrant males. Thus two different relationships appear to exist between circulating testosterone and social rank in maleCrocuta:one apparent in immigrants and the other in natal adult males. Our results suggest that dispersal might disinhibit testosterone secretion in postpubertal male hyenas.     

Patterns of den occupation by the spotted hyaena (Crocuta crocuta)

Spotted hyaenas utilize isolated natal dens (NDs) and communal dens (CDs) for rearing their cubs. Here we describe patterns of natal and CD occupation by hyaenas belonging to one well‐studied clan in the Maasai Mara National Reserve during a 10‐year period. Locations of 98 den sites that were used as natal or CDs by hyaenas in the study clan were digitized in a Geographic Information System, and the duration of use of each den site, frequency of re‐use, and distances involved in den moves were quantified. Hyaenas moved their CD monthly on average. Most CD sites were occupied only once during the study, but several sites were used repeatedly. On rare occasions, the movement of hyaenas to a new den site could be attributed to a disturbance event at the CD, but factors regularly prompting hyaenas to move to new CD sites were unclear. High‐ranking female hyaenas were more likely to rear their cubs from birth in a CD than low‐ranking females. Low‐ranking females almost always utilized isolated NDs for the first few weeks of a litter's development, and low‐ranking females transferred their cubs over longer distances than did high‐ranking females.     

Parental rank and reproductive success of natal rhesus males

In primates, the relationship between the ranks of parents and those of their sons has not been studied systematically, yet it has important implications for sociobiological theories. The influence of parents' ranks upon the ranks and reproductive success of their sons who remain and breed within their natal group was tested in two captive groups of rhesus macaques, Macaca mulatta. Paternity exclusion analyses revealed that both the rank and reproductive success of natal males were strongly associated with their mothers', but not their fathers', ranks. The ranks of natal males were also significantly correlated with their own reproductive success. However, this correlation was not nearly as strong as the correlation between the ranks and reproductive success of the fathers of these natal males. This difference was associated with a decline in reproductive success, but not in rank, of some founding males after natal males reached sexual maturity, and might result from an age bias in mating and/or the increase in the ratio of adult males to females. Although the reproductive advantage enjoyed by sons of high-ranking mothers prior to dispersal from their natal groups might be of evolutionary significance, it is important to determine whether or not this advantage persists after dispersal.     

Territorial Organization of the White Fronted Bee-eater in Kenya

White fronted bee-eaters (Merops bullockoides) live in extended family clans that aggregate to roost and nest in large colonies. Members of a given clan also share a common foraging territory, spatially segregated from the colony, to which they commute daily. The size of this foraging territory is positively related to clan size. Clan foraging territories are divided into a number of loosely overlapping foraging home ranges (FHRs), each occupied by an individual or mated pair of birds. Bee-eaters feed solitarily, flycatching to snap up large insects from widely dispersed perches. Each bird tolerates intrusion on its FHR by various members of its own clan, but aggressively excludes individuals belonging to other clans. Birds defend only their own FHR; however, because of the high amount of FHR overlap, the result is a loose form of group defense of the larger clan feeding area. For this reason we refer to the system as one of clan foraging territories. Birds occupying clan foraging territories located more than 1.5 to 2 km from a colony temporarily abandoned them while feeding nestlings. At such times, these birds provisioned their young by foraging near the colony. Birds that abandoned territories foraged less efficiently, provisioned nestlings at a lower rate, and had lower breeding success than did birds that continued use of their foraging territories. A model is developed relating territory abandonment to the energetics of central place foraging. Bee-eaters typically shift colony locations between successive breeding seasons. Foraging territory locations, in contrast, remain largely stable, resulting in large and unpredictable changes in the quality of any given foraging territory across years (quality being defined as distance from the currently active nesting colony). When a pair bond forms in bee-eaters, one member typically remains in its natal clan while the other moves into the clan of its partner. At this time, the new pair also establishes its own FHR, generally located within or on the periphery of the clan foraging territory of the natal member. The result of this settlement pattern is that white fronted bee-eaters live their lives spatially surrounded by members of their natal or their matrimonial clan. This, in turn, increases the likelihood of both mutualistic and nepotistic interactions among clan members. Such benefits include shared territory defense, enhanced security against predation, and maintenance of close social bonds with potential helpers. We hypothesize that the adaptive value of clan foraging territories lies in long-term familiarity with a foraging area. Such familiarity was demonstrated to lead to improved foraging efficiency and hypothesized to provide both increased security from predation and a more accurate means of monitoring temporal changes in environmental quality. The system of clan foraging territories found in white fronted bee-eaters differs from the all-purpose group territories of most other cooperative breeders studied to date in two important ways. First, foraging territories were not limiting in the sense of restricting dispersal and “forcing” offspring to remain with their natal clans. Unoccupied areas of seemingly suitable habitat were present throughout the study area at all times. Birds also showed no tendency to expand their boundaries or move into areas vacated when neighboring clans decreased in size or died off. Second, breeding status and foraging territory ownership are not linked in Merops bullockoides. All pairs defended foraging areas, yet only about 3/4 of them bred in any given year. This percentage did not differ significantly between pairs occupying high quality foraging territories (located near the active nesting colony) and pairs forced to abandon low quality foraging territories located more distantly. We conclude that foraging territories are not a critical ecological constraining factor for white fronted bee-eaters in Kenya.     

The Influence of Kinship on Familiar Natal Migrant Rhesus Macaques (Macaca mulatta)

In most primate species, females remain in the natal group with kin while males disperse away from kin around the time of puberty. Philopatric females bias their social behavior toward familiar maternal and paternal kin in several species, but little is known about kin bias in the dispersing sex. Male dispersal is likely to be costly because males encounter an increased risk of predation and death, which might be reduced by dispersing together with kin and/or familiar males (individuals that were born and grew up in same natal group) or into a group containing kin and/or familiar males. Here we studied the influence of kinship on familiar natal migrant rhesus macaques (Macaca mulatta) on Cayo Santiago, Puerto Rico, by combining demographic, behavioral, and genetic data. Our data suggest that kinship influences spatial proximity between recent natal immigrants and males familiar to them. Immigrants were significantly nearer to more closely related familiar males than to more distantly related individuals. Within a familiar subgroup, natal migrants were significantly closer to maternal kin, followed by paternal kin, then non-kin, and finally to males related via both the maternal and paternal line. Spatial proximity between natal immigrants and familiar males did not decrease over time in the new group, suggesting that there is no decline in associations between these individuals within the first months of immigration. Overall, our results might indicate that kinship is important for the dispersing sex, at least during natal dispersal when kin are still available.     

Effects of dispersal status on pituitary and gonadal function in the male spotted hyena

Male spotted hyenas (Crocuta crocuta) reach puberty at 24 months of age and then usually emigrate from their natal clans one to 52 months later. Recent work has shown that reproductive success is very low among adult males still residing in their natal groups, and it is similarly low among recent or "short-term" immigrants. Long-term immigrants father the vast majority of cubs born. Here we inquired whether these differences in reproductive success might be associated with variation among males in pituitary or gonadal function. In one free-living hyena population in Kenya, we compared baseline levels of plasma luteinizing hormone (LH) and testosterone (T) among adult natal males, short-term immigrants, and long-term immigrants, and we also compared their pituitary and gonadal responses to GnRH challenge. Mean basal plasma LH values did not differ among groups, but mean basal T concentrations in long-term immigrants were higher than those in either natal males or short-term immigrants. Similarly, pituitary response to GnRH challenge did not vary significantly among groups, but testicular response to challenge was greater in long-term immigrants than in natal males or short-term immigrants. Thus adult natal and immigrant males exhibited similar pituitary function but testicular function was attenuated among adult males that had not yet left their natal groups and also among males attempting to become established in new social groups. This suggests that, like the act of emigration itself, the process of social integration during immigration may have important physiological consequences for male mammals transferring between groups.     

Male Migration in Barbary Macaques (Macaca sylvanus) at Affenberg Salem

We analyzed male migration during a 20-year period in the free-ranging Barbary macaque population of Affenberg Salem. Most natal migrations occurred around puberty, but only one third of all males left the natal group. Secondary group transfers were rare. All males immediately transferred to other bisexual groups. Migration rates were highest during periods with high adult female/male ratios within social groups. Immigrants highly preferred groups with fewer males of their own age than in the natal group, and many males immigrated into groups that had no male their own age. These groups originated from a skewed distribution of resident males during group fissions. A comparison of emigrants with their natal peers supports the inbreeding avoidance hypothesis as cause of emigration rather than the male competition avoidance hypothesis. Emigrants had no lower individual rank position and did not come from lower-ranking matrilines. Emigrants had more female maternal relatives, especially sisters. Males without female relatives almost never emigrated. Conversely, there is virtually no indication that emigrants were evicted from the natal group. Emigrants had no increased mortality. Paternity data revealed that the reproductive success of emigrants and natal males is similar, indicating that emigration had no reproductive cost. Many similarities between emigrants and natal males that separated from female maternal kin during group fissions suggest that inner migration during fissions is an alternative way to avoid maternal inbreeding. The mating system resulted in a genetic structure within social groups that largely diminished the chances for paternal inbreeding even without recognizing paternal kin.     

Dispersal,inbreeding avoidance and reproductive success in white-footed mice

The dispersion pattern of 360 juvenile white-footed mice, Peromyscus leucopus, from 158 matings was monitored to determine whether dispersal was sufficient to prevent close inbreeding. Dispersal was male-biased with 20% of the daughters remaining in their natal home ranges. Dispersal of sons was not ‘forced’ by adult males, but may have been influenced by the presence of their mothers. One mother-son and five father-daughter pairs had overlapping home ranges during the breeding season, but the maximum number of matings among close relatives was three of 135 (2·2%). Dispersal of juvenile males was sufficient to keep close inbreeding at a minimum. Dispersal did not result from reproductive competition. Pregnant and post-lactating females frequently moved to new home ranges. The reproductive success of immigrants was the same as that of natal residents.     

Unraveling the dispersal patterns and the social drivers of natal emigration of a cooperative breeding mammal,the golden lion tamarin

The study of the social drivers of animal dispersal is key to understanding the evolution of social systems. Among the social drivers of natal emigration, the conspecific attraction, aggressive eviction, and reduced social integration hypotheses predict that sexually mature individuals who receive more aggressive behavior and are engaged in less affiliative interactions are more likely to disperse. Few reports have explored these proximate factors affecting emigration in cooperatively breeding species, particularly of Neotropical primates. In this study, we investigated the dispersal patterns and tested the social drivers of natal emigration in the golden lion tamarin (Leontopithecus rosalia) — an endangered species inhabiting Atlantic rainforests fragments in Brazil. We used behavioral and demographic data collected during 7 years from 68 groups of tamarins inhabiting 20 forest fragments. Our analyses from the 160 dispersing individuals showed that dispersal success is higher for males and for those engaged in parallel dispersal, but that males and females use different strategies to enhance their dispersal success, males immigrate into established groups while females form new groups. We did not find high levels of agonistic behavior among group members before natal emigration. Instead we found that conspecific attraction drives natal emigration in both sexes, while additionally the low level of affiliative interactions within the natal group triggers male emigration. We discuss natal emigration in the broader perspective of the cooperative breeding system and the implications of these findings for the conservation of the species.     

Intergroup affiliative interactions and intergroup transfer of young male Japanese macaques (Macaca fuscata)

The social interactions between young male Japanese macaques (Macaca fuscata) and members of two adjacent groups were studied. Young males usually associated with members of a single group. Although some young males occasionally interacted with members of the neighboring group, the frequency of their intergroup affiliative interactions was much lower than that of their intragroup interactions. The intergroup affiliative interactions were less symmetrical than the intragroup interactions. Three- or four-year-old males who remained in their natal group interacted with males of the neighboring group, whereas males over 5 years old did not. Young males revealed a dramatic change in their association partners from males in one group to those in another during the course of their intergroup transfer. Males who remained in their natal group did not attempt to interact with females of the neighboring group. In contrast, males who had transferred to a non-natal group interacted with females in their natal group. It is suggested that intergroup affiliative interactions and intergroup transfer of young male macaques are influenced by close associations between males. The immediate motivation for transfer of young natal macaques may be some attraction to males outside their group rather than sexual attraction to unfamiliar females.     

Mating system and sex allocation in the gregarious parasitoid Cotesia glomerata

The gregarious parasitoid Cotesia glomerata (L.) is often presumed to possess the characteristic attributes of a species that manifests local mate competition (LMC), as it commonly produces female-biased broods. However, our field surveys of sex ratio and laboratory observations of adult behaviour showed that this species is subject to partial local mate competition caused by natal dispersal. On average, 30% of males left their natal patch before mating, with the proportion of dispersing males increasing with an increase in the patch's sex ratio (i.e. proportion of males). Over 50% of females left their natal patch before mating, and only 27.5% of females mated with males emerging from the same natal patch. Although females showed no preference between males that were and were not their siblings, broods from females that mated with siblings had a significantly higher mean brood sex ratio (0.56) than broods from females that mated with nonsiblings (0.39). Furthermore, brood sex ratios increased as inbreeding was intensified over four generations. A field population of this wasp had a mean brood sex ratio of 0.35 over 3 years, which conformed well to the evolutionarily stable strategy sex ratio (r=0.34) predicted by Taylor's partial sibmating model for haplodiploid species. These results suggest that the sex allocation strategy of C. glomerata is based on both partial local mate competition in males and inbreeding avoidance in females. In turn, this mating system plays a role in the evolution of natal dispersal behaviour in this species.Copyright 2003 Published by Elsevier Ltd on behalf of The Association for the Study of Animal Behaviour.      

The disperser dilemma in cooperatively breeding birds

In most cooperatively breeding birds, individuals do not breed with their natal group members. In order to breed, they have either to disperse into another group or wait for an opposite-sex individual to join their group. In most of these species, females disperse more than males. We develop a dynamic game-theoretic model to account for this asymmetry. When males are physically larger/heavier than females, this allows them to effectively welcome female immigrants into their natal group and overcome the local females' opposition more than vice versa. The model further assumes that the dispersal decision is not confined to a restricted time window, but is rather based on acquired information and responsive to opportunities. The model predicts that (i) females disperse more than males, and (ii) females are willing to tolerate more risks in dispersal than do males. The latter prediction is supported inter alia by the fact that in many cooperatively breeding birds, females disperse at a younger age, and further away from their natal group as compared to dispersing males.     

Postdispersal nepotism in male long‐tailed macaques (Macaca fascicularis)

Cooperative behaviors are promoted by kin selection if the costs to the actor are smaller than the fitness benefits to the recipient, weighted by the coefficient of relatedness. In primates, cooperation occurs primarily among female dyads. Due to male dispersal before sexual maturity in many primate species, however, it is unknown whether there are sufficient opportunities for selective tolerance and occasional coalitionary support for kin selection to favor male nepotistic support. We studied the effect of the presence of male kin on correlates of male reproductive success (residence time, duration of high dominance rank) in non‐natal male long‐tailed macaques (Macaca fascicularis). We found that “related” (i.e., related at the half‐sibling level or higher) males in a group have a significantly higher probability to remain in the non‐natal group compared to males without relatives. Moreover, males stayed longer in a group when a relative was present at group entry or joined the same group within 3 months upon arrival. Males with co‐residing relatives also maintained a high rank for longer than those without. To our knowledge, this is the first demonstration of a potential nepotistic effect on residence and rank maintenance among non‐natal males in a social system without long‐term alliances.     

Male spotted hyenas (Crocuta crocuta) queue for status in social groups dominated by females

A long-term study of immigrant male spotted hyenas (Crocuta crocuta) living in large multimale/multifemale groups (clans) demonstrated that males acquire social status by queuing. Maximumlikelihood estimates of parameters of a stochastic queuingmodel that assessed queuing discipline confirmed that immigrantmales respected the convention that their positions in a queueof typically 15 or more individuals was determined by theirsequence of arrival. Levels of aggression among males were low;males did not attempt to improve their social status throughphysical contests. Size and body mass did not influence malesocial status. The stability of queues was insured by an increasein the rate at which males formed coalitions against othermales as they rose in social status and by coalitions between high-ranked males and dominant females. High-ranked, long-tenuredmales chiefly consorted with ("shadowed") and focused theiraffiliative behavior on females of high reproductive valueand disrupted attempts by subordinate males to associate withthese females. High-ranked males also supported females againstlower-ranked males that harassed them. In contrast, lower-ranked,short-tenured males focused their affiliative behavior on young adult females and rarely shadowed or defended females. Malesthat did not disperse from their natal clan (nondispersers)quickly acquired top rank in the male social hierarchy. Irrespectiveof the social status acquired from their mother when young,nondisperser adult males submitted to all adult females.     

Effects of natal male alliances on aggression and power dynamics in rhesus macaques

In the wild, male rhesus macaques disperse at sexual maturity. In captivity, however, males cannot disperse from their natal groups. Thus, the presence of natal males in captive rhesus social groups is unnatural and has the potential to negatively influence group dynamics and stability. A primary difference between natal males and non-natal (immigrant) males is that natal males have the opportunity to form long-term alliances with their maternal kin as well as nonkin. We investigated the factors associated with natal males' kin alliances and the impact of these alliances on measures of natal male behavior, group dynamics, and group stability. We found that natal males more frequently formed alliances with maternal kin when they were from high-ranking matrilines, had more siblings, and were younger. More frequent kin alliances were associated with more frequent use of intense aggression, higher individual rank, and higher degree of integration within the male displacement network. Thus, it seems that natal males use their alliances to be more active and influential in the social group, which may affect group stability. It appears that juvenile natal males from high-ranking matrilines, in particular, have the largest impact on group stability. Younger natal males from high-ranking matrilines formed alliances with kin more frequently and used intense aggression more frequently than older or lower ranking males. Furthermore, groups with a higher proportion of juvenile males from high-ranking matrilines also had higher rates of wounding. We suggest that the presence of natal males in rhesus groups may act in opposition to group stability.     

Finding hidden females in a crowd: Mate recognition in fig wasps

Multi-species mating aggregations are crowded environments within which mate recognition must occur. Mating aggregations of fig wasps can consist of thousands of individuals of many species that attain sexual maturity simultaneously and mate in the same microenvironment, i.e, in syntopy, within the close confines of an enclosed globular inflorescence called a syconium – a system that has many signalling constraints such as darkness and crowding. All wasps develop within individual galled flowers. Since mating mostly occurs when females are still confined within their galls, male wasps have the additional burden of detecting conspecific females that are “hidden” behind barriers consisting of gall walls. In Ficus racemosa, we investigated signals used by pollinating fig wasp males to differentiate conspecific females from females of other syntopic fig wasp species. Male Ceratosolen fusciceps could detect conspecific females using cues from galls containing females, empty galls, as well as cues from gall volatiles and gall surface hydrocarbons.In many figs, syconia are pollinated by single foundress wasps, leading to high levels of wasp inbreeding due to sibmating. In F. racemosa, as most syconia contain many foundresses, we expected male pollinators to prefer non-sib females to female siblings to reduce inbreeding. We used galls containing females from non-natal figs as a proxy for non-sibs and those from natal figs as a proxy for sibling females. We found that males preferred galls of female pollinators from natal figs. However, males were undecided when given a choice between galls containing non-pollinator females from natal syconia and pollinator females from non-natal syconia, suggesting olfactory imprinting by the natal syconial environment.     

Direct fitness benefits of group living in a complex cooperative society of carrion crows, Corvus corone corone

The social behaviour of carrion crows varies between populations. In northern Spain cooperatively breeding groups form through delayed natal dispersal and/or immigration of individuals (usually males) into the territory. In this population, carrion crows therefore breed as either unassisted pairs, pairs with nondispersing 1-2-year-old helpers (nondispersers), pairs with immigrant helpers or mixed groups (pairs with both immigrants and nondispersers). We used a microsatellite-based genotyping system to determine the parentage of 57 nestlings (19 broods). Polygamous mating was involved in 26% of the broods and reproduction was shared among group members of both sexes in at least three groups. Immigrants of both sexes can therefore gain access to mates by living in a group, while reproduction is unlikely to involve nondispersers. This implies that nondispersers and immigrants gain different sorts of benefits from group living and helping at the nest. Our genetic data confirmed that nondispersers associated with their parents on the natal territory and therefore that delayed natal dispersal leads to family formation in the carrion crow. Polygamous mating was not found in groups without immigrants, suggesting that, in this population, breeders lose parentage in their brood when sociality is extended beyond the limit of the nuclear family.Copyright 2002 The Association for the Study of Animal Behaviour. Published by Elsevier Science Ltd. All rights reserved.      

Population genetic structure and gene flow in a gleaning bat,Plecotus auritus

During summer the brown long-eared bat Plecotus auritus (Vespertilionidae) forms stable colonies, comprised of both adult females and males and young of the year. A long-term ringing study conducted in north-east Scotland has established that little movement occurs among colonies and that both sexes are recruited into their natal colony. The aim of the present study was to investigate, using microsatellite DNA markers, if genetic structure within the population reflects the spatial structure indicated by ringing. Inter-colony F_ST estimates obtained for all colony members, and for females and males separately, were low (0.019, 0.026 and 0.011, respectively), but all values differed significantly from zero. These data indicate high gene flow between colonies, although some coancestry among colony members is evident in both sexes. On combining the ringing and genetic data, it is concluded that gene flow occurs via extra-colony copulation, rather than natal dispersal, and that each colony behaves as a distinct subpopulation. Microgeographical genetic isolation by distance was demonstrated for, to our knowledge, the first time in a bat species, and found to be apparent both across the entire study area and along one river valley. The results suggest that extensive macrogeographical population genetic structure may be evident across the species'' range.     

Group Fission in Barbary Macaques (Macaca sylvanus) at Affenberg Salem

We analyzed eight group fissions occurring during a 20-year period in three groups of a free-ranging provisioned Barbary macaque population. The founder group fissioned four times within 3.5 years after transfer to the enclosure, indicating that external factors—new environment, more space, absence of other groups—facilitated group fissions. Two groups resulting from these fissions, split twice within 2.5 and 1 years, respectively, many years later. The process of fissioning lasted from a few months to almost 2 years. Fissions were preceded by peripheralization/subgrouping of mainly young adult males (8-10 years old), suggesting that male competition was the primary force for the fissions. The males were joined by middle- to low-ranking but not the lowest-ranking females. The resulting new groups were usually smaller than the groups in which the former -matriline—old groups—stayed, and they were also more variable in size and sex ratio, suggesting that variable numbers of surplus individuals were expelled during fission. Mean adult sex ratios were similar in both groups after fission, indicating that the competitively superior males in the old groups (groups + -matriline) could not increase their breeding opportunities. Female kin, even of large matrilinies, almost always stayed together during fission. Natal males strongly preferred to join the old groups, and this preference was most pronounced in juveniles and subadults. Hence, most natal males stayed with maternally related females, i.e., remained true natal males, if the females stayed in old groups. They were separated from female kin, i.e., became seminatal, if the females joined the new groups. These seminatal males did not differ from natal males with respect to matrilineal rank, but they had more female relatives, above all more close relatives (sisters), indicating that avoidance of mating with maternal kin was important for group choice. Despite joining the same group as female kin during fissioning, breeding opportunities of natal males (ratio of unrelated females/male) were not less than that of their seminatal peers, because natal males had fewer female relatives. Only a minority of both groups of males would have done better by joining the alternative group. Paternal relatives were distributed during fission by chance, and loss of patrilinies was therefore much less pronounced. We conclude that the rules governing social relationships among Barbary macaque males are less apt to cope with the high number of males resulting from provisioning, whereas the rules regulating social relationships of females living in a nepotistic, female-bonded society are very robust in this respect.     

Patterns and dynamics of sex-biased dispersal in a nocturnal primate, the grey mouse lemur, Microcebus murinus

We examined predictions on the proportion of dispersing natal males and females, dispersal distances, the age at dispersal and the potential for inbreeding over a 6-year period in a free-living population of grey mouse lemurs. We used monthly mark-recapture procedures to determine individual locations and interindividual distances. The analysis of seven polymorphic microsatellite markers for 213 (130 males, 83 females) individuals allowed us to estimate relatedness coefficients and kinship relationships. Closely related males ranged further from each other than closely related females and natal males were found further from their potential mothers than were females. Natal males were more likely to disperse from their birth sites than females, although male dispersal was not universal. Male breeding dispersal was detected in half of the long-term observations. Males therefore seem to be the predominant vectors for gene flow between populations and social units. Females usually stayed within one to two home range diameters of their potential mother, facilitating the evolution of cooperative behaviour by kin selection among females. Most dispersal took place before the mating season, indicating an age of less than 7 months for natal dispersal. The analysis of spatiotemporal coexistence revealed the potential for inbreeding in only 3.8% of the potential mother-son dyads, but in 21.9% of the potential father-daughter dyads and in 41.7% of other closely related male-female dyads. Copyright 2003 Published by Elsevier Science Ltd on behalf of The Association for the Study of Animal Behaviour