The cost of dominance: suppressing subordinate reproduction affects the reproductive success of dominant female banded mongooses

Social species show considerable variation in the extent to which dominant females suppress subordinate reproduction. Much of this variation may be influenced by the cost of active suppression to dominants, who may be selected to balance the need to maximize the resources available for their own offspring against the costs of interfering with subordinate reproduction. To date, the cost of reproductive suppression has received little attention, despite its potential to influence the outcome of conflict over the distribution of reproduction in social species. Here, we investigate possible costs of reproductive suppression in banded mongooses, where dominant females evict subordinates from their groups, thereby inducing subordinate abortion. We show that evicting subordinate females is associated with substantial costs to dominant females: pups born to females who evicted subordinates while pregnant were lighter than those born after undisturbed gestations; pups whose dependent period was disrupted by an eviction attained a lower weight at independence; and the proportion of a litter that survived to independence was reduced if there was an eviction during the dependent period. To our knowledge, this is the first empirical study indicating a possible cost to dominants in attempting to suppress subordinate breeding, and we argue that much of the variation in reproductive skew both within and between social species may be influenced by adaptive variation in the effort invested in suppression by dominants.     

Benefits of foundress associations in the paper wasp Polistes dominulus: increased productivity and survival, but no assurance of fitness returns

Successful Polistes dominulus nests can be started by one ormore nest founding queens (foundresses). Consequently, thereis much interest in the specific benefits that induce cooperationamong foundresses. Here, we experimentally demonstrate one majorbenefit of cooperation, namely that multiple foundresses increasecolony productivity. This increase is close to the value predictedby subtracting the productivity of undisturbed single-foundresscolonies from the productivity of undisturbed multiple-foundresscolonies. However, we found no evidence that an associatingfoundress' contribution to colony growth is preserved if shedisappears (assured fitness returns). Our correlational datasuggest that cooperation provides survival benefits, multiple-foundresscolonies are more likely to survive to produce offspring thanare single-foundress colonies, and individual foundresses inmultiple-foundress groups are less likely to disappear beforeworker emergence than foundresses nesting alone. Therefore,association provides substantial productivity and survival benefitsfor cooperating foundresses.     

Colony genetic structure in a facultatively eusocial hover wasp

The degree of genetic heterogeneity among the individuals inan animal society depends on the society's genetic structure.Genetic heterogeneity, in turn, means that group members willdiffer in their reproductive objectives and conflicts over reproductionmay arise. The resolution of these conflicts may be reflectedin the way that reproduction is partitioned between potentialreproductives. We used 5 microsatellite loci to investigategenetic structure and reproductive skew in 17 nests of the Malaysianhover wasp, Parischnogaster alternata. Parischnogaster alternatacolonies are small (1–10 females), and all adult colonymembers are capable of mating and producing offspring. We foundthat colonies tended to consist of closely related individualsand that at any one time the production of both female and maleoffspring was nearly always monopolized by a single dominantfemale, despite considerable variation between nests in parameterspredicted to affect skew. Subordinate females that remainedin their natal colonies obtained indirect fitness benefits byhelping to raise offspring to which they were related. Subordinatefemales also appeared to be positioned within an age-based queuefor inheritance of the dominant egg-laying position. We suggestthat the high skew in P. alternata may result from strong ecologicalconstraints on solitary nesting, high relatedness, and a relativelyhigh probability that subordinates will eventually inherit theposition of dominance.     

Body Size Shapes Caste Expression,and Cleptoparasitism Reduces Body Size in the Facultatively Eusocial Bees <Emphasis Type="Italic">Megalopta</Emphasis> (Hymenoptera: Halictidae)

We used the facultatively social sweat bee Megalopta genalis (Halictidae) to test whether body size is associated with social caste. Behavioral observations showed that non-reproductive foragers were significantly smaller than reproductive nest mate queens, and foragers were also smaller than presumed pre-dispersal reproductives. Moreover, among females from field-collected nests without behavioral observations, relative body size correlated with relative ovary size. Reproductive status is not a direct result of body size, as body size was not significantly associated with either ovary size or fecundity among both solitary and social reproductives. Reproductive status is apparently an outcome of social competition for reproductive dominance, and status is influenced by size relative to nest mates. Our study is the first to demonstrate an association of body size with caste expression in a facultatively social species with relatively weak seasonal constraints on independent nesting. Larvae of a parasitic fly (Fiebrigella sp., Chloropidae) consume pollen provisions stored in nest cells of M. genalis and M. ecuadoria. We tested whether fly parasitism of M. genalis reduces body size. Parasitized females are significantly smaller as adults than their unparasitized nestmates. This reduction is of a similar magnitude to the size differences between castes, and has the potential to shape host reproductive options by influencing competition with nest mates. We present data on the prevalence of parasitism from four collections of M. genalis and two collections of M. ecuadoria from Barro Colorado Island, Panama, and La Selva, Costa Rica.     

Causes and consequences of incest avoidance in the cooperatively breeding mole-rat, Cryptomys darlingi (Bathyergidae)

A number of social mole-rat species maintain a strong reproductive skew (only one breeding pair in the group) solely through incest avoidance. Incest avoidance probably evolved for one of two reasons, namely for actually maintaining a reproductive skew or, alternatively, to avoid high inbreeding depression. In the latter case a strong reproductive skew would result as a fortuitous by-product of the combination of a cloistral family life style of mole-rats and incest avoidance. We undertook breeding experiments in which the fertility of pairs of unrelated individuals were compared with that of pairs of double first cousins. Inbreeding depression was remarkably high and an accompanying model suggests that it may be sufficient to support the idea that strong incest avoidance evolved primarily to eliminate the costs of inbreeding and subsequently facilitated the evolution of reproductive skew.     

Reproductive specialization in multiple-queen colonies of the ant Formica exsecta

In polygynous (multiple queens per nest) colonies of socialinsects, queens can increase their reproductive share by layingmore eggs or by increasing the proportion of eggs that developinto reproductive individuals instead of workers. We used polymorphicmicrosatellite loci to determine the genetically effective contributionof queens to the production of gynes (new queens), males, and2 different cohorts of workers in a polygynous population ofthe ant Formica exsecta. For this purpose, we developed a newmethod that can be used for diploid and haplodiploid organismsto quantify the degree of reproductive specialization amongbreeders in societies where there are too many breeders to ascertainparentage. Using this method, we found a high degree of reproductivespecialization among nest-mate queens in both female- and male-producingcolonies (sex ratio is bimodally distributed in the study population).For example, a high effective proportion of queens (25% and79%, respectively) were specialized in the production of malesin female- and male-producing colonies. Our analyses furtherrevealed that in female-producing colonies, significantly fewerqueens contributed to gyne production than to worker production.Finally, we found significant changes in the identity of queenscontributing to different cohorts of workers. Altogether, thesedata demonstrate that colonies of F. exsecta, and probably thoseof many other highly polygynous social insect species, are composedof reproductive individuals differing in their investment togynes, males, and workers. These findings demonstrate a newaspect of the highly dynamic social organization of complexanimal societies.     

Genome-wide analysis reveals differences in brain gene expression patterns associated with caste and reproductive status in honey bees (Apis mellifera)

A key characteristic of eusocial species is reproductive division of labour. Honey bee colonies typically have a single reproductive queen and thousands of sterile workers. Adult queens differ dramatically from workers in anatomy, physiology, behaviour and lifespan. Young female workers can activate their ovaries and initiate egg laying; these 'reproductive' workers differ from sterile workers in anatomy, physiology, and behaviour. These differences, however, are on a much smaller scale than those observed between the queen and worker castes. Here, we use microarrays to monitor expression patterns of several thousand genes in the brains of same-aged virgin queens, sterile workers, and reproductive workers. We found large differences in expression between queens and both worker groups (~2000 genes), and much smaller differences between sterile and reproductive workers (221 genes). The expression patterns of these 221 genes in reproductive workers are more queen-like, and may represent a core group of genes associated with reproductive physiology. Furthermore, queens and reproductive workers preferentially up-regulate genes associated with the nurse bee behavioural state, which supports the hypothesis of an evolutionary link between worker division of labour and molecular pathways related to reproduction. Finally, several functional groups of genes associated with longevity in other species are significantly up-regulated in queens. Identifying the genes that underlie the differences between queens, sterile workers, and reproductive workers will allow us to begin to characterize the molecular mechanisms underlying the evolution of social behaviour and large-scale remodelling of gene networks associated with polyphenisms.     

Testing the importance of the distribution of worker sizes to colony performance in the ant species <Emphasis Type=Italic>Formica obscuripes</Emphasis> Forel

We examined the relationship between colony performance and the distribution of worker sizes within colonies in the ant species, Formica obscuripes. We manipulated the distribution of worker sizes within colonies and found that experimental colonies whose distributions mimicked the natural distributions retained a larger percentage of colony biomass over three weeks when fed on honeydew, relative to colonies composed of only large or only small workers. In natural colonies most of the variation in worker sizes was found within, as opposed, to between colonies, suggesting that homeostatic mechanisms within colonies regulated the distribution of worker sizes. While there were no disjunctions in the distribution of worker sizes within colonies, the distribution tended to be bimodal. This study demonstrates that the distribution of worker sizes within colonies is important even for ant species that lack discrete worker castes. Received 31 October 2006; revised 26 December 2006; accepted 4 January 2007.     

Resolving the evolution of sterile worker castes: a window on the advantages and disadvantages of monogamy

Many social Hymenoptera species have morphologically sterile worker castes. It is proposed that the evolutionary routes to this obligate sterility must pass through a ‘monogamy window’, because inclusive fitness favours individuals retaining their reproductive totipotency unless they can rear full siblings. Simulated evolution of sterility, however, finds that ‘point of view’ is critically important. Monogamy is facilitating if sterility is expressed altruistically (i.e. workers defer reproduction to queens), but if sterility results from manipulation by mothers or siblings, monogamy may have no effect or lessen the likelihood of sterility. Overall, the model and data from facultatively eusocial bees suggest that eusociality and sterility are more likely to originate through manipulation than by altruism, casting doubt on a mandatory role for monogamy. Simple kin selection paradigms, such as Hamilton''s rule, can also fail to account for significant evolutionary dynamics created by factors, such as population structure, group-level effects or non-random mating patterns. The easy remedy is to always validate apparently insightful predictions from Hamiltonian equations with life-history appropriate genetic models.     

Evolution of eusociality and the soldier caste in termites: a validation of the intrinsic benefit hypothesis

In termites the evolution of reproductive altruism is not based on a particularly high relatedness between nestmates. For the evolution and maintenance of the ancestral sterile soldier caste, the benefits generated by the soldiers' presence must compensate the loss of the soldiers' reproductive potential. To study the impact of soldiers on colony's fitness, we manipulated the proportion of soldiers to nonsoldiers in colonies of the dry-wood termite Cryptotermes secundus.'Soldier-less' colonies were obtained by removing soldiers and inhibiting their development with an extract of soldier heads. The colonies were set up for 1 year in experimental nests in the field. 'Soldier-less' colonies produced fewer soldiers. The reduction of soldiers neither affected colony survival nor helper growth, but fewer dispersing sexuals were produced in 'soldier-less' than in control colonies. This confirms what was only supposed so far, that in termites soldiers are maintained for their intrinsic benefit to cost ratio.     

Why do chimpanzee males attack the females of neighboring communities?

Our closest nonhuman primate relatives, chimpanzees, engage in potentially lethal between‐group conflict; this collective aggressive behavior shows parallels with human warfare. In some communities, chimpanzee males also severely attack and even kill females of the neighboring groups. This is surprising given their system of resource defense polygyny, where males are expected to acquire potential mates. We develop a simple mathematical model based on reproductive skew among primate males to solve this puzzle. The model predicts that it is advantageous for high‐ranking males but not for low‐ranking males to attack females. It also predicts that more males gain a benefit from attacking females as the community's reproductive skew decreases, i.e., as mating success is more evenly distributed. Thus, fatal attacks on females should be concentrated in communities with low reproductive skew. These attacks should also concur with between‐community infanticide. A review of the chimpanzee literature provides enough preliminary support for this prediction to warrant more detailed testing. Am J Phys Anthropol 155:430–435, 2014. © 2014 Wiley Periodicals, Inc.