Insectes Sociaux

O’Donnell, S.

doi: 10.1007/s00040-011-0178-6pmid: N/A

Powell, S.

doi: 10.1007/s00040-011-0152-3pmid: N/A

New World army ants (Ecitoninae) are nomadic group-predators that are widely thought to have a substantial impact on their prey. Nevertheless, quantitative data on prey intake by army ants is scarce and mostly limited to chance encounters. Here, I quantify the prey intake of the army ant Eciton hamatum at the contrasting scales of raid, colony (sum of simultaneous raids), and population. Like most army ants, E. hamatum conducts narrow ‘column raids’ and has a specialized diet of ant prey. I show that individual raids often had periods of no prey intake, and raid intake rates, calculated in g/min, differed significantly among colonies. Moreover, neither mean nor peak raid intake rates were correlated with colony size. Similarly, colony intake rates differed significantly among colonies, and mean colony intake rates were not correlated with colony size. However, mean colony intake rates were significantly higher than mean raid intake rates, and peak colony intake rate was correlated with colony size. Having multiple raids thus improves colony-level intake rates, and larger colonies can harvest more prey per unit time. Mean colony intake rate across colonies was 0.067 g/min dry weight and mean daily colony intake was calculated at 38.2 g. This intake is comparable to that of Eciton burchellii, which has a more generalized diet and conducts spectacular ‘swarm raids’ that are seen as having a greater impact on prey than column raids. Population size on Barro Colorado Island, Panama, was estimated to be 57 colonies, which extrapolates to a daily population intake of nearly 2 kg of prey dry weight, or 120 g/km2. Broadly, these findings demonstrate that column raiding army ants experience considerable variation in prey intake for individual raids, but can still achieve notable impact at the larger scales of colony and population. Furthermore, they challenge the idea that swarm-raiding species necessarily have greater intake and thus impact on prey. Instead, I suggest that conducting multiple column raids may be a strategy that allows for comparable intake from a more specialized diet.

Willson, S.; Sharp, R.; Ramler, I.; Sen, A.

doi: 10.1007/s00040-011-0171-0pmid: N/A

Foraging army ants face a problem general to many animals—how best to confront resource depletion and environmental heterogeneity. Army ants have presumably evolved a nomadic lifestyle as a way to minimize re-exploitation of previously foraged areas. However, this solution creates a challenge for an army ant colony: foraging by this colony and others creates a shifting landscape of food resources, where colonies should theoretically avoid their own previous foraging paths as well as those of other colonies. Here, we examine how colonies exploit this resource mosaic, using some of the optimality arguments first proposed and tested by Franks and Fletcher (1983), but with much larger data sets in a new location in SW Amazonia. Our data supported Franks and Fletcher’s (1983) model for systematic avoidance of raided areas during the statary phase, as well as a hypothesis of distance optimization between successive statary bivouacs. We also test and find significant evidence that foraging raids turn in opposite directions from the previous day’s directional angles more frequently than what would be expected if turning angles were distributed at random, which acts to move a colony away from recently exploited areas. This implies that colonies follow a straighter line path during the nomadic phase as opposed to a curved one, which acts to maximize distance between statary bivouacs. In addition to intra-colony movement optimization, we examine evidence for inter-colony avoidance from more than 330 colony emigrations and suggest that colony-specific pheromones are not necessarily repulsive to other colonies. Lastly, we compare our results with those of similar studies carried out at Barro Colorado Island (BCI), Panama. Despite a higher density of army ants in the SW Amazon region, colonies spend less time emigrating than their counterparts at BCI, which suggests a higher prey density in SW Amazonia.

Schöning, C.; Shepard, L.; Sen, A.; Kinuthia, W.; Ogutu, J.

doi: 10.1007/s00040-011-0172-zpmid: N/A

Army ant colonies do not have permanent nests but frequently move to new patches. Local food depletion is considered the ultimate cause of this nomadic behaviour, but the proximate causes are not well understood. We tested if and how patch departure time of the aboveground-hunting army ant Dorylus molestus under field conditions is influenced by food availability and nest attacks by predators. In the first food supplement experiment, colonies receiving additional food throughout an entire nest stay did not reside in their nests for longer periods than control colonies. However, the distances travelled by colonies after nest stays during which colonies obtained food were shorter than those before these nest stays, indicating that colonies do assess food availability and avoid moving too far away from patches of high food availability. In the second food supplement experiment, in which colonies were given even larger amounts of food in the second half of their nest stay to mimic a rich unpredictable food source that these highly polyphagous predators are likely to encounter sometimes, patch departure times likewise did not differ between treated and control colonies. Either patch departure time is independent of food availability or there is another, as yet unappreciated proximate cause of colony movements in this species which we were unable to control for in our field experiments. One possibility is that encounters between neighbouring colonies influence patch departure time. In the experiment on the effect of predation, colonies responded to simulated nest attacks by mammals by leaving nests almost instantaneously and thus much earlier than control colonies. Rapid nest evacuation is likely a response to minimize the probability of repeat attacks by predators which cannot be repelled in other ways. Future studies will be necessary to definitively determine whether food availability influences patch departure times and to elucidate the consequences of colony encounters.

Seppä, P.; Fogelqvist, J.; Gyllenstrand, N.; Lorenzi, M.

doi: 10.1007/s00040-011-0149-ypmid: N/A

We used DNA microsatellites to study colony kin structure and breeding patterns in the primitively eusocial wasp Polistes biglumis. P. biglumis inhabits cool areas at high altitudes and, as a consequence, has a reduced colony cycle compared to more temperate Polistes. P. biglumis colonies are always founded and controlled by a single foundress, but nest failure is common and foundresses losing their nests do not have time to start new ones due to the short season. Instead, nests are characterized by frequent female turnover, in the form of females taking over (usurpation) other con-specific nests. Our results showed that most nests had offspring from multiple unrelated females, including some where multiple females were not observed in monitoring. Reconstruction of behavioural events from the genetic data revealed three types of multiple matriline nests: (a) nests that were usurped by another female, where the original nest owner disappeared following the usurpation event, (b) nests that were joined by another female, where the original nest owner stayed following the joining event, (c) nests that were both usurped and joined by other females. We also found, for the first time, a clear indication of multiple mating by Polistes females. Moreover, males mating with the same female were related, which may be explained by the lek mating system of P. biglumis. Finally, we analysed the nest sex ratios and how it changed during the season and found that sexes were produced sequentially, males before females.

Suni, S.; Eldakar, O.

doi: 10.1007/s00040-011-0150-5pmid: N/A

Explaining the evolution of multiple mating is a challenge because of the associated costs. For social insects, mating frequency may have fitness consequences due to effects on social interactions or genetic diversity within colonies. Here, we investigated the evolution of mating frequency in a social insect species with a unique genetic system that requires multiple mating. In certain populations of Pogonomyrmex harvester ants, there are two interbreeding yet genetically distinct mitochondrial lineages. Queens must mate with males of the opposite lineage to produce workers and with males of the same lineage to produce reproductive females. We expected queens of the dependent-lineage system to exhibit high mating frequencies relative to other social insects. Furthermore, we expected queens from populations of highly asymmetric lineage ratios to exhibit even higher mating frequencies, to adequately sample the population and successfully mate with males of the less common lineage. To test these predictions, we estimated the mating frequency of 16 P. barbatus queens, and compared these mating frequencies between two populations, one with relatively equal lineage ratio (60:40) and a second with a highly asymmetrical lineage ratio (96:4). Overall, observed mating frequency exceeded 10, which is high in comparison to other social insects, and our estimates of effective mating frequency were among the highest of Pogonomyrmex species. Mating frequency at the site with the asymmetrical lineage ratio was also significantly higher than the site with the more even ratio. Our results suggest that obligate multiple mating as well as lineage ratio contribute to the evolution of high mating frequency in dependent-lineage populations.

Ujvari, B.; Li, B.; Evans, T.; King, A.; Kitade, O.; Lo, N.

doi: 10.1007/s00040-011-0153-2pmid: N/A

Coptotermes lacteus, a termite found in eastern Australia, is a central-site nester that constructs mounds up to 2 m in height. Mature colonies typically contain the primary king and queen, and up to a million or more worker and soldier offspring. Once a year, male and female nymphs are produced in approximately equal numbers and develop into new alates. Experimental removal of the queen in the field and subsequent mating of the king with a replacement queen, results in an unusual phenomenon whereby the production of female nymphs completely ceases, while the production of male nymphs, and workers of both sexes, continues. The proximate cause of this nymph male-bias is yet to be discovered. The production of male nymphs and workers of both sexes in de-queened C. lacteus colonies is equivalent to offspring production patterns in laboratory crosses of male nymphoid (nymph-derived) with female ergatoid (worker-derived) replacement reproductives in the related species Reticulitermes speratus. An X-linked genetically influenced caste determination (GCD) mechanism has been proposed to account for such offspring patterns in R. speratus. We examined microsatellite genotypes in C. lacteus to test a prediction arising from the R. speratus GCD model: that nymphs should result from reproduction by neotenics, rather than the primary pair. In five of six colonies examined, genotypes indicated that all workers and nymphs were derived from a single reproductive pair. In three of these cases, the primary queen was also located and examined; her genotype matched that inferred from worker and nymph genotypes. These results suggest that the GCD model proposed for R. speratus does not apply to C. lacteus, at least under field conditions. The male-nymph bias following queen removal therefore remains an unresolved issue in C. lacteus.

Koné, N.; Dosso, K.; Konaté, S.; Kouadio, J.; Linsenmair, K.

doi: 10.1007/s00040-011-0154-1pmid: N/A

The Macrotermitinae subfamily is characterized by its symbiosis with fungi of the genus Termitomyces. The most common and presumably primitive mode of reproduction for these fungi is to produce basidiocarps on the mounds of the host termite colony. The seasonal fructification pattern of the fungi seems to depend on the habitat type and termite ecology. We examined Termitomyces diversity and distribution in two phytogeographic zones in central and southern Côte d’Ivoire. Data were collected in different habitats in exhaustive searches with standardized methods for termites and basidiocarps as well. The respective findings were complemented with behavioral and life cycle data of the associated termite species. Basidiocarps occur species-specifically either during the long or the short rainy season in wooded habitats. The diversity and abundance of termites and their associated basidiocarps were significantly correlated only with woody plant species richness. Nuptial flight of termites, comb biomass and Termitomyces fructification periods were correlated. Termitomyces appear to fructify during (1) the period of strong precipitation, (2) in habitats with appropriate microclimatic characteristics.

Bruschini, C.; Cervo, R.

doi: 10.1007/s00040-011-0155-0pmid: N/A

Insect social parasites rely on host workers to rear and protect their own brood. To conquer a host colony, a parasite must overcome the defensive mechanisms of the host, often by exploiting its chemical communication system. A widespread strategy involves the production of specific allomones (the so-called “propaganda pheromones”) to facilitate the usurpation process by manipulating the defensive behavior of the host. Polistes sulcifer is the obligate and permanent social parasite of the congeneric paper wasp Polistes dominulus. In this study, we investigated if the venom volatiles, well known to be alarm pheromones in the host species, could be used by the parasite to manipulate the host defense. We thus performed laboratory bioassays, to evaluate the possible effect of the venom volatile compounds of the parasite on the host. Our results show that host colony members reacted to the venom volatiles extract of the parasite with an increase in intra-colonial aggression compared to the reaction induced by the venom volatiles extract of the host foundress. Besides, a re-analysis of previously published chemical data showed that the parasite venom volatiles profile differs from that of the host: the spiroacetals are absent, whilst the amides are very abundant in the parasite venom when compared with that of the host. Similar to other insect social parasites, Polistes wasp parasites might be able to increase their invasion success by using venom volatile pheromones to distract the host defenders.

Nash, D.; Als, T.; Boomsma, J.

doi: 10.1007/s00040-011-0157-ypmid: N/A

The Alcon blue butterfly (Maculinea alcon) parasitizes the nests of several Myrmica ant species. In Denmark, it uses M. rubra and M. ruginodis, but never M. scabrinodis. To further examine the basis of this specificity and local co-adaptation between host and parasite, the pattern of growth and survival of newly-adopted caterpillars of M. alcon in Myrmica subcolonies was examined in the laboratory. M. alcon caterpillars were collected from three populations differing in their host use, and reared in laboratory nests of all three ant species collected from each M. alcon population. While there were differences in the pattern of growth of caterpillars from different populations during the first few months after adoption, which depended on host ant species and the site from which the ants were collected, there was no evidence of major differences in final size achieved. Survival was, however, much higher in nests of M. rubra than in nests of M. ruginodis and M. scabrinodis, even for caterpillars from a population that is never known to use M. rubra as a host in the field. The caterpillars of M. alcon thus do not show local adaptation in their pattern of growth and survival, but instead show a pattern that may reflect different nestmate recognition abilities of the host ants, related to their sociogenetic organisation. The pattern of observed host ant use in the field seems to result from a combination of differences in local host availability and locally adapted infectivity, modulated by smaller differences in survivorship in the nests of the different host ants.