A Second Host Species of the Inquiline Ant Leptothorax wilsoni

The workerless parasitic ant, Leptothorax wilsoni, as yet known only from colonies of Leptothorax cf. canadensis, was found in five colonies of a second host species, Leptothorax sp. A (sensu Heinze and Buschinger, 1989) near Escoumins, Québec. This is the first finding of an inquiline with more than one host species in the ant tribe Formicoxenni. In contrast to a previous statemem, the palp formula of L. wilsoni is 4. 3

Caterpillars and fungal pathogens: two co-occurring parasites of an ant-plant mutualism

In mutualisms, each interacting species obtains resources from its partner that it would obtain less efficiently if alone, and so derives a net fitness benefit. In exchange for shelter (domatia) and food, mutualistic plant-ants protect their host myrmecophytes from herbivores, encroaching vines and fungal pathogens. Although selective filters enable myrmecophytes to host those ant species most favorable to their fitness, some insects can by-pass these filters, exploiting the rewards supplied whilst providing nothing in return. This is the case in French Guiana for Cecropia obtusa (Cecropiaceae) as Pseudocabima guianalis caterpillars (Lepidoptera, Pyralidae) can colonize saplings before the installation of their mutualistic Azteca ants. The caterpillars shelter in the domatia and feed on food bodies (FBs) whose production increases as a result. They delay colonization by ants by weaving a silk shield above the youngest trichilium, where the FBs are produced, blocking access to them. This probable temporal priority effect also allows female moths to lay new eggs on trees that already shelter caterpillars, and so to occupy the niche longer and exploit Cecropia resources before colonization by ants. However, once incipient ant colonies are able to develop, they prevent further colonization by the caterpillars. Although no higher herbivory rates were noted, these caterpillars are ineffective in protecting their host trees from a pathogenic fungus, Fusarium moniliforme (Deuteromycetes), that develops on the trichilium in the absence of mutualistic ants. Therefore, the Cecropia treelets can be parasitized by two often overlooked species: the caterpillars that shelter in the domatia and feed on FBs, delaying colonization by mutualistic ants, and the fungal pathogen that develops on old trichilia. The cost of greater FB production plus the presence of the pathogenic fungus likely affect tree growth

Lack of patriline-specific differences in chemical composition of the metapleural gland secretion in <em>Acromyrmex octospinosus</em>

Multiple queen-mating (polyandry) in social insects increases the genetic variability among worker offspring, which may enhance colony survival, social productivity and defence against parasites. The unique and complex symbiosis of leaf-cutting ants with a clonal mutualistic fungus makes this social system particularly vulnerable to contamination by pathogenic and unwanted saprophytic fungi and bacteria. Proper defence against such threats requires effective and flexible chemical defence mechanisms. A prime candidate for providing such defences is the meta-pleural gland secretion, which is known to have broad antibiotic properties. Here we use the leaf-cutting ant Acromyrmex octospinosus to specifically test the hypothesis that genetically more diverse worker-offspring produce a more variable spectrum of metapleural gland compounds. We used DNA microsatellite markers to assign workers from two colonies to the six most common patrilines in each colony, and have analysed the degree to which the observed variance in the quantitative chemical composition of the metapleural gland secretion can be explained by genetic differences among patrilines. We found a marginally significant patriline-effect on the overall variability of metapleural gland compounds in one colony, but could not detect such effect in the other colony. We discuss a number of possible reasons why the genetic variance component for quantitative variation in metapleural gland secretion may be low

Variable sensitivity of fungi and bacteria to compounds produced by the metapleural glands of leaf-cutting ants

Ants are the only group of insects that have metapleural glands. Secretions of these exocrine glands are known to have antibiotic properties and have been hypothesised to function as a general defence against microbial and fungal infections. Such defences are likely to be particularly important in leaf-cutting ants that need to protect both themselves and their clonal mutualistic fungus against pathogens. The metapleural gland of the leaf-cutting ant Acromyrmex octospinosus produces an array of organic compounds (Ortius-Lechner et al., 2000), suggesting that different compounds may be effective against different kinds of infections. Here we provide a detailed analysis of the sensitivity of two species of bacteria and seven species of fungi (including the mutualistic fungus) to these metapleural gland compounds, grouped in seven classes: acetic acid, short chain acids, medium chain acids, long chain acids, indoleacetic acid, gamma-lactones and gamma-ketoacids. All classes of compounds inhibited the growth of at least some of the tested micro-organisms. Cluster analysis produced four groups of micro-organisms differing in their overall sensitivity. Among-cluster differences explained a major part of the total variation in sensitivity (MANOVA), although differences between micro-organisms within clusters were also significant. Fungal hyphae and fungal spores never clustered together, indicating that defence mechanisms against these fungal life stages are fundamentally different. The mutualistic fungus was sensitive to all classes of compounds, which suggests that defence via metapleural gland secretion is under constraint when the protection of the fungus garden is concerned

Ant parasite queens revert to mating singly

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