Volatile organic compounds influence prey composition in Sarracenia carnivorous plants.

Sarracenia pitcher plants display interspecific differences in prey, so far only explained by pitcher morphology. We hypothesized that pitcher odours play a role in prey composition. We first compared odour and prey compositions among Sarracenia taxa grown together, forming a kinship gradient from S. purpurea known to capture primarily ants towards S. leucophylla known to capture many flying insects: S. purpurea, S. X mitchelliana, and S. X Juthatip soper & S. X leucophylla horticultural hybrids. We then measured several pitcher traits to disentangle the contributions of morphology and odour to prey variation. The pitcher odours were as diverse as those of generalist-pollinated flowers but with notable differences among taxa, reflecting their relatedness. VOC similarity analyses revealed taxon specificities, that mirrored those revealed by prey similarity analyses. S. X leucophylla stood out by being more specialised in flying insects like bees and moths and by releasing more monoterpenes known to attract flower visitors. S. X Juthatip soper trapped as many bees but fewer moths, sesquiterpenes contributing less to its scent. Ants and Diptera were the main prey of the other two with fatty-acid-derivative-dominated scents. Quantities of the different prey groups can be inferred 98% from quantities of the odour classes and pitcher dimensions. Two syndromes were revealed: ants associated with fatty-acid-derivatives and short pitchers; flying insects associated with monoterpenes, benzenoids and tall pitchers. In S. X leucophylla, emission rate of fatty-acid-derivatives and pitcher length explained most variation in ant captures; monoterpenes and pitcher length explained most variation in bee and moth captures; monoterpenes alone explained most variation in Diptera and wasp captures. Our results suggest that odours are key factors of the diet composition of pitcher plants. They support the hypothesis of perceptual exploitation of insect biases in carnivorous plants and provide new insights into the olfactory preferences of insect groups.

Secondary Symbionts Affect Foraging Capacities of Plant-Specialized Genotypes of the Pea Aphid.

Ecological specialization is widespread in animals, especially in phytophagous insects, which have often a limited range of host plant species. This host plant specialization results from divergent selection on insect populations, which differ consequently in traits like behaviors involved in plant use. Although recent studies highlighted the influence of symbionts on dietary breadth of their insect hosts, whether these microbial partners influence the foraging capacities of plant-specialized insects has received little attention. In this study, we used the pea aphid Acyrthosiphon pisum, which presents distinct plant-specialized lineages and several secondary bacterial symbionts, to examine the possible effects of symbionts on the different foraging steps from plant searching to host plant selection. In particular, we tested the effect of secondary symbionts on the aphid capacity (1) to explore habitat at long distance (estimated through the production of winged offspring), (2) to explore habitat at short distance, and (3) to select its host plant. We found that secondary symbionts had a variable influence on the production of winged offspring in some genotypes, with potential consequences on dispersal and survival. By contrast, symbionts influenced both short-distance exploration and host plant selection only marginally. The implication of symbionts' influence on insect foraging capacities is discussed.