Attraction to and learning from social cues in fruitfly larvae

We examined the use of social information in fruitfly larvae, which represent an ideal model system owing to their robust learning abilities, small number of neurons and well-studied neurogenetics. Focal larvae showed attraction to the distinct odour emanating from food occupied by other larvae. In controlled learning experiments, focal larvae preferred novel odours previously paired with food occupied by other larvae over novel odours previously paired with unoccupied food. When we gave groups of larvae a choice between food patches differing in quality, more larvae aggregated on the higher-quality food, suggesting that attraction to and learning about cues associated with other larvae can be beneficial. Furthermore, larvae were more likely to find the best available food patch in trials when that food patch was occupied by other larvae than in trials when that food patch was unoccupied. Our data suggest, however, that the benefits from joining others may be at least partially offset by the fitness costs of increased competition, because larvae reared in isolation did as well as or better than larvae reared in groups on three key fitness parameters: developmental rate, survival rate and adult dry body mass. Our work establishes fruitfly larvae as a highly tractable model species for further research on the mechanisms that modulate behaviour and learning in a social context.     

The Value of Patch-Choice Copying in Fruit Flies

Many animals copy the choices of others but the functional and mechanistic explanations for copying are still not fully resolved. We relied on novel behavioral protocols to quantify the value of patch-choice copying in fruit flies. In a titration experiment, we quantified how much nutritional value females were willing to trade for laying eggs on patches already occupied by larvae (social patches). Females were highly sensitive to nutritional quality, which was positively associated with their offspring success. Females, however, perceived social, low-nutrition patches (33% of the nutrients) as equally valuable as non-social, high-nutrition ones (100% of the nutrients). In follow-up experiments, we could not, however, either find informational benefits from copying others or detect what females'' offspring may gain from developing with older larvae. Because patch-choice copying in fruit flies is a robust phenomenon in spite of potential costs due to competition, we suggest that it is beneficial in natural settings, where fruit flies encounter complex dynamics of microbial communities, which include, in addition to the preferred yeast species they feed on, numerous harmful fungi and bacteria. We suggest that microbial ecology underlies many cases of copying in nature.     

Mortality rates of honey bees in the wild

Senescence, defined as an age-specific decrease in physiological performance accompanied by an increase in mortality rate, has been studied in a wide range of animals including social insects. It is not clear, however, whether honey bees in the wild live long enough to exhibit senescent decline. I tested for the effects of senescence on honey bees foraging in natural settings and documented the predicted pattern of exponential increase in mortality rate with forager age. These data indicate that, in spite of high rates of external mortality, senescence is an important factor determining the performance of insects such as honey bees in the wild. Received 16 November 2007; revised 1 February 2008 and 10 March 2008; accepted 18 March 2008.     

Effects of perceived danger on flower choice by bees

Studies on animal–flower interactions have mostly neglected the third trophic level of pollinators' predators, even though antipredatory behaviour of pollinators may affect patterns of pollinator visitation, pollen transfer and floral traits. In three experiments, it was found that honeybees showed sensitivity to perceived danger at flowers by preferring apparently safe flowers over equally rewarding alternatives harbouring either a dead bee or a spider, and avoiding revisitation of a site where the bees had escaped a simulated predation attempt. These results suggest that bees, like other animals, take antipredatory measures, which may have far reaching effects on animal–flower interactions.     

Potential fitness consequences of associative learning in a parasitoid wasp

Several studies have documented associative learning in insects,but the adaptive value of such learning is not yet well understood.To evaluate this issue, we quantified long-term fitness consequencesof associative learning in the parasitoid wasp, Biosteres arisanus.We compared individual wasps that were allowed to choose hostsubstrate based on experience ("learning" wasps) to wasps thatcould only make random substrate choice ("random" wasps) inan environment where only one out of two substrates containedhost eggs. In two experiments, the average number of host eggsparasitized and offspring produced were significantly largerfor learning than for random wasps. Our results allow detailedexamination of the conditions under which learning would havepositive fitness effects in ecological systems similar to ours.These conditions include relatively long search duration forhosts; the ability to remember a learned preference over extendedperiods of interfering activities; and large mean differencesbetween alternatives, and small variances, which together allowrapid evaluation of alternatives and long duration of exploitingthe superior one.     

Photorhabdus antibacterial Rhs polymorphic toxin inhibits translation through ADP-ribosylation of 23S ribosomal RNA

Bacteria have evolved sophisticated mechanisms to deliver potent toxins into bacterial competitors or into eukaryotic cells in order to destroy rivals and gain access to a specific niche or to hijack essential metabolic or signaling pathways in the host. Delivered effectors carry various activities such as nucleases, phospholipases, peptidoglycan hydrolases, enzymes that deplete the pools of NADH or ATP, compromise the cell division machinery, or the host cell cytoskeleton. Effectors categorized in the family of polymorphic toxins have a modular structure, in which the toxin domain is fused to additional elements acting as cargo to adapt the effector to a specific secretion machinery. Here we show that Photorhabdus laumondii, an entomopathogen species, delivers a polymorphic antibacterial toxin via a type VI secretion system. This toxin inhibits protein synthesis in a NAD⁺-dependent manner. Using a biotinylated derivative of NAD, we demonstrate that translation is inhibited through ADP-ribosylation of the ribosomal 23S RNA. Mapping of the modification further showed that the adduct locates on helix 44 of the thiostrepton loop located in the GTPase-associated center and decreases the GTPase activity of the EF-G elongation factor.     

Effects of Experience on Short‐ and Long‐term Foraging Performance in Bumblebees

Honeybees in natural settings show a gradual increase in foraging performance similar to the general pattern of lifetime performance seen in a wide variety of animals including humans. To quantify the factors contributing to such gradual increase in foraging success, we studied bumblebees foraging on pepper plants inside a greenhouse. This allowed us to combine the global measure of the net rate of food delivery to the hive with a detailed examination of bees’ performance at flowers over time. Although bees exhibited short‐term improvements in foraging ability during their first few foraging trips, we did not observe the predicted long‐term increase in performance over days. Our results suggest that a variety of flower‐handling tasks, flower choice and movements between plants can be learned quickly under the simple greenhouse settings. The long‐term increase in performance under natural settings may be caused by factors including spatial orientation and locating the best plant species, flower patches and individual plants over a large area.     

Effects of Early‐Life Experience on Learning Ability in Fruit Flies

Learning and memory require the development, modification and maintenance of brain tissue, which cost time and energy. It may be adaptive for developing animals to adjust such investments based on environmental cues indicating the future utility of learning. The optimal learning ability that maximizes fitness will vary with the degree of complexity or difficulty of the environment, and developing animals may show an adaptive plastic modification of the extent of their learning ability based on early‐life cues of environmental complexity. We tested whether fruit fly larvae reared in a ‘complex’ environment, where they had to search, sample and choose between three foods differing in flavour and bitterness subsequently possessed greater learning abilities than larvae reared in a simple environment with only one food type. We tested learning ability both at the larval stage and in young adults. Our results suggest that, despite theoretical and intuitive appeal, these environmental factors did not affect learning ability.