Neurofly 2008 abstracts : the 12th European Drosophila neurobiology conference 6-10 September 2008 Wuerzburg, Germany

This volume consists of a collection of conference abstracts

Happy or Hangry Families: Does kinship mediate cooperation and cannibalism in Drosophila melanogaster larvae?

The fruit fly Drosophila melanogaster has a long history as a research model for studies on behaviour and group dynamics. When individuals are grouped in an environment and resources decrease, then they may behave co-operatively with one another or antagonistically compete. Hamilton’s Law states that if the benefit of helping a related individual out-weighs the cost to its direct fitness, then the individual’s indirect fitness will increase when they help their kin compared to helping an unrelated stranger. Yet it is unknown whether kinship mediates larval behaviour to encourage co-operation and/or lessen antagonistic behaviours between consanguineous individuals. In this thesis I set out to examine and understand how kinship might be important to the evolution of sociality and anti-social behaviours in Drosophila melanogaster larvae. First, I set out to determine if kinship mediates the co-operative feeding cluster behaviour between 3rd instar larvae and whether there are evolutionary benefits to co-operating with kin over unrelated conspecifics in three separate assays. I changed the average degree of relatedness between individuals in the social environment and measured the characteristics of the feeding cluster (size, frequency and number of larvae) in the first assay. In the second assay I measured the weight and survivorship of the matured adult flies, and in the third assay I measured the proportion of related individuals in the clusters. From these assays, I was able to determine that the higher the degree of relatedness between individuals resulted: in increasing clusters with relatives, in increasing cooperation between related individuals in cluster formation, and evidence of benefits to co-operating with kin than strangers (with increased survivorship and weight in females as a predictor of fecundity). Secondly, I also examined how kinship might affect the expression of cannibalistic behaviour towards related individuals compared to unrelated conspecifics. I conducted assays with 2nd instar larvae, giving them the choice to cannibalize related eggs or unrelated eggs. I was able to determine that there is some evidence of cannibalism occurring with larvae more often eating unrelated eggs, however there were also some unexpected results which occurred. For example, there was no difference in the median time to the first incidence of cannibalism nor differences in the duration of the cannibalistic interactions. As such, more experiments need to be conducted to support this hypothesis and to better understand any underlining mechanisms that might be in play. Kinship selection might be the key to unlocking the underlining factors of why individuals behave pleasantly towards one another and antagonistically with rivals; and eventually understanding the genes behind those behaviours might also help us understand our own evolutionary origins of sociality

Mechanisms of Odor-Tracking: Multiple Sensors for Enhanced Perception and Behavior

Early in evolution, the ability to sense and respond to changing environments must have provided a critical survival advantage to living organisms. From bacteria and worms to flies and vertebrates, sophisticated mechanisms have evolved to enhance odor detection and localization. Here, we review several modes of chemotaxis. We further consider the relevance of a striking and recurrent motif in the organization of invertebrate and vertebrate sensory systems, namely the existence of two symmetrical olfactory sensors. By combining our current knowledge about the olfactory circuits of larval and adult Drosophila, we examine the molecular and neural mechanisms underlying robust olfactory perception and extend these analyses to recent behavioral studies addressing the relevance and function of bilateral olfactory input for gradient detection. Finally, using a comparative theoretical approach based on Braitenberg's vehicles, we speculate about the relationships between anatomy, circuit architecture and stereotypical orientation behaviors

Pervasive behavioral effects of microRNA regulation in Drosophila

The effects of microRNA (miRNA) regulation on the genetic programs underlying behavior remain largely unexplored. Despite this, recent work in Drosophila shows that mutation of a single miRNA locus (miR-iab4/iab8) affects the capacity of the larva to correct its orientation if turned upside down (self-righting, SR), suggesting that other miRNAs might also be involved in behavioral control. Here we explore this possibility, studying early larval SR behavior in a collection of 81 Drosophila miRNA mutants covering almost the entire miRNA complement of the late embryo. Unexpectedly, we observe that >40% of all miRNAs tested significantly affect SR time, revealing pervasive behavioral effects of miRNA regulation in the early larva. Detailed analyses of those miRNAs affecting SR behavior (SR-miRNAs) show that individual miRNAs can affect movement in different ways, suggesting that specific molecular and cellular elements are affected by individual miRNA mutations. Furthermore, gene expression analysis shows that the Hox gene Abdominal-B (Abd-B) represents one of the targets deregulated by several SR-miRNAs. Our work thus reveals pervasive effects of miRNA regulation on a complex innate behavior in Drosophila and suggests that miRNAs may be core components of the genetic programs underlying behavioral control in other animals too

Social creatures: model animal systems for studying the neuroendocrine mechanisms of social behaviour

Work was supported by grants awarded to ML (BBSRC BB/S000224/1), OJB (BO 1958/8-2, GRK 2174), KEB (Wellcome Trust 109614/Z/15/Z, MRC MR/N004574/1), AJ (BBSRC BB/S000801) and GL (Israel Science Foundation #1511/16; United States-Israel Binational Science Foundation #2017325; Nella and Leon Benoziyo Center for Neurological Diseases, Richard F. Goodman Yale/Weizmann Exchange Program and Estate of Emile Mimran).The interaction of animals with conspecifics, termed social behaviour, has a major impact on the survival of many vertebrate species. Neuropeptide hormones modulate the underlying physiology that governs social interactions, and many findings concerning the neuroendocrine mechanisms of social behaviours have been extrapolated from animal models to humans. Neurones expressing neuropeptides show similar distribution patterns within the hypothalamic nucleus, even when evolutionarily distant species are compared. During evolution, hypothalamic neuropeptides and releasing hormones have retained not only their structures, but also their biological functions, including their effects on behaviour. Here, we review the current understanding of the mechanisms of social behaviours in several classes of animals, such as worms, insects and fish, as well as laboratory, wild and domesticated mammals.Publisher PDFPeer reviewe

Cracking the Odor Code: Molecular and Cellular Deconstruction of the Olfactory Circuit of Drosophila Larvae

The Drosophila larva offers a powerful model system to investigate the general principles by which the olfactory system processes behaviorally relevant sensory stimuli. The numerically reduced larval olfactory system relieves the formidable molecular and cellular complexity found in other organisms. This thesis presents a study in four parts that investigates molecular and neuronal mechanisms of larval odor coding. First, the larval odorant receptor (OR) repertoire was characterized. ORs define the olfactory receptive range of an animal. Each of the 21 larval olfactory sensory neurons (OSNs) expresses one or rarely two ORs, along with the highly conserved olfactory co-receptor Or83b. Second, odor response profiles of 11 larval OSNs were characterized by calcium imaging. A subset of larval neurons showed overlapping responses to the set of odorants tested, while other neurons showed either very narrow or very broad tuning. Third, the olfactory circuit for ethyl butyrate was investigated in detail. Three OSNs, expressing Or35a, Or42a and Or42b, responded with different sensitivity to ethyl butyrate. Second order projection neurons synapsing with each of these OSNs showed similar concentration tuning, but inhibitory interneurons showed high response thresholds and were only activated at high odor concentrations. We correlated these concentration-dependent response properties with larval chemotaxis behavior. Fourth, the relevance of olfaction to animals was investigated in competitive rearing experiments. Or83b mutants experienced a selective disadvantage when they had to forage for limiting food sources, particularly when competing against larvae with normal olfactory function. Thus, odor coding is achieved both by peripheral tuning and central circuit modulation

The neurogenetics of group behavior in Drosophila melanogaster

Organisms rarely act in isolation. Their decisions and movements are often heavily influenced by direct and indirect interactions with conspecifics. For example, we each represent a single node within a social network of family and friends, and an even larger network of strangers. This group membership can affect our opinions and actions. Similarly, when in a crowd, we often coordinate our movements with others like fish in a school, or birds in a flock. Contributions of the group to individual behaviors are observed across a wide variety of taxa but their biological mechanisms remain largely unknown. With the advent of powerful computational tools as well as the unparalleled genetic accessibility and surprisingly rich social life of Drosophila melanogaster, researchers now have a unique opportunity to investigate molecular and neuronal determinants of group behavior. Conserved mechanisms and/or selective pressures in D. melanogaster can likely inform a much wider phylogenetic scale. Here, we highlight two examples to illustrate how quantitative and genetic tools can be combined to uncover mechanisms of two group behaviors in D. melanogaster: social network formation and collective behavior. Lastly, we discuss future challenges towards a full understanding how coordinated brain activity across many individuals gives rise to the behavioral patterns of animal societies

Bisphenol a affects neurodevelopmental gene expression, cognitive function, and neuromuscular synaptic morphology in Drosophila melanogaster

Bisphenol A (BPA) is an environmentally prevalent endocrine disrupting chemical that can impact human health and may be an environmental risk factor for neurodevelopmental disorders. BPA has been associated with behavioral impairment in children and a variety of neurodevelopmental phenotypes in model organisms. We used Drosophila melanogaster to explore the consequences of developmental BPA exposure on gene expression, cognitive function, and synapse development. Our transcriptome analysis indicated neurodevelopmentally relevant genes were predominantly downregulated by BPA. Among the misregulated genes were those with roles in learning, memory, and synapse development, as well as orthologs of human genes associated with neurodevelopmental and neuropsychiatric disorders. To examine how gene expression data corresponded to behavioral and cellular phenotypes, we first used a predator-response behavioral paradigm and found that BPA disrupts visual perception. Further analysis using conditioned courtship suppression showed that BPA impairs associative learning. Finally, we examined synapse morphology within the larval neuromuscular junction and found that BPA significantly increased the number of axonal branches. Given that our findings align with studies of BPA in mammalian model organisms, this data indicates that BPA impairs neurodevelopmental pathways that are functionally conserved from invertebrates to mammals. Further, because Drosophila do not possess classic estrogen receptors or estrogen, this research suggests that BPA can impact neurodevelopment by molecular mechanisms distinct from its role as an estrogen mimic