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Theoretical and empirical investigations on population stability and dispersal evolution using laboratory populations of Drosophila melanogaster

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dc.contributor.advisor DEY, SUTIRTH en_US
dc.contributor.author TUNG, SUDIPTA en_US
dc.date.accessioned 2018-05-09T03:26:24Z
dc.date.available 2018-05-09T03:26:24Z
dc.date.issued 2018-05 en_US
dc.identifier.uri http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/932
dc.description.abstract Global climate is changing rapidly and is accompanied by large-scale fragmentation and destruction of habitats. These environmental adversities not only affecting the life-history and behaviour of organisms but also compromise the stability of local population dynamics. Although a number of control methods for stabilizing the dynamics had been proposed, there were no comparisons of the relative efficiencies of these methods. More critically, majority of these methods had not yet been validated empirically. Therefore I undertook theoretical study that compared six such control methods in terms of attaining a given level of stability over four different life history/environment combinations. This analysis showed that although no single method was unambiguously superior to others, the methods that involved culling reduce the risk of extinction more efficiently, whereas methods that involve only restocking are better in reducing temporal fluctuations in population sizes. Subsequently, using a series of experiments, I validated the efficiency of four well-known control methods in enhancing the stability of widely fluctuating, extinction-prone populations of Drosophila melanogaster. These experiment showed that methods which incorporate both culling and restocking, can simultaneously achieve multiple kinds of stability and therefore are strong candidates for field applications. I also showed that the choice of methods under a given condition would depend critically upon what kind of stability needs to be attained. Non-Drosophila specific, biologically realistic simulations suggested the generalizability of these results over a wide range of taxa. Subsequently, in order to obtain mechanistic insights about the determinants of dynamics and stability, I built an individual-based, stage-structured model of Drosophila dynamics. This model included parameters that are common to the life-history of several holometabolus insects. I calibrated this model using data from laboratory populations of Drosophila melanogaster. The calibrated model could capture various aspects of Drosophila dynamics under four different nutritional regimes. Further simulations showed that unequal sex-ratio and sex-specific culling are greatly influenced by fecundity, whereas complex interaction between juvenile nutritional levels and adult fecundity determines the efficiency of Sterile Insect Technique, a widely-used pest control method. In the context of global climate change and habitat degradation, dispersal is one of the traits that is likely to be crucial for the survival of many populations. Consequently, understanding the causes and consequences of evolution of dispersal has been a major area of interest in ecology and evolutionary biology. I report the results of an artificial selection experiment for increased dispersal using four large (N~2500) outbred populations of D. melanogaster. Dispersal propensity, ability and kernel evolved rapidly in the selected populations. The differences persisted even in the absence of proximate drivers for dispersal. Interestingly, the selected lines did not incur any major life-history costs, but behavioral traits like activity, exploration and aggression were increased. I also investigated the metabolomic changes that took place in these lines to accommodate the excess energy demand of active dispersal and, as a correlated response, led to the observed behavioral changes. Finally, I summarized the main results of these studies, discussed their potential implications and mentioned possible avenues for further work. en_US
dc.language.iso en en_US
dc.subject Dispersal evolution en_US
dc.subject Fluctuation index en_US
dc.subject Persistence en_US
dc.subject Effective population size en_US
dc.subject Constancy en_US
dc.subject Effort magnitude en_US
dc.subject Both Limiter Control en_US
dc.subject Minimum critical size en_US
dc.subject Stage-structured model en_US
dc.subject Dispersal propensity en_US
dc.subject Dispersal ability en_US
dc.subject Spatial extent en_US
dc.subject Condition-dependent dispersal en_US
dc.subject Phenotype-dependent dispersal en_US
dc.subject Sex-biased dispersal en_US
dc.subject Sterile Insect Technique en_US
dc.subject Life-history en_US
dc.subject Aggression en_US
dc.subject Exploration en_US
dc.subject Locomotor activity en_US
dc.subject NMR spectroscopy en_US
dc.subject Metabolomics en_US
dc.subject Octopamine en_US
dc.subject Biology en_US
dc.title Theoretical and empirical investigations on population stability and dispersal evolution using laboratory populations of Drosophila melanogaster en_US
dc.type Thesis en_US
dc.publisher.department Dept. of Biology en_US
dc.type.degree Ph.D en_US
dc.contributor.department Dept. of Biology en_US
dc.contributor.registration 20123172 en_US


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  • PhD THESES [603]
    Thesis submitted to IISER Pune in partial fulfilment of the requirements for the degree of Doctor of Philosophy

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