TY - JOUR A1 - Poethke, Hans J. A1 - Pfenning, Brenda A1 - Hovestadt, Thomas T1 - The relative contribution of individual and kin selection to the evolution of density-dependent dispersal rates N2 - Questions: What are the relative contributions of kin selection and individual selection to the evolution of dispersal rates in fragmented landscapes? How do environmental parameters influence the relative contributions of both evolutionary forces? Features of the model: Individual-based simulation model of a metapopulation. Logistic local growth dynamics and density-dependent dispersal. An optional shuffling algorithm allows the continuous destruction of any genetic structure in the metapopulation. Ranges of key variables: Depending on dispersal mortality (0.05-0.4) and the strength of environmental fluctuations, mean dispersal probability varied between 0.05 and 0.5. Conclusions: For local population sizes of 100 individuals, kin selection alone could account for dispersal probabilities of up to 0.1. It may result in a ten-fold increase of optimal dispersal rates compared with those predicted on the basis of individual selection alone. Such a substantial contribution of kin selection to dispersal is restricted to cases where the overall dispersal probabilities are small (textless 0.1). In the latter case, as much as 30% of the total fitness of dispersing individuals could arise from the increased reproduction of kin left in the natal patch. KW - dispersal rate KW - dynamics KW - environmental correlation KW - evolutionary modelling KW - genetics KW - individual-based model KW - kin competition Y1 - 2007 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-48225 ER - TY - THES A1 - Pfenning, Brenda T1 - Seasonal life-history adaptation in the water strider GERRIS LACUSTRIS T1 - Anpassung der Lebenslaufstrategie an saisonalen Umwelten beim Gemeinen Wasserläufer Gerris lacustris N2 - Insects living in temperate latitudes need to adjust their life-history to a seasonally variable environment. Reproduction, growth, and development have to be completed within the limited period where environmental conditions are favourable while climatically adverse conditions have to be spent in a state of diapause. Consequently, questions how individuals adapt their life-history to seasonality and which mechanisms underlie the responses to seasonal cues, like photoperiod, are important issues in the study of life-history strategies. This thesis focuses on the life-history adaptation to seasonality in the wing-dimorphic common pond skater Gerris lacustris L. (Heteroptera: Gerridae). Using a combination of field and laboratory studies as well as mathematical modelling, it is adressed how variation in the availability of thermal energy impacts on various aspects of larval development such as accumulated thermal energy (i.e. physiological development time), developmental pathway (direct reproduction vs. diapause) and wing dimorphism. N2 - Insekten in temperierten Breiten müssen ihre Lebenslaufstrategie an eine saisonale Umwelt anpassen. Reproduktion, Wachstum und Entwicklung können nur innerhalb der begrenzten Phase geeigneter Umweltbedingungen stattfinden, während klimatisch ungünstige Bedingungen in einem Stadium der Diapause überdauert werden müssen. Die Fragen, wie Individuen ihre Lebenslaufstrategie an Saisonalität anpassen und welche Mechanismen der Reaktion auf saisonale Umweltreize (insbesondere der Photoperiode) zugrunde liegen, sind daher zentrale Aspekte in der Erforschung von Lebenslaufstrategien. Diese Arbeit beschäftigt sich mit Anpassungen der Lebenslaufstrategie des flügeldimorphen Gemeinen Wasserläufers Gerris lacustris L. (Heteroptera: Gerridae) an Saisonaliät. Mit einer Kombination aus Feld- und Laborstudien sowie mathematischer Modellierung wird untersucht, wie Variationen in der Verfügbarkeit thermaler Energie auf verschiedene Aspekte der Larvalentwicklung - wie die akkumulierte thermale Energie (physiologische Entwicklungszeit), den Entwicklungsweg (direkte Reproduktion vs. Diapause) und den Flügeldimorphimus – Einfluss nehmen. KW - Wanzen KW - Temperatur KW - Habitat KW - Entwicklung KW - Gerridae KW - Lebenslaufstrategie KW - Voltinismus KW - Flügeldimorphismus KW - thermale Energie KW - Gerridae KW - life history strategy KW - voltinism KW - wing dimorphism KW - thermal energy Y1 - 2008 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-27900 ER -