From developmental stability to organismic senility: Hox genes and telomere impact on life history evolution. Australia benefits from training researchers and technicians in new, break-through biotechnology and from applying this knowledge to relevant, cutting-edge questions in highly publicized research fields. This project contains both these ingredients. Our model species (a lizard) has a relatively high level of offspring malformations (ca 15%), which makes it much more likely to detect thei ....From developmental stability to organismic senility: Hox genes and telomere impact on life history evolution. Australia benefits from training researchers and technicians in new, break-through biotechnology and from applying this knowledge to relevant, cutting-edge questions in highly publicized research fields. This project contains both these ingredients. Our model species (a lizard) has a relatively high level of offspring malformations (ca 15%), which makes it much more likely to detect their underlying genetic mechanism. Furthermore, we can also assess how these animals survive and reproduce in relation to how quickly they age, which can be measured by assessing the shortening of telomeres per unit time. Thus, this collaboration provides an opportunity to train Australian researchers and in that process generate very high profile research.Read moreRead less
The evolutionary effect of the domestication process in a model organism. A significant proportion of research in the field of evolutionary biology, focuses on captive populations of laboratory-bred animals. Little is known about the impact of the domestication process on these species, raising questions about the relevance of such studies. The Australian zebra finch is the avian model species of choice in evolutionary biology laboratories in Europe and the USA and the focus of many high profile ....The evolutionary effect of the domestication process in a model organism. A significant proportion of research in the field of evolutionary biology, focuses on captive populations of laboratory-bred animals. Little is known about the impact of the domestication process on these species, raising questions about the relevance of such studies. The Australian zebra finch is the avian model species of choice in evolutionary biology laboratories in Europe and the USA and the focus of many high profile publications. Our investigation into the affect of domestication on the evolutionary biology of this key model species will have a high international impact, raising the profile of Australian research, in addition to providing fundamental knowledge across several areas of reproductive biology.Read moreRead less
Evolution of host relationships among the parasitic wasps inferred from morphology, DNA sequences and mitochondrial genome organisation. The parasitic Hymenoptera (wasps) are extensively used as biological control agents of agricultural and horticultural pests worldwide, but detailed information on their evolutionary relationships, how they have coevolved with major host groups, and the patterns of host relationships across various wasp families are lacking. This project will employ DNA sequence ....Evolution of host relationships among the parasitic wasps inferred from morphology, DNA sequences and mitochondrial genome organisation. The parasitic Hymenoptera (wasps) are extensively used as biological control agents of agricultural and horticultural pests worldwide, but detailed information on their evolutionary relationships, how they have coevolved with major host groups, and the patterns of host relationships across various wasp families are lacking. This project will employ DNA sequence data from 'new' genes, information on mitochondrial genome organisation, as well as morphology, to generate robust phylogenies for braconid and scelionid wasps that can be used to determine patterns of host utilisation and predict hosts for wasp groups where this information is currently unknown.Read moreRead less
Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate furthe ....Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate further knowledge of the diversity and biological significance of subterranean fauna in the arid zone of Australia, providing important background data for assessing the impacts of mining activities on groundwater-dependent-ecosystems and improved strategies for their sustainable management. Read moreRead less