Population growth, genetic variation and adaptation in two Caulerpa species in southeastern Australia. This project will examine factors that influence the population growth, reproduction, genetic variation and adaptation in two seaweeds; the invasive Caulerpa taxifolia and the possibly invasive C. filiformis. A combination of surveys, modelling, molecular genetics and field experiments will be undertaken to achieve this. The current ambiguity surrounding the status of C. filiformis as an inva ....Population growth, genetic variation and adaptation in two Caulerpa species in southeastern Australia. This project will examine factors that influence the population growth, reproduction, genetic variation and adaptation in two seaweeds; the invasive Caulerpa taxifolia and the possibly invasive C. filiformis. A combination of surveys, modelling, molecular genetics and field experiments will be undertaken to achieve this. The current ambiguity surrounding the status of C. filiformis as an invasive species in Australia will be addressed by comparing DNA sequences of Australian and African plants. This project will provide critical data for managing invasive species, but more broadly, increase the current understanding of their biology and the factors important in their population growth and adaptation.Read moreRead less
Climate change and ocean acidification: will southern ocean coccolithophorids be winners or losers? Implications for the global carbon pump. This proposal brings skills on morphotaxonomy, microalgal culturing, physiology and biogeochemistry into the flurry of international activity focusing on consequences of ocean acidification. Increasing atmospheric carbon dioxide (CO2) is predicted to reduce calcification in the phytoplankton Emiliania huxleyi, notably in the Southern Ocean. In contrast, hi ....Climate change and ocean acidification: will southern ocean coccolithophorids be winners or losers? Implications for the global carbon pump. This proposal brings skills on morphotaxonomy, microalgal culturing, physiology and biogeochemistry into the flurry of international activity focusing on consequences of ocean acidification. Increasing atmospheric carbon dioxide (CO2) is predicted to reduce calcification in the phytoplankton Emiliania huxleyi, notably in the Southern Ocean. In contrast, higher CO2 may stimulate photosynthesis and enhanced stratification may also select for E. huxleyi. These changes will affect foodwebs and the ability of the ocean to absorb CO2. Predicting the future success of this key organism is vital to understand the consequences of global change in Australian and Southern Ocean waters and to set targets for carbon emissions.Read moreRead less