Microscale insights into ocean-scale processes: microbial behaviour as a driver of ocean biogeochemistry. Microscopic plankton regulate the ocean's chemical cycles, which ultimately support life on earth. However, the ecological interactions driving these processes are poorly understood. This project will use novel approaches to decipher the behaviours of marine microbes, providing a more complete perception of how ocean ecosystems operate and influence climate.
Understanding marine biodiversity across vast spatial scales. Large-scale studies of biodiversity are frequently recommended by ecologists, but their costs are prohibitive. More efficient, yet accurate, sampling and analytical procedures are needed. This proposal will provide new quantitative knowledge on patterns of diversity of marine species (fish & invertebrates) from local to regional scales across southern Australia and northern New Zealand. An innovative feature of this research is the c ....Understanding marine biodiversity across vast spatial scales. Large-scale studies of biodiversity are frequently recommended by ecologists, but their costs are prohibitive. More efficient, yet accurate, sampling and analytical procedures are needed. This proposal will provide new quantitative knowledge on patterns of diversity of marine species (fish & invertebrates) from local to regional scales across southern Australia and northern New Zealand. An innovative feature of this research is the contribution of new ecological information with novel analytical procedures to identify the consequences of using more cost-effective techniques on quantifying patterns of biodiversity. This understanding is fundamental to the on-going advancement of ecology and conservation biology.Read moreRead less
Regime change: when and how do ecological subordinates turn dominant? This project aims to bridge the gap between physiology and ecology in kelp forest species by developing mechanistic models to predict change and, in an unprecedented step, test them in long-term experiments at naturally acidified sites to understand the consequences of ocean acidification (OA) and warming for kelp forests. Ecosystem change is a frequent outcome of decadal modifications of the physical and chemical environment. ....Regime change: when and how do ecological subordinates turn dominant? This project aims to bridge the gap between physiology and ecology in kelp forest species by developing mechanistic models to predict change and, in an unprecedented step, test them in long-term experiments at naturally acidified sites to understand the consequences of ocean acidification (OA) and warming for kelp forests. Ecosystem change is a frequent outcome of decadal modifications of the physical and chemical environment. Whilst these changes often involve degradation from productive states, we have a poor understanding of the mechanisms which drive change. Key stressors in marine systems, OA and warming are predicted to drive loss of kelp forests but we still don't understand the reality of these predictions.Read moreRead less
The effect of native invasions on Australian fisheries species. This project aims to forecast climate-related changes in the diversity, distribution and abundance of fisheries species. In a changing world where many people depend on oceans for food and livelihood, predicting the future distribution of fisheries species is a challenge. Native invasions and ocean warming are stressing inshore fisheries species, but rigorous empirical data and models that can reliably forecast these effects are lac ....The effect of native invasions on Australian fisheries species. This project aims to forecast climate-related changes in the diversity, distribution and abundance of fisheries species. In a changing world where many people depend on oceans for food and livelihood, predicting the future distribution of fisheries species is a challenge. Native invasions and ocean warming are stressing inshore fisheries species, but rigorous empirical data and models that can reliably forecast these effects are lacking. This project intends to reveal the drivers of successful native invasions, evaluate their effect on fish diversity and productivity, and develop holistic models that forecast their effects on inshore fisheries species’ near-future distribution and stocks.Read moreRead less
Bottom-up effects of nutrients on estuarine fish related ecosystems. Over 84% of Australians live within 50 km of the coast, and have large impacts on coastal ecosystems, such as increasing nutrients in estuaries. Nutrients have strong bottom-up effects on fish ecosystems, especially during critical juvenile life history stages. Elevated nutrients can alter fish productivity and sustainability, having ecosystem and social implications. This project will combine experimental evidence with novel a ....Bottom-up effects of nutrients on estuarine fish related ecosystems. Over 84% of Australians live within 50 km of the coast, and have large impacts on coastal ecosystems, such as increasing nutrients in estuaries. Nutrients have strong bottom-up effects on fish ecosystems, especially during critical juvenile life history stages. Elevated nutrients can alter fish productivity and sustainability, having ecosystem and social implications. This project will combine experimental evidence with novel approaches of fatty acid tracers in food-webs and fish otolith (earbone) chemistry, to determine how nutrients affect fish ecosystems, recruitment, and survivorship. This project will provide information needed to create sustainable fisheries, to safeguard Australia's fisheries resources for future generations.Read moreRead less
Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understandin ....Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understanding of how microbes control seagrass health and an enhanced capacity to develop effective restoration strategies for Australia's valuable seagrass ecosystems. Benefits include improving the extensive environmental, economic, social/cultural services Australian communities derive from seagrass ecosystems.Read moreRead less
The role of pulsed water events in structuring marine benthic communities along the southern Australian coastline. Marked differences in benthic community structure have been observed that are associated with pulsed cold-water events, possibly driven by internal wave phenomena. Such events have the potential to act as very important controls on both regional and local patterns of benthic biodiversity. To date, however, their effects and mechanisms of action have never been examined in Australi ....The role of pulsed water events in structuring marine benthic communities along the southern Australian coastline. Marked differences in benthic community structure have been observed that are associated with pulsed cold-water events, possibly driven by internal wave phenomena. Such events have the potential to act as very important controls on both regional and local patterns of benthic biodiversity. To date, however, their effects and mechanisms of action have never been examined in Australia. The fundamental outcome from this project will be the first assessment of the occurrence, geographical extent and ecological consequences of pulsed water phenomena along the southern Australian coastline.Read moreRead less
Saving seagrass from climate change. This research aims to test whether seagrass ecosystems can be safeguarded from climate change impacts by enhancing genetic connectivity in range edge populations using novel genetic rescue approaches. We will use the range edge seagrass meadows of the UNESCO World Heritage Site of Shark Bay as our model, which was significantly impacted by a marine heat wave in 2010/2011. The project will generate new knowledge on how seagrasses can adapt and survive in situ. ....Saving seagrass from climate change. This research aims to test whether seagrass ecosystems can be safeguarded from climate change impacts by enhancing genetic connectivity in range edge populations using novel genetic rescue approaches. We will use the range edge seagrass meadows of the UNESCO World Heritage Site of Shark Bay as our model, which was significantly impacted by a marine heat wave in 2010/2011. The project will generate new knowledge on how seagrasses can adapt and survive in situ. Expected outcomes are improved conservation, management and restoration practices for seagrass meadows. This should provide significant benefits for long-term resilience of this economically and culturally significant ecosystem.Read moreRead less
The interplay between natural and human perturbations in structuring marine habitats. Empirical predictions of which could be the changes to natural habitats caused by human perturbations will increase the ability to prevent irreversible losses of biodiversity. This project will enable the planning of sound strategies for the conservation of valuable ecosystems, such as kelp forests, in view of the massive changes that will likely take place as a consequence of increasing exploitation of marine ....The interplay between natural and human perturbations in structuring marine habitats. Empirical predictions of which could be the changes to natural habitats caused by human perturbations will increase the ability to prevent irreversible losses of biodiversity. This project will enable the planning of sound strategies for the conservation of valuable ecosystems, such as kelp forests, in view of the massive changes that will likely take place as a consequence of increasing exploitation of marine resources and of global climatic changes. The scientific knowledge generated by this project is necessary for a sustainable development of coastal areas, which would guarantee the provision of goods and services to Australian future generations.Read moreRead less
Local and regional investigations into perturbations of marine habitat. Surprising changes to coastal ecology are forecast as increasing physical stresses (e.g. nutrient and sediment runoff) initiate changes to habitat. Lack of information about perturbations remains a major gap in marine ecology and coastal management. Multifactorial experiments will examine perturbations to one of temperate Australia's most widespread subtidal habitats (kelp forests) to test predictions derived from ecologic ....Local and regional investigations into perturbations of marine habitat. Surprising changes to coastal ecology are forecast as increasing physical stresses (e.g. nutrient and sediment runoff) initiate changes to habitat. Lack of information about perturbations remains a major gap in marine ecology and coastal management. Multifactorial experiments will examine perturbations to one of temperate Australia's most widespread subtidal habitats (kelp forests) to test predictions derived from ecological theory. Tests focus on (1) models about abrupt switches of habitat to contrasting states, and (2) responses among regions bearing striking differences in consumer control. These trans-Australian tests may change the way we view one of the world's most extensive temperate coastlines.Read moreRead less