Predicting Biodiversity from Population Dynamics. This research aims to deepen our understanding of how changes to the environment, including those attributable to human activities, influence the ecological and evolutionary mechanisms that generate and maintain biodiversity. This understanding is of urgent importance, in light of the predicted changes in climate and habitat over the next century, because biodiversity is critical to the proper functioning of ecosystems that human societies depend ....Predicting Biodiversity from Population Dynamics. This research aims to deepen our understanding of how changes to the environment, including those attributable to human activities, influence the ecological and evolutionary mechanisms that generate and maintain biodiversity. This understanding is of urgent importance, in light of the predicted changes in climate and habitat over the next century, because biodiversity is critical to the proper functioning of ecosystems that human societies depend upon. The graduate student involved in this research will have the opportunity to receive in-depth training as part of a cross-disciplinary collaboration that combines mathematics, ecology, evolution, and paleontology.
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Mechanisms of action and expression of bioactive compounds produced by the surface associated marine bacterium Pseudoalteromonas tunicata. The marine surface-associated bacterium Pseudoalteromonas tunicata produces a number of bioactive metabolites that inhibit the colonisation and growth of common fouling organisms such as bacteria, fungi, algae and invertebrate larvae. The antibacterial and antifungal compounds represent novel metabolites active against a remarkable range of both medically and ....Mechanisms of action and expression of bioactive compounds produced by the surface associated marine bacterium Pseudoalteromonas tunicata. The marine surface-associated bacterium Pseudoalteromonas tunicata produces a number of bioactive metabolites that inhibit the colonisation and growth of common fouling organisms such as bacteria, fungi, algae and invertebrate larvae. The antibacterial and antifungal compounds represent novel metabolites active against a remarkable range of both medically and agriculturally important bacteria and fungi. This project aims to explore the identity, mode of action and regulation of expression of these compounds. This research proposal addresses several significant biological concepts and will lead to the development of novel environmentally friendly antifouling and antimicrobial technologies.Read moreRead less
Chemical Defenses Against Microbial Colonisation of Living Marine Surfaces. Microorganisms have a major impact on all ecosystems. Many of these effects are due to the formation of biofilms - cell clusters and their slime matrix - on living and non-living surfaces. Biofilm formation is often regulated by chemical signals. The aim of this project is to understand how naturally produced chemical signals mediate the formation of biofilms on surfaces of marine macroalgae (seaweeds) at both the eco ....Chemical Defenses Against Microbial Colonisation of Living Marine Surfaces. Microorganisms have a major impact on all ecosystems. Many of these effects are due to the formation of biofilms - cell clusters and their slime matrix - on living and non-living surfaces. Biofilm formation is often regulated by chemical signals. The aim of this project is to understand how naturally produced chemical signals mediate the formation of biofilms on surfaces of marine macroalgae (seaweeds) at both the ecological and molecular levels. By understanding colonisation of natural living surfaces, this project will lead directly to significant advances in control of microorganisms in a variety of applied areas (water treatment, biomaterials, antifouling).Read moreRead less