Early evolutionary origins of mechanosensory transduction: structure, function and phylogenetic studies of the family of mechanosensitive channels in cell-walled organisms. The proposed project is based on the recent progress the applicants have made by (i) identifying a novel family of mechanosensitive (MS) channels in cell-walled organisms, which include Archaea and Bacteria (prokaryotes), as well as fungi and plants (eukaryotes), and (ii) determining basic aspects of the structural dynamics ....Early evolutionary origins of mechanosensory transduction: structure, function and phylogenetic studies of the family of mechanosensitive channels in cell-walled organisms. The proposed project is based on the recent progress the applicants have made by (i) identifying a novel family of mechanosensitive (MS) channels in cell-walled organisms, which include Archaea and Bacteria (prokaryotes), as well as fungi and plants (eukaryotes), and (ii) determining basic aspects of the structural dynamics of MscL, the prototype MS channel, using electronparamagnetic resonance spectroscopy and molecular dynamics simulations in combination with the patch clamp technique. The aim of the project is to elucidate the molecular principles underlying the function of MS channels, which is of fundamental importance for understanding of the biophysics and physiology of mechanosensory transduction throughout the biological world.Read moreRead less
Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid i ....Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid in developing and designing artificial tactile sensors inspired by their biological models studied in this project. Long-term, the project is expected to make an original contribution towards developing new technologies and novel medical applications, both of which promise to be of great national benefit.Read moreRead less
Diversity out of a hybrid zone: the interplay of reinforcement and sexual selection in the formation of new species. How are there so many different species? Understanding how new species arise is a fundamental question because it explains current biodiversity and reveals the processes that will continue to give rise to new species in the future. An integral part of any animal species is who they choose to mate with, but how mate choice evolves to create new species remains poorly understood. He ....Diversity out of a hybrid zone: the interplay of reinforcement and sexual selection in the formation of new species. How are there so many different species? Understanding how new species arise is a fundamental question because it explains current biodiversity and reveals the processes that will continue to give rise to new species in the future. An integral part of any animal species is who they choose to mate with, but how mate choice evolves to create new species remains poorly understood. Here I will be studying the processes that affect the evolution of mate choice in an Australian rainforest frog hybrid zone. This system is uniquely suitable for providing internationally important insights into the evolutionary processes that form new species.Read moreRead less
Biohumanities: Philosophical, Historical, and Socio-Cultural Studies of Contemporary Bioscience. Improving understanding of the meaning and implications of contemporary bioscience, especially genetics and molecular biology, through bioliterate research in the humanities and social sciences, and conversely through better assimilation of bioscience and its significance by the humanities and social sciences. The research will be conducted in close collaboration with the Australian scientific commun ....Biohumanities: Philosophical, Historical, and Socio-Cultural Studies of Contemporary Bioscience. Improving understanding of the meaning and implications of contemporary bioscience, especially genetics and molecular biology, through bioliterate research in the humanities and social sciences, and conversely through better assimilation of bioscience and its significance by the humanities and social sciences. The research will be conducted in close collaboration with the Australian scientific community and will be disseminated back to the scientific community, to the humanities and to the Australian public. The project will bring to Australia the strengths of the applicant's existing collaborations with leading research centres in this field in the USA, UK and Canada.Read moreRead less
Thinking Systems: Navigating Through Real and Conceptual Spaces. The project will provide fundamental insights into physical and conceptual spaces and develop applications in robotics and information systems. The project brings together national and international researchers to study how humans and other animals navigate: how trajectories through space are used to build maps, the neural bases of these mapping processes and how to use maps to achieve goals. The project will develop a new generati ....Thinking Systems: Navigating Through Real and Conceptual Spaces. The project will provide fundamental insights into physical and conceptual spaces and develop applications in robotics and information systems. The project brings together national and international researchers to study how humans and other animals navigate: how trajectories through space are used to build maps, the neural bases of these mapping processes and how to use maps to achieve goals. The project will develop a new generation of robots that can learn about the physical spaces they work in, and create concept-mapping systems that can map and navigate information spaces. Also, it will provide new insights into the mechanisms regulating human cognition and mental dysfunctions.Read moreRead less
Neural mechanisms for human form perception. This project aims to determine if there is a single cortical mechanism underlying the human ability to discriminate and recognise objects. It has been speculated that different classes of objects, or forms require different processes. Demonstrating a single process would be a significant advance towards understanding the neural mechanisms giving rise to our ability to segment visual fields into meaningful objects and background. This research provides ....Neural mechanisms for human form perception. This project aims to determine if there is a single cortical mechanism underlying the human ability to discriminate and recognise objects. It has been speculated that different classes of objects, or forms require different processes. Demonstrating a single process would be a significant advance towards understanding the neural mechanisms giving rise to our ability to segment visual fields into meaningful objects and background. This research provides a means for testing models of the neural interactions thought to be generating human form perception and will help us discover how the visual cortex converts raw sensory input into object and form perception.Read moreRead less
The function of truncated MEK1 protein in a G2 phase cell cycle delay and in mitosis. Understanding cell proliferation. Intracellular signaling pathways controlling cell growth are often mutated in cancers and other hyperproliferative diseases. Understanding precisely how these pathways operate and how mutations of these pathways can contribute to uncontrolled growth can readily provide new targets for preventative therapies or cures. We have identified a novel mechanism regulating one compone ....The function of truncated MEK1 protein in a G2 phase cell cycle delay and in mitosis. Understanding cell proliferation. Intracellular signaling pathways controlling cell growth are often mutated in cancers and other hyperproliferative diseases. Understanding precisely how these pathways operate and how mutations of these pathways can contribute to uncontrolled growth can readily provide new targets for preventative therapies or cures. We have identified a novel mechanism regulating one component of a well studied pathway, the MAPK pathway, and new functions for this component. The contribution of this novel component to mechanisms involved in regulating cell growth previously through to be controlled by the canonical MAPK pathway could change our understanding of the fundamental mechanisms controlling cell growth. Read moreRead less
Function of the unique mitotic form of MEK. Many of the mechanisms controlling normal cell growth and division are known, although there are an increasing number of examples of mechanism having more thn the originally defined functions. We have found that one well studied mechanism, the Ras-Raf-MEK-ERK pathway operates in a unique manner during the phase when cell division occurs, known as mitosis. Understanding this novel mechanism and identifying its function at this critical stage of cell d ....Function of the unique mitotic form of MEK. Many of the mechanisms controlling normal cell growth and division are known, although there are an increasing number of examples of mechanism having more thn the originally defined functions. We have found that one well studied mechanism, the Ras-Raf-MEK-ERK pathway operates in a unique manner during the phase when cell division occurs, known as mitosis. Understanding this novel mechanism and identifying its function at this critical stage of cell division will provide insights into how cell control the partitioning of replicated genome and produce two identical daugther cells.Read moreRead less
Functional characterisation of CMAP, a novel centrosome- and midbody-associated protein. Cell division is a highly regulated process involving many components to produce two daughter cells which contain an equal amount of DNA. Thus incorrect localisation and modification of specific proteins that regulate this process cause cell division errors resulting in genomic instability. We have recently identified a novel protein called CMAP that is involved in the final stages of cell division, which in ....Functional characterisation of CMAP, a novel centrosome- and midbody-associated protein. Cell division is a highly regulated process involving many components to produce two daughter cells which contain an equal amount of DNA. Thus incorrect localisation and modification of specific proteins that regulate this process cause cell division errors resulting in genomic instability. We have recently identified a novel protein called CMAP that is involved in the final stages of cell division, which involves the cleavage of the cell membrane to produce two daughter cells. Here, we aim to characterise the mechanism(s) of CMAP function and to identify and characterise CMAP binding proteins to further understand the mechanisms involved in the final stages of cell division to maintain genomic stability.Read moreRead less
Thinking about the future: The nature and development of mental time travel. This project is one of the first systematic investigations into the development of the human capacity to consider future events. A variety of novel tasks will probe what children know about the future and how it relates to their ability to reason about past events. Comparisons between children and apes will further inform us about the nature of this crucial mental skill. The findings will provide valuable information fo ....Thinking about the future: The nature and development of mental time travel. This project is one of the first systematic investigations into the development of the human capacity to consider future events. A variety of novel tasks will probe what children know about the future and how it relates to their ability to reason about past events. Comparisons between children and apes will further inform us about the nature of this crucial mental skill. The findings will provide valuable information for developing appropriate educational approaches and for our understanding of abnormalities. As international leaders in this field, we are in an ideal position to conduct this research, offer unique opportunities for postgraduate training, and to continue in Australia's outstanding tradition of excellence in basic research.Read moreRead less