Discovery Early Career Researcher Award - Grant ID: DE140100946
Funder
Australian Research Council
Funding Amount
$394,561.00
Summary
410 million years of stomatal evolution: key innovations in the transition from passive valves to active pores. Central to the supremacy of seed plants was the evolution of active, metabolic control of the stomata; the pores that regulate both plant productivity and water loss. However, little is known about the transition from passive control of stomata in seedless plants to active stomatal control in seed plants. This project will identify the key physiological and genetic innovations that und ....410 million years of stomatal evolution: key innovations in the transition from passive valves to active pores. Central to the supremacy of seed plants was the evolution of active, metabolic control of the stomata; the pores that regulate both plant productivity and water loss. However, little is known about the transition from passive control of stomata in seedless plants to active stomatal control in seed plants. This project will identify the key physiological and genetic innovations that underpinned the evolution of stomatal control over the past 410 million years. Understanding these evolutionary innovations will offer important insights into stomatal function in seed plants, as well as informing models of global productivity and water use through time, with benefits for Australian agriculture and natural resource management.Read moreRead less
How plants open up: revealing the evolution of stomatal opening mechanisms. This project aims to identify novel and conserved mechanisms that drive the opening of stomata – plant pores that enable CO2 acquisition for photosynthesis. Stomatal movements strongly affect plant productivity and water use efficiency and have profoundly influenced the earth’s climate and terrestrial ecology. This project will address critical gaps in our understanding of how plants open stomata in response to their env ....How plants open up: revealing the evolution of stomatal opening mechanisms. This project aims to identify novel and conserved mechanisms that drive the opening of stomata – plant pores that enable CO2 acquisition for photosynthesis. Stomatal movements strongly affect plant productivity and water use efficiency and have profoundly influenced the earth’s climate and terrestrial ecology. This project will address critical gaps in our understanding of how plants open stomata in response to their environment and the evolutionary history of the genes controlling this fundamental process. A major expected outcome is knowledge of the diversity of stomatal opening pathways, which should ultimately lead to improved predictions of plant responses to environmental change and assist future targeted modification of plant growth.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101133
Funder
Australian Research Council
Funding Amount
$427,067.00
Summary
The quick and the dead: identifying mechanisms for plant drought survival. This project aims to identify genes that control plant responses to low air humidity, which enhance drought survival by restricting water loss. Most plant water loss occurs through pores called stomata. This project expects to identify the genes that close stomata within minutes of decreased humidity by determining the molecular changes that occur over this timeframe and testing candidate genes for a critical role. Divers ....The quick and the dead: identifying mechanisms for plant drought survival. This project aims to identify genes that control plant responses to low air humidity, which enhance drought survival by restricting water loss. Most plant water loss occurs through pores called stomata. This project expects to identify the genes that close stomata within minutes of decreased humidity by determining the molecular changes that occur over this timeframe and testing candidate genes for a critical role. Diverse land plant models will be examined to ensure broad applicability of results. A major expected outcome is new knowledge of genes that minimise plant water loss, which would ultimately benefit plant-based industries through new targets for breeding improved, drought-adapted varieties for food security in a drying climate.Read moreRead less
Global differentiation of the conifer flora. Conifers are among the most widely recognised and well-loved group of plants. This project will place a global perspective on the evolutionary significance of the southern conifers. Furthermore conifers such as the Wollemi Pine, bunyas, kauris and huon pine are of considerable ecotourism value, and this project will provide a basis for interpretation of these important plants.
The role of atmospheric carbon dioxide in fostering hyperdiversity in Australian conifer palaeofloras. Human intervention into atmospheric processes appears to have triggered an excursion in atmospheric CO2 to levels unknown for millennia. Our ability to predict the environmental implications of such a change will play a major role in ameliorating the social and financial impact upon Australia. This project examines the ecology and function of forests that grew under CO2 levels considerably high ....The role of atmospheric carbon dioxide in fostering hyperdiversity in Australian conifer palaeofloras. Human intervention into atmospheric processes appears to have triggered an excursion in atmospheric CO2 to levels unknown for millennia. Our ability to predict the environmental implications of such a change will play a major role in ameliorating the social and financial impact upon Australia. This project examines the ecology and function of forests that grew under CO2 levels considerably higher than present, and will provide an invaluable insight into how future biological systems will function. The evidence produced by this project has potential economic flow-ons, particularly for long-term planning of softwood versus hardwood plantation forestry.Read moreRead less
Mechanisms and evolution of plant water management. This project proposes a new approach to understand the evolution and physiology of stomatal function, and how this interacts with xylem evolution to determine whole-plant water management. Using a combination of membrane-level, and whole-leaf physiological techniques, this project will focus on mechanisms of stomatal closure in diverse plant species. Specific stomatal and xylem responses to water stress will be mapped together onto the gymnospe ....Mechanisms and evolution of plant water management. This project proposes a new approach to understand the evolution and physiology of stomatal function, and how this interacts with xylem evolution to determine whole-plant water management. Using a combination of membrane-level, and whole-leaf physiological techniques, this project will focus on mechanisms of stomatal closure in diverse plant species. Specific stomatal and xylem responses to water stress will be mapped together onto the gymnosperm clade to reveal co-evolutionary linkages between xylem and stomatal physiology. By combining physiological data with evolutionary patterns among major land plant lineages this project will produce a mechanistic framework for interpreting the drought ecology of all plant species.Read moreRead less
Clocks in crops: exploring the role of circadian rhythms in crop adaptation. The project aims to analyse how the circadian clock provides adaptive advantages in legumes and cereals, two major crop groups of global importance. The project expects to produce new fundamental knowledge about how the clock in these crops coordinates their development, physiology, and metabolism in response to environmental cues. The anticipated outcome is a better understanding of key similarities and differences in ....Clocks in crops: exploring the role of circadian rhythms in crop adaptation. The project aims to analyse how the circadian clock provides adaptive advantages in legumes and cereals, two major crop groups of global importance. The project expects to produce new fundamental knowledge about how the clock in these crops coordinates their development, physiology, and metabolism in response to environmental cues. The anticipated outcome is a better understanding of key similarities and differences in clock functions in different species. Another is knowledge of how the ancient clock gene variants still in use today may limit the current or future performance of those crops. This will provide significant benefits, such as to improve productivity of crop plants in diverse and changing environments.Read moreRead less
Understanding plant uptake of organic and inorganic nitrogen for optimal fertiliser application in forestry. Nitrogen (N) in soils occurs in both organic and inorganic forms. Plants can take up inorganic N - nitrate and ammonium - but, on average, these account for only 5% of the soluble N in soils. Recent evidence suggests that plants may be able to tap into some of the 95% of N that occurs in organic forms. We will investigate the importance of organic N uptake for two plantation Eucalyptus sp ....Understanding plant uptake of organic and inorganic nitrogen for optimal fertiliser application in forestry. Nitrogen (N) in soils occurs in both organic and inorganic forms. Plants can take up inorganic N - nitrate and ammonium - but, on average, these account for only 5% of the soluble N in soils. Recent evidence suggests that plants may be able to tap into some of the 95% of N that occurs in organic forms. We will investigate the importance of organic N uptake for two plantation Eucalyptus species by tracing the uptake of different N forms by bacteria, fungi and eucalypts. This information will redefine what is meant by 'available N' and will guide the development of a new test for soil N status.Read moreRead less
New genetic mechanisms linking flowering, growth habit and yield in legumes. This project aims to investigate the genetic control of flowering and flowering-related traits in legumes, an important group of crop plants. The regulation of flowering by environmental factors has a major influence on plant yield and is important for adaptation in natural and agricultural settings. However, it is poorly understood at the molecular level. This project aims to use induced genetic variation and transcrip ....New genetic mechanisms linking flowering, growth habit and yield in legumes. This project aims to investigate the genetic control of flowering and flowering-related traits in legumes, an important group of crop plants. The regulation of flowering by environmental factors has a major influence on plant yield and is important for adaptation in natural and agricultural settings. However, it is poorly understood at the molecular level. This project aims to use induced genetic variation and transcriptome analysis to define new genes and genetic mechanisms through which flowering is regulated by day length and temperature, and to explore the molecular links between flowering and other developmental processes including seed development. This should extend our understanding of how plant architecture, reproduction and yield are regulated by the environment, and address several agronomic issues.Read moreRead less
Genetics, genomics and evolution of flowering time control in legumes. Flowering in plants is strongly regulated by environmental factors, with important consequences for their natural distribution and use in agriculture. This project will characterise genes, genetic diversity and molecular mechanisms that control flowering in legumes, contributing to fundamental biology, crop improvement and research training.