Comparative Paleogenomics of the Arctic Tundra Ecosystem: the genetic response of plants and animals to climate change. This project will use DNA from deep-frozen seeds and bones 100,000 years old to record how species respond to climate change - by adapting and surviving or by shifting ranges and moving. Very large numbers of genes will be examined to identify changes across the genomes of four plant and two animal species, and contrast the responses to major climatic shifts.
Adapting to a changing world: mothers as drivers of evolutionary change. This project will improve our understanding of how organisms will adapt to the unprecedented speed and magnitude of human-induced environmental change. By identifying how mothers modify their offspring to better match the prevailing environment, it will address the role of mothers in directing and accelerating adaptation in our changing world.
Identifying the genes and population histories that drive rapid adaptive change and speciation. This project will uncover the genetic variation and demographic histories that allow rapid adaptation and speciation in natural populations. It will leverage the powerful framework provided by Indo-Australian sea snakes, and new gene sequencing technologies, to reconstruct the evolutionary histories of genes, populations and species. Using this data, it will address inter-related key questions that ar ....Identifying the genes and population histories that drive rapid adaptive change and speciation. This project will uncover the genetic variation and demographic histories that allow rapid adaptation and speciation in natural populations. It will leverage the powerful framework provided by Indo-Australian sea snakes, and new gene sequencing technologies, to reconstruct the evolutionary histories of genes, populations and species. Using this data, it will address inter-related key questions that are critical to effective biodiversity conservation but have rarely been evaluated in the same taxon. It will address what genetic changes are involved in adaptive shifts and speciation, whether these originate de novo or from pre-existing variation and how gene flow and changes in population size promote or constrain adaptation and speciation.Read moreRead less
Seminal fluid interferon-gamma: a potential inhibitor of reproductive success. This project aims to investigate mechanisms by which infection, heat stress and psycho-social stress interfere with fertility by inducing a signalling factor in seminal fluid that suppresses female immune adaptation for pregnancy. Factors in seminal fluid in addition to sperm parameters are known to affect male reproductive success, but these are not well defined. The cytokine interferon-gamma (IFNG) is variably prese ....Seminal fluid interferon-gamma: a potential inhibitor of reproductive success. This project aims to investigate mechanisms by which infection, heat stress and psycho-social stress interfere with fertility by inducing a signalling factor in seminal fluid that suppresses female immune adaptation for pregnancy. Factors in seminal fluid in addition to sperm parameters are known to affect male reproductive success, but these are not well defined. The cytokine interferon-gamma (IFNG) is variably present in seminal plasma of several mammalian species. It was recently discovered that IFNG interferes with the female immune response required for reproductive success. This project will investigate how seminal fluid IFNG alters female immune adaptation for pregnancy. This will define how environmental factors induce seminal fluid IFNG and determine whether inhibitory effects of IFNG can be overcome with pharmacological inhibitors to boost reproductive success.Read moreRead less
Capturing Proteus: 65 million years of ecosystem change revealed through evolution of Proteaceae in Australasia. By assessing past changes in the iconic Australian plant family Proteaceae, this research will show how the Australasian vegetation has responded to 65 million years of profound landscape and climate changes. This knowledge from the past will give important insights into how ecosystems can be expected to change under future climate scenarios.
Primary producers; morphological flexibility under environmental constraints. Climate change impacts on phytoplankton that uptake nutrients for incorporation into food webs including marine mammals and fish. This project will study the morphological flexibility of diatoms to reveal principles underlying nutrient uptake under different climatic scenarios.