Engineering nanomaterial interactions with the cell surface. This Fellowship aims to advance understanding of the endothelial cell surface, a key tissue barrier, and its interactions with nanomaterials. Enabled by cross-disciplinary collaboration, it expects to develop knowledge in matrix biology of the cell surface and materials as well as new methods to analyse their interactions. This is expected to unravel causal relationships between nanomaterial features and interactions at the cell surfac ....Engineering nanomaterial interactions with the cell surface. This Fellowship aims to advance understanding of the endothelial cell surface, a key tissue barrier, and its interactions with nanomaterials. Enabled by cross-disciplinary collaboration, it expects to develop knowledge in matrix biology of the cell surface and materials as well as new methods to analyse their interactions. This is expected to unravel causal relationships between nanomaterial features and interactions at the cell surface which will be integrated to engineer optimised materials. This will address the current and critical challenges of nanomaterial technologies in the efficient and targeted interactions with cells with long-term benefits for the consumer, biotechnology and healthcare sectors.Read moreRead less
Investigation of novel mechanisms for the regulation of sperm-oocyte interactions. Through work with national and international collaborators, this project aims to provide unprecedented insights into how spermatozoa recognise and bind to an oocyte. The approach is based on strong preliminary data indicating that molecular chaperones play a key role in the functional remodelling of the spermatozoon by promoting the assembly of multimeric oocyte receptor complexes. Through the use of state-of-the ....Investigation of novel mechanisms for the regulation of sperm-oocyte interactions. Through work with national and international collaborators, this project aims to provide unprecedented insights into how spermatozoa recognise and bind to an oocyte. The approach is based on strong preliminary data indicating that molecular chaperones play a key role in the functional remodelling of the spermatozoon by promoting the assembly of multimeric oocyte receptor complexes. Through the use of state-of-the-art cell biology and proteomic technologies, the project aims to investigate how molecular chaperones orchestrate these changes and in doing so, improve understanding of the fertilisation cascade and open up new contraceptive strategies.Read moreRead less
Dissecting key steps of the miRNA-mediated gene regulation and its implication in immune response and cancer. This project will characterise in detail one of the most important ways that genes are turned off in humans. This process is involved in many diseases including cancer and infections. The result will provide potential novel drug targets to prevent and treat such diseases.
Illuminating the dark neutrophil glycoproteome. This project aims to shed light on the highly complex and dynamic sugar-coated surfaces of neutrophil white blood cells critical for the cell communication and function of our innate immune system. The project expects to generate molecular-level insights into neutrophil biology by detailing the structure, formation, regulation, interactions and functions of these cell-surface sugars across the varied neutrophil life stages using systems glycobiolog ....Illuminating the dark neutrophil glycoproteome. This project aims to shed light on the highly complex and dynamic sugar-coated surfaces of neutrophil white blood cells critical for the cell communication and function of our innate immune system. The project expects to generate molecular-level insights into neutrophil biology by detailing the structure, formation, regulation, interactions and functions of these cell-surface sugars across the varied neutrophil life stages using systems glycobiology approaches. The project will map the extensive sugar remodelling on and in the neutrophil and reveal new sugar-mediated mechanisms governing key immune processes. This project will benefit the community by expanding our knowledge of fundamental processes underpinning our innate immune system.Read moreRead less
Novel models to advance our understanding of mammalian development. This project aims to add to the understanding of cellular processes underpinning mammalian development. Protein phosphorylation is a dynamic process regulated by both protein kinases and protein phosphatases. While the role of kinases in cellular functions are well defined, the roles of protein phosphatases are not well understood. Using a range of laboratory models this project aims to discover the function of the phosphatase P ....Novel models to advance our understanding of mammalian development. This project aims to add to the understanding of cellular processes underpinning mammalian development. Protein phosphorylation is a dynamic process regulated by both protein kinases and protein phosphatases. While the role of kinases in cellular functions are well defined, the roles of protein phosphatases are not well understood. Using a range of laboratory models this project aims to discover the function of the phosphatase PP2A, in cell proliferation, survival, differentiation and DNA damage repair. The anticipated outcome is an improved understanding of all stages of mammalian development. This will provide significant benefits in the biotechnology, chemical and pharmaceutical industries.Read moreRead less
Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D prin ....Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D printing of living cells and commercially viable reprogramming materials. The project expects to contribute fundamental knowledge in materials and biomedical sciences, while providing tools that will benefit commercial ventures in cell and tissue manufacturing.Read moreRead less
Programming physical and biological cues to promote vessel growth . This project aims to engineer new hydrogel-based biomaterials that allow spatio-temporal modulation of physical and biological cues to direct blood vessels growth, as well as compatible with advanced bioprinting platforms. It will generate new knowledge in biomaterials, biofabrication and advanced material processing. Expected outcomes include new knowledge in biomaterial-vascular interaction, novel vascular bioinks, cross-disci ....Programming physical and biological cues to promote vessel growth . This project aims to engineer new hydrogel-based biomaterials that allow spatio-temporal modulation of physical and biological cues to direct blood vessels growth, as well as compatible with advanced bioprinting platforms. It will generate new knowledge in biomaterials, biofabrication and advanced material processing. Expected outcomes include new knowledge in biomaterial-vascular interaction, novel vascular bioinks, cross-disciplinary, international collaboration and research training. This project will provide significant benefit to Australia's scholarly output and reputation, as well as long term benefits to biomedical, veterinary and cosmetic through new materials and cutting-edge manufacturing platforms. Read moreRead less
Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated grow ....Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated growth factor signalling, as well as cross-disciplinary, international collaboration & research training. This should provide significant benefit to Australia’s scholarly output & reputation & long term benefits to biomedical, veterinary, cosmetic, & food industries through new materials & processing technologies. Read moreRead less
Overcoming antibiotic resistance: rapid discovery of new antibacterial drug targets using chemical proteomics. The prevalence of multidrug-resistant bacteria in the community is a critical public health issue and there is an urgent and compelling need for new antibiotics with novel modes of action to combat these deadly superbugs. While antibiotics from nature have long been a mainstay of the pharmaceutical industry, their development as drugs can be challenging as their cellular targets and mod ....Overcoming antibiotic resistance: rapid discovery of new antibacterial drug targets using chemical proteomics. The prevalence of multidrug-resistant bacteria in the community is a critical public health issue and there is an urgent and compelling need for new antibiotics with novel modes of action to combat these deadly superbugs. While antibiotics from nature have long been a mainstay of the pharmaceutical industry, their development as drugs can be challenging as their cellular targets and modes of action are frequently unknown. In this project, innovative chemical proteomics approaches will be used to rapidly identify and characterise the cellular targets and modes of action of both newly discovered and historic antibiotic natural products, thereby overcoming this bottleneck and accelerating the development of next-generation antibiotics.Read moreRead less
Cellular mechanisms linking smoking and cardiovascular disease. Everyone develops fatty streaks in their arteries. Why some streaks remain benign, and others progress to clinically-relevant lesions is not completely understood. This project will assess novel cellular mechanisms involved in plaque development, to enable the more effective design of new therapeutic strategies to treat heart disease.