Novel antimicrobial target discovery by an integrated approach. The project aims to uncover the molecular targets of BDM-I, a novel antimicrobial candidate discovered by the start-up Australian company BioDiem Ltd. BDM-I is active against many drug resistant bacterial and fungal microorganisms and it is currently in pre-clinical development. However, the lack of resistant phenotypes makes it difficult to identify BDM-I’s mechanism of action. The project plans to use an integrated approach that c ....Novel antimicrobial target discovery by an integrated approach. The project aims to uncover the molecular targets of BDM-I, a novel antimicrobial candidate discovered by the start-up Australian company BioDiem Ltd. BDM-I is active against many drug resistant bacterial and fungal microorganisms and it is currently in pre-clinical development. However, the lack of resistant phenotypes makes it difficult to identify BDM-I’s mechanism of action. The project plans to use an integrated approach that combines a novel technique of in silico screening with experimental validation. Project outcomes are anticipated to include the first computational method to integrate target and ligand similarity for proteome-scale target and off-target discovery, which will advance the global fight against drug-resistant microorganisms.Read moreRead less
Molecular toxinology of Australia's lesser known venomous snakes. This proposal represents a tremendous opportunity for biodiscovery from venomous snakes. This will be achieved through the researchers' unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution great potential in drug discovery and other commercial applications. This project will provide Australian graduate and post-graduate stude ....Molecular toxinology of Australia's lesser known venomous snakes. This proposal represents a tremendous opportunity for biodiscovery from venomous snakes. This will be achieved through the researchers' unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution great potential in drug discovery and other commercial applications. This project will provide Australian graduate and post-graduate students with finely tuned skills in cutting edge methodological techniques and a fluent understanding of molecular evolution, preparing them to be internationally competitive scientists.Read moreRead less
The “New” Biochemistry of Polyamines: When Metabolic Pathways Collide. Basic biochemistry and the metabolic regulation of proliferation remain as the fundamental building blocks of knowledge in cell biology that have enabled breakthrough advances in biology and medicine. Polyamines are unique and ubiquitous low-Mr amines that play vital roles in many biological processes, including proliferation, DNA/RNA synthesis, etc. This proposal will mechanistically dissect the "new" biochemistry of polyami ....The “New” Biochemistry of Polyamines: When Metabolic Pathways Collide. Basic biochemistry and the metabolic regulation of proliferation remain as the fundamental building blocks of knowledge in cell biology that have enabled breakthrough advances in biology and medicine. Polyamines are unique and ubiquitous low-Mr amines that play vital roles in many biological processes, including proliferation, DNA/RNA synthesis, etc. This proposal will mechanistically dissect the "new" biochemistry of polyamines, as we have discovered that polyamines are regulated by iron at 2-major levels, involving >10-key polyamine pathway proteins. This proposal represents first-in-field studies specifically designed to dissect mechanisms involved in this relationship. Our Central Hypothesis is that iron regulates polyamine metabolism.Read moreRead less
Special Research Initiatives - Grant ID: SR0354892
Funder
Australian Research Council
Funding Amount
$40,000.00
Summary
The Australian Protease Network. Proteases are pivotal enzymes during birth, life, ageing and death of all organisms. Proteases regulate most physiological processes by controlling protein activation, synthesis and turnover and are essential for replication and spread of viruses, bacteria and parasites that cause infectious diseases. Blockbuster drugs and diagnostics already target a few proteases. Australians have made innovative contributions individually to understanding and regulating these ....The Australian Protease Network. Proteases are pivotal enzymes during birth, life, ageing and death of all organisms. Proteases regulate most physiological processes by controlling protein activation, synthesis and turnover and are essential for replication and spread of viruses, bacteria and parasites that cause infectious diseases. Blockbuster drugs and diagnostics already target a few proteases. Australians have made innovative contributions individually to understanding and regulating these enzymes. However this initiative aims to network their efforts by value-adding to the current protease research through promoting national and international collaborations to improve our understanding of biology, and encourage exploitation of proteases/inhibitors/receptors for pharmaceutical and industrial applications.Read moreRead less
Mapping and defining inter-organ cross talk during exercise. This project aims to examine precisely how organs communicate and interact. These interactions are particularly important during exercise, when continued movement demands intricate organ communication, and have major ramifications for the whole organism as it ages. Precisely how this communication takes place is unclear, but we now know that the movement of cargo with extracellular vesicles (EVs) plays an integral role in organ to orga ....Mapping and defining inter-organ cross talk during exercise. This project aims to examine precisely how organs communicate and interact. These interactions are particularly important during exercise, when continued movement demands intricate organ communication, and have major ramifications for the whole organism as it ages. Precisely how this communication takes place is unclear, but we now know that the movement of cargo with extracellular vesicles (EVs) plays an integral role in organ to organ communication. This project expects to build upon unprecedented recent developments we have made in the biology of inter-organ communication via EVs. The expected outcomes will have broad impact across life science and biotechnology.Read moreRead less
Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cel ....Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cell migration with relevance to the basic biology of inflammation, repair and regeneration and new innovations for cell imaging. Significant benefits are expected to arise from this new knowledge and from advanced skills training and improved national capabilities in bio-imaging and analysis.Read moreRead less
Understanding how RNA editing regulates RNA fate. This project aims to address how RNA editing mediated by ADAR1 alters the interactions of targeted RNA with the innate immune sensing system. ADAR1 editing converts adenosine to inosine within double stranded RNA. It is known that this is key to prevent activation of the innate immune sensor MDA5 by endogenous RNA. However, we do not understand why edited RNA is tolerated and unedited RNA is not. This project will generate new knowledge regarding ....Understanding how RNA editing regulates RNA fate. This project aims to address how RNA editing mediated by ADAR1 alters the interactions of targeted RNA with the innate immune sensing system. ADAR1 editing converts adenosine to inosine within double stranded RNA. It is known that this is key to prevent activation of the innate immune sensor MDA5 by endogenous RNA. However, we do not understand why edited RNA is tolerated and unedited RNA is not. This project will generate new knowledge regarding the effect of editing on how endogenous RNA is perceived by the innate immune system.Read moreRead less
Discovery of novel circular proteins in bacteria, plants and animals: applications in drug design and crop protection. The overall goal is to use innovative methods in chemistry, biochemistry and molecular biology to determine the structures and functions of several families of circular proteins that have exciting pharmaceutical and agricultural applications. These molecules differ from conventional proteins in that they have no ends: their termini are seamlessly joined, thereby making them exce ....Discovery of novel circular proteins in bacteria, plants and animals: applications in drug design and crop protection. The overall goal is to use innovative methods in chemistry, biochemistry and molecular biology to determine the structures and functions of several families of circular proteins that have exciting pharmaceutical and agricultural applications. These molecules differ from conventional proteins in that they have no ends: their termini are seamlessly joined, thereby making them exceptionally stable and resistant to enzyme digestion. The big question is ?How and why does Nature produce circular proteins?" Increasing our knowledge of why circular proteins have evolved will facilitate their applications in drug design and in the development of novel insecticides.Read moreRead less
Functional characterization of SSB2: a novel single-stranded DNA binding protein. Defects in the DNA damage response pathway underpin many human genetic disorders and diseases. A detailed understanding of this pathway has enormous implications for future medicine. The proposed research will lead to functional characterization of a new protein, identify new concepts in DNA damage repair pathways, train young researchers and place Australia among the leaders in this internationally significant and ....Functional characterization of SSB2: a novel single-stranded DNA binding protein. Defects in the DNA damage response pathway underpin many human genetic disorders and diseases. A detailed understanding of this pathway has enormous implications for future medicine. The proposed research will lead to functional characterization of a new protein, identify new concepts in DNA damage repair pathways, train young researchers and place Australia among the leaders in this internationally significant and highly competitive area of research. It will underpin the national research priority of Promoting and Maintaining Good Health and help Australia capitalise on a plethora of opportunities for future economic and health benefits.Read moreRead less