Aurora Kinase: Molecular, Cellular And Functional Studies Deciphering Its Role In Stroke Injury
Funder
National Health and Medical Research Council
Funding Amount
$580,993.00
Summary
In stroke patients, oxygen deprivation indirectly induces massive nerve cell death by activating an enzyme called aurora kinase A (AURKA). We aim at unravelling (i) how AURKA is activated by oxygen deprivation, (ii) where the activated AURKA is localised in cells, and (iii) how the activated AURKA induces nerve cell death.The study will benefit development of therapeutic strategies to protect against brain damage in stroke since this is novel and different target for drug targeting.
A New Function For An Old Enzyme: Src Protein Kinase Directs Excitotoxic Neuronal Death In Stroke
Funder
National Health and Medical Research Council
Funding Amount
$513,975.00
Summary
In our previous investigation of how brain cells die in patients suffering from stroke, we found that stroke causes aberrant activation of an enzyme called Src in the affected brain cells. Furthermore, this aberrantly activated Src directs the brain cells to undergo cell death. Our proposal, which aims to decipher this neurotoxic mechanism of the aberrantly activated Src will benefit development of new therapeutic strategies to reduce brain damage in stroke patients.
Promoting Regrowth Of Nerve Fibres Into The Epidermis During Diabetic Neuropathy By LRP Agonists
Funder
National Health and Medical Research Council
Funding Amount
$427,102.00
Summary
Nerve damage can develop post injury or disease and is often very debilitating, slow to heal and can cause increased pain. Our work aims to examine a new class of molecules that we show can activate selected fat-receptors on nerve cells to guide the growth of regenerating nerves. We will determine how these receptors function with the aim of developing a novel class of therapeutics directed at healing nerve damage.
Validating CaMKK2 As A Rational Treatment Target For Bipolar Disorder
Funder
National Health and Medical Research Council
Funding Amount
$688,175.00
Summary
Bipolar disorder is a disabling, chronic mental illness that profoundly impairs the ability of affected individuals to function in daily life. Existing treatments for bipolar disorder are inadequate and lack the necessary efficacy and tolerability required for long-term therapy. This project will validate the enzyme, CaMKK2, as a rational treatment target for bipolar disorder, which will guide the development of more effective and safer drugs to improve patient outcomes.
Understanding Epigenetic Modification During Oogenesis For Novel Treatments Of Female Infertility
Funder
National Health and Medical Research Council
Funding Amount
$314,644.00
Summary
Infertility affects about 10% of Australian women and the success rates of current infertility treatments are low due to our poor knowledge of eggs development. The numbers of obese and older women trying to conceive are increasing; fertility treatments are even less effective for them. I have generated mouse models to elucidate the pathways regulating egg development. I will study for alterations in these pathways in the mouse models which perfectly mimic the obesity and aging in women.
Transcriptional Effectors Of Oncogenic ERK Signaling In Colorectal Cancer
Funder
National Health and Medical Research Council
Funding Amount
$820,776.00
Summary
This project aims to unravel how one of the most frequently deregulated molecular pathways in colorectal cancer controls the expression of genes required for these tumours to grow and spread. We expect this work to uncover novel therapeutic targets to effectively inactivate this pathway and biomarkers to select patients most likely to benefit from existing therapies.
Migration And Differentiation Of Enteric Neuron Precursors
Funder
National Health and Medical Research Council
Funding Amount
$385,116.00
Summary
There are many millions of nerve cells within the wall of the intestine, and they control many intestinal functions, including motility. During development, these nerve cells arise from cells which migrate away from the developing brain and first enter the stomach. The migratory cells are called neural crest cells. After entering the stomach, neural crest cells migrate within the wall of the gastrointestinal tract, until they reach the far (anal) end. In embryonic mice, this colonisation of the ....There are many millions of nerve cells within the wall of the intestine, and they control many intestinal functions, including motility. During development, these nerve cells arise from cells which migrate away from the developing brain and first enter the stomach. The migratory cells are called neural crest cells. After entering the stomach, neural crest cells migrate within the wall of the gastrointestinal tract, until they reach the far (anal) end. In embryonic mice, this colonisation of the entire small and large intestines by neural crest cells takes over 4 days, and in humans the process probably takes at least one week. It is essential that the neural crest cells colonise the entire gastrointestinal tract, since regions of intestine lacking neural crest cells (and hence nerve cells) cannot function and intestinal contents build up in front of the region lacking nerve cells. This condition is found in some babies (Hirschsprung's disease), and it can only be treated by surgically removing the region lacking nerve cells. It is therefore essential that migratory neural crest cells colonise the entire gastrointestinal tract. Currently, little is known about the mechanisms controlling the migration of neural crest cells, and whether a) particular molecules within the gut wall are important for migration, and-or b) the migratory behaviour of the neural crest cells is regulated mostly by the neural crest cells themselves. In this study we will take time-lapse images of neural crest cells migrating through the gut of embryonic mice to identify the factors that are important for the migration. After the neural crest cells have colonised the entire intestine, they develop into different types of nerve cells. We will also examine some of the factors affecting the development of different types of nerve cells.Read moreRead less
Many infants and children suffer from bowel motility disorders, for example, chronic constipation affects up to 1 in 10 children. However, the cause of many of these paediatric motility disorders remains unknown. In this project, we will examine the development of wiring of the nervous system that controls bowel motility. This is the first study to investigate the development of cell-cell communication during early stages of nervous system development.
ROLE OF RIP KINASES & IAPs IN MUCOSAL IMMUNE DEFENCE
Funder
National Health and Medical Research Council
Funding Amount
$631,168.00
Summary
Pathogenic bacteria are master manipulators of the inflammatory signalling pathways designed to thwart them. Understanding how they do this will allow us to develop drugs that limit their ability to infect. We have shown that pathogenic bacteria inject a protein called EspL into human cells to promote the destruction of a family of human proteins, called RIP Kinases (RIPK), that co-ordinate the inflammatory response and aim now to discover how EspL causes RIPK degradation and thereby promotes in ....Pathogenic bacteria are master manipulators of the inflammatory signalling pathways designed to thwart them. Understanding how they do this will allow us to develop drugs that limit their ability to infect. We have shown that pathogenic bacteria inject a protein called EspL into human cells to promote the destruction of a family of human proteins, called RIP Kinases (RIPK), that co-ordinate the inflammatory response and aim now to discover how EspL causes RIPK degradation and thereby promotes infection.Read moreRead less
The Importance Of Receptor Trafficking For Signalling Of Pain And Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$787,604.00
Summary
Inflammation and pain are normal processes that are essential for survival: inflammation fights infections and pain allows avoidance of danger. These processes are normally tightly controlled and are transient. During disease, they become dysregulated and chronic. By understanding the normal processes of inflammation and pain, and by determining how dysregulation causes disease, we aim to develop new treatments for diseases that are a major cause of human suffering.