Therapeutic Targeting Of Ribosome Biogenesis In Cancer And Ribosomopathies
Funder
National Health and Medical Research Council
Funding Amount
$763,845.00
Summary
My fellowship application will build on my international leadership in understanding growth control in human disease. My vision is to uncover the molecular mechanisms governing the loss of normal control of the synthesis of the molecular machines, termed ribosomes, that are responsible for synthesising all cell proteins. I will translate these findings into new paradigms to treat patients suffering from diseases such as cancer and ribosomopathies, that are associated with ribosome dysfunction.
I am a molecular-cell biologist investigating the genetic control of lymphocyte differentiation. I study the mechanisms of action of transcription factors expressed specifically in B cells that regulate B lymphocyte specialisation and function, that determine the ability of mature B cells to respond to signals from other cells or from invading pathogens, and that enable the differentiation of antibody-secreting cells, the effectors of the B cell lineage. I lead the commercialisation efforts of o ....I am a molecular-cell biologist investigating the genetic control of lymphocyte differentiation. I study the mechanisms of action of transcription factors expressed specifically in B cells that regulate B lymphocyte specialisation and function, that determine the ability of mature B cells to respond to signals from other cells or from invading pathogens, and that enable the differentiation of antibody-secreting cells, the effectors of the B cell lineage. I lead the commercialisation efforts of our research Program.Read moreRead less
Breast cancers have diverse characteristics such as their response to treatment and their propensity to relapse. We know that the individual suit of oncogenic lesions probably influences diversity but the characteristics of the cell type from which the cancer arose probably also plays a part. This Application addresses this question and investigates a major new discovery made by the applicant that the ets transcription factor Elf5 plays a key role in specifying the diversity in breast cancer.
Epilepsy is a very common and serious brain disorder. Epilepsy often includes other disabilities, reduction in quality of life and is associated with increased risk of early death. 30% of people with epilepsy are unable to gain control of their seizures with currently available medications. The genetic causes of the large majority of epilepsy cases have not yet been found. This project aims to identify new genetic causes of epilepsy and its related disorders.
The development of protective immunity is essential to fight infection. This depends on a small number of master regulatory transcription factors that drive the differentiation of precursor cells into mature immune cells such as NK, T and dendritic cells. This proposal will provide a fundamental advance in our understanding of immune cells and impact strategies aimed at the prevention and treatment of pathogen infections.
The cell types of the blood, such as red and white blood cells, are produced in the bone marrow from a rare stem cell. The stem cell uses a handful of important master-regulatory genes that act in a hierarchy to promote the blood cell differentiation process. This research aims to understand how these master-regulators function in isolation and together in producing the white blood cells that are required for our immune response to microbes, vaccination and to prevent cancer.
I aim to decipher the role of heritable, genetic DNA variation in human neurological disease. I will use next generation genomics technologies together with sophisticated cellular models to address the important questions of the biology of epilepsy and intellectual disability in particular. I aim to develop a treatment for a specific type of epilepsy, which affects only girls from the age of 6 months. My ultimate goal is to improve the life of the patients and their relatives.
The genetic material is packaged in the cell nucleus with histone proteins. Modifications of histones determine if a particular area of the genome is active or repressed. We are investigating the roles of a family of histone modifying proteins, the MYST proteins. Mutations in these proteins cause intellectual disability and cancer. The research program will provide knowledge that may become the basis for the development of drugs for the treatment of cancer and neurodegenerative disorders.
I am a Molecular Biologist who has built up a large set of transgenic animal models based around the NPY system to use them in an integrated physiology approach to investigate important regulatory mechanisms in the interaction of the brain with peripheral
High-Throughout Identification And Targeting Of New Breast Cancer Genes.
Funder
National Health and Medical Research Council
Funding Amount
$640,210.00
Summary
Recent studies have identified DNA sequence variations within the human genome that are associated with an increased risk or can influence the outcome of breast cancer. This research program will identify the key genes affecting cancer development and assess their contribution to cancer growth. I will then use this knowledge to assess their suitability for drug development. Understanding how our DNA contributes to breast cancer will provide new avenues for prevention or treatment.