Role Of FHA Domains As Protein-protein Interaction Modules In Cell Signalling
Funder
National Health and Medical Research Council
Funding Amount
$191,973.00
Summary
The proper processing of information in cells involves the association of different proteins to signalling complexes. We will decipher the role the so-called FHA module plays in the formation of protein complexes. FHA modules are present in several proteins that are important for the repair of damaged DNA and the stability of chromosomes. Understanding the structure and function of this module will be relevant for various forms of cancer where DNA is damaged.
Mechanisms Of Control Of Cell Growth And Proliferation By The AKT Kinase Family
Funder
National Health and Medical Research Council
Funding Amount
$568,452.00
Summary
Ribosome synthesis and function is critical for normal cell growth and division and hence this process is exquisitely regulated. Conversely, de-regulated cell growth can lead to cancer. We have identified new roles for the AKT and SGK families of kinases in controlling this process. This proposal aims to establish the mechanisms by which these enzymes control ribosome synthesis to better understand growth control and to provide insight for targeting these pathways in growth driven cancers.
Engineered Histones As DNA Carriers With Application In Therapeutic Gene Delivery
Funder
National Health and Medical Research Council
Funding Amount
$417,750.00
Summary
We intend to apply our knowledge of protein transport to the nucleus to enhance the delivery of DNA to target cells. This relates to the use of gene therapy to treat genetic defects such as inborn errors of metabolism, where a disease-causing lack-of-function mutation can be overcome by engineering cells within the organism which express, in the necessary quantities and in response to the appropriate regulatory signals, the particular component which is lacking. A limiting factor in gene therapy ....We intend to apply our knowledge of protein transport to the nucleus to enhance the delivery of DNA to target cells. This relates to the use of gene therapy to treat genetic defects such as inborn errors of metabolism, where a disease-causing lack-of-function mutation can be overcome by engineering cells within the organism which express, in the necessary quantities and in response to the appropriate regulatory signals, the particular component which is lacking. A limiting factor in gene therapy approaches is the low efficiency of nuclear uptake of introduced DNA, where it has been estimated that < 1% of the DNA taken up is actually expressed. Our proposal seeks to develop approaches to enhance non-viral-mediated gene delivery, in particular by optimising this critical, limiting step of the delivery of exogenous DNA to the nucleus. We intend to apply knowledge from studies of nuclear targeting and chromatin assembly to improve gene transfer technologies. We will build on our work showing that specific signals for nuclear import - nuclear targeting signals (NTSs) - can be used to enhance nuclear gene delivery and expression. Since DNA in the normal cellular context is in the form of chromatin - a specific complex with proteins such as histones - we intend to use reconstituted chromatin as the transfecting DNA, whereby histones engineered to include NTSs and other modular sequence elements will be used. Chromatin should not only enable NTSs and other sequence modules to be linked to the DNA but also protect against nuclease-mediated degradation prior to nuclear entry, condense the DNA to enable more efficient cellular-nuclear entry, and ensure expression of the transfected reporter gene by presenting it to the cell in a physiological context. Our approaches should contribute to bringing gene therapy closer to reality in the clinic.Read moreRead less
This established team of investigators will research into the molecular control of white blood cell formation and function, using a multidisciplinary, team approach to fundamental biological questions with a focus on potential clinical and commercial outcomes. The team will also attempt to identify new validated targets for therapeutic intervention by using both forward and reverse genetic approaches in mice coupled with complete phenotypic analyses of the blood cell system.
Characterization Of Novel Regulators Of Erythropoiesis
Funder
National Health and Medical Research Council
Funding Amount
$437,545.00
Summary
Mature red and white blood cells develop from hemopoietic stem cells in the adult bone marrow. The production of red blood cells is primarily controlled by the hormone erythropoietin (epo). The availability of this hormone in a recombinant form has aided in the treatment of numerous forms of anaemia resulting from kidney failure, malignancies, and AIDS. Previously we had identified that the protein Lyn must be present inside primitive red blood cells for epo to stimulate them to become mature fu ....Mature red and white blood cells develop from hemopoietic stem cells in the adult bone marrow. The production of red blood cells is primarily controlled by the hormone erythropoietin (epo). The availability of this hormone in a recombinant form has aided in the treatment of numerous forms of anaemia resulting from kidney failure, malignancies, and AIDS. Previously we had identified that the protein Lyn must be present inside primitive red blood cells for epo to stimulate them to become mature functional cells. We have identified six molecules which interact with Lyn in red blood cells. We have shown that amolecule called HS1 is important for epo function in individual red blood cells and now we plan to investigate its functions in whole animals, including mice that lack the HS1 gene. We have also shown that a molecule called Trip1 is important for red blood cell development. Interestingly, this molecule also interacts with the thyroid hormone receptor and can influence the effects of epo and thyroid hormone on red blood cell development. The interplay between these two hormones will be looked at in more detail both at the cell and whole animal levels in normal mice and those lacking the thyroid hormone receptor gene. The third Lyn binding molecule we isolated is a novel gene-we have named it ankyrin repeat protein in line with the molecules it is related to. This gene is expressed in red blood cells and we aim to investigate what role it plays in the development of these cells. The fourth gene is also novel and is closely related to another called AFAP-110, which can exert effects on the structure of a cell. Its role in red blood cell structure will also be investigated. Finally, the last two molecule we have identified are both novel and are unrelated to any other known proteins. As above, the effects of these two molecules on red blood cell development will be investigated.Read moreRead less
Role Of PAK1 In Colorectal Cancer Growth And Metastasis Regulated By Gastrins
Funder
National Health and Medical Research Council
Funding Amount
$460,070.00
Summary
Increased level of PAK1(a protein kinase) was associated with the progression of colorectal (large bowel) cancer (CRC). Gastrin peptides are growth factors responsible for CRC development. The objective of this project is to determine the role of PAK1 in the regulation of CRC growth and metastasis by gastrin peptides. We will use cell culture, animal models and clinical samples in the program. A successful outcome will lead to the development of new CRC therapies such as inhibitors of PAK1.
FHA Domain-dependent Functions Of Cell Cycle Checkpoint Kinases
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
Human chromosomes as carriers of the genetic information are constantly subjected to DNA damage. This usually occurs spontaneously, simply as a result of oxidation of DNA residues as a byproduct of cellular energy consumption or as a result of errors during chromosome duplication in growing cells, and is compounded by chemical or physical agents, for example carcinogens, UV rays or X-rays. DNA damage can have severe consequences if not properly repaired, leading to genomic instability with loss ....Human chromosomes as carriers of the genetic information are constantly subjected to DNA damage. This usually occurs spontaneously, simply as a result of oxidation of DNA residues as a byproduct of cellular energy consumption or as a result of errors during chromosome duplication in growing cells, and is compounded by chemical or physical agents, for example carcinogens, UV rays or X-rays. DNA damage can have severe consequences if not properly repaired, leading to genomic instability with loss of vast tracts of DNA or inappropriate genome rearrangements, that may ultimately give rise to cancer. To prevent such dire consequences, all organisms from yeast to man contain molecular checkpoints that sense the presence of DNA damage and then activate a cellular response program that includes damage repair and prevention of cell division while damage persists. These molecular checkpoints are highly conserved throughout evolution which allows us to analyse the details involved in simple organisms such as yeast, to draw general conclusions on their function in more complex human cells. Along these lines, we are studying the function of two yeast proteins that are similar to the human Chk2 protein, a tumour suppressor that is mutated in a subset of families suffering from the Li-Fraumeni multi-cancer syndrome. We have identified new pathways by which these proteins contribute to the survival of cells after treatment with DNA damaging agents and will further charaterise these in the present proposal.Read moreRead less