Analysis Of APC And APC Protein Complexes In Colon Cancer
Funder
National Health and Medical Research Council
Funding Amount
$110,786.00
Summary
Colorectal cancer is one of the foremost causes of death in Australia. A defective form of a protein called APC has been shown to be present in more than 80% of colon tumours. How APC contributes to colon cancer is still not known. We aim to determine the function of the APC protein by studying the APC protein and proteins that interact with APC in normal and cancerous colon epithelial cells. We will use cells derived from normal colon epithelium as well as from colon carcinomas. Once we have id ....Colorectal cancer is one of the foremost causes of death in Australia. A defective form of a protein called APC has been shown to be present in more than 80% of colon tumours. How APC contributes to colon cancer is still not known. We aim to determine the function of the APC protein by studying the APC protein and proteins that interact with APC in normal and cancerous colon epithelial cells. We will use cells derived from normal colon epithelium as well as from colon carcinomas. Once we have identified proteins that interact with APC in normal colonic cells, we will have a more complete understanding of the function of APC and its role in the development of colonic tumours.Read moreRead less
From Endoderm To Gut: Regulation Of Lineage Allocation And Morphogenesis In The Murine Embryo
Funder
National Health and Medical Research Council
Funding Amount
$439,500.00
Summary
One of the most critical steps in early development is the generation of the full complement of cell types required to build the embryo. A thorough understanding of the mechanisms underlying this is vital for the development of methods for directing the differentiation of stem cells for use in regenerative medicine. The objective of our research is to understand the cellular and molecular mechanisms underlying the assignment of cells to particular fates and the establishment of the body plan of ....One of the most critical steps in early development is the generation of the full complement of cell types required to build the embryo. A thorough understanding of the mechanisms underlying this is vital for the development of methods for directing the differentiation of stem cells for use in regenerative medicine. The objective of our research is to understand the cellular and molecular mechanisms underlying the assignment of cells to particular fates and the establishment of the body plan of the embryo. The endodermal cell layer forms the lining of the embryonic gut which gives rise to the entire gastrointestinal tract, the respiratory tract and other structures including the liver and the pancreas during organogenesis. This investigation focuses on the questions of how the pluripotent progenitor cells are allocated to the endodermal lineage and how the embryonic gut is patterned during early development of the mouse embryo. Analysis of endoderm development will provide insights into the roles of the allocation of progenitor cells to tissue lineages, cell movement, and diversification and maturation of functional cell types. These processes are universally relevant to the formation of all types of organ primordia in the embryo. Understanding the complexity of tissue interactions and the interplay of molecular mechanisms of cell lineage choice and differentiation in the embryo is a major challenge. However, knowledge of the processes that drive tissue differentiation in the embryo is absolutely crucial for enhancing our ability to direct cell and tissue differentiation for the realization of cell-based technologies in biomedicine.Read moreRead less
One of the most critical steps in embryonic development is the assembly of the different tissue components into a three-dimensional structure in order to build a major body part of the foetus. In the development of the head, this form-shaping process undertaken by different cell populations is coordinated by genetic activity that is triggered by signals received by cells. The objective of our research is to understand how one of the many signalling mechanisms, WNT signalling, works in making the ....One of the most critical steps in embryonic development is the assembly of the different tissue components into a three-dimensional structure in order to build a major body part of the foetus. In the development of the head, this form-shaping process undertaken by different cell populations is coordinated by genetic activity that is triggered by signals received by cells. The objective of our research is to understand how one of the many signalling mechanisms, WNT signalling, works in making the head and face of the embryo. We will study the development of embryos of mice in which mutations have been introduced experimentally in genes that code for factors of the WNT signalling pathway. Understanding the complexity of tissue interactions and the interplay of molecular mechanisms of head formation in the embryo is a major challenge. However, knowledge of the processes in animal models will contribute to a better delineation of the role of signalling in normal head development. It will also help to direct the focus of future clinical investigations to the most relevant genetic determinants of birth defects of the head and face, which is present in about 8 per 10,000 births in Australia.Read moreRead less
The majority of stroke results from focal brain infarction, followed by substantial secondary excitotoxic damage in the surrounding areas. Tau has been shown to contribute to excitotoxicity and neurodegeneration in mouse models of Alzheimer’s disease (AD). Preliminary data show that tau reduction also protects against excitotoxic damage after experimental stroke. We aim to dissect the molecular mechanisms of stroke using a tau-deficient mouse model.
Identifying Novel Antimalarial Targets Using ENU Mutagenesis In The Mouse
Funder
National Health and Medical Research Council
Funding Amount
$760,170.00
Summary
Malaria is estimated to cause 1.2 million deaths per year. The malarial parasite has developed resistance to most drugs and new drugs are needed. We aim to mimic the protective red blood cell diseases common in human populations in malarial endemic areas by identifying host targets that are important in parasite growth.
Molecular Regulation Of Pluripotency In The Mammalian Germline
Funder
National Health and Medical Research Council
Funding Amount
$611,935.00
Summary
Germ cells generate sperm in males or oocytes in females. In males, germ cell numbers are tightly controlled in the embryo, with too few germ cells causing infertility, and unrestrained germ cell numbers leading to testicular cancer. We have discovered a molecular mechanism that regulates germ cells in the embryo, and propose to study in mice how this regulation is accomplished and the consequences of defective regulation, in order to learn more about how infertility and testis cancer arise.