grant

Gene-environment interactions and experience-dependent plasticity in the healthy and diseased cerebral cortex [ 2004 - 2006 ]

Also known as: Gene-environment interactions in the healthy and diseased cerebral cortex

Research Grant

[Cite as https://purl.org/au-research/grants/nhmrc/299891]

Researchers: Prof Anthony Hannan (Principal investigator) ,  Dr Mark Murphy Prof Ramesh Rajan

Brief description Huntington's disease (HD) is a devastating illness in which movement disorders (including chorea) and mental problems progress for 10-20 years after onset, and inevitably lead to death. HD is caused by an expansion in a repeating segment of DNA in a single gene and is inherited by 50% of the offspring of sufferers. Despite this strong genetic factor, we have recent evidence from a mouse model, in which the human HD gene mutation has been inserted into the mouse genome, supporting a role for environmental factors in disease onset and progression. Following on from our work showing that environmental enrichment delays disease and progression in this mouse model of HD, we are using experimental manipulations of the environment to examine effects on brain degeneration and behaviour. This project aims to investigate gene-environment interactions in HD, focusing on dysfunction of neurons in the cerebral cortex. The combination of behavioural, physiological, anatomical and molecular analysis of HD mice will bring us closer to a comprehensive understanding of HD. This will have implications for the development of new therapies for HD. Our environmental enrichment paradigm may also lead to development of occupational therapy strategies for HD and other neurological disorders. There are at least ten other fatal brain disorders which are caused by the same DNA repeat expansion in other genes. New insights into HD will therefore have implications for the understanding and development of therapeutics for these other DNA repeat expansion brain diseases. Furthermore, another devastating brain disorder which, like HD, involves abnormal protein interactions and dysfunction of the cortex, is Alzheimer's disease. Understanding HD may therefore also have implications for our understanding of Alzheimer's disease. Additionally, analysing control mice in this project will provide new information on mechanisms of plasticity in the normal cortex, which may underlie learning and memory.

Funding Amount $AUD 249,250.00

Funding Scheme NHMRC Project Grants

Notes Standard Project Grant

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