Estimation And Partitioning Of The Still-missing Heritability For Complex Disease
Funder
National Health and Medical Research Council
Funding Amount
$291,856.00
Summary
We have pioneered the use of multi-marker statistical genetic methods in human genetics to elucidate the genetic architecture of complex traits, including common diseases. We have shown that between a third and a half of additive genetic variation is captured by common genetic variants, leaving two-thirds to a half truly ‘missing’. In this proposal we will test our hypothesis that the still-missing heritability is due to low frequency causal variants. Applications of genomic medicine require thi ....We have pioneered the use of multi-marker statistical genetic methods in human genetics to elucidate the genetic architecture of complex traits, including common diseases. We have shown that between a third and a half of additive genetic variation is captured by common genetic variants, leaving two-thirds to a half truly ‘missing’. In this proposal we will test our hypothesis that the still-missing heritability is due to low frequency causal variants. Applications of genomic medicine require this fundamental knowledge to progress fully.Read moreRead less
Dynamics And Mechanisms Of Immune Complex-mediated Skin Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$526,467.00
Summary
Type III hypersensitivity underlies a number of common autoimmune diseases, including rheumatoid arthritis and lupus erythematosus. These diseases are caused by the deposition of immune complexes (IC) and the accumulation of neutrophils within small blood vessels. We will use real time imaging to dissect in space and time the recruitment of neutrophils and IC deposition during type III hypersensitivity reactions in order to better understand the pathogenesis of these conditions.
Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune ....Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune diseases. An agent that could block the effects of C5a could be very useful clinically. There is no such drug available as yet. We have developed powerful agents which specifically block C5a in laboratory tests on isolated cells and tissues, and now propose to test their effectiveness in rats in which the above human disease conditions are mimicked. Our preliminary results are very promising, and we will conduct further testing to determine the scope of the actions of the new drugs. One of our new agents is orally active in rats, and we will determine how the blood levels of the drug relate to its beneficial effects. We are also planning to develop agents that are more effective when given by mouth. The results could lead to a new type of anti-inflammatory drug for humans suffering from a variety of diseases that are poorly treatable at present.Read moreRead less
Human Fc Receptors In Antibody Mediated Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$640,824.00
Summary
A series of major Australian discoveries is leading to the development of therapies to treat major inflammatory diseases such as rheumatoid arthritis, lupus and similar autoimmune diseases where there is a significant unmet need for new therapies. A major molecule, caled Fc receptor was discoverd by the researchers who have now found new ways to prevent it activating inflammatory cells and therby preventi tissue destruction.
We have discovered how a rare type of human antibody called IgG4 exerts a major regulatory influence on the body's immune system. We have discovered how IgG4 can "switch" off inflammatory white blood cells which has broad implications for the development of new forms of therapy for switching off allergies and autoimmune diseases and for switching on immunity to infections and cancers.
Developing And Applying Biologically Plausible Statistical Models For Normal And Non-normal Family Data
Funder
National Health and Medical Research Council
Funding Amount
$339,700.00
Summary
Although molecular and computing advances have enabled more detailed investigations of inherited diseases and the ability to fit realistic statistical models to these data, limitations still exist when analysing family data. Often only basic statistical analyses are performed, due to the lack of understanding of complexities within the data and-or inability of researchers to fit appropriate statistical models. These factors have hampered the search for genes and environmental factors influencing ....Although molecular and computing advances have enabled more detailed investigations of inherited diseases and the ability to fit realistic statistical models to these data, limitations still exist when analysing family data. Often only basic statistical analyses are performed, due to the lack of understanding of complexities within the data and-or inability of researchers to fit appropriate statistical models. These factors have hampered the search for genes and environmental factors influencing common diseases. This project aims to develop novel, biologically realistic statistical models for investigation of common, complex diseases, such as heart disease and cancer, in families. These models will incorporate both measured and unmeasured genetic and environmental factors, and will be applicable to both normally distributed and non-normally distributed traits. Model fitting will use computer-intensive simulation techniques. Application of the models to data from two large pre-existing studies of international renown, the Victorian Family Heart Study and the Australian Prostate Cancer Family Study, will enable a better understanding of the genetic and environmental factors influencing heart disease and cancer. The models will also be applicable to many other studies of diseases which use data from families, and allow more accurate and useful information to be obtained from data. Software will also be made freely available to other researchers. This will ultimately translate into better outcomes from familial genetic research, and eventually, better prevention, detection, and treatment of the diseases.Read moreRead less