Application Of New Technologies And Methods In Nutrition Research – The Example Of Phenotypic Flexibility
Funder
National Health and Medical Research Council
Funding Amount
$210,823.00
Summary
The aim of the Nutritech project is to develop better diagnostics of the effect of foods and dietary supplements on the health of an individual. NutriTech will develop new analytical technologies to comprehensively investigate the diet-health interrelationship and critically assess their usefulness for the future of nutrition research. A new automated method for measuring the effect of diet on multiple measures of DNA damage and nutrients in single cells will be developed at CSIRO.
One of the interesting questions in human biology is why monozygotic twins, which have an identical genetic make up, can still vary in many complex traits such as height, eye colour and susceptibility to various mental and disease states. It is clear that this variation is not always due simply to environment. We propose in this application to show that, even if the genetic code is identical in monozygotic twins, epigenetic marks such as DNA methylation and histone modifications can vary between ....One of the interesting questions in human biology is why monozygotic twins, which have an identical genetic make up, can still vary in many complex traits such as height, eye colour and susceptibility to various mental and disease states. It is clear that this variation is not always due simply to environment. We propose in this application to show that, even if the genetic code is identical in monozygotic twins, epigenetic marks such as DNA methylation and histone modifications can vary between critical genes giving rise to differences in gene expression patterns. We propose that the variation in the methylation pattern arises after the two embryos have split, at a time when the developing embryo undergoes genome-wide demethylation followed by de novo re-methylation. The importance of this project is NOT what it tells us about twins themselves, but that twins can provide the clue to disease processes which affect everybody in the population. The results of these experiments will determine the extent to which epigenetic changes to the genome that occur early in embryonic development provide an additional source of variation in gene expression that could contribute to phenotypic variation. By using identical twins we eliminate the possibility that epigenetic modifications that we observe are themselves influenced by genotype. Determining these epigenetic differences will provide an insight into the mechanisms underlying complex traits and human disease.Read moreRead less
In this grant we aim to study the moecular basis of cancer. The promoter regions of tumour suppressor genes are often modified in cancer by a chemical process called methylation. Methylation of DNA is associated with gene silencing. Therefore DNA methylation is commonly regarded as causing the silencing of genes in cancer. In this grant, we aim to determine if methylation is causal in triggering gene silencing in cancer, or if methylation is a consequence of gene silencing. This is a critical di ....In this grant we aim to study the moecular basis of cancer. The promoter regions of tumour suppressor genes are often modified in cancer by a chemical process called methylation. Methylation of DNA is associated with gene silencing. Therefore DNA methylation is commonly regarded as causing the silencing of genes in cancer. In this grant, we aim to determine if methylation is causal in triggering gene silencing in cancer, or if methylation is a consequence of gene silencing. This is a critical distinction in understanding the role of methylation in cancer development.Read moreRead less
The Mutagenic Influence Of 5-methylcytosine And Its Relevance For Cancer Treatment
Funder
National Health and Medical Research Council
Funding Amount
$844,462.00
Summary
Over time our cells accumulate damage to their DNA, which introduces mistakes in the genetic code. These mistakes can alter genes that regulate cell growth and survival and, in this way, they begin the process of turning a normal cell into a cancer. This research is investigating the cellular repair mechanisms that safeguard against DNA damage. Manipulating these repair mechanisms may offer a new way to treat cancer, by selectively inducing DNA damage within cancer cells.
Deciphering The Role Of Atypical DNA Methylation In Neuronal Genome Regulation And Neurological Disorders
Funder
National Health and Medical Research Council
Funding Amount
$773,484.00
Summary
This research will use a combination of genomic, biochemical and functional genomics approaches to investigate the role of the atypical mCH form of DNA methylation in neuronal genome regulation and function, and provide new insights into the role of the epigenome in healthy brain function and neural pathologies.
This study will address the idea that cancer commonly involves a genetic pathway that is normally used by stem cells to proliferate in an undifferentiated state. We have evidence to indicate that this system is active in cancer cells and believe this could explain how cancer cells manage to divide rapidly in a primitive state. This project may bring a new perspective to the study of malignant transformation and has the potential to reveal multiple new targets for cancer therapy.