Environmental Influences In The Establishment Of The Epigenetic Landscape In Children
Funder
National Health and Medical Research Council
Funding Amount
$695,097.00
Summary
The DNA in each of our cells does not exist alone, it is packaged into complex structures called chromosomes, through association with many different proteins. The distribution of these proteins varies along the length of a chromosome depending on the type of cell and this phenomenon is called 'epigenetics', literally meaning 'above the DNA'. Epigenetic analysis is the study of how proteins and other molecules can change the activity of a gene without changing the DNA sequence. All of our cells ....The DNA in each of our cells does not exist alone, it is packaged into complex structures called chromosomes, through association with many different proteins. The distribution of these proteins varies along the length of a chromosome depending on the type of cell and this phenomenon is called 'epigenetics', literally meaning 'above the DNA'. Epigenetic analysis is the study of how proteins and other molecules can change the activity of a gene without changing the DNA sequence. All of our cells use epigenetic changes to help control how they grow and develop. Evidence suggests a direct link between diet and environmental influences on our epigenetic profile. Recent research has traced the origins of many of the health problems of adult life back to the earliest periods of development _ to the time spent in the womb and the first few years of life. If we are born with a low birth weight, we are more likely to get sick later in life. Overwhelming evidence exists that the environment in the womb is critical for a healthy birth weight (and health in later life) and it is thought that epigenetics may be the missing link between this environment, low birth weight, and therefore health in later life. In addition, mounting evidence supports a general link between epigenetic de-regulation and predisposition to disease. However, the timing and the overall contribution of environmental- genetic influences to the establishment of faulty epigenetic markings remain largely unknown. Twins are the best model to study this link as they share similar (but not identical environments) and some share identical genetic makeup. Using twins, Dr Jeffrey Craig and his team will investigate the factors in the prenatal environment that modify specific cells, leading to low birth weight and increase disease risk later in life. They predict that this occurs via specific changes in gene activity caused by epigenetic disruption.Read moreRead less
Transforming Growth Factor Beta Signalling In Malignant Mesothelioma Growth And Collagen Production
Funder
National Health and Medical Research Council
Funding Amount
$509,917.00
Summary
Many cancers contain abundant connective tissue molecules called extracellular matrix (ECM) and data show that interaction of ECM with cells are important in the growth of cancers (1). Changes in expression of ECM and their receptors (integrins) have been associated with malignant changes in cells, enhanced tumour growth and resistance to chemotherapy (2,3). We have recently shown that inhibition of collagen, the most abundant ECM molecule produced by malignant mesothelioma (MM) cells, reduced M ....Many cancers contain abundant connective tissue molecules called extracellular matrix (ECM) and data show that interaction of ECM with cells are important in the growth of cancers (1). Changes in expression of ECM and their receptors (integrins) have been associated with malignant changes in cells, enhanced tumour growth and resistance to chemotherapy (2,3). We have recently shown that inhibition of collagen, the most abundant ECM molecule produced by malignant mesothelioma (MM) cells, reduced MM growth. How cancer cells regulate ECM production and control their growth is unclear but strong evidence suggests the growth factor transforming growth factor-beta (TGFB) plays an important role. We and others showed that MM cells secrete all forms (1-3) of TGFB, and TGFB1,2-like activity has been reported in pleural effusions from MM (4,5). All TGFB forms stimulate MM cells to grow and make ECM (6,7). We showed that high levels of collagen produced by MM are enhanced by TGFB. Small molecules called antisense oligonucleotides (AO) which blocked production of TGFB2 by cells, reduced MM cell growth in soft agar, a characteristic of cancer, and partially blocked MM growth in animal models (4,6). This was supported by studies using soluble TGFB type II receptors, which blocks TGFB1,3 (8), and our studies using TGFB2 specific antibodies, as both studies reduced tumour growth. These findings support a role for TGFB in MM growth. However, all TGFB forms can promote cell grow and collagen synthesis and therefore ways to block all TGFB forms are required to ensure maximal effect. This study will examine the effect of blocking common downstream signalling pathways of all three TGFB isoforms on MM collagen production and tumour growth. These pathways are activated when TGFB binds to its receptors sending messages to the nucleus of the cell to make collagen or grow. By identifying which TGFB signalling pathway is important, we may be able to design novel therapeutic approaches to help treat patients with this disease.Read moreRead less