Regulation Of Innate Immunity And Tumour Progression By Activating Transcription Factor 3
Funder
National Health and Medical Research Council
Funding Amount
$473,469.00
Summary
Toll-like receptors (TLRs) play an essential role in innate immune responses and are involved in initiating tumourigenesis via inflammatory pathways. We have shown that the transcription factor ATF3 is a negative regulator of TLR signalling. We will study how modulation of the activity of ATF3 affects the inflammatory response and tumour progression. This will provide a molecular basis on which to design therapeutic reagents for the treatment of cancer.
The Role Of NF-kB Transcription Factors In Regulating T Cell Transcription Networks
Funder
National Health and Medical Research Council
Funding Amount
$534,000.00
Summary
T cells are a key element of the adaptive immune response and help to distinguish between self and non-self. Hence, an inappropriate T cell response can lead to autoimmunity and chronic inflammatory disease. When T cells are activated by an immune signal they switch on the production of an array of proteins that control both T cell function and other arms of the immune system. The genes encoding these proteins possess molecular switches (promoters and enhancers) that respond to immune signals. T ....T cells are a key element of the adaptive immune response and help to distinguish between self and non-self. Hence, an inappropriate T cell response can lead to autoimmunity and chronic inflammatory disease. When T cells are activated by an immune signal they switch on the production of an array of proteins that control both T cell function and other arms of the immune system. The genes encoding these proteins possess molecular switches (promoters and enhancers) that respond to immune signals. These molecular switches bind groups of proteins known as transcription factors. One family of transcription factors that plays a key role in T cell function is the NF-kB family consisting of five different members, three of which are important in T cell function. Aberrant NF-kB function or expression has been associated with autoimmunity, chronic inflammation and cancer. In addition, NF-kB proteins are key components of transplant rejection. There is enormous interest in using the NF-kB pathway as a therapeutic target for these pathologies. We currently have a detailed knowledge of the biology of these factors through studies of mice lacking specific family members. While we know some of the genes that are switched on by the NF-kB proteins, we currently lack a sufficiently detailed knowledge of NF-kB-regulated genes in order to link the molecular function with the biological outcomes. In order to understand the molecular mechanism of NF-kB function and relate this to the biological outcomes, we need a global view of NF-kB action in the cell. This proposal uses both experimental and computational approaches to decipher the gene expression program controlled by NF-kB proteins in T cells. The T cell transcription networks in which NF-kB proteins participate will also be investigated. The knowledge generated by these experiments will provide a solid basis for designing therapeutic approaches based on the NF-kB pathway.Read moreRead less
Morphometric Analysis Of Normal Airway Structure In Childhood And The Influence Of A History Of Asthma On This Structure
Funder
National Health and Medical Research Council
Funding Amount
$186,113.00
Summary
The architectural structure of the airways of the lung is thought to have profound effects on airway function. Changes in this structure are believed to be partly responsible for limiting the flow of air into the lung in conditions such as constant wheezing, bronchitis and asthma. Pathological studies carried out on adult lungs have shown that the structure of the airways is indeed altered in patients with lung disease when compared with patients with no history of breathing difficulties. For ex ....The architectural structure of the airways of the lung is thought to have profound effects on airway function. Changes in this structure are believed to be partly responsible for limiting the flow of air into the lung in conditions such as constant wheezing, bronchitis and asthma. Pathological studies carried out on adult lungs have shown that the structure of the airways is indeed altered in patients with lung disease when compared with patients with no history of breathing difficulties. For example, the walls of the airways are much thicker in patients with lung disease. This thickening means that the airways are much narrower and therefore not able to carry as much air as in people with healthy lungs. In addition, the muscle within the airway wall, which is normally very sparse, is much denser in people with asthma and bronchitis. Thus, the airways can be squeezed closed more easily. It is not known if these changes are present in children who have lung disease. X-rays and sophisticated breathing tests suggest that these children may also have thicker walls and more muscle in their airways. The major difficulties in assessing whether such changes are present in children, is the lack of information on the normal structure in infants; how this changes as they grow to adulthood; or if there are any gender differences. This project aims to obtain this information from the airways of male and female children from 0-18 years. This information can then be used as a basis for comparison with the structure found in children with lung disease, in particular asthma, and therefore assist in making assessments as to the cause of their breathing difficulties. With more knowledge about these causes, we will be in a better position to design new and better treatments and produce ways of preventing them ever occurring.Read moreRead less
Mechanisms By Which Chromatin Modulates Gene Expression.
Funder
National Health and Medical Research Council
Funding Amount
$267,750.00
Summary
Gene expression in a cell occurs in the nucleus where genes are stored. In the nucleus, DNA is not in a free form but is covered with an equivalent weight of protein to form a structure known as chromatin. Chromatin is a periodic structure made up of repeating, regularly spaced subunits, the subunit being the nucleosome. A nucleosome consists of a group of proteins (histones) wrapped around with DNA. A nucleosome is both capable of blocking and activating gene expression. Therefore one important ....Gene expression in a cell occurs in the nucleus where genes are stored. In the nucleus, DNA is not in a free form but is covered with an equivalent weight of protein to form a structure known as chromatin. Chromatin is a periodic structure made up of repeating, regularly spaced subunits, the subunit being the nucleosome. A nucleosome consists of a group of proteins (histones) wrapped around with DNA. A nucleosome is both capable of blocking and activating gene expression. Therefore one important function of chromatin is to tightly regulate gene expression which is essential to allow an organism to develop properly. When gene expression is not accurately controlled by chromatin developmental defects or cancer can result from the production of incorrect proteins. To control correct gene expression, highly specific mechanisms must operate in the cell to remove, or modify, nucleosomes at certain genes at a precise time during development. One mechanism that we believe to be important is changing the make-up of a nucleosome. This can be achieved in the cell by the replacement of histones with different specialized forms of these histones (variants). We believe that these histone variants can specifically generate chromosomal domains which could in some cases expose or in other cases hide certain genes and thereby turn them on or off. Employing a new approach, we will study one of these histone variants to discover the role it plays in determining the type of chromosomal domain made and the role of this domain has in turning genes on or off at precise times in early development during the formation of different specialized cell types. This new information may define targets for the prevention of incorrect gene expression during cancer progression or abnormal development.Read moreRead less