The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammator ....The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammatory or allergic disease, such as arthritis or asthma. This team of researchers from the Hanson Institute in Adelaide, combining expertise in molecular and cell biology, protein chemestry, structual biology and animal models, has been working together for over 10 years, investigating the molecular mechanisms involved in controlling the formation and activities of blood vessels and white blood cells. This program seeks to further that understanding, and to develop drugs that have the potential of ameliorating the inflammatory condition.Read moreRead less
One of the most amazing engineering achievements in nature is how over 2 meters of genetic material (DNA) can be compacted and squeezed nearly a million times to fit into a human cell. The remarkable structure that achieves this is the chromosome. Fundamental to the survival of a multicellular organism is that the chromosome is stably maintained throughout out the life of an organism. For example, defects in maintaining chromosome stability can lead to aneuploidy (cells with an abnormal number o ....One of the most amazing engineering achievements in nature is how over 2 meters of genetic material (DNA) can be compacted and squeezed nearly a million times to fit into a human cell. The remarkable structure that achieves this is the chromosome. Fundamental to the survival of a multicellular organism is that the chromosome is stably maintained throughout out the life of an organism. For example, defects in maintaining chromosome stability can lead to aneuploidy (cells with an abnormal number of chromosomes), a feature exhibited by many forms of cancer. This packaging of genomic DNA that produces a chromosome is achieved by a complex scheme of folding. At the first level, DNA is first wrapped around a mixture of proteins (called histones) to form a complete unit known as a nucleosome. About 30 million of these building blocks are required in every human cell to compact our DNA. Higher, more complicated levels of organization exist in which a linear array of nucleosomes fold to various extents to form distinct functional and structural domains. Importantly, specialised chromosomal domains, like the telomere and centromere, are assembled that keep the ends of the chromosomes stable and enable a chromosome to copy itself every time our cells divide and grow, respectively. How a chromosome is divided into these different compartments remains a mystery. This investigation will show that a key cellular mechanism that determines how the chromosome is organised into stable domains is by changing the make-up of chromosomal domains through the replacement of histone proteins with specialised forms of histones called variants . These histone variants control the way a linear array of nucleosomes fold into complex three-dimensional structures to perform a specialised function. This fundamental research will provide important new information on how chromosomes become unstable in cancer. It will also enable new strategies, which stabilise the chromosome, to be explored.Read moreRead less
Structure And Function Of The Alternative Splicing Factor ZNF265
Funder
National Health and Medical Research Council
Funding Amount
$509,017.00
Summary
Now that the human genome has been sequenced, we can see that a human being is defined bye approximately 30000 genes. One of the biggest surprises to come from this work was that the number of genes was significantly smaller than many predicted. Similar surprise was registered at the discovery that the genome of the fruit fly actually contained fewer genes than that of the model worm, Caenorhabditis elegans. Part of the explanation for these apparent discrepencies lies in the phenomenon known as ....Now that the human genome has been sequenced, we can see that a human being is defined bye approximately 30000 genes. One of the biggest surprises to come from this work was that the number of genes was significantly smaller than many predicted. Similar surprise was registered at the discovery that the genome of the fruit fly actually contained fewer genes than that of the model worm, Caenorhabditis elegans. Part of the explanation for these apparent discrepencies lies in the phenomenon known as gene splicing, whereby one gene can actually give rise to many different isoforms of the same protein. These different isoforms can have different structures and-or functions, and dramatically increase the complexity that it is possible for an organism to achieve with a given number of genes. The process of splicing is very intricate, requiring precise control to allow an organism to develop normally. Many human genetic diseases are known to arise from problems with splicing. However, our understanding of the mechanisms of splicing is rather incomplete. This proposal aims to improve our understanding of the splicing process through a range of biophysical and molecular biological approaches. This information should prove useful in understanding human development and disease.Read moreRead less
The C-type Lectin, Mincle, Is A Macrophage Receptor For Candida Albicans.
Funder
National Health and Medical Research Council
Funding Amount
$465,210.00
Summary
The yeast Candida albicans is an important opportunistic infection that causes both mucosal and disseminated disease in patients whose innate or adaptive immune responses are impaired Infection and proliferation results in fungal colonisation of the tissues, and a variable degree of tissue damage. The latter is determined both by the virulence properties of the organism and by the genetic makeup of the host. This large, extracellular pathogen is eradicated from the body predominantly by acavenge ....The yeast Candida albicans is an important opportunistic infection that causes both mucosal and disseminated disease in patients whose innate or adaptive immune responses are impaired Infection and proliferation results in fungal colonisation of the tissues, and a variable degree of tissue damage. The latter is determined both by the virulence properties of the organism and by the genetic makeup of the host. This large, extracellular pathogen is eradicated from the body predominantly by acavenger (phagocytic) cells, which are also important in determining the severity of the associated tissue lesions. A phagocytic cell that is central to both innate and adaptive immune responses is the macrophage, which not only takes up and kills the yeast, but also is capable of of killing and digesting it, and presenting the components to cells of the adaptive immune system. This project is based on the postulate that the outcome and severity of infection is determined, at least in part, by the early functional response of the macrophage to the overall virulence properties of the yeast. The response is initiated by interactions with cell-surface receptors, and this study will show that a novel macrophage receptor, Mincle, is an important part of the innate immune response to fungal infections. We have shown that it is associated with differences in susceptibility to yeast infections in inbred mouse strains; it can discriminate between different isolates of the yeast; and it initiates the inflammatory signalling cascade. Our project will define the specific role of this receptor in fungal infection. The results will be important in understanding the basic biology of host resistance, and will offer new opportunities for therapeutic intervention by selectively blocking or modifying different activation pathways.Read moreRead less