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
The Role Of Heterochromatin In Regulating Cellular Proliferation And Development
Funder
National Health and Medical Research Council
Funding Amount
$504,000.00
Summary
Fundamental to the development of a multicellular organism is that for each cell type performing a specialised function, a different set of genes are turned on with the remainder being shut off. One of the most significant unanswered questions in biology is how a cell-type specific gene expression profile is established during early development. The answer to this question has important implications in understanding normal and abnormal cellular processes. Gene expression in a cell occurs in the ....Fundamental to the development of a multicellular organism is that for each cell type performing a specialised function, a different set of genes are turned on with the remainder being shut off. One of the most significant unanswered questions in biology is how a cell-type specific gene expression profile is established during early development. The answer to this question has important implications in understanding normal and abnormal cellular processes. 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 (histones) to form a structure known as chromatin. It has become clear that the chromatin structure encompassing a gene is the critical factor that determines whether a gene is expressed or silenced. We propose that developmental and cell-type specific mechanisms operate in a cell to assemble genes into highly specialised chromatin structures that permit (euchromatin) or restrict (heterochromatin) gene expression. In other words, the genome of each different cell type is organised into a unique and dynamic chromatin pattern and this pattern determines the gene expression profile. This investigation will show that the critical cellular mechanism that determines the chromatin pattern for a particular cell type is the regulation of the quantity and quality of heterochromatin. Specifically, we will demonstrate that this is achieved, in a developmental and tissue specific manner, by changing the make-up of chromosomal domains through the replacement of histone proteins with specialised forms of histones called variants . In addition, we will expose a new mechanism of how heterochromatin formation controls the rate of cellular proliferation. This information will provide new insights into how gene expression profiles are established at precise times in early development, and offer a new strategy to inhibit the proliferation of cancer cells.Read moreRead less
Characterization of erythroid differentiation related factor (EDRF): a novel a-globin binding protein. Hemoglobin, a four-subunit protein comprising two alpha and two beta polypeptide chains, is the essential oxygen transporter found in all mammals. Problems with the synthesis of hemoglobin can give rise to a range of common and serious human disorders, including thalassaemia and anemia. We have discovered a protein, EDRF, that appears to interact directly with alpha-globin (but not beta-globin) ....Characterization of erythroid differentiation related factor (EDRF): a novel a-globin binding protein. Hemoglobin, a four-subunit protein comprising two alpha and two beta polypeptide chains, is the essential oxygen transporter found in all mammals. Problems with the synthesis of hemoglobin can give rise to a range of common and serious human disorders, including thalassaemia and anemia. We have discovered a protein, EDRF, that appears to interact directly with alpha-globin (but not beta-globin) and to play a role in the regulation of hemoglobin production. We now seek to understand the nature of this interaction at a molecular level and mechanistic level.Read moreRead less