Matching Between Codon Usage And TRNA Abundance Determines The Expression Of Targeting Genes In Mammalian Cells
Funder
National Health and Medical Research Council
Funding Amount
$358,500.00
Summary
This proposal is about optimal production of protein drugs (biopharmaceuticals), using genetic engineering in the laboratory and gene therapy in patients. It will explore the science behind a novel observation that the optimal way to use the genetic code to encode proteins for production varies from cell to cell in the lab, and from tissue to tissue in patients. If successful, a simple test can be used to decide the optimal genetic code for a specific application.
Functional Characterisation Of Regulators Of Human Globin Gene Switching
Funder
National Health and Medical Research Council
Funding Amount
$232,131.00
Summary
Red blood cells produce haemoglobin, a tetramer of two alpha globin chains and two beta-globin chains. Haemoglobin reversibly interacts with oxygen in such a way that it efficiently shuttles oxygen between the lungs and the rest of the body. Integrity of the hemoglobin molecule, and red cells which carry it, is essential for life of all organisms with blood. The alpha-globin and beta-globin chains that make up haemoglobin are prodcued by red cell precursors in the bone marrow according to the ge ....Red blood cells produce haemoglobin, a tetramer of two alpha globin chains and two beta-globin chains. Haemoglobin reversibly interacts with oxygen in such a way that it efficiently shuttles oxygen between the lungs and the rest of the body. Integrity of the hemoglobin molecule, and red cells which carry it, is essential for life of all organisms with blood. The alpha-globin and beta-globin chains that make up haemoglobin are prodcued by red cell precursors in the bone marrow according to the genetic blueprint (genes) that are inherited. Genetic disorders resulting from defects in the beta-globin gene are the most common inherited disorders of man. Children who fail to make beta-globin have a disease known as beta-thalassaemia. They are transfusion dependent from ~ 6 months of age and need intensive chelation therapy (infusions) to avoid the serious consequnces of iron overload. The average life expectancy in Western cultures is ~ 30 years. There is no cure. In third world countries where a reliable blood supply is unavailable, death occurs earlier. Patients are aften infected with blood born viruses such as hepatitis B, hepatitis C and the AIDS virus, HIV. Sickle cell anaemia is also a very common disease. It is due to a single DNA base mutation at in the beta-globin gene that results in production of normal amounts of a defective beta-globin molecule (HbS). In low oxygen, HbS molecules polymerize in red cells and irreversibly damage them. These red cells get trapped in small blood capillaries throughout the circulation causing small infarcts which results in severe pain and organ damage. The life expectancy is <2 years in the thrid world and ~20-30 years in the west. The irony of these two diseases is that there is a perfectly normal fetal globin gene that has been silenced during fetal life. This grant aims to understand the mechanism of the switch from fetal to adult globin gene usage so it can be reversed in adults with b-thalassemia and sickle cell diseaseRead moreRead less
Identification Of Critical Regulatory Elements In The BRCA1 Gene
Funder
National Health and Medical Research Council
Funding Amount
$227,036.00
Summary
Breast cancer affects approximately one in ten women and is therefore a major health problem. In order to improve the diagnosis, treatment and prognosis of this disease, it is critical to understand the molecular defects that contribute to disease initiation and progression. Over the last twenty years significant progress has been made in this regard, however there still remain a considerable number of unanswered questions. For example, it is not yet clear precisely what contribution each of the ....Breast cancer affects approximately one in ten women and is therefore a major health problem. In order to improve the diagnosis, treatment and prognosis of this disease, it is critical to understand the molecular defects that contribute to disease initiation and progression. Over the last twenty years significant progress has been made in this regard, however there still remain a considerable number of unanswered questions. For example, it is not yet clear precisely what contribution each of these genes makes. This is largely due to limitations in current mutation detection strategies and an incomplete understanding of all of the genetic elements for which disruption can lead to loss of gene function. This propsal aims to identify all of the genetic elements critical for the expression of an important breast cancer gene called BRCA1. Furthermore, it aims to determine the status of these elements in breast cancer patients, thus expanding our knowledge of the actual contribution disruption of this gene makes to this disease.Read moreRead less
This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does ....This is a study of the biological system of epigenetics. Every cell in our body has the same genetics, or library of information contained in the form of DNA sequence. Epigenetics is the system that controls how this DNA is used in a particular situation, or what books are opened and read. During embryonic development, cells know what they want to become, e.g., a muscle cell, and, once they take on an identity, remember that they are when they duplicate themselves during growth. Epigenetics does not achieve this through changing genetics the library always stays intact. Rather, it acts by using proteins or chemicals to make DNA functional in one way, or another. Genomic imprinting is a special type of epigenetics. While an embryo has received identical genetic information from each of its parents, the epigenetic information received from each parent was not entirely the same. Some genes which behave differently according to what parent they came from. For example, a gene that makes a growth factor protein is active only if received from the father. If received from the mother, it is inactive, and makes no protein. Genes behaving in this way are known as imprinted genes. We are trying to discover what epigenetic mechanisms are behind this behaviour of imprinted genes. One way we are approaching this problem is to study germ cells the cells giving rise to eggs and sperm. These cells are unusual in that their imprinted genes behave in the same way regardless of whether they were received from the mother or father, i.e., like any other gene. If we can understand why this is the case, we will be better able to understand why imprinted genes behave the way they do in the rest of the cells of the body. Broadly, the mechanisms we uncover should further our understanding of germ cell development, gene expression, and disease. Perturbations in the epigenetic profile are likely causes of human disease, including cancer.Read moreRead less
Marsupial germ cells and genes. Germ cells are the most fascinating cells in the body, since theirs is the unique responsibility for transmitting life from generation to generation. Studies in mice have suggested that position in the embryo determines their origin, but the early embryology of the mouse is so different from that of other mammals that the events need confirming and extending in another species. The simplified embryology of the tammar wallaby makes it ideal for studying one of the ....Marsupial germ cells and genes. Germ cells are the most fascinating cells in the body, since theirs is the unique responsibility for transmitting life from generation to generation. Studies in mice have suggested that position in the embryo determines their origin, but the early embryology of the mouse is so different from that of other mammals that the events need confirming and extending in another species. The simplified embryology of the tammar wallaby makes it ideal for studying one of the most fundamental questions in the whole of biology: what is the basis for the primal distinction between sex and soma?Read moreRead less
How does the unilaminar blastocyst form an embryo? Marsupials are synonymous with Australia and they are scientifically amazing. An understanding how the single-layered marsupial blastocyst cells are directed to form the complex organisation of an embryo would help us understand the biology underlying the developmental potential of all cells. Understanding these processes is not only of great fundamental interest to developmental biology but also for the development of embryonic stem cell lines. ....How does the unilaminar blastocyst form an embryo? Marsupials are synonymous with Australia and they are scientifically amazing. An understanding how the single-layered marsupial blastocyst cells are directed to form the complex organisation of an embryo would help us understand the biology underlying the developmental potential of all cells. Understanding these processes is not only of great fundamental interest to developmental biology but also for the development of embryonic stem cell lines. This research will continue Australia's high profile in reproductive biology using one of our iconic native mammals. A greater understanding of marsupial reproduction will also contribute to management of our threatened marsupial populations.Read moreRead less