Mechanisms Underlying The Effects Of Retinoic Acid Receptor Gamma In Haemopoiesis And Bone Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$366,801.00
Summary
My recent studies have demonstrated that a model of vitamin A deficiency results in impaired blood cell production and contributes to a blood cell disorder that can progress to leukaemia. There are also reduced numbers of blood stem cells (which give rise to all blood cells) and bone (which helps to regulate blood cell production) in this mouse model. In these studies I seek to understand more on how vitamin A deficiency causes these defects, which may lead to better treatment of such diseases.
The Roles Of Retinoic Acid Receptors In Regulating Haemopoiesis And Bone
Funder
National Health and Medical Research Council
Funding Amount
$601,484.00
Summary
My research has shown that vitamin A is very important to the normal function of blood and bone cells. I will further explore the uses of vitamin A products to improve the treatment of patients with a range of different blood and bone diseases. These studies may lead to better treatments of patients with a wide range of blood cell diseases. It may also reveal better treatments for patients with bone diseases such as cancer and osteoporosis.
The Roles Of Retinoids And Their Receptors In Haemopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$474,750.00
Summary
Haemopoietic stem cells (HSCs) are the most widely studied adult somatic stem cell. HSCs have huge potential, sustaining blood cell production throughout an individual's life. Cancers (leukaemias) and other disorders of the blood are largely treated by transplantation of HSCs. However, due to their rare occurrence, it is often difficult to obtain large numbers of HSCs for transplantation, especially from sources of HSCs such as cord blood. Furthermore, protocols requiring manipulation of HSCs, s ....Haemopoietic stem cells (HSCs) are the most widely studied adult somatic stem cell. HSCs have huge potential, sustaining blood cell production throughout an individual's life. Cancers (leukaemias) and other disorders of the blood are largely treated by transplantation of HSCs. However, due to their rare occurrence, it is often difficult to obtain large numbers of HSCs for transplantation, especially from sources of HSCs such as cord blood. Furthermore, protocols requiring manipulation of HSCs, such as gene therapy, have been largely unsuccessful, in part due to the lack of success in growing HSCs outside of the body. In such situations, therefore, determining culture conditions that would enable us to grow HSCs outside of the body are highly desirable. This application is based on the studies of CIA, who recently made the novel discoveries that the vitamin A derivative, all-trans retinoic acid (ATRA) has different effects in the regulation of blood cell production. ATRA is currently used in the treatment of acute promyelocytic leukaemia, as it enhances the maturation of the leukaemic cells. CIA has demonstrated that ATRA has the opposite effect on HSCs, with recent data strongly suggesting that ATRA induces the expansion of HSCs outside of the body. The studies outlined in this proposal seek to further define the mechanisms involved in these effects of ATRA and other vitamin A derivatives (collectively termed retinoids) in the regulation of blood cell production. The first specific aim will determine how retinoids expand HSCs. The second specific aim will explore the roles of the different RARs in the regulation of blood cell production. These studies have direct clinical relevance in improving protocols for transplantation and gene therapy of HSCs. Furthermore, insight gained into the roles of retinoids in blood cell production may also lead to the improvement of treatments of various types of blood disorders.Read moreRead less
Mechanisms Underlying The Effects Of TNFalpha In Bone And Haemopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$589,425.00
Summary
Recent studies have identified that bone plays an important role in blood cell production. We have discovered that elevated levels of TNF alpha (which increases with ageing and can negatively impact on health) contributes to a blood cell disorder that can progress to leukaemia. There are also reduced numbers of blood stem cells and bone in this mouse model. In these studies we will determine how TNFalpha contributes to blood and bone defects, which may lead to better treatment of such diseases.