The corticospinal pathway is the major route from the brain to the spinal cord for the control of voluntary movement in people. Little is known about how transmission through this pathway might alter with activity. It is known that, elsewhere in the brain, connections between nerve cells can be made stronger or weaker by specific patterns of activity and it is thought that such changes underlie learning and memory. We propose that similar changes might happen in the spinal cord at the connection ....The corticospinal pathway is the major route from the brain to the spinal cord for the control of voluntary movement in people. Little is known about how transmission through this pathway might alter with activity. It is known that, elsewhere in the brain, connections between nerve cells can be made stronger or weaker by specific patterns of activity and it is thought that such changes underlie learning and memory. We propose that similar changes might happen in the spinal cord at the connection between the nerve cells which carry signals from the brain and the nerve cells which carry the signals out to the muscle. This project will demonstrate that the connections in the pathway from the brain to the muscle can be strengthened or weakened in a controlled way by imposed patterns of activity. In addition, we know that after voluntary contractions, there are dramatic changes in the way signals in this pathway are transmitted to muscles. After brief strong voluntary contractions, muscle responses are immediately reduced. After longer contractions in which the muscles become fatigued, the reduction is followed by an increase in responses which can last many minutes. Thus, this project will also study changes in the pathway from the brain to the muscle after natural activity. The effects of changes induced by artificial or natural activity on the control of voluntary movement will also be investigated. Understanding how activity drives changes in the pathway that controls voluntary movement is important for all situations that involve learning motor tasks. These include normal development and learning of motor skills, as well as rehabilitation after all kinds of nerve or muscle injury. It is also important in understanding motor changes that occur when activity is altered by disorders like spinal cord injury or stroke. Improved understanding of the processes occuring should allow improvement in rehabilitation therapies.Read moreRead less
Isolation And Function Of Human Oogenesis Genes Regulating Meiosis, Recruitment, Growth And Maturation Of The Oocyte.
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Reproductive medicine has progressed very rapidly with the development of in vitro fertilization (IVF) and has delivered the opportunity for a broad group of infertile couples to form their own families. As a consequence, treatment of infertility by major surgery and artificial insemination with donor sperm have declined and there is an increasing interest in the use of IVF to diagnose severe genetic disease in embryos of families at risk. However, little is known about the underlying processes ....Reproductive medicine has progressed very rapidly with the development of in vitro fertilization (IVF) and has delivered the opportunity for a broad group of infertile couples to form their own families. As a consequence, treatment of infertility by major surgery and artificial insemination with donor sperm have declined and there is an increasing interest in the use of IVF to diagnose severe genetic disease in embryos of families at risk. However, little is known about the underlying processes that form the follicles containing the developing germ cells and the matured oocytes needed for IVF. The cohort of oocytes that can be harvested from any patient depends on unknown recruitment processes initiating development of a subset of the quiescent germ cells and happens in an unregulated and spontaneous manner. The present project will identify the known and unknown genes involved in recruitment of oocytes from the basal primordial population. These genes will become candidates for aiding infertile women, improving their response to fertility drugs, the development of novel contraceptive methods and potentially increasing the reproductive life span of women. Knowledge of the genes expressed in oocytes matured in vivo and in vitro will have an important bearing on the long-term opportunity to use fertility drugs in vitro instead of administration to patients for IVF. This would dramatically reduce the cost of IVF and the side-effects of hyperstimulation of ovaries of patients and the associated sequelae. The research project is a discovery program leading to the identification of the genes that govern oogenesis in the human. It is only recently that techniques have been developed to sufficient sensitivity to detect the small quantities of RNA proceeded by active genes in the individual germ cells and oocytes.Read moreRead less