Elucidating The Mechanisms Of Action Of And Resistance To Endoperoxide Antimalarials
Funder
National Health and Medical Research Council
Funding Amount
$716,755.00
Summary
Artemisinin-based antimalarials (ARTs) save hundreds of thousands of lives every year. Unfortunately resistance of P. falciparum to ART is now emerging in South East Asia and it is critical to know how and why. We will determine what is different about resistant parasites and will develop assays to monitor drug resistance in the field. We have found that the immature form of the malaria parasite is more resistant to ARTs, which helps explain resistance. We will build on this to develop new targe ....Artemisinin-based antimalarials (ARTs) save hundreds of thousands of lives every year. Unfortunately resistance of P. falciparum to ART is now emerging in South East Asia and it is critical to know how and why. We will determine what is different about resistant parasites and will develop assays to monitor drug resistance in the field. We have found that the immature form of the malaria parasite is more resistant to ARTs, which helps explain resistance. We will build on this to develop new targetted treatments.Read moreRead less
The Structural Basis Of Direction Selectivity In The Retina
Funder
National Health and Medical Research Council
Funding Amount
$401,705.00
Summary
The retina is part of the central nervous system and there are almost one hundred types of retinal neurons which process visual information before it is passed up the optic nerve to the brain. This project examines how some of these neurons are wired together to form a simple neuronal circuit that detects the direction of a moving object. The elucidation of the cellular mechanisms of direction selectivity will provide an important paradigm of complex processing by simple neuronal circuits, with ....The retina is part of the central nervous system and there are almost one hundred types of retinal neurons which process visual information before it is passed up the optic nerve to the brain. This project examines how some of these neurons are wired together to form a simple neuronal circuit that detects the direction of a moving object. The elucidation of the cellular mechanisms of direction selectivity will provide an important paradigm of complex processing by simple neuronal circuits, with direct relevance to information processing in other parts of the central nervous system. In particular, the project may provide strong evidence for two neuronal strategies that may be of general significance. First, information may be processed at a very local level, which would greatly increase the computational power of a single neuron. Second, neurons may make selective contact with only some processes of an input neuron, which would require novel mechanisms for producing the necessary specificity.Read moreRead less
Spatial Arrangement And Three-dimensional Structure Of Human Centromeres
Funder
National Health and Medical Research Council
Funding Amount
$283,000.00
Summary
Centromeres occur at the main constriction of chromosomes. They allow duplicated chromosomes to divide, control cell division and are involved in the control of gene expression. Faulty centromeres are found in many types of cancer and in other genetic diseases. They are also implicated in extra-chromosome disorders such as Down syndrome. Centromeres have a different structure to the rest of the chromosome and it is this structure we wish to study. We want to see how centromere DNA folds up tight ....Centromeres occur at the main constriction of chromosomes. They allow duplicated chromosomes to divide, control cell division and are involved in the control of gene expression. Faulty centromeres are found in many types of cancer and in other genetic diseases. They are also implicated in extra-chromosome disorders such as Down syndrome. Centromeres have a different structure to the rest of the chromosome and it is this structure we wish to study. We want to see how centromere DNA folds up tightly at the centromere. We also want to find out why centromeres locate in certain regions of the nucleus, because this may influence how the centromere works and how they regulate genes. Human centromeres come in many sizes and forms; by looking at a wide range of human centromeres, common structural and spatial properties will emerge. We have discovered very small centromeres - neocentromeres - which are much easier to study than other centromeres. We have used these centromeres to construct human minichromosomes, which we believe represent the main, all-human way forward to treat people with gene therapy. One way to help us achieve our aims is to stretch out centromeres in a controlled way to make it easier to visualise their structure. Our tools will be antibodies, fluorescently-labelled proteins and high resolution microscopes. These include an electron microscope, and microscopes that can produce optical sections and in turn a 3D image. One of these is the confocal laser scanning microscope; the other involves removal of out-of-focus light from images using deconvolution software to achieve the same goal. We will detect different centromere proteins with different fluorochromes for fluorescence microscopes and different sizes of gold particles for the electron microscope. Using these microscopes we have already been able to find out where one of our neocentromeres is located within the nucleus. We have also started to look at centromeres with the electron microscope.Read moreRead less
Breaking Malaria's Lethal Grip: Targeting The Assembly Of An Adhesive Complex On Infected Red Blood Cells
Funder
National Health and Medical Research Council
Funding Amount
$817,426.00
Summary
The malaria parasite, Plasmodium falciparum, infects the red blood cells of its human victims. It causes them to stick to blood vessel walls in the brain, causing severe cerebral complications and death. Adhesion is mediated by a Velcro-like protein that is presented at the red blood cell surface. This project will fully elucidate the pathway for trafficking of the adhesion protein to the red blood cell surface with a view to finding new ways of interfering with malaria disease.
Architecture Of The Hendra Virus Nucleocapsid And Implications For Replication
Funder
National Health and Medical Research Council
Funding Amount
$342,108.00
Summary
Hendra virus causes sporadic fatal outbreaks in horses, which may result in human deaths through direct contact with infected animals. The unanticipated surge of Hendra cases since mid-2011, the broad host range of the virus and the discovery of other related viruses worldwide highlight the epidemic potential of hendra-related paramyxoviruses. To improve our preparedness against paramyxoviruses, this Project aims at determining the structure of the viral replication machinery.
Modulating The Skin Immune System With Physical Stimulus
Funder
National Health and Medical Research Council
Funding Amount
$425,353.00
Summary
The Fellowship will be based between Uni QLD and Massachusetts General Hospital, Harvard Medical School. It will consist of pre-clinical development and validation of an in vivo optical micro-manipulation system for laser-guided extraction of cells. A comparable system will then be developed for characterization of leukocytes in healthy and diseased human skin. The long term outcomes will be better characterisation of inflammatory skin disease resulting in new targets and therapeutic strategies.
A Novel Patch-fluorimetry Technique For Investigating Structural Changes During Gating Of Mechanosensitive Ion Channnels
Funder
National Health and Medical Research Council
Funding Amount
$387,018.00
Summary
Membrane proteins, especially membrane channels play an important role in regulating the flow of substances across the cell. Dysfunction in these channels can lead to a variety of diseases. Thus approximately 60% of drug development is targeted against such proteins. In our research, we are looking at membrane channels found in bacteria. Understanding the function of these channels will help us develop novel anti-bacterial agents. It will also aid to understand a role of ion channels in disease.