Synaptic Connectivity Of Colour Pathways In Primate Retina
Funder
National Health and Medical Research Council
Funding Amount
$367,500.00
Summary
The first step in the visual process occurs when light enters the eye and activates specialised nerve cells called photoreceptors. The photoreceptors for daytime vision (called cones for their cone-like shape) comprise three types, which are sensitive to the long- (red), medium- (green) or short-wavelength (blue) regions of the visible spectrum. Although the properties of the cones are well known, the way in which they are functionally connected to nerve pathways for vision is not clearly unders ....The first step in the visual process occurs when light enters the eye and activates specialised nerve cells called photoreceptors. The photoreceptors for daytime vision (called cones for their cone-like shape) comprise three types, which are sensitive to the long- (red), medium- (green) or short-wavelength (blue) regions of the visible spectrum. Although the properties of the cones are well known, the way in which they are functionally connected to nerve pathways for vision is not clearly understood. Clinical research has shown that reduced sensitivity to blue light is a feature of the early stages of certain visual diseases (for example, glaucoma), so it is important to know how the short-wavelength (blue) cones contribute to visual functions such as form, motion and colour perception. Such knowledge can help to design better tests for diagnosis of visual disorders, and will improve our understanding of the normal function of the visual system in the human brain. In this project the connections of neurones in the primate retina (the nerve cells which line the back of the eye) will be analysed. The blue cones and other nerve cells will be identified using contemporary anatomical methods (double- and triple-label immunocytochemistry) combined with a new method for high-resolution light microscopy, called deconvolution microscopy. Immunocytochemistry is a method borrowed from the field of immunology, where specific antibodies are raised which bind selectively to label specific populations of neurones. Deconvolution microscopy allows rapid and simultaneous visualisation of multiple labelled cell classes, at a resolution close to the limit of the light microscope. Together, these techniques allow the wiring diagram of the blue cones within the retina to be analysed to a higher level of accuracy than previously achieved. The results will improve our understanding of the role of blue-cone circuits in normal vision and visual disorders.Read moreRead less
Promoting Regrowth Of Nerve Fibres Into The Epidermis During Diabetic Neuropathy By LRP Agonists
Funder
National Health and Medical Research Council
Funding Amount
$427,102.00
Summary
Nerve damage can develop post injury or disease and is often very debilitating, slow to heal and can cause increased pain. Our work aims to examine a new class of molecules that we show can activate selected fat-receptors on nerve cells to guide the growth of regenerating nerves. We will determine how these receptors function with the aim of developing a novel class of therapeutics directed at healing nerve damage.
Combining Timelapse Imaging And Computational Modelling To Understand The Mechanisms Of Axon Guidance In The Developing Retinotectal System
Funder
National Health and Medical Research Council
Funding Amount
$438,793.00
Summary
Understanding how patterns of brain wiring develop is crucial for understanding many cognitive disorders. One of the commonest types of connection pattern in the brain is a topographic map, where nearby neurons in one structure connect to nearby neurons in another structure. Using the transgenic tools available in the zebrafish as a model system, we will combine novel experiments with computational modelling to understand the rules which govern the formation of topographic maps in the brain.
Deciphering The Mechanisms Underlying LRP-mediated Axon Guidance
Funder
National Health and Medical Research Council
Funding Amount
$370,659.00
Summary
Nerve damage can develop post injury or disease and are often very debilitating, slow to heal and cause increased pain. Our work aims to examine a new class of molecules that we show can activate selected fat-receptors on nerve cells to guide the growth of regenerating nerves. We will determine how these receptors function with the aim of developing a novel class of therapeutics directed at healing nerve damage.
The Role Of Store-operated Calcium Entry In Neuronal Development
Funder
National Health and Medical Research Council
Funding Amount
$353,140.00
Summary
Defects in brain development can manifest in a range of disorders including autism and mental retardation. The highly complex, precise network that is our nervous system forms during development. Our work will determine the role of key proteins in guiding developing neurons. Understanding the function of such proteins will improve our ability to predict the outcome caused by mutations in these proteins, in the developing foetus.