The Role Of Crim-1 In Lens Development And Eye Disease.
Funder
National Health and Medical Research Council
Funding Amount
$196,527.00
Summary
We have recently isolated a novel gene (Crim1) and shown it to be strongly expressed during eye development. Its protein structure indicates that it may act to regulate the activities of two growth factor families, the TGF superfamily and the insulin-IGFs. These growth factors effect the behaviour of many cell types that influence events in normal and pathological development. For example in the eye lens, TGF 1 can induce cataractous changes in epithelial cells and early differentiating fibres; ....We have recently isolated a novel gene (Crim1) and shown it to be strongly expressed during eye development. Its protein structure indicates that it may act to regulate the activities of two growth factor families, the TGF superfamily and the insulin-IGFs. These growth factors effect the behaviour of many cell types that influence events in normal and pathological development. For example in the eye lens, TGF 1 can induce cataractous changes in epithelial cells and early differentiating fibres; however, TGF signalling appears to be required for events in late stages of fibre cell maturation. Cataract is the leading cause of blindness and arises when lens cell architecture is disrupted and-or proteins aggregate abnormally. In humans, following ocular trauma, eye surgery, or in association with other diseases, cataracts can develop. These cataracts feature the development of subcapsular fibrotic plaques which obscure vision. We have shown that lenses cultured in the presence of TGF can mimic production of these plaques suggesting that these cataracts result from inappropriate activation of TGF . TGF is expressed in the lens and is abundant in the ocular media that bathes the lens. Thus, it appears that complex regulation of TGF bioavailability is required; epithelial cells and young fibre cells need to be protected from its cataractogenic effects, whereas older fibres require TGF signalling for maturation and-or survival. The expression pattern of Crim1 in the lens is consistent with it having a key role in inhibiting TGF in the lens. Thus, we hypothesise that Crim1 plays important roles in the lens, possibly via the modulation of members of the TGF superfamily and insulin-IGFs. We predict that Crim1 acts to maintain the lens epithelial phenotype and facilitate events in early fibre differentiation. If so, this may have implications for devising molecular strategies for preventing or slowing diseases, such as the various forms of human cataract.Read moreRead less
Genetic And Molecular Basis Of Congenital Cataracts
Funder
National Health and Medical Research Council
Funding Amount
$454,510.00
Summary
Cataracts are caused when the lens of the eye (which focuses light), loses transparency. They typically occur in older individuals, but can also occur in children, even as early as from birth. They usually result in severe vision impairment which can result in complete blindness. The only treatment is invasive surgery where the outcomes are poor, particulary in very young children. This research aims to discover the genes that cause cataract in children and to investigate how cataracts form. We ....Cataracts are caused when the lens of the eye (which focuses light), loses transparency. They typically occur in older individuals, but can also occur in children, even as early as from birth. They usually result in severe vision impairment which can result in complete blindness. The only treatment is invasive surgery where the outcomes are poor, particulary in very young children. This research aims to discover the genes that cause cataract in children and to investigate how cataracts form. We are working with several large Australian families that have severe childhood cataracts in order to identify the specific genes that cause their disease. This is achieved through an investigation of the entire genome of these families which allows us to precisely pinpoint any genetic changes. We can then look for these changes in the genes in other childhood cataract patients as well as in adults with cataracts. This information will increase our understanding of how the lens of the eye works and how cataracts can form. One gene that can cause cataracts has already been identified, this is the Nance-Horan Syndrome gene. We will investigate the role of this gene in the lens of the eye. This gene also causes other severe disabilities including mental retardation. The exact function of this gene is unknown but by determining how it works we will be able to better understand cataract formation and mental retardation, with the ultimate aim of developing better diagnosis and timely treatment for these disorders.Read moreRead less
The Roles Of Beta-catenin, APC And The Wnt/beta-catenin Pathway In Lens Development And Cataract
Funder
National Health and Medical Research Council
Funding Amount
$456,764.00
Summary
Cataract is a leading cause of blindness. Many risk factors have been identified but the basic cellular and molecular mechanisms that cause cataract are not well understood. Investigation of these mechanisms is essential to identify potential targets for future therapies to arrest or prevent cataract formation. The lens is composed of epithelial and fibre cells. Much of our research has focussed on identifying genes and cell signalling pathways that regulate formation of fibre cells from the epi ....Cataract is a leading cause of blindness. Many risk factors have been identified but the basic cellular and molecular mechanisms that cause cataract are not well understood. Investigation of these mechanisms is essential to identify potential targets for future therapies to arrest or prevent cataract formation. The lens is composed of epithelial and fibre cells. Much of our research has focussed on identifying genes and cell signalling pathways that regulate formation of fibre cells from the epithelial cells. However, considerably less is known about factors that regulate formation of the epithelium itself. As the epithelial cells are affected in some types of cataract it is vitally important to understand the mechanisms that control formation and maintenance of these cells. Our previous studies have identified a growth factor family (TGF-beta) that causes epithelial cataracts. Importantly, our recent studies have identified another growth factor signalling pathway (Wnt-beta-catenin) as being essential for the formation and maintenance of the lens epithelium. We hypothesise that this pathway is disrupted dring cataract formation. This project uses state of the art tools and techniques to investigate the role of two central molecular components of this Wnt pathway (APC and beta-catenin) in the developing lens. By genetically manipulating the activity of these proteins in the mouse lens we will investigate the roles these molecules and the Wnt signalling pathway play in lens development and whether inappropriate activity results in abnormal development or cataract. We will also be able to investigate whether modulating this pathway affects the formation of epithelial cataracts by TGFbeta. The results will provide detailed information on how these molecules regulate lens structure and function and have the potential to identify targets for preventing or ameliorating cataracts.Read moreRead less
Inductive Interactions Between Lens And Optic Cup Specify Cell Fates
Funder
National Health and Medical Research Council
Funding Amount
$265,500.00
Summary
Normal eye development depends on interactions between embryonic eye tissues. In the front part of the eye inductive interactions between lens and optic vesicle are important for the formation and growth of lens, ciliary body and iris. Our recent studies indicate that a family of developmentally important growth factors, the Wnts, plays key roles in this process. Our proposed studies will examine, for the first time, the role of Wnts in lens, ciliary body and iris development. Specific experimen ....Normal eye development depends on interactions between embryonic eye tissues. In the front part of the eye inductive interactions between lens and optic vesicle are important for the formation and growth of lens, ciliary body and iris. Our recent studies indicate that a family of developmentally important growth factors, the Wnts, plays key roles in this process. Our proposed studies will examine, for the first time, the role of Wnts in lens, ciliary body and iris development. Specific experimental outcomes will show if Wnts are important in promoting the formation and maintenance of the front part of the lens, the lens epithelium. The outcomes will also give us information on the molecules that mediate the effects of Wnts on lens cells and if regulatory factors from the lip of the optic cup-ciliary body can influence the pathways by which Wnts can influence the lens cells. In addition we will learn if lens-derived Wnts have a role in the formation of ciliary body and iris. Identifying factors that regulate the formation of eye tissues is fundamental to understanding the molecular basis of eye disease. For example, cataract is the most common cause of blindness in the world. Cataract surgery is the most common surgical procedure and is placing an ever-increasing burden on health care budgets. Cataracts that most commonly require surgery usually involve abnormal growth and behaviour of lens cells such as occurs in posterior subcapsular cataract and posterior capsular opacification (also known as aftercataract because it occurs subsequently to cataract surgery). Identifying molecules and mechanisms that are involved in normal formation and growth of lens cells is fundamental to understanding these diseases. In addition, as it is well known that the lens is required for the normal formation of the front part of the eye, including the ciliary body and iris, results from this study may also shed light on some developmental abnormalities such as small eye.Read moreRead less
Role Of Primary Cilia And PCP Proteins In Lens Development: Implications For Lens Regeneration After Cataract Surgery
Funder
National Health and Medical Research Council
Funding Amount
$413,742.00
Summary
Cataract extraction is the most common surgical procedure conducted in our hospitals today. Unfortunately, a complication of surgery is the development of a secondary cataract. This is caused by residual lens epithelial cells undergoing a wound healing response that leads to severe scarring and loss of vision. This project will identify the factors that are needed to maintain lens epithelial cells in a normal state so that they can act as stem cells that can be induced to regenerate a new lens t ....Cataract extraction is the most common surgical procedure conducted in our hospitals today. Unfortunately, a complication of surgery is the development of a secondary cataract. This is caused by residual lens epithelial cells undergoing a wound healing response that leads to severe scarring and loss of vision. This project will identify the factors that are needed to maintain lens epithelial cells in a normal state so that they can act as stem cells that can be induced to regenerate a new lens that can transmit and focus light as normal.Read moreRead less
Regulation Of Lens Cell Behaviour By RTK Antagonists, Sef And Sprouty.
Funder
National Health and Medical Research Council
Funding Amount
$319,446.00
Summary
Cataract, the loss of transparency of the eye lens, is a major cause of world blindness. A cure for cataract depends on a better understanding of the molecular processes in the normal and cataractous lens. Lens growth is regulated by controlled proliferation of epithelial cells and their localised differentiation into fibres. As disruption to this tight regulation leads to cataract, identifying the molecules that control cell proliferation and differentiation will provide insights into the mecha ....Cataract, the loss of transparency of the eye lens, is a major cause of world blindness. A cure for cataract depends on a better understanding of the molecular processes in the normal and cataractous lens. Lens growth is regulated by controlled proliferation of epithelial cells and their localised differentiation into fibres. As disruption to this tight regulation leads to cataract, identifying the molecules that control cell proliferation and differentiation will provide insights into the mechanisms involved in cataract formation. Following cataract surgery, for example, many patients develop aftercataract which results from residual lens cells. These residual cells, unlike those tightly regulated in the normal lens, divide and differentiate to form a secondary cataract. The main aim of this study is to understand what molecules regulate the proliferation and differentiation of lens cells. Growth factors are key regulators of cell behaviour and our studies provide evidence that FGF growth factors play pivotal roles in the lens by influencing cell proliferation and differentiation. We have recently identified inhibitors of FGF in the lens, called Sprouty and Sef; molecules shown in other systems to effectively block FGF intracellular signalling pathways. To understand how Sef and Sprouty regulate lens cell proliferation and fibre differentiation, we plan to examine what regulates their expression, and more importantly their role in FGF-induced cell signalling in normal lens biology. To do this, we will use a well established explant culture system to monitor the effectiveness of these endogenous inhibitors on growth factor-induced lens cell proliferation and differentiation, as well as use transgenic mice technology to determine the role they play in situ. By understanding the molecular and cellular processes essential for normal lens development, we can better understand how disruptions of these processes lead to cataract formation.Read moreRead less