Assessing the role of the transcription factor FOXC1 in the expression and regulation of the Adherens junction protein N-Cadherin during corneal endothelium development.

Govender, Viveshree Shalom.

03 October 2013

The proper organization and differentiation of the anterior segment is pivotal for normal eye development. Neural crest-derived POM cells are key contributors to correct anterior segment formation, differentiating to form the monolayered corneal endothelium. Mice with homozygous null mutations in the forkhead transcription factor gene, Foxc1, fail to develop a proper corneal endothelium stabilized by adherens junctions, with the endothelium adhering to the lens, preventing anterior chamber separation. The aim of this study was to evaluate the interaction between Foxc1 and the adherens junction protein, N-cadherin, as well as an associated gene, Msx1, during key stages in corneal endothelium development. Foxc1 was over-expressed in E12.5 and E13.5 POM cells and qPCR was carried out to determine the effect of Foxc1 on N-cadherin and Msx1 gene expression. Data showed over-expression of Foxc1 in wildtype E12.5 and E13.5 POM cells to cause significant fluctuations in N-cadherin and Msx1 expression (p < 0.05). POM cells were then transfected with a Foxc1 knock-down plasmid or the Foxc1 overexpression plasmid to evaluate the effect of Foxc1 on N-cadherin protein expression by Western blot analysis, however, these results were inconsistent with the gene expression analyses with no significant differences in N-cadherin expression detected. N-cadherin protein expression and localization was then further assessed by means of immunocytochemistry (ICC) and confocal microscopy in monolayer and hanging-drop POM cell cultures. Both qPCR and confocal microscopy data showed consistency, indicating increased amounts of N-cadherin in E12.5 cells relative to E13.5 cells, with membrane-bound N-cadherin showing a clear lattice-work pattern in hanging drop culture. Foxc1 over-expression/knock-down studies on E12.5 and E13.5 POM cells together suggest that N-cadherin is transcriptionally regulated by Foxc1 and that Foxc1 has a threshold level at which it is able to exert control over N-cadherin in POM cells. Foxc1 expression is therefore essential in establishing N-cadherin adhesion junctions in the corneal endothelium. Preliminary data also suggests that Msx1 may directly interact with Foxc1 in POM cells, however, further studies must be undertaken to verify and establish the effects of Foxc1/N-cadherin/ Msx1 interaction in the development of a cohesive, integrated corneal endothelium and functional anterior segment. / Thesis (M.Sc.)-University of KwaZulu-Natal, Westville, 2011.

Cornea.

Anterior segment (Eye)

Keratitis.

Theses--Microbiology.

The role of lens-derived signals in the development of the corneal endothelium.

Silla, Zenzele.

31 October 2013

Corneal endothelial development is an intricate process driven by finely tuned gene expression. Its formation is necessary for the continued normal development of the anterior segment of the eye. The presence of an inductive lens able to secrete factors such as TGFβ2 as well as the expression of Foxc1 and Pitx2 is essential to corneal endothelial development, as in the absence of any of these; the corneal endothelium fails to form. Corneal endothelial development begins as peri-ocular mesenchyme (POM) cells migrate into the space between the lens and surface ectoderm at E11.5. From E12.5, these cells begin to transition from a mesenchymal to an epithelial/endothelial (MET) phenotype, differentiating into a monolayered endothelium by E15 characterised by inter-cellular junctions. To study the initial process of development, immortalised POM cell lines from E12.5 and E13.5 embryos were used. Expression of the key genes, the transcription factors, Foxc1 and Pitx2 and two genes involved in EMT/MET, Slug and Tsc22, were analysed at these stages to establish the developmental norm. The effect of the lens on these expression levels was then determined. To establish whether TGFβ2 is the lens secreted signal responsible for gene expression changes, cells were subjected to TGFβ2 treatment. In all these experiments, the role of Foxc1 in regulating gene expression was determined by Foxc1 overexpression and knockdown. The effect of the lens on cellular proliferation and on the expression and cellular arrangement of N-cadherin, a junction protein was also determined. The results showed that, at E12.5, the lens downregulates Foxc1 and Pitx2 expression, is a potent inducer of Tsc22 expression and is required for maintaining Slug levels. TGFβ2 was shown to play a role in Foxc1 and Pitx2 downregulation. Analysis suggests that Tsc22 expression is responsive to lens signals, but that TGFβ2 is not the signal responsible for its downregulation between E12.5 and E13.5. The lens has no effect on Slug expression in the presence of Foxc1, but when Foxc1 is silenced, Slug is induced. Thus, Foxc1 plays a crucial regulatory role in Slug expression. At E13.5, as differentiation is initiated, Foxc1 expression remains responsive to the lens and to TGFβ2. Pitx2 expression is still induced by the lens but, at this stage, TGFβ2 does not play a part in Pitx2 regulation suggesting involvement of other unknown lens secreted signals. Other lens secreted signal/s were also shown to downregulate Tsc22 and Slug at this stage. The lens was implicated in MET as it was shown to have an effect on N-cadherin localisation in 3-dimensional culture. E12.5 Spheroids exposed to E6 lenses formed a distinct lattice arrangement of N-cadherin compared to the uniform distribution in control cells. Although the 13.5 control cell aggregates also showed a lattice framework, it was more pronounced in the lens treated cells. The transcriptional role of Foxc1 was determined by overexpression and knockdown experiments where Foxc1 overexpression and knockdown upregulated Tsc22 and downregulated Pitx2 and Slug at E12.5. At E13.5, Pitx2 was downregulated and Slug was upregulated in response to aberrant expression of Foxc1. This was illustrative of the sensitivity these genes have to Foxc1 expression during development. It is known that the presence of a functioning lens and Foxc1 are essential for proper development of the corneal endothelium, which in turn is necessary for normal eye development. The understanding of the precise molecular mechanisms required for corneal endothelial development and the processes requisite for cell proliferation and differentiation has important consequences for providing further insight into the pathophysiology of anterior segment dysgenesis and glaucoma. Previous studies suggest that stem-cell like qualities are conferred in cells undergoing EMT. Such an investigation may lead to application in regenerative medicine such as the bioengineering of corneal tissue. / Thesis (M.Sc.)-University of KwaZulu-Natal, Westville, 2013.

Cornea.

Anterior segment (Eye)

Theses--Microbiology.

Quantitative analysis of the linear optical character of the anterior segment of the eye

Mathebula, Solani David

04 February 2014

D.Phil. (Optometry) / An important issue in the quantitative analysis of optical systems is, for example, the question of how to calculate an average of a set of eyes. An average that also has an optical character as a whole and is representative or central to the optical characters of the eyes within that set of eyes. In the case of refraction, an average power is readily calculated as the arithmetic average of several dioptric power matrices. The question then is: How does one determine an average that represents the average optical character of a set of eyes, completely to first order? The exponential-mean-log transference has been proposed by Harris as the most promising solution to the question of the average eye. For such an average to be useful, it is necessary that the exponential-mean-log-transference satisfies conditions of existence, uniqueness and symplecticity, The first-order optical nature of a centred optical system (or eye) is completely characterized by the 4x4 ray transference. The augmented ray transference can be represented as a 5x5 matrix and is usually partitioned into 2x2 and 2x 1 submatrices. They are the dilation A, disjugacy B, divergence C, divarication D, transverse translation e and deflection 1t. These are the six fundamental first-orders optical properties of the system. Other optical properties, called derived properties, of the system can be obtained from them. Excluding decentred or tilted elements, everything that can happen to a ray is described by a 4x4 system matrix. The transference, then, defines the four A, B, C and D fundamental optical properties of the system…

Anterior segment (Eye)

Vision - Testing

A study of the monocyte-derived cell populations of the uveal tract and retina in homeostatic conditions and during the early stages of ocular autoimmune disease

Kezic, Jelena Marie

January 2008

The eye contains closely related but widely different tissues, offering a unique opportunity to investigate the phenotype and function of monocyte-derived cell populations within functionally unique microenvironments in a single complex organ. The uveal tract and retina contain rich networks of immune cells that reside and traffic through the eye, these cells having been implicated in various ocular inflammatory processes and immune-mediated diseases. One such inflammatory condition is human posterior uveitis, an autoimmune disease mainly affecting the retina. As current treatments for posterior uveitis only serve to slow down disease progression, studies using animal models, namely, experimental autoimmune uveoretinitis (EAU), have focused on determining the key cellular and molecular mediators involved in disease initiation in order to expand the potential for novel therapeutic applications. The overall purpose of experiments in this thesis was to explore monocyte-derived cell populations of the uveal tract and retina, this being achieved by utilising a novel transgenic mouse model. Cx3cr1gfp/gfp transgenic mice on both BALB/c and C57Bl/6 backgrounds contain an enhanced green fluorescent protein (eGFP) encoding cassette knocked into the Cx3cr1 gene, disrupting its expression but facilitating GFP expression under the control of the Cx3cr1 promoter. Heterozygous (Cx3cr1+/gfp) mice were generated by crossing Cx3cr1gfp/gfp mice to wild-type (WT) mice. This transgenic model allowed for the exquisite visualisation of Cx3cr1-bearing monocyte-derived dendritic cells (DC) and macrophages in ocular tissues, whilst also enabling the investigation of a potential role for Cx3cr1 in recruiting monocyte-derived cells to the eye in steady-state and inflammatory conditions.

Uveitis -- Animal models

Retina -- Diseases -- Animal models

Transgenic mice

Autoimmunity

Macrophages

Uveal tract

Retina

Microglia