heparitin-sulfate and Eye-Abnormalities

heparitin-sulfate has been researched along with Eye-Abnormalities* in 2 studies

Other Studies

2 other study(ies) available for heparitin-sulfate and Eye-Abnormalities

Article	Year
Heparan sulfate regulates intraretinal axon pathfinding by retinal ganglion cells. Investigative ophthalmology & visual science, 2011, Aug-22, Volume: 52, Issue:9 PURPOSE. Heparan sulfate (HS) is abundantly expressed in the developing neural retina; however, its role in the intraretinal axon guidance of retinal ganglion cells (RGCs) remains unclear. In this study, the authors examined whether HS was essential for the axon guidance of RGCs toward the optic nerve head. METHODS. The authors conditionally ablated the gene encoding the exostosin-1 (Ext1) enzyme, using the dickkopf homolog 3 (Dkk3)-Cre transgene, which disrupted HS expression in the mouse retina during directed pathfinding by RGC axons toward the optic nerve head. In situ hybridization, immunohistochemistry, DiI tracing, binding assay, and retinal explant assays were performed to evaluate the phenotypes of the mutants and the roles of HS in intraretinal axon guidance. RESULTS. Despite no gross abnormality in RGC distribution, the mutant RGC axons exhibited severe intraretinal guidance errors, including optic nerve hypoplasia, ectopic axon penetration through the full thickness of the neural retina and into the subretinal space, and disturbance of the centrifugal projection of RGC axons toward the optic nerve head. These abnormal phenotypes shared similarities with the RGC axon misguidance caused by mutations of genes encoding Netrin-1 and Slit-1/2. Explant assays revealed that the mutant RGCs exhibited disturbed Netrin-1-dependent axon outgrowth and Slit-2-dependent repulsion. CONCLUSIONS. The present study demonstrated that RGC axon projection toward the optic nerve head requires the expression of HS in the neural retina, suggesting that HS in the retina functions as an essential modulator of Netrin-1 and Slit-mediated intraretinal RGC axon guidance. Topics: Animals; Axons; Enzyme-Linked Immunosorbent Assay; Eye Abnormalities; Female; Fluorescent Antibody Technique, Indirect; Heparitin Sulfate; Immunoenzyme Techniques; In Situ Hybridization; Intercellular Signaling Peptides and Proteins; Male; Mice; Mice, Inbred C57BL; Mice, Mutant Strains; Mice, Transgenic; N-Acetylglucosaminyltransferases; Nerve Growth Factors; Nerve Tissue Proteins; Netrin-1; Neural Conduction; Neuronal Plasticity; Optic Disk; Phenotype; Polymerase Chain Reaction; Retina; Retinal Ganglion Cells; Tumor Suppressor Proteins; Visual Pathways	2011
Heparan sulfate deficiency in periocular mesenchyme causes microphthalmia and ciliary body dysgenesis. Experimental eye research, 2010, Volume: 90, Issue:1 The heparan sulfate (HS) is a component of proteoglycans in the extracellular matrix and on cell surfaces, modulating developmental processes. The aim of this study is to investigate whether the defect of HS in the periocular mesenchyme impairs ocular morphogenesis. First, using Protein 0-Cre transgenic mice, we ablated Ext1, which encodes an indispensable enzyme for HS synthesis, in the developing periocular mesenchyme. The expression of Ext1 messenger RNA (mRNA) and HS were observed by RT-PCR and immunohistochemistry, respectively. The phenotypes in the mutant were evaluated by light microscopy and immunohistochemistry for cellular makers. Second, the distribution of the mutant periocular mesenchymal cells was tracked using a Rosa26 Cre-reporter gene. No mutant embryos (Protein 0-Cre;Ext1(flox/flox)) were identified after embryonic day 14.5 (E14.5). RT-PCR showed that an intense band amplified from Ext1 was observed in cDNAs from the control periocular mesenchymal cells at E13.5; however, the band for Ext1 was hardly detectable in cDNA from the mutant embryo, indicating that the mRNA was missing in the mutant periocular mesenchyme at E13.5. The HS expression was disrupted in the periocular mesenchyme of the mutant ocular tissues. The HS deficiency resulted in microphthalmia with reduced axial lengths, lens diameters, and vitreous sizes compared with the littermate eyes. The mutant embryos showed agenesis of the anterior chamber, where cells expressing Cre recombinase were distributed. Moreover, the mutants showed phenotypic alterations in the neural ectoderm including dysgenesis of the presumptive ciliary body and agenesis of the optic nerve head. These findings demonstrate that HS in the periocular mesenchyme plays a critical role in normal ocular morphogenesis, indicating reciprocal interactions between the periocular mesenchyme and the neural ectoderm. Topics: Animals; Carbohydrate Epimerases; Ciliary Body; Eye Abnormalities; Female; Genotype; Heparitin Sulfate; Immunoenzyme Techniques; Male; Mesoderm; Mice; Mice, Transgenic; Microphthalmos; Morphogenesis; N-Acetylglucosaminyltransferases; Reverse Transcriptase Polymerase Chain Reaction; RNA, Messenger; Smad Proteins; Sulfotransferases	2010

Article

Year

Heparan sulfate regulates intraretinal axon pathfinding by retinal ganglion cells.

Investigative ophthalmology & visual science, 2011, Aug-22, Volume: 52, Issue:9

PURPOSE. Heparan sulfate (HS) is abundantly expressed in the developing neural retina; however, its role in the intraretinal axon guidance of retinal ganglion cells (RGCs) remains unclear. In this study, the authors examined whether HS was essential for the axon guidance of RGCs toward the optic nerve head. METHODS. The authors conditionally ablated the gene encoding the exostosin-1 (Ext1) enzyme, using the dickkopf homolog 3 (Dkk3)-Cre transgene, which disrupted HS expression in the mouse retina during directed pathfinding by RGC axons toward the optic nerve head. In situ hybridization, immunohistochemistry, DiI tracing, binding assay, and retinal explant assays were performed to evaluate the phenotypes of the mutants and the roles of HS in intraretinal axon guidance. RESULTS. Despite no gross abnormality in RGC distribution, the mutant RGC axons exhibited severe intraretinal guidance errors, including optic nerve hypoplasia, ectopic axon penetration through the full thickness of the neural retina and into the subretinal space, and disturbance of the centrifugal projection of RGC axons toward the optic nerve head. These abnormal phenotypes shared similarities with the RGC axon misguidance caused by mutations of genes encoding Netrin-1 and Slit-1/2. Explant assays revealed that the mutant RGCs exhibited disturbed Netrin-1-dependent axon outgrowth and Slit-2-dependent repulsion. CONCLUSIONS. The present study demonstrated that RGC axon projection toward the optic nerve head requires the expression of HS in the neural retina, suggesting that HS in the retina functions as an essential modulator of Netrin-1 and Slit-mediated intraretinal RGC axon guidance.

Topics: Animals; Axons; Enzyme-Linked Immunosorbent Assay; Eye Abnormalities; Female; Fluorescent Antibody Technique, Indirect; Heparitin Sulfate; Immunoenzyme Techniques; In Situ Hybridization; Intercellular Signaling Peptides and Proteins; Male; Mice; Mice, Inbred C57BL; Mice, Mutant Strains; Mice, Transgenic; N-Acetylglucosaminyltransferases; Nerve Growth Factors; Nerve Tissue Proteins; Netrin-1; Neural Conduction; Neuronal Plasticity; Optic Disk; Phenotype; Polymerase Chain Reaction; Retina; Retinal Ganglion Cells; Tumor Suppressor Proteins; Visual Pathways

2011

Heparan sulfate deficiency in periocular mesenchyme causes microphthalmia and ciliary body dysgenesis.

Experimental eye research, 2010, Volume: 90, Issue:1

The heparan sulfate (HS) is a component of proteoglycans in the extracellular matrix and on cell surfaces, modulating developmental processes. The aim of this study is to investigate whether the defect of HS in the periocular mesenchyme impairs ocular morphogenesis. First, using Protein 0-Cre transgenic mice, we ablated Ext1, which encodes an indispensable enzyme for HS synthesis, in the developing periocular mesenchyme. The expression of Ext1 messenger RNA (mRNA) and HS were observed by RT-PCR and immunohistochemistry, respectively. The phenotypes in the mutant were evaluated by light microscopy and immunohistochemistry for cellular makers. Second, the distribution of the mutant periocular mesenchymal cells was tracked using a Rosa26 Cre-reporter gene. No mutant embryos (Protein 0-Cre;Ext1(flox/flox)) were identified after embryonic day 14.5 (E14.5). RT-PCR showed that an intense band amplified from Ext1 was observed in cDNAs from the control periocular mesenchymal cells at E13.5; however, the band for Ext1 was hardly detectable in cDNA from the mutant embryo, indicating that the mRNA was missing in the mutant periocular mesenchyme at E13.5. The HS expression was disrupted in the periocular mesenchyme of the mutant ocular tissues. The HS deficiency resulted in microphthalmia with reduced axial lengths, lens diameters, and vitreous sizes compared with the littermate eyes. The mutant embryos showed agenesis of the anterior chamber, where cells expressing Cre recombinase were distributed. Moreover, the mutants showed phenotypic alterations in the neural ectoderm including dysgenesis of the presumptive ciliary body and agenesis of the optic nerve head. These findings demonstrate that HS in the periocular mesenchyme plays a critical role in normal ocular morphogenesis, indicating reciprocal interactions between the periocular mesenchyme and the neural ectoderm.

Topics: Animals; Carbohydrate Epimerases; Ciliary Body; Eye Abnormalities; Female; Genotype; Heparitin Sulfate; Immunoenzyme Techniques; Male; Mesoderm; Mice; Mice, Transgenic; Microphthalmos; Morphogenesis; N-Acetylglucosaminyltransferases; Reverse Transcriptase Polymerase Chain Reaction; RNA, Messenger; Smad Proteins; Sulfotransferases

2010