Project description:Juvenile primates develop myopia when their visual experience is degraded by lid fusion. In response to the abnormal visual input, retinal neural networks cause an excessive growth of the postequatorial segment of the eye, but the mechanism underlying this axial elongation is unknown. By combining analysis of gene expression, injection of the thymidine analog 5-bromo-2'-deoxyuridine and immunocytochemistry, we show that the retinal periphery in both juvenile rhesus macaques and green monkeys harbors a population of mitotically active neuroprogenitor cells that proliferate when the visual experience is altered by lid fusion. Furthermore, the number of dividing cells is highly correlated with the axial elongation of the eye and the resulting myopic refractive error. Thus, the retina undergoes active growth during the postnatal development of the primate eye. This growth is modulated by the visual input and accelerates considerably when the eye develops axial myopia. cDNA subtractions, construction of cDNA libraries and differential screening were performed as previously described (Tkatchenko et al, 2000). Two subtractions were carried out resulting in two cDNA libraries. One library was enriched in clones potentially up-regulated in the retina of the closed eye and the other was enriched in cDNAs potentially down-regulated. One thousand clones from each library were analyzed, and 535 differentially-expressed cDNAs were amplified by PCR and spotted onto glass slides coated with poly-L-lysine (five duplicates for each cDNA). The slides were then processed, hybridized with Cy3- and Cy5-labeled complex cDNA probes and washed in 0.2xSSC as described at http://cmgm.stanford.edu/pbrown/protocols/. Two hybridizations with color swap were carried for each monkey. After hybridization, slides were scanned using a GenePix 4000B microarray scanner (Axon Instruments, Union City, CA). The images were acquired and processed using the GenePix Pro 5.1 software package (Axon Instruments). The data obtained were normalized against GAPDH expression level and mean values (the reported values) and P-values (probability associated with a Student's t-test) were calculated for duplicate experiments (n = 10) with color swap using Microsoft Excel. Genes were defined as differentially regulated if P< 0.05. Cluster analysis was performed using the Genesis software package (provided by Alexander Sturn, Graz University of Technology, Austria).

Project description:In chicks, the avian homologue of the early growth response protein-1 (ZENK) has been shown to be increased in a special cell type of the retina, the glucagonergic amacrine cells, under conditions that lead to a reduction in eye growth (myopic defocus, recovery of myopia) and decreased under conditions that enhance ocular growth (hyperopic defocus, form-deprivation). The investigation of Egr-1 knock-out mice showed that homozygous knock-out mice with no functional Egr-1 protein developed relative axial myopia at the age of 42 and 56 days, compared to heterozygous- and wildtype Egr-1 knock-out mice. To clarify the role of Egr-1 in the retinal regulation of eye growth, and to get an idea about the biochemical pathways underlying this mechanism, we studied the role of Egr-1 in more detail using Affymetrix microarrays. Experiment Overall Design: Retinal samples of young homozygous Egr-1 knock-out and wildtype mice at the age of 30 days (hm30 and wt30; no difference in axial eye length yet) and 42 days (hm42 and wt42; already a difference in axial eye length of 59 µm) were taken to compare the mRNA expression changes over time between these two genotypes and within the same genotype between the two age groups.

Project description:To identify to identify target tissues and molecules involved with refractive myopic shift and axial length elongation in a murine lens-induced myopia model, we performed comprehensive analysis by microRNA array. Negative 30diptor (-30D) lens was fixed on right eye (-30D) of C57BL/6J mice (3weeks old, N=3) for 3 weeks, the refraction and the axial length were measured using a refractometer and a SD-OCT system in all eyes. Eye balls were enucleated and separated to cornea, iris, lens, retina, choroid and sclera. Total RNA was extracted from individual ocular components. MicroRNA expression analysis was carried out using Agilent Mouse miRNA Microarray (8×60K) miRBase21.0 (Agilent). Expression ratio calculation and miRNA varying expression were extracted by GeneSpring GX 14.5 (Agilent). After 3weeks of lens fixing, a refractive change and an axial length elongation change were observed (Normal vs -30D: 0.95 ± 1.85D vs -18.42 ± 3.98D, 0.155 mm ± 0.015mm vs 0.273 ± 0.009 mm), respectively. MiRNA expression changes that induced only by -30D lens fixing was confirmed in each part of the eyeball. By expression ratio calculation and miRNA varying expression analysis, upregulated miRNA (56 in cornea, 13 in iris, 6 in lens, 0 in retina, 29 in choroid and 30 in sclera) and downregulated miRNA (7 in cornea, 28 in iris, 17 in lens, 9 in retina, 7 in choroid and 40 in sclera) were observed. Overlapping miRNAs were also found while each eye tissues. In this study, miRNA varying expression were observed in each ocular part of the murine lens-induced myopia model. These miRNAs dysregulation may be functionally involved with the refractive myopia shift and the axial length elongation.

Project description:Development of myopia is associated with large-scale changes in ocular tissue gene expression. Although differential expression of coding genes underlying development of myopia has been a subject of intense investigation, the role of non-coding genes such as microRNAs in the development of myopia is largely unknown. In this study, we explored myopia-associated miRNA expression profiles in the retina and sclera of C57Bl/6J mice with experimentally induced myopia using microarray technology. We found a total of 53 differentially expressed miRNAs in the retina and no differences in miRNA expression in the sclera of C57BL/6J mice after 10 days of visual form deprivation, which induced -6.93 ± 2.44 D (p < 0.000001, n = 12) of myopia. We also identified their putative mRNA targets among mRNAs found to be differentially expressed in myopic retina and potential signaling pathways involved in the development of form-deprivation myopia using miRNA-mRNA interaction network analysis. Analysis of myopia-associated signaling pathways revealed that myopic response to visual form deprivation in the retina is regulated by a small number of highly integrated signaling pathways. Our findings highlight substantial involvement of miRNAs in the regulation of refractive eye development, and in the development of myopia through the retinal gene regulation.

Project description:In chicks, the avian homologue of the early growth response protein-1 (ZENK) has been shown to be increased in a special cell type of the retina, the glucagonergic amacrine cells, under conditions that lead to a reduction in eye growth (myopic defocus, recovery of myopia) and decreased under conditions that enhance ocular growth (hyperopic defocus, form-deprivation). The investigation of Egr-1 knock-out mice showed that homozygous knock-out mice with no functional Egr-1 protein developed relative axial myopia at the age of 42 and 56 days, compared to heterozygous- and wildtype Egr-1 knock-out mice. To clarify the role of Egr-1 in the retinal regulation of eye growth, and to get an idea about the biochemical pathways underlying this mechanism, we studied the role of Egr-1 in more detail using Affymetrix microarrays.

Project description:We investigated diurnal changes in gene expression in the retina and choroid at the onset of experimental myopia. We induced visual form deprivation myopia in young chicks, and isolated retinal and choroidal tissues separately in form- deprived and contralateral control eyes every 4 hours over a single 24-hour period.

Project description:Myopia has become the major cause of visual impairment worldwide. However, its retina-related pathogenesis remains unclear. In recent years, proteomics has become a high-throughput tool to explain biological mechanisms. In this study, we examined the retinas of guinea pigs with form deprivation myopia using 4D label-free proteomics and found disorders of retinal metabolism in experimental myopia.

Project description:Following laboratory and clinical findings implicating circadian biology in the pathogenesis of myopia (nearsightedness), we examined gene expression in two crucial tissues controlling post-natal refractive development, the retina and choroid. Inducing unilateral visual form deprivation myopia in young chicks, a widely studied and validated model, we isolated retinal and choroidal tissues every 4 hours over a single day from myopic and contralateral control eyes during a period time when myopia progresses rapidly.

Project description:Myopia has become the major cause of visual impairment worldwide. Although the pathogenesis of myopia remains controversial, proteomics studies suggest that dysregulation of retinal metabolism is potentially involved in the pathology of myopia. Lysine lactylation of proteins plays a key role in regulating cellular metabolism, but little is known about its role in the form-deprived myopic retina. In this study, we performed lactylation proteomic analysis of the retinas of form-deprived myopic guinea pigs and found downregulated levels of lactylation of metabolism-critical enzymes in the retina. As the first report on retinal lactylation in myopic eyes, this study provides a reliable basis for further studies on retinal lactylation in myopic eyes.

Project description:Myopia has become the major cause of visual impairment worldwide. Although the pathogenesis of myopia remains controversial, proteomics studies suggest that dysregulation of retinal metabolism is potentially involved in the pathology of myopia. Lysine acetylation of proteins plays a key role in regulating cellular metabolism, but little is known about its role in the form-deprived myopic retina. In this study, we performed acetylation proteomic analysis of the retinas of form-deprived myopic guinea pigs and found downregulated levels of acetylation of metabolism-critical enzymes in the retina. As the first report on retinal acetylation in myopic eyes, this study provides a reliable basis for further studies on retinal acetylation in myopic eyes