Gene transcription profile of the detached retina (An AOS Thesis).

Transactions of the American Ophthalmological Society Pub Date : 2009-12-01

David N Zacks

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Abstract

Purpose: Separation of the neurosensory retina from the retinal pigment epithelium (RPE) yields many morphologic and functional consequences, including death of the photoreceptor cells, Müller cell hypertrophy, and inner retinal rewiring. Many of these changes are due to the separation-induced activation of specific genes. In this work, we define the gene transcription profile within the retina as a function of time after detachment. We also define the early activation of kinases that might be responsible for the detachment-induced changes in gene transcription.

Methods: Separation of the retina from the RPE was induced in Brown-Norway rats by the injection of 1% hyaluronic acid into the subretinal space. Retinas were harvested at 1, 7, and 28 days after separation. Gene transcription profiles for each time point were determined using the Affymetrix Rat 230A gene microarray chip. Transcription levels in detached retinas were compared to those of nondetached retinas with the BRB-ArrayTools Version 3.6.0 using a random variance analysis of variance (ANOVA) model. Confirmation of the significant transcriptional changes for a subset of the genes was performed using microfluidic quantitative real-time polymerase chain reaction (qRT-PCR) assays. Kinase activation was explored using Western blot analysis to look for early phosphorylation of any of the 3 main families of mitogen-activated protein kinases (MAPK): the p38 family, the Janus kinase family, and the p42/p44 family.

Results: Retinas separated from the RPE showed extensive alterations in their gene transcription profile. Many of these changes were initiated as early as 1 day after separation, with significant increases by 7 days. ANOVA analysis defined 144 genes that had significantly altered transcription levels as a function of time after separation when setting a false discovery rate at < or =0.1. Confirmatory RT-PCR was performed on 51 of these 144 genes. Differential transcription detected on the microarray chip was confirmed by qRT-PCR for all 51 genes. Western blot analysis showed that the p42/p44 family of MAPK was phosphorylated within 2 hours of retinal-RPE separation. This phosphorylation was detachment-induced and could be inhibited by specific inhibitors of MAPK phosphorylation.

Conclusions: Separation of the retina from the RPE induces significant alteration in the gene transcription profile within the retina. These profiles are not static, but change as a function of time after detachment. These gene transcription changes are preceded by the activation of the p42/p44 family of MAPK. This altered transcription may serve as the basis for many of the morphologic, biochemical, and functional changes seen within the detached retina.

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离体视网膜的基因转录谱(AOS论文)。

目的:神经感觉视网膜与视网膜色素上皮(RPE)的分离会产生许多形态学和功能上的后果，包括感光细胞死亡、米勒细胞肥大和视网膜内部重新连接。许多这些变化是由于分离诱导的特定基因的激活。在这项工作中，我们将视网膜内的基因转录谱定义为脱离后时间的函数。我们还定义了可能导致分离诱导的基因转录变化的激酶的早期激活。方法:在褐-挪威大鼠视网膜下间隙注射1%透明质酸，诱导视网膜脱离RPE。分别于分离后1、7、28天摘取视网膜。使用Affymetrix大鼠230A基因微阵列芯片测定每个时间点的基因转录谱。采用随机方差分析(ANOVA)模型，利用BRB-ArrayTools Version 3.6.0对离体视网膜与非离体视网膜的转录水平进行比较。使用微流控实时定量聚合酶链反应(qRT-PCR)检测证实了基因子集的显著转录变化。激酶活化使用Western blot分析，寻找三个主要的丝裂原活化蛋白激酶家族(MAPK)的早期磷酸化:p38家族，Janus激酶家族和p42/p44家族。结果:从RPE分离的视网膜显示其基因转录谱的广泛改变。许多这些变化早在分离后1天就开始了，7天后显著增加。ANOVA分析定义了144个基因，当将错误发现率设置为<或=0.1时，它们的转录水平随分离后时间的变化而显著改变。对这144个基因中的51个进行了验证性RT-PCR。在芯片上检测到的51个基因的差异转录均通过qRT-PCR得到证实。Western blot分析显示，MAPK的p42/p44家族在视网膜- rpe分离后2小时内被磷酸化。这种磷酸化是分离诱导的，可以被特异性的MAPK磷酸化抑制剂抑制。结论:视网膜与RPE分离可引起视网膜内基因转录谱的显著改变。这些轮廓不是静态的，而是随着时间的变化而变化的。在这些基因转录变化之前，MAPK的p42/p44家族被激活。这种转录的改变可能是许多形态、生化和功能变化的基础，这些变化在离体视网膜内可见。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Transactions of the American Ophthalmological Society

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