Temporal Changes in Gene Expression after Injury in the Rat Retina

doi:10.1167/iovs.03-1047

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Temporal Changes in Gene Expression after Injury in the Rat Retina

Félix Vázquez-Chona, Bong K. Song, and Eldon E. Geisert, Jr

From the Department of Ophthalmology, University of Tennessee Health Science Center, Memphis, Tennessee.

PURPOSE. The goal of this study was to define the temporal changesin gene expression after retinal injury and to relate thesechanges to the inflammatory and reactive response. A specificemphasis was placed on the tetraspanin family of proteins andtheir relationship with markers of reactive gliosis.

METHODS. Retinal tears were induced in adult rats by scrapingthe retina with a needle. After different survival times (4hours, and 1, 3, 7, and 30 days), the retinas were removed,and mRNA was isolated, prepared, and hybridized to the AffymatrixRG-U34A microarray (Santa Clara, CA). Microarray results wereconfirmed by using RT-PCR and correlation to protein levelswas determined.

RESULTS. Of the 8750 genes analyzed, approximately 393 (4.5%)were differentially expressed. Clustering analysis revealedthree major profiles: (1) The early response was characterizedby the upregulation of transcription factors; (2) the delayedresponse included a high percentage of genes related to cellcycle and cell death; and (3) the late, sustained profile clustereda significant number of genes involved in retinal gliosis. Thelate, sustained cluster also contained the upregulated crystallingenes. The tetraspanins Cd9, Cd81, and Cd82 were also associatedwith the late, sustained response.

CONCLUSIONS. The use of microarray technology enables definitionof complex genetic changes underlying distinct phases of thecellular response to retinal injury. The early response clustersgenes associate with the transcriptional regulation of the wound-healingprocess and cell death. Most of the genes in the late, sustainedresponse appear to be associated with reactive gliosis.

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