RNA Sequencing of Lens Capsular Epithelium Implicates Novel Pathways in Pseudoexfoliation Syndrome

Overview

Journal Invest Ophthalmol Vis Sci

Specialty Ophthalmology

Date 2022 Mar 29

PMID 35348588

Authors

Sean Mullany

Henry Marshall

Tiger Zhou

Daniel Thomson

Joshua M Schmidt

Ayub Qassim

Lachlan S W Knight

Georgina Hollitt

Ella C Berry

Thi Nguyen

Minh-Son To

David Dimasi

Abraham Kuot

Joshua Dubowsky

Rhys Fogarty

Michelle Sun

Luke Chehade

Shilpa Kuruvilla

Devaraj Supramaniam

James Breen

Shiwani Sharma

John Landers

Stewart Lake

Richard A Mills

Mark M Hassall

Weng O Chan

Sonja Klebe

Emmanuelle Souzeau

Owen M Siggs

Jamie E Craig

Affiliations

Soon will be listed here.

Abstract

Purpose: Pseudoexfoliation syndrome (PEX) is a common systemic disease that results in severe and often irreversible vision loss. Despite considerable research effort, PEX remains incompletely understood. This study sought to perform the first RNAseq study in elucidate the pathophysiology of PEX, and contribute a publicly available transcriptomic data resource for future research.

Methods: Human ocular lens capsular epithelium samples were collected from 25 patients with PEX and 39 non-PEX controls undergoing cataract surgery. RNA extracted from these specimens was subjected to polyadenylated (mRNA) selection and deep bulk RNA sequencing. Differential expression analysis investigated protein-coding gene transcripts. Exploratory analyses used pathway analysis tools, and curated class- and disease-specific gene sets.

Results: Differential expression analysis demonstrated that 2882 genes were differentially expressed according to PEX status. Genes associated with viral gene expression pathways were among the most upregulated, alongside genes encoding ribosomal and mitochondrial respiratory transport chain proteins. Cell adhesion protein transcripts including type 4 collagen subunits were downregulated.

Conclusions: This comparative transcriptomic dataset highlights novel and previously recognized pathogenic pathways in PEX and provides the first comprehensive transcriptomic resource, adding an additional layer to build further understanding of PEX pathophysiology.

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