Pathway analysis identifies altered mitochondrial metabolism, neurotransmission, structural pathways and complement cascade in retina/RPE/ choroid in chick model of formdeprivation myopia
Purpose. RNA sequencing analysis has demonstrated bidirectional changes in
metabolism, structural and immune pathways during early induction of defocus
induced myopia. Thus, the aim of this study was to investigate whether similar gene
pathways are also related to the more excessive axial growth, ultrastructural and
elemental microanalytic changes seen during the induction and recovery from formdeprivation myopia (FDM) in chicks and predicted by the RIDE model of myopia.
Methods. Archived genomic transcriptome data from the first three days of induction
of monocularly occluded form deprived myopia (FDMI) in chicks was obtained
from the GEO database (accession # GSE6543) while data from chicks monocularly
occluded for 10 days and then given up to 24 h of normal visual recovery (FDMR)
were collected. Gene set enrichment analysis (GSEA) software was used to determine
enriched pathways during the induction (FDMI) and recovery (FDMR) from FD.
Curated gene-sets were obtained from open access sources.
Results. Clusters of significant changes in mitochondrial energy metabolism, neurotransmission, ion channel transport, G protein coupled receptor signalling, complement cascades and neuron structure and growth were identified during the 10 days of
induction of profound myopia and were found to correlate well with change in axial
dimensions. Bile acid and bile salt metabolism pathways (cholesterol/lipid metabolism
and sodium channel activation) were significantly upregulated during the first 24 h of
recovery from 10 days of FDM.
Conclusions. The gene pathways altered during induction of FDM are similar to those
reported in defocus induced myopia and are established indicators of oxidative stress,
osmoregulatory and associated structural changes. These findings are also consistent
with the choroidal thinning, axial elongation and hyperosmotic ion distribution
patterns across the retina and choroid previously reported in FDM and predicted by
RIDE.
Funding
This study was supported by National Health and Medical Research Council Development (ID448606) to DPC and SGC and a further Australian Research Council (DP110103784).
History
Publication Date
2018-01-01
Journal
PeerJ
Volume
6
Pagination
35 p.
Publisher
PeerJ
ISSN
2167-8359
Rights Statement
This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.