Creation of an Isogenic Human iPSC-Based RGC Model of Dominant Optic Atrophy Harboring the Pathogenic Variant c.1861C>T (p.Gln621Ter) in the OPA1 Gene.
Marta García-LópezLydia Jiménez-VicenteRaquel González-JabardoHelena DoradoIrene Gomez-ManjonMiguel Angel MartinCarmen AyusoJoaquín ArenasMaría Esther GallardoPublished in: International journal of molecular sciences (2024)
Autosomal dominant optic atrophy (ADOA) is a rare progressive disease mainly caused by mutations in OPA1 , a nuclear gene encoding for a mitochondrial protein that plays an essential role in mitochondrial dynamics, cell survival, oxidative phosphorylation, and mtDNA maintenance. ADOA is characterized by the degeneration of retinal ganglion cells (RGCs). This causes visual loss, which can lead to legal blindness in many cases. Nowadays, there is no effective treatment for ADOA. In this article, we have established an isogenic human RGC model for ADOA using iPSC technology and the genome editing tool CRISPR/Cas9 from a previously generated iPSC line of an ADOA plus patient harboring the pathogenic variant NM_015560.3: c.1861C>T (p.Gln621Ter) in heterozygosis in OPA1 . To this end, a protocol based on supplementing the iPSC culture media with several small molecules and defined factors trying to mimic embryonic development has been employed. Subsequently, the created model was validated, confirming the presence of a defect of intergenomic communication, impaired mitochondrial respiration, and an increase in apoptosis and ROS generation. Finally, we propose the analysis of OPA1 expression by qPCR as an easy read-out method to carry out future drug screening studies using the created RGC model. In summary, this model provides a useful platform for further investigation of the underlying pathophysiological mechanisms of ADOA plus and for testing compounds with potential pharmacological action.
Keyphrases
- crispr cas
- genome editing
- induced pluripotent stem cells
- oxidative stress
- endothelial cells
- copy number
- poor prognosis
- cell death
- multiple sclerosis
- cell cycle arrest
- dna methylation
- long non coding rna
- risk assessment
- emergency department
- mitochondrial dna
- small molecule
- optical coherence tomography
- signaling pathway
- dna damage
- single molecule
- cell proliferation
- combination therapy