Comparative Analysis of Retinal Organotypic Cultures and In Vivo Axotomized Retinas.
María José González-RiquelmeFernando Lucas-RuizCaridad Galindo-RomeroRaquel BoiaAntónio Francisco AmbrósioManuel Vidal-SanzAna Raquel SantiagoMarta Agudo-BarriusoPublished in: International journal of molecular sciences (2023)
Retinal organotypic cultures (ROCs) are used as an in vivo surrogate to study retinal ganglion cell (RGC) loss and neuroprotection. In vivo, the gold standard to study RGC degeneration and neuroprotection is optic nerve lesion. We propose here to compare the course of RGC death and glial activation between both models. The left optic nerve of C57BL/6 male mice was crushed, and retinas analyzed from 1 to 9 days after the injury. ROCs were analyzed at the same time points. As a control, intact retinas were used. Retinas were studied anatomically to assess RGC survival, microglial, and macroglial activation. Macroglial and microglial cells showed different morphological activation between models and were activated earlier in ROCs. Furthermore, microglial cell density in the ganglion cell layer was always lower in ROCs than in vivo. RGC loss after axotomy and in vitro followed the same trend up to 5 days. Thereafter, there was an abrupt decrease in viable RGCs in ROCs. However, RGC somas were still immuno-identified by several molecular markers. ROCs are useful for proof-of-concept studies on neuroprotection, but long-term experiments should be carried out in vivo. Importantly, the differential glial activation observed between models and the concomitant death of photoreceptors that occurs in vitro may alter the efficacy of RGC neuroprotective therapies when tested in in vivo models of optic nerve injury.
Keyphrases
- optic nerve
- optical coherence tomography
- neuropathic pain
- single cell
- cell therapy
- cerebral ischemia
- brain injury
- lps induced
- induced apoptosis
- spinal cord injury
- stem cells
- spinal cord
- cell proliferation
- cell death
- signaling pathway
- mesenchymal stem cells
- endoplasmic reticulum stress
- oxidative stress
- cell cycle arrest
- pi k akt
- silver nanoparticles