Neuroprotective effects of syngeneic bone marrow‐derived mononuclear stem cell transplantation and intraperitoneal minocycline in the treatment of inherited photoreceptor retinal degeneration

Abstract

Inherited retinal degenerations are diseases characterized by photoreceptor loss secondary to genetic defects and Retinitis Pigmentosa (RP) is the most frequent inherited retinal degeneration. This disease has a prevalence of around 1 in 4000 individuals and is caused by mutations in more than 300 genes. RP is characterized by progressive loss of photoreceptors (fist rods following by cones), activation of microglial cells and gliosis increases of macroglial cell.The Royal college of Surgeon (RCS) rat is a well characterized animal models of RP which suffer a mutation of the MERTK gene, that impedes the normal photoreceptor outer segment phagocytosis by RPE cells thus triggers the simultaneous degeneration of rods and cones. Recent studies have shown that microglial activation starts simultaneously with the beginning of photoreceptor death in the RCS retinas, suggesting that microglial cells play an important role in the retinal degeneration progression.Therapies for inherited photoreceptor degeneration aim to prevent or delay death of the photoreceptors, or in specific circumstances try to replace them.The Bone marrow derived‐mononuclear cells (BM‐MNCs) are a mononuclear CD34+ subpopulation of bone marrow‐derived cells that can be separated from the other cellular fractions of the bone marrow aspirate using a Ficoll density gradient‐based protocol. These cells have shown promising results in different animal models of neuronal degeneration, including inherited photoreceptor degenerations such us: improve the morphology of the photoreceptors outer segment, decrease synaptic degeneration in the outer plexiform layer and reduce glial fibrillary acidic protein expression in Müller cells.On the other hands minocycline is a broad‐spectrum tetracycline antibiotic, of which it has been demonstrated has antimicrobial, anti‐inflammatory, antiapoptotic, neuroprotective, and microglial inhibition effects in central nervous system diseases.In RCS rat retina the neuroprotective effect of minocycline against photoreceptor apoptosis is can be explained by mainly two different mechanisms: (1) a direct antiapoptotic effect on photoreceptors and/or (2) an effect through its anti‐inflammatory properties reducing microglial cells activation and migration.The question arises whether the combination of intravitreal BM‐MNCs transplantation with minocycline, substances that increase survival presumably through different mechanisms, could further increase photoreceptor survival and therefore be used for the treatment of retinal degenerations.Our results showed that intravitreal transplantation of BM‐MNCs increase photoreceptor survival, improved the morphology of the photoreceptors outer segment, and reduce retinal thinning (in vivo). On the other hands intraperitoneally minocycline treatment, and reduced activation and migration of microglia and produced a significant rescue of photoreceptors. Finally, our result show that combination both treatments had higher neuroprotective effects in the retina, increasing photoreceptor survival, than each of the treatments alone.In conclusion in RCS rat animal model of photoreceptor degeneration, minocycline reduces microglial activation and migration, and intravitreal transplantation of BM‐MNCs and minocycline increase photoreceptor survival. The combination of both treatments shows greater neuroprotective effects than their isolated effects, and therefore could be indicated for treatment of the early stages of photoreceptor degenerations.