Genetically modified bone marrow cells halt mitral cell loss by modulating inflammation and protecting against DNA damage

Abstract

[EN]Cell therapy is a promising strategy for tackling neurodegenerative diseases. The most outstanding results with this approach usually involve neuroprotection of damaged neurons at risk of death, but only with limited success. Current therapies are often based on the idea of “one gene, one disease, one drug” for single targets, a concept that limits their actual effectiveness. In contrast, combining different strategies can establish an advanced cell therapy that can slow down neuronal degeneration. In this study, we took advantage of the combination of cell and gene therapy, by transplanting bone marrow stem cells genetically modified to overexpress insulin-like growth factor 1 (IGF1) into a model of selective neurodegeneration, the PCD mouse. This animal is characterized by progressive neuronal loss in the olfactory bulb and alterations in IGF1 levels, among other symptoms. Using different techniques (cell cultures, viral transduction, cell transplants, flow cytometry, qPCR, ELISA, immunohistochemistry, advanced image analysis), our findings showed that neuronal death was virtually blocked, even 130 days after cell transplantation, a result clearly more successful than previous studies. The effects of this transplant are based in part on the regulation of neuroinflammation, increasing the proportion of reactive microglia and reducing that of proinflammatory microglia. In addition, IGF1 overexpression dramatically reduced DNA damage in mutant animals via IGF binding protein 3 pathway: this enhances neuroprotection by complementing the basal effect of cell therapy itself. In summary, our work supports the idea that combining therapeutic approaches and their synergies is a more effective tactic for combating neuronal loss.