Oligodendrocyte development and myelination rely on an unusual membrane-associated transcription factor that shares functional domains with bacteriophage proteins.
Although the transcription factors required for the generation of oligodendrocytes and CNS myelination during development have been relatively well established, it is not known whether continued expression of the same factors is required for the maintenance of myelin in the adult. Here, we use an inducible conditional knock-out strategy to investigate whether continued oligodendrocyte expression of the recently identified transcription factor myelin gene regulatory factor (MRF) is required to maintain the integrity of myelin in the adult CNS. Genetic ablation of MRF in mature oligodendrocytes within the adult CNS resulted in a delayed but severe CNS demyelination, with clinical symptoms beginning at 5 weeks and peaking at 8 weeks after ablation of MRF. This demyelination was accompanied by microglial/macrophage infiltration and axonal damage. Transcripts for myelin genes, such as proteolipid protein, MAG, MBP, and myelin oligodendrocyte glycoprotein, were rapidly downregulated after ablation of MRF, indicating an ongoing requirement for MRF in the expression of these genes. Subsequently, a proportion of the recombined oligodendrocytes undergo apoptosis over a period of weeks. Surviving oligodendrocytes gradually lose the expression of mature markers such as CC1 antigen and their association with myelin, without reexpressing oligodendrocyte progenitor markers or reentering the cell cycle. These results demonstrate that ongoing expression of MRF within the adult CNS is critical to maintain mature oligodendrocyte identity and the integrity of CNS myelin.
Optic neuropathies are characterised by a loss of retinal ganglion cells (RGCs) that lead to vision impairment. Development of cell therapy requires a better understanding of the signals that direct stem cells into RGCs. Human embryonic stem cells (hESCs) represent an unlimited cellular source for generation of human RGCs in vitro. In this study, we present a 45-day protocol that utilises magnetic activated cell sorting to generate enriched population of RGCs via stepwise retinal differentiation using hESCs. We performed an extensive characterization of these stem cell-derived RGCs by examining the gene and protein expressions of a panel of neural/RGC markers. Furthermore, whole transcriptome analysis demonstrated similarity of the hESC-derived RGCs to human adult RGCs. The enriched hESC-RGCs possess long axons, functional electrophysiological profiles and axonal transport of mitochondria, suggestive of maturity. In summary, this RGC differentiation protocol can generate an enriched population of functional RGCs from hESCs, allowing future studies on disease modeling of optic neuropathies and development of cell therapies.
Cybrid technology was used to replace Leber hereditary optic neuropathy (LHON) causing mitochondrial DNA (mtDNA) mutations from patient-specific fibroblasts with wildtype mtDNA, and mutation-free induced pluripotent stem cells (iPSCs) were generated subsequently. Retinal ganglion cell (RGC) differentiation demonstrates increased cell death in LHON-RGCs and can be rescued in cybrid corrected RGCs.
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