Tso Danju, McKinnon Randall D
Department of Surgery (Neurosurgery), Rutgers-Robert Wood Johnson Medical School, New Brunswick, NJ, USA.
Neural Regen Res. 2015 Sep;10(9):1356-8. doi: 10.4103/1673-5374.165209.
The brain and spinal cord can not replace neurons or supporting glia that are lost through traumatic injury or disease. In pre-clinical studies, however, neural stem and progenitor cell transplants can promote functional recovery. Thus the central nervous system is repair competent but lacks endogenous stem cell resources. To make transplants clinically feasible, this field needs a source of histocompatible, ethically acceptable and non-tumorgenic cells. One strategy to generate patient-specific replacement cells is to reprogram autologous cells such as fibroblasts into pluripotent stem cells which can then be differentiated into the required cell grafts. However, the utility of pluripotent cell derived grafts is limited since they can retain founder cells with intrinsic neoplastic potential. A recent extension of this technology directly reprograms fibroblasts into the final graftable cells without an induced pluripotent stem cell intermediate, avoiding the pluripotent caveat. For both types of reprogramming the conversion efficiency is very low resulting in the need to amplify the cells in culture which can lead to chromosomal instability and neoplasia. Thus to make reprogramming biology clinically feasible, we must improve the efficiency. The ultimate source of replacement cells may reside in directly reprogramming accessible cells within the brain.
大脑和脊髓无法替换因创伤性损伤或疾病而丢失的神经元或支持性神经胶质细胞。然而,在临床前研究中,神经干细胞和祖细胞移植可以促进功能恢复。因此,中枢神经系统具有修复能力,但缺乏内源性干细胞资源。为了使移植在临床上可行,该领域需要一种组织相容性良好、符合伦理且无致瘤性的细胞来源。生成患者特异性替代细胞的一种策略是将自体细胞(如成纤维细胞)重编程为多能干细胞,然后将其分化为所需的细胞移植物。然而,多能细胞衍生移植物的效用有限,因为它们可能保留具有内在肿瘤形成潜力的原始细胞。该技术的最新进展直接将成纤维细胞重编程为最终可移植的细胞,无需诱导多能干细胞中间体,从而避免了多能性的问题。对于这两种重编程类型,转化效率都非常低,导致需要在培养中扩增细胞,这可能会导致染色体不稳定和肿瘤形成。因此,为了使重编程生物学在临床上可行,我们必须提高效率。替代细胞的最终来源可能在于直接重编程大脑内可获取的细胞。