Kirillova Irina, Gussoni Emanuela, Goldhamer David J, Yablonka-Reuveni Zipora
Department of Biological Structure, University of Washington School of Medicine, Magnuson Health Sciences Center, Box 357420, Room I-146, 1959 NE Pacific Street, Seattle, WA 98195, USA.
Dev Biol. 2007 Nov 15;311(2):449-63. doi: 10.1016/j.ydbio.2007.08.056. Epub 2007 Sep 7.
Satellite cells are recognized as the main source for myoblasts in postnatal muscle. The possible participation of other cell types in myofiber maintenance remains a subject of debate. Here, we investigated the potential of vascular preparations from mouse retina to undergo myogenesis when cultured alone or with differentiated primary myogenic cultures. The choice of retina, an organ richly supplied with capillary network and anatomically separated from skeletal muscles, ensures that the vasculature preparation is devoid of satellite cells. We demonstrate that retina-derived cells spontaneously fuse with preexisting myotubes and contribute additional myonuclei, some of which initiate expression of muscle-specific genes after fusion. Myogenic differentiation of retinal cells prior to their fusion with preexisting myotubes was not detected. Although originating from vasculature preparations, nuclei undergoing myogenic reprogramming were contributed by cells that were neither endothelial nor blood borne. Our results suggest smooth muscle/pericytes as the possible source, and that myogenic reprogramming depends on the muscle specific transcription factor MyoD. Our studies provide insights into a novel avenue for myofiber maintenance, relying on nuclei of non-myogenic origin that undergo fusion and subsequent myogenic conversion within host myofibers. This process may support ongoing myofiber maintenance throughout life.
卫星细胞被认为是出生后肌肉中肌母细胞的主要来源。其他细胞类型在肌纤维维持中的可能参与仍然是一个有争议的话题。在这里,我们研究了从小鼠视网膜分离的血管制剂在单独培养或与分化的原代成肌培养物一起培养时发生肌生成的潜力。选择视网膜作为研究对象,是因为它富含毛细血管网络且在解剖学上与骨骼肌分离,这确保了血管制剂中没有卫星细胞。我们证明,视网膜来源的细胞能自发地与预先存在的肌管融合,并贡献额外的肌细胞核,其中一些在融合后启动肌肉特异性基因的表达。在视网膜细胞与预先存在的肌管融合之前,未检测到其成肌分化。尽管这些进行成肌重编程的细胞核来源于血管制剂,但它们并非由内皮细胞或血细胞贡献。我们的结果表明平滑肌/周细胞可能是其来源,并且成肌重编程依赖于肌肉特异性转录因子MyoD。我们的研究为肌纤维维持的新途径提供了见解,该途径依赖于非肌源性来源的细胞核,这些细胞核在宿主肌纤维内发生融合并随后进行成肌转化。这一过程可能支持一生中持续的肌纤维维持。