Fredette B, Rutishauser U, Landmesser L
Physiology and Neurobiology Department, University of Connecticut, Storrs 06269-3042.
J Cell Biol. 1993 Dec;123(6 Pt 2):1867-88. doi: 10.1083/jcb.123.6.1867.
Muscle development in vivo involves a complex sequence of cell-cell interactions in which secondary myotubes first form in association with primary myotubes and subsequently separate from them. We show here that during this process N-cadherin and the different structural forms of NCAM are regulated in a pattern that involves both temporal changes in expression and localization to particular regions of the muscle cell surface. In particular, levels of N-cadherin on maturing myotubes are decreased, and the form of NCAM synthesized by the muscle changes from a transmembrane non-polysialylated to a lipid-linked polysialylated membrane protein. Moreover, while NCAM was distributed on all myotube surfaces, the polysialyated form of NCAM was restricted to regions of the myotube surface that had recently separated from neighboring cells. We previously found that blockade of nerve-induced activity by d-Tubocurarine perturbed muscle cell interactions, resulting in a failure of myotubes to separate. We now show that this activity blockade also alters adhesion molecule expression. First, N-cadherin was no longer down-regulated in maturing myotubes, and its persistence on the surfaces of mature myotubes may partly explain their failure to separate. Secondly, the developmental switch from transmembrane to lipid-linked NCAM did not occur, and polysialylated NCAM was no longer formed. As the unusual physical properties of PSA have been proposed to impede cell-cell interactions, this alteration would also be expected to compromise cell separation. Together, these results suggest that the regulated expression of both N-cadherin and NCAM isoforms including their polysialylation, is an essential mechanism for the normal separation of secondary myotubes from primary myotubes.
体内肌肉发育涉及一系列复杂的细胞间相互作用,在此过程中,次级肌管首先与初级肌管相关联形成,随后与初级肌管分离。我们在此表明,在此过程中,N-钙黏着蛋白和不同结构形式的神经细胞黏附分子(NCAM)受到一种模式的调控,该模式涉及表达的时间变化以及在肌肉细胞表面特定区域的定位。特别是,成熟肌管上的N-钙黏着蛋白水平降低,肌肉合成的NCAM形式从跨膜非多唾液酸化转变为脂连接多唾液酸化膜蛋白。此外,虽然NCAM分布在所有肌管表面,但NCAM的多唾液酸化形式仅限于肌管表面最近与相邻细胞分离的区域。我们之前发现,用d-筒箭毒碱阻断神经诱导的活动会扰乱肌肉细胞间的相互作用,导致肌管无法分离。我们现在表明,这种活动阻断也会改变黏附分子的表达。首先,成熟肌管中的N-钙黏着蛋白不再下调,其在成熟肌管表面的持续存在可能部分解释了它们无法分离的原因。其次,从跨膜NCAM到脂连接NCAM的发育转变未发生,多唾液酸化NCAM也不再形成。由于多唾液酸(PSA)不同寻常的物理特性被认为会阻碍细胞间相互作用,这种改变也可能会损害细胞分离。总之,这些结果表明,N-钙黏着蛋白和包括其多唾液酸化在内的NCAM亚型的调控表达是次级肌管与初级肌管正常分离的重要机制。