Friedlander D R, Brackenbury R, Edelman G M
J Cell Biol. 1985 Aug;101(2):412-9. doi: 10.1083/jcb.101.2.412.
During normal development, the neural cell adhesion molecule N-CAM changes at the cell-surface from a sialic acid-rich embryonic, or E form, to several adult, or A forms that have less sialic acid (E-to-A conversion). To investigate the cellular and molecular mechanisms that underlie these changes, we have established conditions under which E-to-A conversion occurs in cultured explants of central nervous system tissues. Mouse cerebellum, chick spinal cord, and chick retina that express the E form of N-CAM were dissected and cultured on collagen gels. After 3-6 d in culture, increased proportions of A forms were synthesized, as revealed by specific immunoprecipitation and immunoblotting. The rate of E-to-A conversion and the proportions of the different A forms synthesized in vitro were similar to those observed for the tissues in vivo at comparable times. In addition, the explants incorporated radioactive precursors of amino sugars into N-CAM, and the electrophoretic mobilities of the E and A forms of N-CAM were altered by treatment with neuraminidase in a way comparable to that found for N-CAM obtained directly from tissue. These results suggest that the post translational processing in vitro was similar to that in vivo. Logistic studies on cell division and death in the explants suggested that E-to-A conversion resulted mainly from a specific increase in synthesis of A forms in individual cells rather than as a consequence of differential birth or death within distinct cell populations. The data were consistent with the possibility that the increase in synthesis of A forms occurred either in cells that had previously synthesized E forms or in a distinct population of cells that already synthesized A forms. Cells dissociated from embryonic central nervous system tissues and cultured in vitro were also found to undergo E-to-A conversion at the same rate as the explant cultures, which suggests that if intercellular signals were responsible for initiation of the change in synthetic pattern, they had already occurred in vivo before the time of culture. In pulse-chase experiments, the E form of N-CAM that was synthesized during the first day after explantation persisted as E form for several days, at times when newly synthesized N-CAM was predominantly in A forms. These results indicate that in cultured neural tissue, the E form of N-CAM is not processed into A forms but is gradually degraded and replaced by newly synthesized A forms.(ABSTRACT TRUNCATED AT 400 WORDS)
在正常发育过程中,神经细胞黏附分子N-CAM在细胞表面从富含唾液酸的胚胎型(E型)转变为几种唾液酸含量较少的成年型(A 型)(E型向A型的转变)。为了研究这些变化背后的细胞和分子机制,我们建立了中枢神经系统组织培养外植体中发生E型向A型转变的条件。解剖并在胶原凝胶上培养表达N-CAM E型的小鼠小脑、鸡脊髓和鸡视网膜。培养3-6天后,通过特异性免疫沉淀和免疫印迹发现,A型的合成比例增加。体外E型向A型的转变速率以及合成的不同A型的比例与在体内相应时间观察到的组织情况相似。此外,外植体将氨基糖的放射性前体掺入N-CAM中,并且N-CAM的E型和A型的电泳迁移率通过神经氨酸酶处理而改变,其方式与直接从组织获得的N-CAM相似。这些结果表明体外的翻译后加工与体内相似。对外植体中细胞分裂和死亡的逻辑研究表明,E型向A型的转变主要是由于单个细胞中A型合成的特异性增加,而不是不同细胞群体中出生或死亡差异的结果。数据与A型合成增加可能发生在先前合成E型的细胞中或已经合成A型的不同细胞群体中的可能性一致。还发现从胚胎中枢神经系统组织解离并在体外培养的细胞以与外植体培养相同的速率进行E型向A型的转变,这表明如果细胞间信号负责合成模式变化的启动,那么它们在培养前已经在体内发生。在脉冲追踪实验中,外植后第一天合成的N-CAM的E型在几天内持续为E型,此时新合成的N-CAM主要为A型。这些结果表明,在培养的神经组织中,N-CAM的E型不会加工成A型,而是逐渐降解并被新合成的A型取代。(摘要截短至400字)
