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胚胎中软骨形成的调控

CONTROL OF CHONDROGENESIS IN THE EMBRYO.

作者信息

HOLTZER H

出版信息

Biophys J. 1964 Jan;4(1 Pt 2):SUPPL239-55. doi: 10.1016/s0006-3495(64)86941-1.

DOI:10.1016/s0006-3495(64)86941-1

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1367628/

Abstract

Control of chondrogenesis in the embryo involves mechanisms which induce certain cells to synthesize chondroitin sulfate, as well as mechanisms which regulate the continued production of these molecules in differentiated chondrocytes. The embryonic spinal cord and notochord induce somite cells to chondrify. Interaction between these inducers and somite cells, however, is not sufficient in itself to transform the latter into chondrocytes; there must be additional reactions. The notion that induction simply involves the transmission of information-rich molecules like RNA or protein from inducers to somite cells is thought unlikely. When differentiated 10-day chondrocytes with all the enzymes and genetic information for the synthesis of chondroitin sulfate are removed from their mucopolysaccharide matrix and cultured as isolated cells in vitro, they rapidly transform from spherical cells to stellate ones. Correlated with this change in shape and increase in surface area of cell membrane is the cessation of the production of chondroitin sulfate. The stellate cells are induced to synthesize DNA and multiply; their progeny, though permitted to resume their originally spherical shape, do not differentiate into recognizable chondrocytes again. Experiments of this kind suggest the presence of metabolic controls located in the cytoplasm and/or cell membrane.

摘要

胚胎中软骨形成的控制涉及诱导某些细胞合成硫酸软骨素的机制，以及调节分化软骨细胞中这些分子持续产生的机制。胚胎脊髓和脊索诱导体节细胞软骨化。然而，这些诱导物与体节细胞之间的相互作用本身不足以将后者转化为软骨细胞；还必须有其他反应。诱导仅仅涉及从诱导物向体节细胞传递富含信息的分子（如RNA或蛋白质）这种观点被认为不太可能。当将具有合成硫酸软骨素的所有酶和遗传信息的分化10天的软骨细胞从其粘多糖基质中取出并作为分离细胞在体外培养时，它们会迅速从球形细胞转变为星状细胞。与这种形状变化和细胞膜表面积增加相关联的是硫酸软骨素产生的停止。星状细胞被诱导合成DNA并增殖；它们的后代虽然被允许恢复其原来的球形形状，但不会再次分化为可识别的软骨细胞。这类实验表明存在位于细胞质和/或细胞膜中的代谢控制。