Carrino D A, Dennis J E, Drushel R F, Haynesworth S E, Caplan A I
Department of Biology, Case Western Reserve University, Cleveland, OH 44106-7080.
Biochem J. 1994 Feb 15;298 ( Pt 1)(Pt 1):51-60. doi: 10.1042/bj2980051.
Large, chondroitin sulphate-containing proteoglycans are synthesized by three prominent tissue in the embryonic chick limb. One of these proteoglycans is aggrecan, the phenotype-specific proteoglycan of cartilage. Another, PG-M, is produced by prechondrogenic mesenchymal cells. The third, M-CSPG, is made by developing skeletal muscle cells. While the carbohydrate components of PG-M and M-CSPG share some similarities, both of these proteoglycans clearly have different carbohydrate moieties from those of aggrecan. To compare these three proteoglycans at another level, their core protein structures were analysed in three ways: by the presence or absence of monoclonal antibody epitopes, by one-dimensional peptide display of the cyanogen bromide-cleaved core proteins and by electron microscopic imaging of the molecules. Monoclonal antibodies whose epitopes are present in aggrecan core protein were tested with core protein preparations from M-CSPG and PG-M. One of these, 7D1, recognizes both PG-M and M-CSPG, while another, 1C6, shows no reactivity for the non-cartilage proteoglycans. The absence of 1C6 reactivity is of interest, as its epitope is in a region of the aggrecan core protein known to have a functional homologue in the core proteins of PG-M and M-CSPG. The cyanogen bromide-fragmented peptide pattern of M-CSPG is the same as that of PG-M, and both are different from that of aggrecan. The aggrecan pattern has one prominent large band (molecular mass 130 kDa), some less prominent large bands (molecular mass 70-100 kDa) and several smaller bands. In contrast, the PG-M and M-CSPG patterns show no bands with molecular masses > 73 kDa, and the smaller bands (molecular mass < 40 kDa) have a different pattern to that of the smaller bands from aggrecan. The electron microscopic images of aggrecan show a core protein with one end having two globular regions separated by a short linear segment; adjacent to this is a long linear segment, which sometimes contains a third globular region at the end of the core protein opposite the end with the double-globe structure. M-CSPG and PG-M core proteins never show images with the double-globe structure. Instead, one end of the molecule has a single globular domain, and a second globular region is variably present at the opposite end of the core protein. Thus, by all three methods, the core proteins of PG-M and M-CSPG appear to be the same and both differ from the core protein of aggrecan.
含硫酸软骨素的大型蛋白聚糖由胚胎期鸡肢体中的三种主要组织合成。其中一种蛋白聚糖是聚集蛋白聚糖,即软骨的表型特异性蛋白聚糖。另一种是PG-M,由软骨前间充质细胞产生。第三种是M-CSPG,由发育中的骨骼肌细胞产生。虽然PG-M和M-CSPG的碳水化合物成分有一些相似之处,但这两种蛋白聚糖的碳水化合物部分显然与聚集蛋白聚糖不同。为了在另一个层面比较这三种蛋白聚糖,我们通过三种方式分析了它们的核心蛋白结构:通过单克隆抗体表位的有无、通过对溴化氰裂解的核心蛋白进行一维肽展示以及通过对分子进行电子显微镜成像。用来自M-CSPG和PG-M的核心蛋白制剂检测了其表位存在于聚集蛋白聚糖核心蛋白中的单克隆抗体。其中一种抗体7D1能识别PG-M和M-CSPG,而另一种抗体1C6对非软骨蛋白聚糖无反应性。1C6无反应性这一点很有意思,因为其表位位于聚集蛋白聚糖核心蛋白的一个区域,已知该区域在PG-M和M-CSPG的核心蛋白中有功能同源物。M-CSPG经溴化氰裂解后的肽图谱与PG-M相同,且两者均与聚集蛋白聚糖的不同。聚集蛋白聚糖的图谱有一条突出的大带(分子量130 kDa)、一些不太突出的大带(分子量70 - 100 kDa)和几条较小的带。相比之下,PG-M和M-CSPG的图谱中没有分子量> 73 kDa的条带,且较小的带(分子量< 40 kDa)与聚集蛋白聚糖的较小带图谱不同。聚集蛋白聚糖的电子显微镜图像显示一个核心蛋白,其一端有两个由短线性段隔开的球状区域;与此相邻的是一个长线性段,该段有时在核心蛋白与双球状结构相对的一端含有第三个球状区域。M-CSPG和PG-M的核心蛋白从未显示出具有双球状结构的图像。相反,分子的一端有一个单球状结构域,在核心蛋白相对的另一端可变地存在第二个球状区域。因此,通过所有这三种方法,PG-M和M-CSPG的核心蛋白似乎是相同的,且两者均与聚集蛋白聚糖的核心蛋白不同。
