Hogervorst F, Admiraal L G, Niessen C, Kuikman I, Janssen H, Daams H, Sonnenberg A
Department of Immunohematology, The Netherlands Red Cross Blood Transfusion Service, Amsterdam.
J Cell Biol. 1993 Apr;121(1):179-91. doi: 10.1083/jcb.121.1.179.
Two cytoplasmic variants of the alpha 6 integrin, alpha 6A and alpha 6B, have been identified previously (Hogervorst, F., I. Kuikman, A. G. van Kessel, and A. Sonnenberg. 1991. Eur. J. Biochem. 199:425-433; Cooper, H. M., R. N. Tamura, and V. Quaranta. 1991. J. Cell Biol. 115:843-850). Using synthetic peptides, containing sequences of their cytoplasmic domains, we have produced mAbs specific for either of the variants. These antibodies reacted with a variety of different epithelial tissues. In some tissues (e.g., salivary gland) both variants could be detected while in others only one of the variants was found (e.g., alpha 6A in epidermis and alpha 6B in kidney). Among nonepithelial cells and tissues, perineural fibroblasts and Schwann cells in peripheral nerves and platelets reacted with anti-alpha 6A, while microvascular endothelia reacted with both anti-alpha 6A and anti-alpha 6B. From our immunohistochemical results there is not evidence that combination with beta 1 or beta 4 is restricted to one of the two variants of alpha 6. This was confirmed by immunoprecipitation studies which showed that both beta 1 and beta 4 were coprecipitated by both anti-alpha 6A or anti-alpha 6B antibodies from cells. Also, the distribution of alpha 6A and alpha 6B subunits associated with beta 1 on cells attached to laminin was similar: both were found in focal contacts colocalizing with vinculin. In contrast, the alpha 6A subunit, associated with beta 4 in cultures of a squamous cell carcinoma cell line, was found to codistribute with bullous pemphigoid antigen 230 in hemidesmosomal-like structures. The alpha 6A and alpha 6B variants, immunoprecipitated from various cell lines, exhibited slightly different electrophoretic mobilities. Analysis of the antigens under reducing conditions showed that the mobility of the light chains, but not of the heavy chains, is different. In addition, in some cells the light chains of alpha 6A and alpha 6B, each are of two different sizes. Treatment with N-glycanase showed that these two light chain variants of alpha 6A and alpha 6B are not due to differences in N-linked glycosylation, and may therefore represent alternative proteolytic products of the alpha 6 precursor. We further demonstrate that alpha 6A, but not alpha 6B, is a major target for PMA-induced phosphorylation. Phosphorylated alpha 6A contained phosphoserine and a small amount of phosphotyrosine. There are also two variants of the integrin alpha 3 subunit with different cytoplasmic domains, but in the cell lines examined only alpha 3A could be demonstrated by RT-PCR.(ABSTRACT TRUNCATED AT 400 WORDS)
先前已鉴定出α6整合素的两种细胞质变体,即α6A和α6B(霍格沃斯特,F.,I. 奎克曼,A. G. 范凯塞尔,以及A. 索南伯格。1991年。《欧洲生物化学杂志》199:425 - 433;库珀,H. M.,R. N. 田村,以及V. 夸兰塔。1991年。《细胞生物学杂志》115:843 - 850)。利用含有其细胞质结构域序列的合成肽,我们制备了对任一变体具有特异性的单克隆抗体。这些抗体与多种不同的上皮组织发生反应。在一些组织(如唾液腺)中可检测到两种变体,而在其他组织中仅发现一种变体(如表皮中的α6A和肾中的α6B)。在非上皮细胞和组织中,外周神经中的神经周成纤维细胞和雪旺细胞以及血小板与抗α6A发生反应,而微血管内皮细胞与抗α6A和抗α6B均发生反应。从我们的免疫组织化学结果来看,没有证据表明与β1或β4的结合仅限于α6的两种变体之一。免疫沉淀研究证实了这一点,该研究表明抗α6A或抗α6B抗体均可从细胞中共沉淀β1和β4。此外,在附着于层粘连蛋白的细胞上,与β1相关的α6A和α6B亚基的分布相似:两者都存在于与纽蛋白共定位的粘着斑中。相比之下,在鳞状细胞癌细胞系培养物中与β4相关的α6A亚基,被发现与大疱性类天疱疮抗原230在半桥粒样结构中共分布。从各种细胞系中免疫沉淀得到的α6A和α6B变体表现出略有不同的电泳迁移率。在还原条件下对抗抗原的分析表明,轻链而非重链的迁移率不同。此外,在一些细胞中,α6A和α6B的轻链各自有两种不同大小。用N - 糖苷酶处理表明,α6A和α6B的这两种轻链变体并非由于N - 连接糖基化的差异,因此可能代表α6前体的替代性蛋白水解产物。我们进一步证明,α6A而非α6B是佛波酯诱导磷酸化的主要靶点。磷酸化的α6A含有磷酸丝氨酸和少量磷酸酪氨酸。整合素α3亚基也有两种具有不同细胞质结构域的变体,但在所检测的细胞系中,通过逆转录 - 聚合酶链反应仅能证实α3A的存在。(摘要截断于400字)
