Fukuda K, Hori H, Utani A, Burbelo P D, Yamada Y
Craniofacial Developmental Biology and Regeneration Branch, National Institute of Dental Research, NIH, Bethesda, Maryland 20892, USA.
Biochem Biophys Res Commun. 1997 Feb 3;231(1):178-82. doi: 10.1006/bbrc.1997.6069.
Collagen IV molecules represent a major structural component of basement membranes providing a network of support for the supramolecular structure. Like other collagens, collagen IV forms a triple-helical molecule composed of three alpha chains. Six different alpha chains exist for collagen IV, although the most common isoform consists of two alpha 1(IV) and one alpha 2(IV) chain. To understand the molecular mechanism of triple-helical formation of collagen IV, we expressed recombinant alpha 1(IV) and alpha 2(IV) mouse collagen chains in Chinese hamster ovary (CHO) cells. An expression vector containing the full length cDNA for the mouse alpha 1(IV) chain was stably transfected into CHO cells and a cell line, A222, which expressed recombinant alpha 1(IV) chains was selected. These A222 cells were then infected with a retroviral expression vector containing the mouse alpha 2(IV) chain and a cell line, A222-A2, stably expressing both recombinant alpha 1(IV) and alpha 2(IV) chains was obtained. Immunoprecipitation of A222 cell lysates revealed a high level of alpha 1(IV) chain monomer, which was unable to form a homotrimer. Analysis of A222-A2 cell lysates revealed the presence of both monomeric alpha 2(IV) and alpha 1(IV) chains as well as a higher molecular weight collagen IV species. Second dimensional SDS-PAGE analysis demonstrated that the high molecular weight species was a heterotrimer consisting of two alpha 1(IV) and one alpha 2(IV) chain. This heterotrimer collagen IV species was pepsin-resistant indicating the formation of a stable triple-helical structure. Pulse-chase experiments showed that the monomer alpha 1(IV) chain was secreted, but at a much slower rate than the heterotrimer. Together these results demonstrate that the alpha 1(IV) chain is not capable of forming homotrimers and suggest that the coexpression with the alpha 2(IV) chain is necessary to form a triple-helical structure.
IV型胶原蛋白分子是基底膜的主要结构成分,为超分子结构提供支撑网络。与其他胶原蛋白一样,IV型胶原蛋白形成由三条α链组成的三螺旋分子。IV型胶原蛋白存在六种不同的α链,尽管最常见的异构体由两条α1(IV)链和一条α2(IV)链组成。为了了解IV型胶原蛋白三螺旋形成的分子机制,我们在中国仓鼠卵巢(CHO)细胞中表达了重组α1(IV)和α2(IV)小鼠胶原蛋白链。将含有小鼠α1(IV)链全长cDNA的表达载体稳定转染到CHO细胞中,并筛选出表达重组α1(IV)链的细胞系A222。然后用含有小鼠α2(IV)链的逆转录病毒表达载体感染这些A222细胞,获得稳定表达重组α1(IV)和α2(IV)链的细胞系A222-A2。对A222细胞裂解物进行免疫沉淀显示高水平的α1(IV)链单体,其无法形成同三聚体。对A222-A2细胞裂解物的分析显示存在单体α2(IV)和α1(IV)链以及更高分子量的IV型胶原蛋白种类。二维SDS-PAGE分析表明,高分子量种类是由两条α1(IV)链和一条α2(IV)链组成的异三聚体。这种异三聚体IV型胶原蛋白种类对胃蛋白酶具有抗性,表明形成了稳定的三螺旋结构。脉冲追踪实验表明,单体α1(IV)链被分泌,但速度比异三聚体慢得多。这些结果共同表明,α1(IV)链不能形成同三聚体,并表明与α2(IV)链共表达对于形成三螺旋结构是必要的。
