Vertebrate collagen fibrils are heterotypically composed of a quantitatively major and minor fibril collagen. In non-cartilaginous tissues, type I collagen accounts for the majority of the collagen mass, and collagen type V, the functions of which are poorly understood, is a minor component. Type V collagen has been implicated in the regulation of fibril diameter, and we reported recently preliminary evidence that type V collagen is required for collagen fibril nucleation (Wenstrup, R. J., Florer, J. B., Cole, W. G., Willing, M. C., and Birk, D. E. (2004) J. Cell. Biochem. 92, 113-124). The purpose of this study was to define the roles of type V collagen in the regulation of collagen fibrillogenesis and matrix assembly. Mouse embryos completely deficient in pro-␣1(V) chains were created by homologous recombination. The col5a1؊/؊ animals die in early embryogenesis, at approximately embryonic day 10. The type V collagen-deficient mice demonstrate a virtual lack of collagen fibril formation. In contrast, the col5a1؉/؊ animals are viable. The reduced type V collagen content is associated with a 50% reduction in fibril number and dermal collagen content. In addition, relatively normal, cylindrical fibrils are assembled with a second population of large, structurally abnormal collagen fibrils. The structural properties of the abnormal matrix are decreased relative to the wild type control animals. These data indicate a central role for the evolutionary, ancient type V collagen in the regulation of fibrillogenesis. The complete dependence of fibril formation on type V collagen is indicative of the critical role of the latter in early fibril initiation. In addition, this fibril collagen is important in the determination of fibril structure and matrix organization.Type V collagen is a member of the fibril subclass of collagens, which have in common a triple helical domain composed of an uninterrupted series of Gly-X-Y triplets. Type V collagen is a quantitatively minor component of predominantly type I collagen fibrils in most non-cartilaginous tissues. Several isoforms of type V collagen exist, which differ in the type and ratio of constituent chains, including heterotypic molecules containing type XI collagen chains. The most abundant and widely distributed isoform is ␣1(V) 2 ␣2(V), which forms heterotypic fibrils with type I collagen (1). The role of type V collagen in the organization and biological properties of collagenous extracellular matrix is poorly understood. Observations of an inverse correlation between type V collagen:type I collagen ratios and collagen fibril diameter in in vitro fibril assembly experiments (2), cell cultures (3, 4), and in various tissues (5) have led to the hypothesis that type V collagen serves as a negative regulator of collagen fibril diameter (3-5). That function may be mediated by retention of the non-collagenous amino-terminal propeptide after type V collagen molecules are incorporated into fibrils (2, 6 -9). This non-collagenous domain projects outward through the gap between adj...
