The yeast two-hybrid system was used to reveal the interactions between proteins residing within the cutaneous basement membrane zone and other gene products expressed in cultured human keratinocytes. The proteins of interest included type VII collagen, the predominant component of anchoring fibrils, and laminin 5, a component of anchoring filaments. Although the two-hybrid system was not able to verify a direct interaction between the type VII collagen NC1 domain and the short arm of Lam(beta)3, the type VII collagen NC1 domain (tVII/NC1) and the laminin 5 beta3 chain globular domain VI (lam5/beta3) cDNAs, when used as baits, detected four overlapping cDNA clones encoding thrombospondin 1 (TSP1). The overlapping region of these cDNAs encodes amino acids 400-459, a segment included within a 70 kDa chymotryptic fragment known to bind type V collagen, laminin-1 and other matrix components. The type VII collagen NC1/TSP1 interaction was confirmed by exchanging the vectors, and the interacting domain was mapped by testing a set of both 5' and 3' deletion constructs. The central region of TSP1, when used as a bait in two-hybrid system, showed strong binding to the fibronectin (FN) type III-like repeats 4-7 of type VII collagen NC1 domain. The TSP1 bait also interacted with laminin 5 beta3 chain domain V/III, and the TSP1/laminin 5 beta3 chain interaction was verified by a GST-fusion protein interaction assay. The transcripts encoding TSP1, TSP2, Lam(beta)3 and type VII collagen were abundant in cultured foreskin keratinocytes, and the expression of TSP1 and TSP2 in a wide variety of adult and fetal tissues was confirmed by PCR analysis of multiple tissue cDNA panels. Furthermore, TSP1 type I repeats showed self interaction, and recognized a clone for extracellular matrix protein fibrillin-2. In addition, clones encoding angiogenesis related protein Jagged1 and a platelet enzyme phospholipase scramblase were identified. Thus, the results indicate several previously undetected interactions of TSP1, which is known to be highly expressed during embryonic development, tissue remodeling and wound healing.