Role of zinc-binding- and hemopexin domain-encoded sequences in the substrate specificity of collagenase and stromelysin-2 as revealed by chimeric proteins.

The relationship of enzyme structure to substrate specificity for the matrix metalloproteinases interstitial collagenase and stromelysin-2 has been investigated by analysis of the cleavage specificity of recombinant human collagenase-stromelysin-2 hybrid proteins and C terminally truncated collagenase and stromelysin-2. Two series of chimeric proteins were devised by progressive substitution of exon-encoded domains. The recombinant proteins were expressed in COS-7 cells as protein A-fusion proteins and purified on an IgG affinity matrix. Treatment with 4-amino-phenylmercuric acetate released active metalloproteinase of the sizes predicted for the chimeric proteins. Active forms of both the chimeric protein series and the short form enzymes expressed both casein- and gelatin-degrading activities. Like stromelysin, the catalytic activity of stromelysin-2 was contained in the N-terminal domain (encoded by exons 1-5) and was apparently independent of the C-terminal domain (encoded by exons 6-10). Only full-length collagenase displayed a triple helicase (collagenolytic) activity; no combination of N- or C-terminal collagenase domains fused with stromelysin-2 domains had such activity. This suggests that the triple helicase activity is a composite of elements derived from both halves of the collagenase molecule. C terminally truncated collagenase (exons 1-5) and a hybrid of collagenase exons 1-5 and stromelysin-2 exons 6-10 cleaved denatured type I collagen (gelatin) to generate diagnostic peptides in gelatin fingerprint assays. When exon 5 (the exon encoding the zinc-binding domain) was derived from stromelysin-2, the enzyme specificity in the fingerprint assay changed to that of native stromelysin-2. In contrast, when exon 5 was derived from collagenase, the specificity reflected that of the parent enzyme. Our data also suggest that mismatching of exons 2 and 5 destabilizes the enzyme, presumably by altering the geometry of the propeptide-zinc-binding site interaction. We conclude that the loss of triple helicase collagenolytic activity is not accompanied by a shift to the broad specificity characteristic of stromelysin. Rather, the zinc-binding domain confers a distinct cleavage specificity on each metalloproteinase.