A potential physiological role of stromelysin-1 (MMP-3) in the expression or activation of gelatinase A (MMP-2) or gelatinase B (MMP-9) in the wall of injured arteries was studied with the use of homozygous MMP-3–deficient (MMP-3^−/−) mice. One week after perivascular electric injury of the carotid or femoral artery in wild-type (MMP-3^+/+) or MMP-3^−/− mice, 70 kD and 65 kD proMMP-2 levels were enhanced by twofold to fourfold, with corresponding increases of 20- to 40-fold for active 61 kD and 58 kD MMP-2, and of 10- to 80-fold for 94 kD proMMP-9. Active MMP-2 species represented approximately one third of the total MMP-2 concentration for both MMP-3^+/+ and MMP-3^−/− mice. Active 83 kD MMP-9 was not detected in noninjured carotid or femoral arteries, whereas one week after injury its contribution to the total MMP-9 level was 11% to 18% for MMP-3^+/+ and MMP-3^−/− mice. Immunostaining of arterial sections confirmed enhanced expression of both MMP-2 and MMP-9 after vascular injury. Double immunostaining showed colocalization of MMP-9 with macrophages in the adventitia, whereas MMP-2 was also detected mainly in the adventitia but failed to colocalize with smooth muscle cells. Cell culture experiments confirmed comparable ratios of active versus latent MMP-2 in skin fibroblasts and smooth muscle cells derived from MMP-3^+/+ and MMP-3^−/− mice. Addition of plasmin(ogen) did not significantly affect activation of proMMP-2. In MMP-3^+/+ and MMP-3^−/− macrophages, comparable levels of 94 kD proMMP-9 were detected, and plasmin(ogen)-mediated conversion to 83 kD MMP-9 was obtained in both genotypes. These data thus indicate that proMMP-2 activation may occur via a plasmin- and MMP-3–independent mechanism, whereas plasmin can directly activate proMMP-9 via a MMP-3–independent mechanism.