Renal remodelling in hyperinsulinic/insulinopenic states is mediated by glucotoxicity, endothelial dysfunction and vascular and nephron collagen turnover. Hypertensive and renal links are renewed by renoprotective interventions of renin-angiotensin. Vasoactive peptide processing and vascular collagen deposition are under the tight control of two zinc metalloproteinase families that regulate vascular tone and trophicity: gluzincins (or vasopeptidases) are convertases of angiotensins, endothelins or atrial natriuretic factors; and metzincins or matrix metalloproteases (MMP, matrixins)] regulate vascular type IV collagen basement membrane proteolysis. Association of natural tissue inhibitors of MMPs, pharmacological inhibitors of vasopeptidases [either conventional (angiotensin-converting enzyme inhibitors) or innovative (omapatrilat)], together with synthetic MMP inhibitors, are currently screened to counteract vascular remodelling and renal scarring. Our studies focused on the 72 kDa (MMP-2) and 92 kDa (MMP-9) matrixin gelatinases and tissue inhibitors involved in basement membrane degradation and rebuilding. Three complementary settings were developed, allowing evaluations from basic to clinical stages. A leucocyte-endothelial transmigration model was designed for transcription and addressing of enzymes and inhibitors, in situ matrix degradation, and blockading by metalloprotease inhibitors (captopril). Insulin-resistant fructose-fed rats showed heavy proteinuria and glomerulosclerosis involving angiotensin II-dependent changes in renal gelatinases and inhibitors. Urinary gelatinolytic profiles from Type 2 diabetic patients with overt nephropathy were compared with those of normal first-degree relatives and age-matched healthy controls. Physiologically, MMP-9 was the primary urinary gelatinolytic enzyme. In Type 2 diabetic proteinuric patients, MMP-9 and MMP-2 releases were significantly increased in the absence of renin-angiotensin blockade, while first-degree relatives showed reduced gelatinase levels suggestive of a genetic control of renal matrix regulation prior to potential glycaemic dysregulation. These preliminary data suggest that local MMP/TIMP imbalance is involved in diabetic renal remodelling. Further studies are needed to define the redundancies and specificities of vasopeptidase and MMP inhibitors, differentiate the antihypertensive effect from target-organ protection, screen for innovative pharmacological compounds, and validate simple, efficient biological markers of renal fibrosis progression and the effect of anti-fibrotic therapeutic interventions.