Abstract
The astacin protease Meprin β represents an emerging target for drug development due to its potential involvement in disorders such as acute and chronic kidney injury and fibrosis. Here, we elaborate on the structural basis of inhibition by a specific Meprin β inhibitor. Our analysis of the crystal structure suggests different binding modes of the inhibitor to the active site. This flexibility is caused, at least in part, by movement of the C-terminal region of the protease domain (CTD). The CTD movement narrows the active site cleft upon inhibitor binding. Compared with other astacin proteases, among these the highly homologous isoenzyme Meprin α, differences in the subsites account for the unique selectivity of the inhibitor. Although the inhibitor shows substantial flexibility in orientation within the active site, the structural data as well as binding analyses, including molecular dynamics simulations, support a contribution of electrostatic interactions, presumably by arginine residues, to binding and specificity. Collectively, the results presented here and previously support an induced fit and substantial movement of the CTD upon ligand binding and, possibly, during catalysis. To the best of our knowledge, we here present the first structure of a Meprin β holoenzyme containing a zinc ion and a specific inhibitor bound to the active site. The structural data will guide rational drug design and the discovery of highly potent Meprin inhibitors.
Highlights
Meprin β was produced in Pichia pastoris, applying an optimized version of a previously described protocol [34]
The activation of Pro-Meprin by trypsin resulted in removal of the poly-histidin tag and the pro-peptide (Figure S1)
Truncated variant Meprin β62–595 (Mβ∆C), despite reduced protein yield, identical specific activity was detected when compared with the previous variant Meprin β62–562
Summary
Meprins (Meprin α and β) are multidomain, Zn-dependent proteases They belong to the astacin family and metzincin superfamily of endo-proteinases. Discovered in the early 1980s in human intestine and mouse kidney [1,2,3], Meprins have only been described in vertebrate tissue such as human skin, leukocytes and various cancer cells. They are involved in a broad range of proteolytic processes, among these connective tissue homeostasis and immunological and intestinal barrier function [4,5,6]. The development of selective and potent inhibitors represents a vital approach for treatment of fibrosis, nephritis and neurodegeneration [7]
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