Functional Roles of N‐Linked Glycosylation of Human Matrix Metalloproteinase 9

Matrix metalloproteinase‐9 (MMP‐9) is a secreted endoproteinase with a critical role in the regulation of the extracellular matrix and proteolytic activation of signaling molecules. Human (h)MMP‐9 has two well‐defined N‐glycosylation sites at residues N38 and N120; however, their role has remained mostly unexplored partly because expression of the N‐glycosylation‐deficient N38S has been difficult due to a recently discovered single nucleotide polymorphism‐dependent miRNA‐mediated inhibitory mechanism. hMMP‐9 cDNA encoding amino acid substitutions at residues 38 (modified‐S38, mS38) or 120 (N120S) were created in the background of a miRNA‐binding site disrupted template and expressed by transient transfection. hMMP‐9 harboring a single mS38 replacement secreted well, whereas N120S, or a double mS38/N120S hMMP‐9 demonstrated much reduced secretion. Imaging indicated endoplasmic reticulum (ER) retention of the non‐secreted variants and co‐immunoprecipitation confirmed an enhanced strong interaction between the non‐secreted hMMP‐9 and the ER‐resident protein calreticulin (CALR). Removal of N‐glycosylation at residue 38 revealed an amino acid‐dependent strong interaction with CALR likely preventing unloading of the misfolded protein from the ER chaperone down the normal secretory pathway. As with other glycoproteins, N‐glycosylation strongly regulates hMMP‐9 secretion. This is mediated, however, through a novel mechanism of cloaking an N‐glycosylation‐independent strong interaction with the ER‐resident CALR.