BACKGROUND: Matrix metalloproteinases (MMPs) play a key role in cardiovascular disease, in particular aneurysm formation and plaque rupture. Surprisingly, little is known about MMP substrates in the vasculature. METHODS AND RESULTS: We used a proteomics approach to identify vascular substrates for 3 MMPs, 1 of each of the 3 major classes of MMPs: Human arteries were incubated with MMP-3 (a member of stromelysins), MMP-9 (considered a gelatinase), and MMP-14 (considered a member of the collagenases and of the membrane-bound MMPs). Candidate substrates were identified by mass spectrometry based on increased release from the arterial tissue on digestion, spectral evidence for proteolytic degradation after gel separation, and identification of nontryptic cleavage sites. Using this approach, novel candidates were identified, including extracellular matrix proteins associated with the basement membrane, elastic fibers (emilin-1), and other extracellular proteins (periostin, tenascin-X). Seventy-four nontryptic cleavage sites were detected, many of which were shared among different MMPs. The proteomics findings were validated by immunoblotting and by digesting recombinant/purified proteins with exogenous MMPs. As proof-of-principle, results were related to in vivo pathology by searching for corresponding degradation products in human aortic tissue with different levels of endogenous MMP-9. CONCLUSIONS: The application of proteomics to identify MMP targets is a new frontier in cardiovascular research. Our current classification of MMPs based on few substrates is an oversimplification of a complex area of biology. This study provides a more comprehensive assessment of potential MMP substrates in the vasculature and represents a valuable resource for future investigations.
BACKGROUND: Matrix metalloproteinases (MMPs) play a key role in cardiovascular disease, in particular aneurysm formation and plaque rupture. Surprisingly, little is known about MMP substrates in the vasculature. METHODS AND RESULTS: We used a proteomics approach to identify vascular substrates for 3 MMPs, 1 of each of the 3 major classes of MMPs: Human arteries were incubated with MMP-3 (a member of stromelysins), MMP-9 (considered a gelatinase), and MMP-14 (considered a member of the collagenases and of the membrane-bound MMPs). Candidate substrates were identified by mass spectrometry based on increased release from the arterial tissue on digestion, spectral evidence for proteolytic degradation after gel separation, and identification of nontryptic cleavage sites. Using this approach, novel candidates were identified, including extracellular matrix proteins associated with the basement membrane, elastic fibers (emilin-1), and other extracellular proteins (periostin, tenascin-X). Seventy-four nontryptic cleavage sites were detected, many of which were shared among different MMPs. The proteomics findings were validated by immunoblotting and by digesting recombinant/purified proteins with exogenous MMPs. As proof-of-principle, results were related to in vivo pathology by searching for corresponding degradation products in human aortic tissue with different levels of endogenous MMP-9. CONCLUSIONS: The application of proteomics to identify MMP targets is a new frontier in cardiovascular research. Our current classification of MMPs based on few substrates is an oversimplification of a complex area of biology. This study provides a more comprehensive assessment of potential MMP substrates in the vasculature and represents a valuable resource for future investigations.
Authors: Javier Barallobre-Barreiro; Shashi K Gupta; Anna Zoccarato; Rika Kitazume-Taneike; Marika Fava; Xiaoke Yin; Tessa Werner; Marc N Hirt; Anna Zampetaki; Alessandro Viviano; Mei Chong; Marshall Bern; Antonios Kourliouros; Nieves Domenech; Peter Willeit; Ajay M Shah; Marjan Jahangiri; Liliana Schaefer; Jens W Fischer; Renato V Iozzo; Rosa Viner; Thomas Thum; Joerg Heineke; Antoine Kichler; Kinya Otsu; Manuel Mayr Journal: Circulation Date: 2016-08-24 Impact factor: 29.690
Authors: Rugmani Padmanabhan Iyer; Ying Ann Chiao; Elizabeth R Flynn; Kevin Hakala; Courtney A Cates; Susan T Weintraub; Lisandra E de Castro Brás Journal: Proteomics Clin Appl Date: 2015-12-17 Impact factor: 3.494
Authors: Charles A Galea; Hai M Nguyen; K George Chandy; Brian J Smith; Raymond S Norton Journal: Cell Mol Life Sci Date: 2013-08-03 Impact factor: 9.261
Authors: Julian E Fuchs; Susanne von Grafenstein; Roland G Huber; Christian Kramer; Klaus R Liedl Journal: PLoS Comput Biol Date: 2013-11-14 Impact factor: 4.475