Insights into the degradation of human elastin by matrilysin-1.

Human matrilysin-1 (MMP-7) is one of the most potent elastases besides macrophage elastase in the family of matrix metalloproteinases (MMPs). It has been reported to provide macrophages with the highest elastinolytic capacity and plays key roles in diseases such as emphysema and cancer. Describing the enzymatic turnover of matrix components helps to understand the molecular basis of disease processes. Hence, in this work, the cleavage behavior of MMP-7 with respect to its natural substrate human elastin was investigated using mass spectrometric (MS) techniques and molecular modeling. Elastin peptides in the range of 500-8000 Da released through the action of MMP-7 were analyzed and domains susceptible to proteolytic attack by MMP-7 were identified. MMP-7 was found to mainly cleave in N- and C-terminal regions of elastin's precursor, which involves linkages in domains encoded by exons 2, 3, 5-7, 26, and 30-33. In contrast, only few cleavages were found in the central part of the precursor and no cleavages in regions in elastin that are involved in cross-linking. MMP-7 shows a strong preference for Leu in P(1)' and also accepts Val, Gly, and Pro at this position, whereas Ala is not preferred at P(1)'. Analysis by molecular modeling revealed that not only the size of the amino acid residue in P(1)' but also the orientation of the neighboring P(1) residue and, thus, the orientation of the peptide bond that is cleaved influences the cleavage preference of MMP-7. Overall, this study provides an important insight into the degradation of human elastin by MMP-7 and may aid in the development of approaches to treat elastin-degrading diseases.

Degradation of tropoelastin by matrix metalloproteinases--cleavage site specificities and release of matrikines.

To provide a basis for the development of approaches to treat elastin-degrading diseases, the aim of this study was to investigate the degradation of the natural substrate tropoelastin by the elastinolytic matrix metalloproteinases MMP-7, MMP-9, and MMP-12 and to compare the cleavage site specificities of the enzymes using complementary MS techniques and molecular modeling. Furthermore, the ability of the three proteases to release bioactive peptides was studied. Tropoelastin was readily degraded by all three MMPs. Eighty-nine cleavage sites in tropoelastin were identified for MMP-12, whereas MMP-7 and MMP-9 were found to cleave at only 58 and 63 sites, respectively. Cleavages occurred predominantly in the N-terminal and C-terminal regions of tropoelastin. With respect to the cleavage site specificities, the study revealed that all three MMPs similarly tolerate hydrophobic and/or aliphatic amino acids, including Pro, Gly, Ile, and Val, at P(1)'. MMP-7 shows a strong preference for Leu at P(1)', which is also well accepted by MMP-9 and MMP-12. Of all three MMPs, MMP-12 best tolerates bulky charged and aromatic amino acids at P(1)'. All three MMPs showed a clear preference for Pro at P(3) that could be structurally explained by molecular modeling. Analysis of the generated peptides revealed that all three MMPs show a similar ability to release bioactive sequences, with MMP-12 producing the highest number of these peptides. Furthermore, the generated peptides YTTGKLPYGYGPGG, YGARPGVGVGGIP, and PGFGAVPGA, containing GxxPG motifs that have not yet been proven to be bioactive, were identified as new matrikines upon biological activity testing.

MMP-12 catalytic domain recognizes and cleaves at multiple sites in human skin collagen type I and type III.

Collagens of either soft connective or mineralized tissues are subject to continuous remodeling and turnover. Undesired cleavage can be the result of an imbalance between proteases and their inhibitors. Owing to their superhelical structure, collagens are resistant to many proteases and matrix metalloproteinases (MMPs) are required to initiate further degradation by other enzymes. Several MMPs are known to degrade collagens, but the action of MMP-12 has not yet been studied in detail. In this work, the potential of MMP-12 in recognizing sites in human skin collagen types I and III has been investigated. The catalytic domain of MMP-12 binds to the triple helix and cleaves the typical sites -Gly(775)-Leu(776)- in alpha-2 type I collagen and -Gly(775)-Ile(776)- in alpha-1 type I and type III collagens and at multiple other sites in both collagen types. Moreover, it was observed that the region around these typical sites contains comparatively less prolines, of which some have been proven to be only partially hydroxylated. This is of relevance since partial hydroxylation in the vicinity of a potential scissile bond may have a local effect on the conformational thermodynamics with probable consequences on the collagenolysis process. Taken together, the results of the present work confirm that the catalytic domain of MMP-12 alone binds and degrades collagens I and III.

In vitro degradation of human tropoelastin by MMP-12 and the generation of matrikines from domain 24.

Degradation of elastic fibers in tissues can result in the development of disorders that include aneurysms, atherosclerosis, and loss of skin elasticity. Tropoelastin is the precursor of the cross-linked elastin and its expression is triggered by elastin-degrading factors as a response to damage. Factors like UV radiation not only increase the expression of tropoelastin but also potent metalloelastases such as macrophage elastase (MMP-12). The development of elastin-degrading diseases, moreover, is a chronic process during which elastin and tropoelastin are repeatedly exposed to attacks by MMP-12. Hence, in this work we report the in vitro susceptibility of tropoelastin and the potential of MMP-12 to generate matrikines. This work provides evidence that tropoelastin is substantially and rapidly degraded by MMP-12 even at very dilute enzyme concentrations. MMP-12 cleaves at least 86 sites in tropoelastin. Analysis of the generated peptides revealed that some small peptides contained the motif GXXPG that may enable them to bind with the elastin binding protein (EBP). Furthermore, using synthesized peptides it was confirmed that several sites in the sequence encoded by exon 24 which contains repetitive units of biologically active VGVAPG domains are susceptible to attack by MMP-12, provided that the active subsites in MMP-12 (S(4) to S(4)') are occupied. Such cleavage events have lead to the generation of ligands that may bind to EBP.

Mapping of macrophage elastase cleavage sites in insoluble human skin elastin.

Macrophage elastase (MMP-12) is a member of the family of matrix metalloproteinases (MMPs) and is active against multiple extracellular protein substrates such as elastin. Its effect on elastin is central to emphysema in the lung and photoaging of skin. Its expression in the skin increases on photodamaged skin and upon aging. Detecting and characterizing peptides cleaved in elastin, therefore, helps to understand such degradative disease processes in the skin and is also needed to assist in the rational design of agents that specifically inhibit the degradation. In this study, cleavage sites of MMP-12 in human skin elastin were extensively investigated. The peptides formed as a result of cleavages by this enzyme in the human skin elastin were characterized using mass spectrometry. A total of 41 peptides ranging from 4 to 41 amino acids were identified and 36 cleavage sites were determined. Amino acids encoded by exons 5, 6, 26, 28-31 were particularly susceptible to cleavages by MMP-12 and none or very few cleavages were detected from domains encoded by the remaining exons. The amino acid preferences of the different subsites on the catalytic domain of MMP-12 were analyzed.