Jennifer Vandooren

Biochemistry and molecular biology of gelatinase B or matrix metalloproteinase-9 (MMP-9): the next decade.

Abstract Research on matrix metalloproteinases (MMPs) and in particular on gelatinase B, alias MMP-9, has grown exponentially in the decade 2003–2012. Structural details about flexibility of MMP-9 monomers, together with glycosylation, oligomerization, heterogeneity and instability of the wildtype enzyme explain why crystallography experiments have not yet been successful for the intact enzyme. MMP-9 may be viewed as a multidomain enzyme in which the hemopexin, the O-glycosylated and the catalytic domains yield support for attachment, articulation and catalysis, respectively. The stepwise proteolytic activation of the inactive zymogen into a catalytically active form becomes gradually better understood. Priming of activation by MMP-3 may be executed by meprins that destabilize the interaction of the aminoterminus with the third fibronectin repeat. Alternatively, autocatalytic activation may occur in the presence of molecules that tightly bind to the catalytic site and that push the cystein residue in the prodomain away from the catalytic zinc ion. Thanks to the development of degradomics technologies, substrate repertoires of MMP-9 have been defined, but it remains a challenge to determine and prove which substrates are biologically relevant. The substrate repertoire has been enlarged from extracellular to membrane-bound and efficient intracellular substrates, such as crystallins, tubulins and actins. Biological studies of MMP-9 have tuned the field from being primarily cancer-oriented towards vascular and inflammatory research. In tumor biology, it has been increasingly appreciated that MMP-9 from inflammatory cells, particularly neutrophils, co-determines prognosis and outcome. Aside from the catalytic functions executed by aminoterminal domains of MMP-9, the carboxyterminal hemopexin (PEX) domain of gelatinase B exerts non-catalytic anti-apoptotic signaling effects. The recognition that gelatinase B is induced by many pro-inflammatory cytokines, whereas its inhibitors are increased by anti-inflammatory cytokines, has generated interest to target MMP-9 in acute lethal conditions, such as bacterial meningitis, sepsis and endotoxin shock, and in acute exacerbations of chronic diseases. Previously described transcriptional regulation of MMP-9 is complemented by epigenetic checkpoints, including histone modifications and microRNAs. Because activation of proMMP-9 may be executed by other MMPs, the therapeutic dogma that MMP inhibitors need to be highly selective may be keyed down for the treatment of life-threatening conditions. When inflammation and MMP-9 fulfill beneficial functions to clear damaging protein complexes, such as in systemic autoimmune diseases, therapeutic MMP inhibition has to be avoided. In Mmp9 gene knockout mice, specific spontaneous phenotypes emerged with effects on the skeletal, reproductive and nervous systems. These findings not only have clinical correlates in bone growth and fertility, but also stimulate research on the roles of MMPs and MMP-9 in endocrinology, immunology and the neurosciences. Mmp9-deficient mice are valuable tools to define MMP-9 substrates in vivo and to study the role of this enzyme in animal models of inflammatory, vascular, neoplastic and degenerative diseases. Future challenges include solving the crystal structure, definition of the functions of covalent oligomers and heteromers in biology and pathology, life-imaging of MMP-9 activity, substrate determination in situ and the study of inhibitor effects on fertility, cancer and inflammation and in neurobiology and regenerative medicine. Such studies will better define conditions in which inhibition of MMP-9 is beneficial or has to be avoided.

Zymography methods for visualizing hydrolytic enzymes

Zymography is a technique for studying hydrolytic enzymes on the basis of substrate degradation. It is a powerful, but often misinterpreted, tool yielding information on potential hydrolytic activities, enzyme forms and the locations of active enzymes. In this Review, zymography techniques are compared in terms of advantages, limitations and interpretations. With in gel zymography, enzyme forms are visualized according to their molecular weights. Proteolytic activities are localized in tissue sections with in situ zymography. In vivo zymography can pinpoint proteolytic activity to sites in an intact organism. Future development of novel substrate probes and improvement in detection and imaging methods will increase the applicability of zymography for (reverse) degradomics studies.

VEGF-A recruits a proangiogenic MMP-9–delivering neutrophil subset that induces angiogenesis in transplanted hypoxic tissue

Recruitment and retention of leukocytes at a site of blood vessel growth are crucial for proper angiogenesis and subsequent tissue perfusion. Although critical for many aspects of regenerative medicine, the mechanisms of leukocyte recruitment to and actions at sites of angiogenesis are not fully understood. In this study, we investigated the signals attracting leukocytes to avascular transplanted pancreatic islets and leukocyte actions at the engraftment site. Expression of the angiogenic stimulus VEGF-A by mouse pancreatic islets was elevated shortly after syngeneic transplantation to muscle. High levels of leukocytes, predominantly CD11b(+)/Gr-1(+)/CXCR4(hi) neutrophils, were observed at the site of engraftment, whereas VEGF-A-deficient islets recruited only half of the amount of leukocytes when transplanted. Acute VEGF-A exposure of muscle increased leukocyte extravasation but not the levels of SDF-1α. VEGF-A-recruited neutrophils expressed 10 times higher amounts of MMP-9 than neutrophils recruited to an inflammatory stimulus. Revascularization of islets transplanted to MMP-9-deficient mice was impaired because blood vessels initially failed to penetrate grafts, and after 2 weeks vascularity was still disturbed. This study demonstrates that VEGF-A recruits a proangiogenic circulating subset of CD11b(+)/Gr-1(+) neutrophils that are CXCR4(hi) and deliver large amounts of the effector protein MMP-9, required for islet revascularization and functional integration after transplantation.

The Sputum Colour Chart as a predictor of lung inflammation, proteolysis and damage in non-cystic fibrosis bronchiectasis: a case-control analysis.

Non‐cystic fibrosis bronchiectasis (NCFB) is characterized by a vicious cycle of airway infection, inflammation and structural damage with inappropriate mucus clearance. Our aim was to relate the value of proteolytic enzymes, proteolytic enzyme activity and inflammatory markers to disease severity and symptoms in patients with NCFB.

Gelatin degradation assay reveals MMP-9 inhibitors and function of O-glycosylated domain.

AIM To establish a novel, sensitive and high-throughput gelatinolytic assay to define new inhibitors and compare domain deletion mutants of gelatinase B/matrix metalloproteinase (MMP)-9. METHODS Fluorogenic Dye-quenched (DQ)™-gelatin was used as a substrate and biochemical parameters (substrate and enzyme concentrations, DMSO solvent concentrations) were optimized to establish a high-throughput assay system. Various small-sized libraries (ChemDiv, InterBioScreen and ChemBridge) of heterocyclic, drug-like substances were tested and compared with prototypic inhibitors. RESULTS First, we designed a test system with gelatin as a natural substrate. Second, the assay was validated by selecting a novel pyrimidine-2,4,6-trione (barbiturate) inhibitor. Third, and in line with present structural data on collagenolysis, it was found that deletion of the O-glycosylated region significantly decreased gelatinolytic activity (k(cat)/k(M) ± 40% less than full-length MMP-9). CONCLUSION The DQ™-gelatin assay is useful in high-throughput drug screening and exosite targeting. We demonstrate that flexibility between the catalytic and hemopexin domain is functionally critical for gelatinolysis.

Infliximab restores the dysfunctional matrix remodeling protein and growth factor gene expression in patients with inflammatory bowel disease.

Background:Matrix metalloproteinases (MMPs), tissue inhibitors of metalloproteinases (TIMPs), a disintegrin and metalloprotease with thrombospondin motifs [ADAM(TS)s] and growth factors are involved in inflammation and tissue damage and repair, all occurring in inflammatory bowel disease (IBD). We studied the impact of anti-inflammatory therapy with infliximab on mucosal expression of these tissue remodeling genes in patients with IBD. Methods:Mucosal gene expression of 23 MMPs, 4 TIMPs, 50 ADAM(TS)s, and 158 growth factors was investigated in 61 patients with IBD before and after the first infliximab therapy and in 12 controls, with microarrays and quantitative RT-PCR. Protein localization, mucosal gelatinase levels, and net gelatinolytic activity were investigated by immunohistochemistry, zymography analysis, and gelatin degradation assay, respectively. Results:In patients with active IBD before infliximab versus controls, gene expression of many MMPs, TIMPs, ADAM(TS)s, and growth factors was upregulated, whereas colonic expression of MMP28 and TGFA and ileal expression of ADAMDEC1 and AGT were downregulated. After controlling inflammation with infliximab, most gene dysregulations observed at baseline were restored in responders. Increased ratio of MMP1/TIMP1 expression at baseline in active IBD was restored in responders with colonic mucosal healing. With immunohistochemistry, protein localization differences of MMP1, MMP3, REG1A, and TIMP1 were shown between active IBD and control mucosa. With zymography analysis and gelatin degradation assay, higher gelatinase levels and net gelatinolytic activity were measured before infliximab and levels normalized after infliximab. Conclusions:Our data suggest that suppression of inflammation results in the arrest of epithelial damage and subsequent mucosal healing. Therefore, the therapeutic potential of agents targeting MMPs or growth factors as primary therapy seems rather complex.

Azithromycin decreases MMP-9 expression in the airways of lung transplant recipients ☆

The neomacrolide antibiotic azithromycin is known to have an anti-inflammatory effect and is increasingly being used in the treatment of chronic inflammatory pulmonary diseases. We investigated whether azithromycin influenced matrix remodeling. Matrix metalloproteinase (MMP)-9 protein levels were measured by ELISA in bronchoalveolar lavaga fluid in 10 stable patients and in 10 lung transplant patients suffering from nCLAD/NRAD. MMP-9 was measured via ELISA before and after 3 to 6 months of azithromycin therapy. We further elaborated on the role of MMP-9 by performing gelatin-zymography and gelatinolytic activity assays. Differential and total cell counts on BAL were performed in all cases. The nCLAD/NRAD patients showed higher airway neutrophilia (p<0.0001), ELISA MMP-9 (p<0.0001), zymography proMMP-9 (p<0.0001), activated MMP-9 (p=0.0003) and gelatinolytic activity (p=0.0002) compared to the control group. Airway neutrophilia in the nCLAD/NRAD group significantly decreased after 3-6 months of treatment with azithromycin (p=0.0020). This was associated with a decrease in ELISA MMP-9 levels (p=0.0059), in activated MMP-9 shown on zymography (p=0.016) and in gelatinolytic activity (p=0.031). Remarkably, proMMP-9 levels were not altered by azithromycin. Although azithromycin significantly reduced ELISA MMP-9 levels and gelatinolytic activity in transplant patients, these levels remained higher compared to control patients (p=0.0011 and p=0.043). Neutrophil counts, activated MMP-9 and gelatinolytic activity levels in nCLAD/NRAD decreased after azithromycin treatment, but some remained elevated compared to control patients. This illustrates that treatment with azithromycin did not completely restore chronic inflammation in the airways and suggested that preventive therapy may yield added value to curative therapy.

Heterogeneity of serum gelatinases MMP-2 and MMP-9 isoforms and charge variants

The matrix metalloproteinases (MMPs) gelatinase A (MMP‐2) and gelatinase B (MMP‐9) are mediators of brain injury in multiple sclerosis (MS) and valuable biomarkers of disease activity. We applied bidimensional zymography (2‐DZ) as an extension of classic monodimensional zymography (1‐DZ) to analyse the complete pattern of isoforms and post‐translational modifications of both MMP‐9 and MMP‐2 present in the sera of MS patients. The enzymes were separated on the basis of their isoelectric points (pI) and apparent molecular weights (Mw) and identified both by comparison with standard enzyme preparations and by Western blot analysis. Two MMP‐2 isoforms, and at least three different isoforms and two different states of organization of MMP‐9 (the multimeric MMP‐9 and the N‐GAL‐MMP‐9 complex) were observed. In addition, 2‐DZ revealed for the first time that all MMP‐9 and MMP‐2 isoforms actually exist in the form of charge variants: four or five variants in the N‐GAL complex, more charge variants in the case of MMP‐9; and five to seven charge variants for MMP‐2. Charge variants were also observed in recombinant enzymes and, after concentration, also in sera from healthy individuals. Sialylation (MMP‐9) and phosphorylation (MMP‐2) contributed to molecular heterogeneity. The detection of charge variants of MMP‐9 and MMP‐2 in MS serum samples illustrates the power of 2‐DZ and demonstrates that in previous studies MMP mixtures, rather than single molecules, were analysed. These observations open perspectives for better diagnosis and prognosis of many diseases and need to be critically interpreted when applying other methods for MS and other diseases.

Glycosylation of matrix metalloproteases and tissue inhibitors: present state, challenges and opportunities.

Current knowledge about the glycosylation of matrix metalloproteinases (MMPs) and the inhibitors of metalloproteinases (TIMPs) is reviewed. Whereas structural and functional aspects of the glycobiology of many MMPs is unknown, research on MMP-9 and MMP-14 glycosylation reveals important functional implications, such as altered inhibitor binding and cellular localization. This, together with the fact that MMPs contain conserved and many potential attachment sites for N-linked and O-linked oligosaccharides, proves the need for further studies on MMP glycobiology.

On the structure and functions of gelatinase B/Matrix metalloproteinase-9 in neuroinflammation

The blood-brain barrier (BBB) is a specific structure that is composed of two basement membranes (BMs) and that contributes to the control of neuroinflammation. As long as the BBB is intact, extravasated leukocytes may accumulate between two BMs, generating vascular cuffs. Specific matrix metalloproteinases, MMP-2 and MMP-9, have been shown to cleave BBB beta-dystroglycan and to disintegrate thereby the parenchymal BM, resulting in encephalomyelitis. This knowledge has been added to the molecular basis of the REGA model to understand the pathogenesis of multiple sclerosis, and it gives further ground for the use of MMP inhibitors for the treatment of acute neuroinflammation. MMP-9 is associated with central nervous system inflammation and occurs in various forms: monomers and multimers. None of the various neurological and neuropathologic functions of MMP-9 have been associated with either molecular structure or molecular form, and therefore, in-depth structure-function studies are needed before medical intervention with MMP-9-specific inhibitors is initiated.