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From Proteopedia

Matrix metalloproteinase-8

MMP-8, also called, Neutrophil collagenase or Collagenase 2, is a zinc-dependent and calcium-dependent enzyme mainly produced by neutrophils. It belongs to the matrix metalloproteinase (MMP) family which is involved in the breakdown of extracellular matrix in embryonic development, reproduction, and tissue remodeling, as well as in disease processes. The gene coding this family is localized on the chromosome 11 of Homo sapiens with 467 residues.^[1]

is the reloading for the initial structure of the catalytic domain of MMP-8. ( Protein Data Bank ID : 2OY4 )

1 Classification
2 Structure and domains
3 Mechanism
4 Inhibitors of MMP-8
- 4.1 Endogenous inhibitors
- 4.2 Synthetic inhibitors
5 Function
6 Disease
- 6.1 Involvement
- 6.2 Therapeutic potential

Classification

EC 3.4.24.34 This classification means that this enzyme:

is an hydrolase: it hydrolyzes covalent bonds
is an endopeptidase: it cleaves peptide bond
cleaves interstitial collagens in the triple helical domain (at a site about three-fourths away from the N-terminus)

The metalloendopeptidase activity is defined by a mechanism in which water acts as a nucleophile, one or two metal ions hold the water molecule in place, and charged amino acid side chains are ligands for the metal ions.^[2] The difference between this classification and EC 3.4.24.7 is that this enzyme cleaves type III collagen more slowly than type I.

(On BRENDA, you can find all pieces of information about the MMP-8 enzyme like, for example, a list of different substrates or inhibitors)

Structure and domains

MMP-8 is composed of several domains: a propeptide, a catalytic domain, a hinge region, and a C-terminal hemopexin-like domain.^[3].

Propeptide

It corresponds to 79 aminoacids, from Phe21 to Met100. The sequence of residue is: FPVSSKEKNTKTVQDYLEKFYQLPSNQYQSTRKNGTNVIVEKLKEMQRFFGLNVTGKPNEETLDMMKKPRCGVPDSGGFM

Catalytic domain

Thanks to X-ray crystallography, the catalytic domain structure has been solved with 1,7 Å resolution (PDB ID : 2OY4).This domain is composed of 157 residues, from Met86 to Gly242, organized in and .The protein folding and especially the zinc environment of the collagenase catalytic domain is very close to the astacins and the snake venom metalloproteinases. The catalytic domain alone has proteolytic activity against other protein substrates and synthetic substrates.^[4]

Subsites

Besides the catalytic site, the MMPs have other sites called subsites which can also interact with the substrates and inhibitors. Conventionally, the subsites on the left of the catalytic Zn2+ are designated as S1, S2, S3, ..., Sn and the ones on the right are known as S1', S2', etc.

One of these subsites, the S1' pocket, is the main subsite for the substrate recognition. This pocket is variable in amino acid composition and depth and can be used to classify the MMPs.

MMP-8 belongs to the class of the intermediate MMPs according to the depth of its .^[5] This pocket is delimited by the Leu193, Val194, His197, Leu214, Tyr216, Tyr219, Ala220 and Arg222 residues.^[6]. Moreover, this pocket is rich in hydrophobic amino acids, what is suitable for binding to the substrates of MMP-8.

CA996 pocket interaction

Ca2+ interactions

This enzyme binds 3 Ca ions, 2 of them in the catalytic domain, which are packed against the top of the beta sheet and have mostly a structural function, stabilizing the catalytic domain.^[4] The residues involved in the Ca996 interactions (coordinate bonds) are .

Zn2+ interactions

The zinc-binding motif HEXGHXXGXXH presents in the catalytic domain is characteristic for the protease activity of MMP-8.

ZN998 pocket interaction

Zn999 : the catalytic zinc

It is involved in the catalytic activity and is situated at the bottom of the active-site. This ion is penta-coordinated with: His197, His201 and His207 of MMP-8 and probably (according to the mechanism model described bellow) with a Gly residue of the substrate and a water molecule. On this you can only see the 3 His of MMP-8 with the Zn999.

Zn998 : the structural zinc

The residues involved in the Zn998 interactions are . The glutamic acid adjacent to the first histidine is essential for catalysis. It should be noted that scientists were unable to exchange or remove this Zinc in their crystals, which is suggesting that there is a tight interaction with MMP-8.^[4]

Hinge domain

It corresponds to a short linker region from G242 to P258, with the following sequence: GLSSNPIQPTGPSTPKP, between the catalytic and the hemopexin domains. The exact role of this domain isn't very well clear but it's known that autoproteolysis could occurred in MMP-8 leading to an unstable protein and different mutants^[7] were made in the hinge region and shown that stability of MMP-8 could be increased, decreased or unchanged. Moreover, sequence alignements of collagenolytic MMPs in this hinge domain reveal that they all have the four prolines in the same positions, suggesting that these prolines could be important for the specific collagenolytic activity.

Hemopexin domain

The hemopexin domain has two conserved cysteines that are disulfide bonded. Mutation of those cysteines to alanines ^[8] or reduction and alkylation destroy collagenolytic activity (K. Suzuki and H.Nagase, unpublished results).^[3] It is essential for the substrate recognition of MMP-8 and the single catalytic domain of MMP-8 is not able to cleave collagen. However, neutrophil collagenase is still able to cleave other substrates. It seems that the collagen binds to two sites on MMP-8 : one in the catalytic site and another in the hemopexin domain. One hypothesis is that when the collagen binds to both sites, its helical structure is destabilized and unwound. Thus, the cleavage site of collagen is accessible and the cleavage reaction can occur.^[9]

Unfortunately, no structure of the full MMP-8 protein has been crystallized yet, but you can see in orange the hemopexin domain of human pro-MMP1 which is very well conserved between these two proteins. In this article Matrix metalloproteinases: structures, evolution, and diversification,Irina Massova, Lakshmi P. Kotra, Rafael Fridman and Shahriar Mobashery, there are good pieces of information on conservations among the MMPs family.

Mechanism

MMP-8 is secreted as inactive proprotein and then activated after a cleavage by extracellular proteinases. Indeed, it can't be activated without removal of the activation peptide. After this protease activation, recent evidences suggest that, there is formation of an intramolecular complex between the Cysteine residue (Cys91) of the propeptide domain and essential zinc atom in the catalytic domain. It is called the Cysteine-switch: it inhibits the action of MMP-8. This discovery is unprecedented in enzymology and offers the opportunity for multiple modes of physiological activation of MMP-8. Moreover, since conditions are different in the diversity of cells and tissues, this may allow a metabolic flexibility in MMP activation control.^[10]

To express collagenolytic activity, MMP-8 needs to have both the catalytic and hemopexin domains. The linker peptide can position the hemopexin domain in such a way that it bends over the active site of the catalytic domain. But understanding how the Hemopexin domain assists in the cleavage of collagen is elusive.^[11] Thus, the collagen would be captured between these two domains. However, the active site cannot accommodate the entire triple helix in a native state. The linker peptide would, by means of its collagen-like conformation, change the quaternary structure of the captured collagen. Interactions between proline residues of the collagenase and a specific region of the collagen would generate a “proline zipper,” resulting in destabilization of the cleavage site area of the collagen. After destabilization, one chain of the triple helix fits in the specificity pocket or to the right of the active-site zinc. At first, the Gly residue of the substrate binds the thanks to the Zn2+ atom. When it binds it takes the place of unstable water molecules and establishes stabilizing interactions with the active site thanks to its C terminal part.^[12] The carboxyl group of the glutamate (GLU 198 in the active site green link above) serves as a general base to draw a proton from the displaced water molecule, thereby facilitating the nucleophilic attack of the water molecule on the carbonyl carbon of the peptide scissile bond. Then, the Alanine residue of the active site makes a hydrogen bond with the NH group of the substrate. Moreover, this NH group becomes the new N-terminus after cleavage.^[13]

The cleavage is at Gly775–Ile776 or Leu776 in each alpha-chain of the collagen molecule^[7] and takes place at neutral pH. It generates fragments that spontaneously lose their helical conformation, denature to gelatin, and become soluble. The gelatin is then susceptible to attack by gelatinases and other proteases.^[14]

There is no crystallized complex of MMP-8 and the collagen, however you can see the complex of MMP-1 and a triple-helical collagen peptide, MMP-1 being very close to MMP-8 it gives an idea of the MMP8-collagen complex.

Inhibitors of MMP-8

Endogenous inhibitors

The tissue inhibitors of metalloproteinases (TIMPs) are specific inhibitors of the whole family of MMPs proteins. Currently, four TIMPs were identified (TIMP-1, TIMP-2, TIMP-3, TIMP-4). They are 21 to 29kDa proteins, contain 2 subdomains (N-ter and C-ter) and have a "wedge-like" shape. This is the N-ter domain which interacts with the catalytic domains of MMPs and impedes their proteolytic activity.^[13] The Cys1 residue is crucial for the inhibitor effect of TIMPs because it can interact with the catalytic zinc of the MMPs. The result is a chelation of the zinc by the N-terminal amino group and the carbonyl group of Cys1.^[15] Moreover, this interaction triggers the expulsion of the water molecule which was bound to the zinc.

No structures of MMP-8 with TIMPs are available on the Protein Data Bank. However, the mechanism of inhibition is common to all the MMPs. To see the interaction between the catalytic domain of MMP-3 and TIMP-1 (in green) click .^[16]

Synthetic inhibitors

Because endogenous TIMPs have a broad spectrum of action over MMPs, researches were conducted to produce engineered TIMPs and modify their affinity for MMPs. For instance, mutation of the Thr2 of TIMP-1 modifies the specificity of this inhibitor as this residue interacts with the S1' pocket of the MMPs.^[17]

Besides the modification of TIMPs, the research for MMPs inhibitors resulted in the discovery of molecules with the ability to interact with the catalytic domain of MMPs. The first developed synthetic inhibitors were molecules that mimic the natural substrates of MMPs combined with a zinc chelating groupement.^[18]

Numerous range of compounds such as hydroxamate, thiol, pyrimidine and phosphorus based-molecules were developed. Those inhibitors inhibit the activity of MMPs by chelating the catalytic zinc like for MMP-8.^[19]

Recently, new range of inhibitors which do not chelate the catalytic zinc were developed. Those compounds target the selectivity regions for substrates of the MMPs rather than binding to the catalytic zinc. For instance, they can interact with the S1' pocket and induce a conformational change like of MMP-8.^[20]

Function

A major function of MMPs is thought to be the removal of ECM in tissue resorption. Because of their recognized roles in disease (see below) the MMPs have long been considered as pharmacological targets, but their multiplicity, associated with their variable expressions in different tissues and their apparently overlapping substrate specificities, have presented considerable challenges to those hoping to design suitable therapeutic inhibitors.

Disease

Involvement

Overexpression of MMP-8, or inadequate control by TIMPs, can be associated with a lot of pathological conditions^[21] because they facilitates penetration of anatomical barriers.

Psoriasis: In patient with psoriasis, highly elevated levels of nitric oxide (NO) are released at the surface of psoriatic plaques. The peroxynitrite-dependent activation of the collagenase MMP-8 may induce the formation of extended rete pegs.^[22]
Sclerosis: MMPs can directly disrupt components of the blood–brain barrier or act on receptors expressed by blood–brain barrier-ECs.^[23]
Osteoarthritis
Rheumatoid arthritis
Osteoporosis
Meningitis: The behavior of MMPs towards the blood-brain barrier can induce the accumulation of blood-derived leukocytes in the central nervous system.
Alzheimer's disease
Tumor growth and metastasis: MMPs play an important role in tumor invasion and progression and their activities are required for increased motility of the epithelial cells and for growth of metastasized tumor cells. Furthermore, MMPs have been shown to be an essential actor in angiogenesis and tumor cell intravasation, both of which are required for tumor cell growth and metastasis.^[24]
Periodontitis: MMP-8 has been associated with the progression of periodontitis, a common inflammatory disease of the supporting structures of the teeth^[25]

What makes this MMP unique is its exclusive pattern of expression in inflammatory conditions: the density of the interstitial collagen network increases in inflamed tissue.^[26]

Therapeutic potential

As potential markers for disease severity in viral respiratory infections^[27]
As an actor in the body's response to wound healing and that the latter is the pathological consequence of the disease with detrimental effects. Indeed, MMP-8 could remove damaged ECM components at the wounded site.^[28]

You can find very interesting pieces of information concerning MMPs related diseases and therapeutic potentials in a nature paper: "Is there new hope for therapeutic matrix metalloproteinase inhibition, Roosmarijn E. Vandenbroucke & Claude Libert".

References

↑ "MMP-8 matrix metallopeptidase 8 (neutrophil collagenase)"
↑ "Metalloendopeptidase activity"
↑ ^3.0 ^3.1 Substrate specificity of MMPs
↑ ^4.0 ^4.1 ^4.2 Bode W, Reinemer P, Huber R, Kleine T, Schnierer S, Tschesche H. The X-ray crystal structure of the catalytic domain of human neutrophil collagenase inhibited by a substrate analogue reveals the essentials for catalysis and specificity. EMBO J. 1994 Mar 15;13(6):1263-9. PMID:8137810
↑ Gupta SP, Patil VM. Specificity of binding with matrix metalloproteinases. EXS. 2012;103:35-56. doi: 10.1007/978-3-0348-0364-9_2. PMID:22642189 doi:http://dx.doi.org/10.1007/978-3-0348-0364-9_2
↑ Verma RP, Hansch C. Matrix metalloproteinases (MMPs): chemical-biological functions and (Q)SARs. Bioorg Med Chem. 2007 Mar 15;15(6):2223-68. Epub 2007 Jan 17. PMID:17275314 doi:http://dx.doi.org/10.1016/j.bmc.2007.01.011
↑ ^7.0 ^7.1 Knauper V, Docherty AJ, Smith B, Tschesche H, Murphy G. Analysis of the contribution of the hinge region of human neutrophil collagenase (HNC, MMP-8) to stability and collagenolytic activity by alanine scanning mutagenesis. FEBS Lett. 1997 Mar 17;405(1):60-4. PMID:9094424
↑ Hirose T, Patterson C, Pourmotabbed T, Mainardi CL, Hasty KA. Structure-function relationship of human neutrophil collagenase: identification of regions responsible for substrate specificity and general proteinase activity. Proc Natl Acad Sci U S A. 1993 Apr 1;90(7):2569-73. PMID:8464863
↑ Piccard H, Van den Steen PE, Opdenakker G. Hemopexin domains as multifunctional liganding modules in matrix metalloproteinases and other proteins. J Leukoc Biol. 2007 Apr;81(4):870-92. Epub 2006 Dec 21. PMID:17185359 doi:http://dx.doi.org/10.1189/jlb.1006629
↑ Van Wart HE, Birkedal-Hansen H. The cysteine switch: a principle of regulation of metalloproteinase activity with potential applicability to the entire matrix metalloproteinase gene family. Proc Natl Acad Sci U S A. 1990 Jul;87(14):5578-82. PMID:2164689
↑ Chung L, Dinakarpandian D, Yoshida N, Lauer-Fields JL, Fields GB, Visse R, Nagase H. Collagenase unwinds triple-helical collagen prior to peptide bond hydrolysis. EMBO J. 2004 Aug 4;23(15):3020-30. Epub 2004 Jul 15. PMID:15257288 doi:http://dx.doi.org/10.1038/sj.emboj.7600318
↑ Piccard H, Van den Steen PE, Opdenakker G. Hemopexin domains as multifunctional liganding modules in matrix metalloproteinases and other proteins. J Leukoc Biol. 2007 Apr;81(4):870-92. Epub 2006 Dec 21. PMID:17185359 doi:http://dx.doi.org/10.1189/jlb.1006629
↑ ^13.0 ^13.1 Visse R, Nagase H. Matrix metalloproteinases and tissue inhibitors of metalloproteinases: structure, function, and biochemistry. Circ Res. 2003 May 2;92(8):827-39. PMID:12730128 doi:http://dx.doi.org/10.1161/01.RES.0000070112.80711.3D
↑ "Neutrophil collagenase"
↑ Nagase H, Visse R, Murphy G. Structure and function of matrix metalloproteinases and TIMPs. Cardiovasc Res. 2006 Feb 15;69(3):562-73. Epub 2006 Jan 5. PMID:16405877 doi:http://dx.doi.org/10.1016/j.cardiores.2005.12.002
↑ [http://www.rcsb.org/pdb/explore/explore.do?structureId=1UEA "Metalloprotease-Inhibitor Complex
↑ Brew K, Nagase H. The tissue inhibitors of metalloproteinases (TIMPs): an ancient family with structural and functional diversity. Biochim Biophys Acta. 2010 Jan;1803(1):55-71. doi: 10.1016/j.bbamcr.2010.01.003. , Epub 2010 Jan 15. PMID:20080133 doi:http://dx.doi.org/10.1016/j.bbamcr.2010.01.003
↑ Jacobsen JA, Major Jourden JL, Miller MT, Cohen SM. To bind zinc or not to bind zinc: an examination of innovative approaches to improved metalloproteinase inhibition. Biochim Biophys Acta. 2010 Jan;1803(1):72-94. doi: 10.1016/j.bbamcr.2009.08.006. , Epub 2009 Aug 25. PMID:19712708 doi:http://dx.doi.org/10.1016/j.bbamcr.2009.08.006
↑ 'Crystal structure of the complex between MMP-8 and a N-hydroxyurea inhibitor'
↑ 'Crystal structure of the complex between MMP-8 and a non-zinc chelating inhibitor'
↑ "Extra Binding Region Induced by Non-Zinc Chelating Inhibitors into the S1′ Subsite of Matrix Metalloproteinase 8"
↑ Savill NJ, Weller R, Sherratt JA. Mathematical modelling of nitric oxide regulation of rete peg formation in psoriasis. J Theor Biol. 2002 Jan 7;214(1):1-16. PMID:11786028 doi:http://dx.doi.org/10.1006/jtbi.2001.2400
↑ Larochelle C, Alvarez JI, Prat A. How do immune cells overcome the blood-brain barrier in multiple sclerosis? FEBS Lett. 2011 Dec 1;585(23):3770-80. doi: 10.1016/j.febslet.2011.04.066. Epub, 2011 May 4. PMID:21550344 doi:http://dx.doi.org/10.1016/j.febslet.2011.04.066
↑ Westermarck J, Kahari VM. Regulation of matrix metalloproteinase expression in tumor invasion. FASEB J. 1999 May;13(8):781-92. PMID:10224222
↑ Liu KZ, Hynes A, Man A, Alsagheer A, Singer DL, Scott DA. Increased local matrix metalloproteinase-8 expression in the periodontal connective tissues of smokers with periodontal disease. Biochim Biophys Acta. 2006 Aug;1762(8):775-80. Epub 2006 Jul 22. PMID:16928431 doi:http://dx.doi.org/10.1016/j.bbadis.2006.05.014
↑ Balbin M, Fueyo A, Knauper V, Pendas AM, Lopez JM, Jimenez MG, Murphy G, Lopez-Otin C. Collagenase 2 (MMP-8) expression in murine tissue-remodeling processes. Analysis of its potential role in postpartum involution of the uterus. J Biol Chem. 1998 Sep 11;273(37):23959-68. PMID:9727011
↑ Brand KH, Ahout IM, de Groot R, Warris A, Ferwerda G, Hermans PW. Use of MMP-8 and MMP-9 to assess disease severity in children with viral lower respiratory tract infections. J Med Virol. 2012 Sep;84(9):1471-80. doi: 10.1002/jmv.23301. PMID:22825827 doi:http://dx.doi.org/10.1002/jmv.23301
↑ Gao M, Nguyen TT, Suckow MA, Wolter WR, Gooyit M, Mobashery S, Chang M. Acceleration of diabetic wound healing using a novel protease-anti-protease combination therapy. Proc Natl Acad Sci U S A. 2015 Dec 8;112(49):15226-31. doi:, 10.1073/pnas.1517847112. Epub 2015 Nov 23. PMID:26598687 doi:http://dx.doi.org/10.1073/pnas.1517847112

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