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Revision as of 12:43, 17 November 2009

spinqualitylabelsall models PDB ID 2oxu Show:Asymmetric Unit Biological Assembly Drag the structure with the mouse to rotate   Export Animated Image
2oxu, resolution 1.24Å ()
Ligands:	,
Gene:	MMP12, HME (Homo sapiens)
Activity:	Macrophage elastase, with EC number 3.4.24.65
Related:	1y93, 1rmz, 2oxw, 2oxz, 2oy2, 2oy4
Structural annotation: Resources: InterPro : Ipr000585, Ipr006025, Ipr002477, Ipr001818, Ipr006026 Pfam : PF00413 UniProt : P39900
Functional annotation: Cellular component: proteinaceous extracellular matrix Biological process: metabolic process proteolysis cell motility Molecular function: metallopeptidase activity catalytic activity metal ion binding macrophage elastase activity peptidase activity hydrolase activity metalloendopeptidase activity calcium ion binding zinc ion binding
Evolutionary conservation: Toggle Conservation Colors: Rows = identical sequences: Further Information: Caveats, Explanation, Complete Results at ConSurfDB
Resources:	FirstGlance, OCA, RCSB, PDBsum
Coordinates:	save as pdb, mmCIF, xml

Matrix Metallopeptidase 12 : 2oxu.

Introduction

2oxu is a human protease. It belongs to the Matrix Metalloproteinase’s family (MMPs). Theses MMPs are secreted as inactive proproteins and then activated after a cleavage by extracellular proteinases. MMPs are sorted into 17 classes depending on their localization in the cell, and on their substrates. For instance, 2Oxu is a macrophage metalloelastane indexed in MMP12 subfamily. This hydrolysis involves two cofactors: and . Zn2+ atoms are part of the enzyme whereas Ca2+ atoms are hydrogen bounded to the backbone of the protein. In healthy cells, 2oxu is implied in tissue remodelling and cell signalling. Its role is to allow the migration of the macrophages in tissues by hydrolysing soluble and insoluble elastin of the extracellular matrix. Because of its activity, this protein is also involved in metastasis and tumor development; that's why it is considered as an important target for drug therapies.

From structural data to the enzymatic mecanism

Thanks to X-ray crystallography, the structure of 2oxu has been solved with 1,24 Å resolution. This enzyme consists of and organized like as you can see on the J-mol figure.

The hydrolysis of the Substrate can be divided in four essential events:

1- Substrate's fixation

2- Substrate's cleavage

3- First fragment's release

4- Second fragment's release

The substrate polypeptide sequence which is recognized by the enzyme is the following one : ProGlnGly(206)IleAlaGly(209). It is known to be cleaved between Gly(206) and ILE. Before the addition of the substrate, the active site is closed.

A video of this hydrolisis is available online [1]

Substrate's fixation

The is composed by one Glu residue near 3 His residues which maintain a . One of them is as well bound to the Glu residue thanks to a hydrogen bond. The second Zn2+ atom is not involved in the active site. At first, the Gly 206 residue of the substrate binds the active site 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. Then, the Ala 182 residue of the enzyme makes a hydrogen bond with the NH group of the substrate: this allows the substrate to enter the cavity of the catalytic site. The rest of the protein is stabilized by 4 hydrogen bonds with the amino acid located in the cavity.

Substrate's cleavage

A proton of one of the three H2O moves to the Glu219 catalytic site's residue. It creates a hydroxyl group with a high nucleophilic character. That leads to a nucleophilic attack by zinc-coordinated hydroxyl group, on one of the carbonyl group of the substrate (Gly206). It leads to what is called a gem-diol intermediate form of the substrate. Two fragments are then sitting in the cavity: IleAlaGly209 and ProGlnGly206.

First fragment's release

The fragment IleAlaGly is strongly bounded to the enzyme thanks to the bonds that have been created at the fixation's step. But the fragment ProGlnGly just remains in place thanks to a Gly206 monodentate coordination with the Zn atom. Then a water molecule binds this Zn atom: it becomes five coordinated, which facilitates the detachment of the ProGlnGly fragment through an associative ligand exchange mechanism.

Second fragment's release

IleAlaGly remains in the active site but is subjected to a rearrangement. After the release of ProGlnGly, repulsion between positively charged zinc ion and NH3+ (coming from the peptide's cleavage) increases. It forces IlaAlaGly to enter deeper in the substrate's cavity to make hydrophobic interactions. The transfer of this fragment prevents Ala208 to continue binding Pro208. The former bound is broken, and the fragment is no more stabilized. Finally the cavity opens and the fragment is released.

Regulation

One of the two Zn2+ ions is involved in the catalytic site to catalyse the reaction. The second Zn2+ atom and the three Ca2+ binds the enzyme to stabilize its 3D strucure. Ca2+ concentrational change may regulate MMP12 activity.

Some structural modification of 2oxu, can be a way to lower it's enzymatic activity :

• Glu 219 play a very important rôle in the substrate's fixation : if it is mutated and replaced by an non-ionizable residue, it lowers the enzymatic activity.

• If the ionization of NH2 to NH3+ can be prevented, it won't lead to any charge repulsion with Zn2+ : the substrate won't enter the cavity very deeply and so will remain bound to the enzyme, preventing the next binding with the next substrate.

As we said before, several ionzable residue are found in the catalytic site. These ionizable residue allow electrostatic interractions between the enzyme and the substrate, thus decreasing the activation energy of the reaction. If these residues are modified, the activation energy increases and the reaction becomes lower.

Research for inhibitors : current stakes

MMPs are thought to play a major role on cell behaviors such as cell proliferation, allowing a tumor to spread for instance. That's the reason why researchers still are working to learn more about the enzyme structure in order to find new ways to inhibit it. Some natural inhibitors have already been found : they are called Tissue Inhibitor of MetalloProteinases (TIMPs) and are sorted into four classes : TIMP-1, TIMP-2, TIMP-3 and TIMP-4. On the other hand, researchers have successfully produced synthetic inhibitors, containning a chelating group which binds the catalytic zinc atom involved in the catalic site. Common chelating groups include hydroxamates, carboxylates, thiols, and phosphinyls. Hydroxymates are particularly potent inhibitors of MMPs thanks to their bidentate chelation of the zinc atom. A 2oxu inhibitor can also inhibit other MMPs provided that some substitutents are modified to interact with various binding pockets on the MMP of interest : From a a single inhibitor, researchers are able to create more or less specificity toward several enzymes.

References

http://www.nlm.nih.gov/cgi/mesh/2009/MB_cgi?mode=&term=Matrix+metalloproteinases