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ST2/IL33 complex

Introduction

Interleukin 33 is a cytokine member of the IL-1 superfamily. Cytokines are proteins involved in cell signaling. Their role is to regulate the function and the activity of other cells. IL-33 is involved in innate and adaptive immune responses.

In 2005, IL-33 was identified as a ligand for the transmembrane receptor ST2 and it IL-1 receptor accessory protein (IL-1RAcP), both members of the interleukin-1 receptor family. IL-33/ST2 signaling is involved in T-cell immune responses.

We will focuse on the interaction bewteen IL33 and the ST2 ectodomain (as you can see ).

Function

Caracteristics of IL-33:

IL-33 is constitutively expressed in several cells, such as epithelial or endothelial cells. IL-33 is also expressed in an inducible way by immune cells. In this case, the constitutive expression of IL-33 is very low or absent. In mast cells, the expression of IL-33 is induced by the calcium, but the mechanisms are still unclear. IL-33 is secreted in damaged tissues, where it activates the immune response.

Target cells:

ST2 exists in a soluble form (sST2) and a transmembrane form (ST2L). The both forms can interact with IL-33. ST2L are expressed in T lymphocytes, when they are specializing into Th2 cells (T helper type 2 cells, a specific type of T lymphocytes). This specialization occurs in the presence of IL4, expected to be secreted by polynuclear basophils.

IL-33 interacts with the ectodomain of ST2L. This interaction provokes the recruitment of the myeloid differentiation primary-response protein 88 (MYD88) complex, which is involved in the immune response against commune viral infections and some bacterial infections.

When IL-33 interacts with the sST2, it inhibits the fixation of IL-33 of the ectodomain of ST2.

Structure

Understanding:

The understanding of the interaction of IL-33 with its receptors has been discovered thanks to the determination of the crystal structure of IL-33 in complex with ectodomain of ST2.

Besides, the combination of crystallography and small-angle X-ray-scattering methods reveal that ST2 has a very flexible conformation. In fact, ST2 is constituted of three IgG-like domains (D1 to D3) as highlighted here. D1 and D2 gather to form a single D1D2 module, connected through a linker with the D3 domain. ST2 contains also three residues linked with NAG.allowed by the flexibility between the D3 and D1D2 module (domains of ST2), contrary to IL-1RAcP.

This conformational specificity provides a capactity of ligand-binding with IL-33. Moreover, the rigidity of IL-1RAcP explains that it can not bind the IL-33 ligand directly.

Overall structure:

In humans, IL-33 in its full length is composed of 270 residues and is biologically active. The model includes IL-33 residues Ser117 to Ser268 and ST2 residues Ser21 to Arg317.

The structure of IL-33 consists in a 12-stranded β-trefoil loops with changing conformations. Specific loops, such as the β4-β5 loop, are involved in the interaction with the accessory receptor IL-1RAcP when IL-33 is bound to ST2.

IL-33/ST2 interactions:

In the complex, IL-33 interacts with the three domains of ST2. The binding interface is very large and composed of two separate sites.

In the first binding site, thirteen IL-33 residues from β-loops are in contact with the D1D2 module of ST2: the four marked acids residues of IL-33 form a salt-bridge with five marked ST2 residues respectively. Besides, Glu144 and Asp149 form hydrogen bonds with main-chain atoms of ST2. IL-33 mutation of one of the acid residues (144, 148, 149 and 244) highly decreases the affinity of ST2 for IL-33.

In the second binding site, eight IL-33 residues from β-strands interact with the D3 domain of ST2.

There are both hydrophobic and hydrophilic interactions. Residues of IL-33 form an hydrophobic cluster (IL-33 residues Tyr163 and Leu182 and ST2 residues Leu246, Leu306, and Leu311). A salt-bridge interaction occurs between acidic residue Glu165 and Arg313 of ST2.

References

1. Xi Liua, Michal Hammelb, Yanfeng Hea, John A. Tainerc,d, U-Ser Jenge, Linqi Zhangf, Shuying Wangg, and Xinquan Wanga Structural insights into the interaction of IL-33 with its receptors (2013) DOI: 10.1073/pnas.1308651110

2. Ananda S. Mirchandani, Robert J. Salmond, Foo Y. Interleukin-33 and the function of innate lymphoid cells (2012) DOI: 10.1016/j.it.2012.04.005

3. Rahul Kakkar & Richard T. Lee. The IL-33/ST2 pathway: therapeutic target and novel biomarker (2008) DOI: 10.1038/nrd2660

4. Lécart S, Lecointe N, Subramaniam A, Alkan S, Ni D, Chen R, Boulay V, Pène J, Kuroiwa K, Tominaga S, Yssel H. Activated, but not resting human Th2 cells, in contrast to Th1 and T regulatory cells, produce soluble ST2 and express low levels of ST2L at the cell surface. http://www.ncbi.nlm.nih.gov/pubmed/12355452

5. Chia-Lin Hsu and Paul J Bryce. Inducible IL-33 expression by mast cells is regulated by a calcium-dependent pathway. http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3541686/

LIEN VERT POUR FAIRE AFFICHER LE DEGRADE DE COULEUR DE N TER A C TER

(schéma pour code couleur).

Lien vert pour afficher les deux protéines :

ST2 domain IL3

Lien pour faire apparaitre les trois résidus de ST2 liés chacun à un NAG : Lien pour faire apparaitre le site 1 d'interaction entre ST2 et IL33 : Faire apparaitre les feuillets beta de IL33 : Lien pour faire apparaitre le site 2 d'interaction entre ST2 et IL33 : Lien pour faire apparatire l'hélice alpha de IL33 : Lien pour la poche hydrophobe de st2 : Lien pour les domaines D1 D2 D3 :

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Caroline Cuer

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Revision as of 12:21, 8 January 2015

ST2/IL33 complex

Introduction

Function

Structure

References

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@@ Line 16: / Line 16: @@
 [[Caracteristics of IL-33:]]
-IL-33 is consitutively expressed in several cells, such as epithelial or endothelial cells. IL-33 is also expressed in an inducible way by immune cells. In this case, the consitutive expression of IL-33 is very low or absent.
+IL-33 is constitutively expressed in several cells, such as epithelial or endothelial cells. IL-33 is also expressed in an inducible way by immune cells. In this case, the constitutive expression of IL-33 is very low or absent. In mast cells, the expression of IL-33 is induced by the calcium, but the mechanisms are still unclear. IL-33 is secreted in damaged tissues, where it activates the immune response.
 [[Target cells:]]
-ST2 exists in a soluble form (sST2) and a transmembrane form (ST2L). We will focuse on the transmembrane form, which interacts with IL33. ST2L are expressed in T lymphocytes, when they are specialising into Th2 cells (T helper type 2 cells, a specific type of T lymphocytes). This specialisation occurs in the presence of IL4, expeted to be secreted by polynuclear basophils.
+ST2 exists in a soluble form (sST2) and a transmembrane form (ST2L). The both forms can interact with IL-33. ST2L are expressed in T lymphocytes, when they are specializing into Th2 cells (T helper type 2 cells, a specific type of T lymphocytes). This specialization occurs in the presence of IL4, expected to be secreted by polynuclear basophils.
-IL-33 is an extracellular cytokine involved in the polarization of Th2 cells and activation of other immune cells, such as basophils and eosinophils.
-expliquer type 2 immune response
-Recently, it has been discovered that type 2 innate lymphoid cells (ILC2s) are major targets of IL-33. Indeed, when ILC2s is stimulated by IL-33, ILC2s show high levels of ST2 and release high quantities of Th2 cytokines. It initiates type 2 immune responses during allergic diseases or against helminth infection.
+IL-33 interacts with the ectodomain of ST2L. This interaction provokes the recruitment of the myeloid differentiation primary-response protein 88 (MYD88) complex, which is involved in the immune response against commune viral infections and some bacterial infections.
+When IL-33 interacts with the sST2, it inhibits the fixation of IL-33 of the ectodomain of ST2.
 == Structure ==
-Understanding:
-The understanding of the interaction of IL-33 with its receptors has been discovered thanks to the determination of the crystal structure of IL-33 in complex with ectodomain of ST2 as shown here.
+[[Understanding:]]
-Besides, the combination of crystallography and small-angle X-ray-scattering methods reveal that ST2 has a very flexible conformation allowed by the flexibility between the D3 and D1D2 module (domains of ST2), contrary to IL-1RAcP.
+The understanding of the interaction of IL-33 with its receptors has been discovered thanks to the determination of the crystal structure of IL-33 in complex with ectodomain of ST2.
-This conformational specificity provides a structural view of ligand-binding with IL-1 primary receptors. Moreover, the rigidity of IL-1RAcP explains that it can not bind ligand directly.
+Besides, the combination of crystallography and small-angle X-ray-scattering methods reveal that ST2 has a very flexible conformation. In fact, ST2 is constituted of three IgG-like domains (D1 to D3) as highlighted here. D1 and D2 gather to form a single D1D2 module, connected through a linker with the D3 domain. ST2 contains also three residues linked with NAG.allowed by the flexibility between the D3 and D1D2 module (domains of ST2), contrary to IL-1RAcP.
+This conformational specificity provides a capactity of ligand-binding with IL-33. Moreover, the rigidity of IL-1RAcP explains that it can not bind the IL-33 ligand directly.
 Overall structure:
 In humans, IL-33 in its full length is composed of 270 residues and is biologically active.
-The model includes IL-33 residues Ser117 to Asn171, Gly179 to Val252, and Glu261 to Ser268 and ST2 residues Ser21 to Ser51, Ser56 to Lys223, Asn232 to Gly271, and Gly279 to Arg317.
+The model includes IL-33 residues Ser117 to Ser268 and ST2 residues Ser21 to Arg317.
+The structure of IL-33 consists in a 12-stranded β-trefoil loops with changing conformations. Specific loops, such as the β4-β5 loop, are involved in the interaction with the accessory receptor IL-1RAcP when IL-33 is bound to ST2.
-The structure of IL-33 consists in a 12-stranded β-trefoil loops with changing conformations. Specific loops, such as the β4-β5 loop, are involved in the interaction with the accessory receptor IL-1RAcP when IL-33 is bind to ST2.
-ST2 is constituted of three IgG-like domains (D1 to D3) as highlighted here. D1 and D2 gather to form a single D1D2 module, connected through a linker with the D3 domain.
@@ Line 54: / Line 51: @@
 In the complex, IL-33 interacts with the three domains of ST2. The binding interface is very large and composed of two separate sites.
-In the first binding site, thirteen IL-33 residues from  β-loops are in contact with the D1D2 module of ST2: Glu144, Glu148, Asp149, and Asp244 form a bridge with ST2 residues Arg38, Lys22, Arg198, and Arg35, respectively. Besides, Glu144 and Asp149 form hydrogen bonds with main-chain atoms of ST2.
+In the first binding site, thirteen IL-33 residues from β-loops are in contact with the D1D2 module of ST2: the four marked acids residues of IL-33 form a salt-bridge with five marked ST2 residues respectively. Besides, Glu144 and Asp149 form hydrogen bonds with main-chain atoms of ST2. IL-33 mutation of one of the acid residues (144, 148, 149 and 244) highly decreases the affinity of ST2 for IL-33.
+In the second binding site, eight IL-33 residues from β-strands interact with the D3 domain of ST2.
+There are both hydrophobic and hydrophilic interactions. Residues of IL-33 form an hydrophobic cluster (IL-33 residues Tyr163 and Leu182 and ST2 residues Leu246, Leu306, and Leu311). A salt-bridge interaction occurs between acidic residue Glu165 and Arg313 of ST2.
-In the second binding site, eight IL-33 residues from β-strands interact with the  D3 domain of ST2.
-There are both hydrophobic and hydrophilic interactions. Residues of IL-33 form an hydrophobic cluster (Tyr164 and Leu182 and ST2 residues Leu246, Leu306, and Leu311). A salt-bridge interaction occurs between acidic residue Glu165 and Arg313 of ST2.