Jia-huai Wang

Structural basis for allostery in integrins and binding to fibrinogen-mimetic therapeutics.

Integrins are important adhesion receptors in all Metazoa that transmit conformational change bidirectionally across the membrane. Integrin α and β subunits form a head and two long legs in the ectodomain and span the membrane. Here, we define with crystal structures the atomic basis for allosteric regulation of the conformation and affinity for ligand of the integrin ectodomain, and how fibrinogen-mimetic therapeutics bind to platelet integrin αIIbβ3. Allostery in the β3 I domain alters three metal binding sites, associated loops and α1- and α7-helices. Piston-like displacement of the α7-helix causes a 62° reorientation between the β3 I and hybrid domains. Transmission through the rigidly connected plexin/semaphorin/integrin (PSI) domain in the upper β3 leg causes a 70 Å separation between the knees of the α and β legs. Allostery in the head thus disrupts interaction between the legs in a previously described low-affinity bent integrin conformation, and leg extension positions the high-affinity head far above the cell surface.

Structures of the αL I Domain and Its Complex with ICAM-1 Reveal a Shape-Shifting Pathway for Integrin Regulation

The structure of the I domain of integrin alpha L beta 2 bound to the Ig superfamily ligand ICAM-1 reveals the open ligand binding conformation and the first example of an integrin-IgSF interface. The I domain Mg2+ directly coordinates Glu-34 of ICAM-1, and a dramatic swing of I domain residue Glu-241 enables a critical salt bridge. Liganded and unliganded structures for both high- and intermediate-affinity mutant I domains reveal that ligand binding can induce conformational change in the alpha L I domain and that allosteric signals can convert the closed conformation to intermediate or open conformations without ligand binding. Pulling down on the C-terminal alpha 7 helix with introduced disulfide bonds ratchets the beta 6-alpha 7 loop into three different positions in the closed, intermediate, and open conformations, with a progressive increase in affinity.

HIV-1 broadly neutralizing antibody extracts its epitope from a kinked gp41 ectodomain region on the viral membrane

Although rarely elicited during natural human infection, the most broadly neutralizing antibodies (BNAbs) against diverse human immunodeficiency virus (HIV)-1 strains target the membrane-proximal ectodomain region (MPER) of viral gp41. To gain insight into MPER antigenicity, immunogenicity, and viral function, we studied its structure in the lipid environment by a combination of nuclear magnetic resonance (NMR), electron paramagnetic resonance (EPR), and surface plasmon resonance (SPR) techniques. The analyses revealed a tilted N-terminal alpha helix (aa 664-672) connected via a short hinge to a flat C-terminal helical segment (675-683). This metastable L-shaped structure is immersed in viral membrane and, therefore, less accessible to immune attack. Nonetheless, the 4E10 BNAb extracts buried W672 and F673 after initial encounter with the surface-embedded MPER. The data suggest how BNAbs may perturb tryptophan residue-associated viral fusion involving the mobile N-terminal MPER segment and, given conservation of MPER sequences in HIV-1, HIV-2, and SIV, have important implications for structure-guided vaccine design.

2 å crystal structure of an extracellular fragment of human CD40 ligand

BACKGROUND The CD40 ligand (CD40L) is a member of the tumor necrosis factor (TNF) family of proteins and is transiently expressed on the surface of activated T cells. The binding of CD40L to CD40, which is expressed on the surface of B cells, provides a critical and unique pathway of cellular activation resulting in antibody isotype switching, regulation of apoptosis, and B cell proliferation and differentiation. Naturally occurring mutations of CD40L result in the clinical hyper-IgM syndrome, characterized by an inability to produce immunoglobulins of the IgG, IgA and IgE isotypes. RESULTS We have determined the crystal structure of a soluble extracellular fragment of human CD40L to 2 A resolution and with an R factor of 21.8%. Although the molecule forms a trimer similar to that found for other members of the TNF family, such as TNF alpha and lymphotoxin-alpha, and exhibits a similar overall fold, there are considerable differences in several loops including those predicted to be involved in CD40 binding. CONCLUSIONS The structure suggests that most of the hyper-IgM syndrome mutations affect the folding and stability of the molecule rather than the CD40-binding site directly. Despite the fact that the hyper-IgM syndrome mutations are dispersed in the primary sequence, a large fraction of them are clustered in space in the vicinity of a surface loop, close to the predicted CD40-binding site.

Crystal structure of the human CD4 N-terminal two-domain fragment complexed to a class II MHC molecule

The structural basis of the interaction between the CD4 coreceptor and a class II major histocompatibility complex (MHC) is described. The crystal structure of a complex containing the human CD4 N-terminal two-domain fragment and the murine I-Ak class II MHC molecule with associated peptide (pMHCII) shows that only the “top corner” of the CD4 molecule directly contacts pMHCII. The CD4 Phe-43 side chain extends into a hydrophobic concavity formed by MHC residues from both α2 and β2 domains. A ternary model of the CD4-pMHCII-T-cell receptor (TCR) reveals that the complex appears V-shaped with the membrane-proximal pMHCII at the apex. This configuration excludes a direct TCR–CD4 interaction and suggests how TCR and CD4 signaling is coordinated around the antigenic pMHCII complex. Human CD4 binds to HIV gp120 in a manner strikingly similar to the way in which CD4 interacts with pMHCII. Additional contacts between gp120 and CD4 give the CD4–gp120 complex a greater affinity. Thus, ligation of the viral envelope glycoprotein to CD4 occludes the pMHCII-binding site on CD4, contributing to immunodeficiency.

Crystal structure of the TSP-1 type 1 repeats: a novel layered fold and its biological implication

Thrombospondin-1 (TSP-1) contains three type 1 repeats (TSRs), which mediate cell attachment, glycosaminoglycan binding, inhibition of angiogenesis, activation of TGFβ, and inhibition of matrix metalloproteinases. The crystal structure of the TSRs reported in this article reveals a novel, antiparallel, three-stranded fold that consists of alternating stacked layers of tryptophan and arginine residues from respective strands, capped by disulfide bonds on each end. The front face of the TSR contains a right-handed spiral, positively charged groove that might be the “recognition” face, mediating interactions with various ligands. This is the first high-resolution crystal structure of a TSR domain that provides a prototypic architecture for structural and functional exploration of the diverse members of the TSR superfamily.

Structure of a heterophilic adhesion complex between the human CD2 and CD58 (LFA-3) counterreceptors.

Interaction between CD2 and its counterreceptor, CD58 (LFA-3), on opposing cells optimizes immune recognition, facilitating contacts between helper T lymphocytes and antigen-presenting cells as well as between cytolytic effectors and target cells. Here, we report the crystal structure of the heterophilic adhesion complex between the amino-terminal domains of human CD2 and CD58. A strikingly asymmetric, orthogonal, face-to-face interaction involving the major beta sheets of the respective immunoglobulin-like domains with poor shape complementarity is revealed. In the virtual absence of hydrophobic forces, interdigitating charged amino acid side chains form hydrogen bonds and salt links at the interface (approximately 1200 A2), imparting a high degree of specificity albeit with low affinity (K(D) of approximately microM). These features explain CD2-CD58 dynamic binding, offering insights into interactions of related immunoglobulin superfamily receptors.

Structural Basis of CD8 Coreceptor Function Revealed by Crystallographic Analysis of a Murine CD8αα Ectodomain Fragment in Complex with H-2Kb

Abstract The crystal structure of the two immunoglobulin variable–like domains of the murine CD8αα homodimer complexed to the class I MHC H-2K b molecule at 2.8 A resolution shows that CD8αα binds to the protruding MHC α3 domain loop in an antibody-like manner. Comparison of mouse CD8αα/H-2K b and human CD8αα/HLA-A2 complexes reveals shared as well as species-specific recognition features. In both species, coreceptor function apparently involves the participation of CD8 dimer in a bidentate attachment to an MHC class I molecule in conjunction with a T cell receptor without discernable conformational alteration of the peptide or MHC antigen-presenting platform.

Structure of the influenza virus A H5N1 nucleoprotein: implications for RNA binding, oligomerization, and vaccine design

The threat of a pandemic outbreak of influenza virus A H5N1 has become a major concern worldwide. The nucleoprotein (NP) of the virus binds the RNA genome and acts as a key adaptor between the virus and the host cell. It, therefore, plays an important structural and functional role and represents an attractive drug target. Here, we report the 3.3‐Å crystal structure of H5N1 NP, which is composed of a head domain, a body domain, and a tail loop. Our structure resolves the important linker segments (residues 397–401, 429–437) that connect the tail loop with the remainder of the molecule and a flexible, basic loop (residues 73–91) located in an arginine‐rich groove surrounding Arg150. Using surface plasmon resonance, we found the basic loop and arginine‐rich groove, but mostly a protruding element containing Arg174 and Arg175, to be important in RNA binding by NP. We also used our crystal structure to build a ring‐shaped assembly of nine NP subunits to model the miniribonucleo‐protein particle previously visualized by electron microscopy. Our study of H5N1 NP provides insight into the oligomerization interface and the RNA‐binding groove, which are attractive drug targets, and it identifies the epitopes that might be used for universal vaccine development.—Ng, A. K.‐L., Zhang, H., Tan, K., Li, Z., Liu, J.‐h., Chan, P. K.‐S., Li, S.‐M., Chan, W.‐Y., Au, S. W.‐N., Joachimiak, A., Walz, T., Wang, J.‐H., Shaw, P.‐C. Structure of the influenza virus A H5N1 nucleoprotein: implications for RNA binding, oligomerization, and vaccine design. FASEB J. 22, 3638–3647 (2008)

Structural specializations of immunoglobulin superfamily members for adhesion to integrins and viruses

Summary: The circulation and migration of leukocytes are critical for immune surveillance and immune response to infection or injury. The key step of leukocyte recruitment involves the adhesion between immunoglobulin superfamily (IgSF) proteins on endothelium and integrin molecules on leukocyte surfaces. Some of the IgSF members are subverted as virus receptors. Four crystal structures of N‐terminal two‐domain fragments of these IgSF proteins have been determined: intercellular adhesion molecule‐1 (IC.AM‐l), ICAM‐2, vascular adhesion molecule‐1 (VCAM‐1), and mucosal address in cell adhesion molecule‐1 (MAdCAM‐1), An acidic residue near the bottom of domain 1 plays a key role in integrin binding. For ICAM‐1 and ICAM‐2, this glutamic add residue is located on a flat surface, complementary to the flat surface of the 1 domain of the integrin to which they bind, lymphocyte function‐associated antigen‐1 (LFA‐1). For VCAM‐1 and MAdCAM‐1, the acidic residue is aspartic acid, and it resides on a protruded CD loop which may be complementary to a more pocket‐like structure in the a4 integrins to which they bind, which lack I domains. A number of unique structural features of this subclass of IgSF have been identified which are proposed to consolidate the domain structure to resist force during adhesion to integrins. Different mechanisms are proposed for the different CAMs to present the integrin‐binding surface toward the opposing cell for adhesion, and prevent ds interaction with integrins on the same cell. Finally, CD4 and ICAM‐1 are compared in the context of ligand binding and virus binding, which shows how human immunodeficiency virus and rhinovirus fit well with the distinct structural feature of their cognate receptors.