Structure-function of the putative I-domain within the integrin beta 2 subunit

Magnesium Deficiency and Cardiometabolic Disease

Magnesium (Mg²⁺) has many physiological functions within the body. These include important roles in maintaining cardiovascular functioning, where it contributes to the regulation of cardiac excitation-contraction coupling, endothelial functioning and haemostasis. The haemostatic roles of Mg²⁺ impact upon both the protein and cellular arms of coagulation. In this review, we examine how Mg²⁺ homeostasis is maintained within the body and highlight the various molecular roles attributed to Mg²⁺ in the cardiovascular system. In addition, we describe how nutritional and/or disease-associated magnesium deficiency, seen in some metabolic conditions, has the potential to influence cardiac and vascular outcomes. Finally, we also examine the potential for magnesium supplements to be employed in the prevention and treatment of cardiovascular disorders and in the management of cardiometabolic health.

RTX Toxins Ambush Immunity's First Cellular Responders

The repeats-in-toxin (RTX) family represents a unique class of bacterial exoproteins. The first family members described were toxins from Gram-negative bacterial pathogens; however, additional members included exoproteins with diverse functions. Our review focuses on well-characterized RTX family toxins from Aggregatibacteractinomycetemcomitans (LtxA), Mannheimiahaemolytica (LktA), Bordetella pertussis (CyaA), uropathogenic Escherichia coli (HlyA), and Actinobacillus pleuropneumoniae (ApxIIIA), as well as the studies that have honed in on a single host cell receptor for RTX toxin interactions, the β₂ integrins. The β₂ integrin family is composed of heterodimeric members with four unique alpha subunits and a single beta subunit. β₂ integrins are only found on leukocytes, including neutrophils and monocytes, the first responders to inflammation following bacterial infection. The LtxA, LktA, HlyA, and ApxIIIA toxins target the shared beta subunit, thereby targeting all types of leukocytes. Specific β₂ integrin family domains are required for the RTX toxin’s cytotoxic activity and are summarized here. Research examining the domains of the RTX toxins required for cytotoxic and hemolytic activity is also summarized. RTX toxins attack and kill phagocytic immune cells expressing a single integrin family, providing an obvious advantage to the pathogen. The critical question that remains, can the specificity of the RTX-β₂ integrin interaction be therapeutically targeted?

A role for specific collagen motifs during wound healing and inflammatory response of fibroblasts in the teleost fish gilthead seabream

Specific sites and sequences in collagen to which cells can attach, either directly or through protein intermediaries, were identified using Toolkits of 63-amino acid triple-helical peptides and specific shorter GXX'GEX″ motifs, which have different intrinsic affinity for integrins that mediate cell adhesion and migration. We have previously reported that collagen type I (COL-I) was able to prime in vitro the respiratory burst and induce a specific set of immune- and extracellular matrix-related molecules in phagocytes of the teleost fish gilthead seabream (Sparus aurata L.). It was also suggested that COL-I would provide an intermediate signal during the early inflammatory response in gilthead seabream. Since fibroblasts are highly involved in the initiation of wound repair and regeneration processes, in the present study SAF-1 cells (gilthead seabream fibroblasts) were used to identify the binding motifs in collagen by end-point and real-time cell adhesion assays using the collagen peptides and Toolkits. We identified the collagen motifs involved in the early magnesium-dependent adhesion of these cells. Furthermore, we found that peptides containing the GFOGER and GLOGEN motifs (where O is hydroxyproline) present high affinity for SAF-1 adhesion, expressed as both cell number and surface covering, while in cell suspensions, these motifs were also able to induce the expression of the genes encoding the proinflammatory molecules interleukin-1β and cyclooxygenase-2. These data suggest that specific collagen motifs are involved in the regulation of the inflammatory and healing responses of teleost fish.

Expression, activation, and function of integrin alphaMbeta2 (Mac-1) on neutrophil-derived microparticles

Leukocyte-derived microparticles (MPs) are markers of cardiovascular diseases and contribute to pathogenesis by their interaction with various cell types. The presence and activation state of a multifunctional leukocyte receptor, integrin alpha(M)beta(2) (CD11b/18), on MPs derived from human neutrophils (PMNs) were examined. alpha(M)beta(2) expression was significantly enhanced on MPs derived from stimulated compared with resting PMNs. Furthermore, alpha(M)beta(2) on MPs from stimulated but not resting PMNs was in an activated conformation because it was capable of binding activation-specific monoclonal antibodies (CBRM1/5 and mAb24) and soluble fibrinogen. MPs expressing active alpha(M)beta(2) interacted with and were potent activators of resting platelets as assessed by induction of P-selectin expression and activation of alpha(IIb)beta(3). With the use of function-blocking antibodies and MPs obtained from alpha(M)(-/-)-deficient mice, we found that engagement of GPIbalpha on platelets by alpha(M)beta(2) on MPs plays a pivotal role in MP binding. Platelet activation by MPs occurs by a pathway dependent on Akt phosphorylation. PSGL-1/P-selectin interaction also is involved in the conjugation of MPs to platelets, and the combination of blocking reagents to both alpha(M)beta(2)/GPIbalpha and to PSGL-1/P-selectin completely abrogates MP-induced platelet activation. Thus, cooperation of these 2 receptor/counterreceptor systems regulates the prothrombotic properties of PMN-derived MPs.

HIV transfer between CD4 T cells does not require LFA-1 binding to ICAM-1 and is governed by the interaction of HIV envelope glycoprotein with CD4

Background

Cell-to-cell HIV transmission requires cellular contacts that may be in part mediated by the integrin leukocyte function antigen (LFA)-1 and its ligands intercellular adhesion molecule (ICAM)-1, -2 and -3. The role of these molecules in free virus infection of CD4 T cells or in transinfection mediated by dendritic cells (DC) has been previously described. Here, we evaluate their role in viral transmission between different HIV producing cells and primary CD4 T cells.

Results

The formation of cellular conjugates and subsequent HIV transmission between productively infected MOLT cell lines and primary CD4 T cells was not inhibited by a panel of blocking antibodies against ICAM-1, ICAM-3 and α and β chains of LFA-1. Complete abrogation of HIV transmission and formation of cellular conjugates was only observed when gp120/CD4 interactions were blocked. The dispensable role of LFA-1 in HIV transmission was confirmed using non-lymphoid 293T cells, lacking the expression of adhesion molecules, as HIV producing cells. Moreover, HIV transmission between infected and uninfected primary CD4 T cells was abrogated by inhibitors of gp120 binding to CD4 but was not inhibited by blocking LFA-1 binding to ICAM-1 or ICAM-3. Rather, LFA-1 and ICAM-3 mAbs enhanced HIV transfer. All HIV producing cells (including 293T cells) transferred HIV particles more efficiently to memory than to naive CD4 T cells.

Conclusion

In contrast to other mechanisms of viral spread, HIV transmission between infected and uninfected T cells efficiently occurs in the absence of adhesion molecules. Thus, gp120/CD4 interactions are the main driving force of the formation of cellular contacts between infected and uninfected CD4 T cells whereby HIV transmission occurs.

Monomeric expression of bovine beta2-integrin subunits reveals their role in Mannheimia haemolytica leukotoxin-induced biological effects

The ruminant-specific leukotoxin (Lkt) of Mannheimia haemolytica is the key virulence factor contributing to the pathogenesis of lung injury in bovine pneumonic pasteurellosis. Previous studies by us and others indicate that M. haemolytica Lkt binds to CD18, the beta subunit of bovine beta(2)-integrins on leukocytes, and that the species specificity of Lkt-induced effects is resident in the beta subunit CD18 and not in the alpha subunit CD11. However, Lkt also binds to the CD11a subunit of LFA-1. Furthermore, antibodies specific for CD18 or CD11a inhibit signaling events leading to elevation of intracellular [Ca(2+)], tyrosine phosphorylation of the cytosolic domain of CD18, and cytolysis of bovine leukocytes. These observations underscore the need for further investigation to identify the precise subunit of bovine LFA-1 utilized by M. haemolytica Lkt as the functional receptor. For this purpose, monomeric bovine CD18 and CD11a and heterodimeric LFA-1 were expressed in the HEK-293 cell line by transfection, and the resulting transfectants were tested for susceptibility to Lkt-induced effects. All three transfectants effectively bound Lkt. However, Lkt-induced cytolysis was observed only with transfectants expressing monomeric bovine CD18 or LFA-1. Furthermore, intracellular [Ca(2+)] elevation following exposure to Lkt, which is a marker for postbinding signaling leading to cellular activation, was seen only with transfectants expressing monomeric bovine CD18 or LFA-1. These results clearly indicate that the bovine CD18 subunit of beta(2)-integrins is the functional receptor for M. haemolytica Lkt.

Detection of constitutive homomeric associations of the integrins Mac-1 subunits by fluorescence resonance energy transfer in living cells

Integrins alpha(M)beta(2) plays important role on leukocytes, such as adhesion, migration, phagocytosis, and apoptosis. It was hypothesized that homomeric associations of integrin subunits provide a driving force for integrins activation, and simultaneously inducing the formation of integrins clusters. However, experimental reports on homomeric associations between integrin subunits are still controversial. Here, we proved the homomeric associations of the isolated Mac-1 subunits in living cells using three-channel fluorescence resonance energy transfer (FRET) microscopy and FRET spectra methods. We found that the extent of homomeric associations between beta(2) subunits is higher than alpha(M) subunits. Furthermore, FRET imaging indicated that the extent of homomeric associations of the Mac-1 subunits is higher along the plasma membrane than in the cytoplasm. Finally, we suggested that homomeric associations of the transmembrane domains or/and cytoplasmic domains may provide the driving force for the formation of constitutive homomeric associations between alpha(M) or beta(2) subunits.

Structural insights into the central complement component C3

C3 is a central protein of the complement system, which is important to immune defense and provides a link between innate and adaptive immunity. Three pathways of complement activation converge at the activation of C3 yielding a diverse set of biological responses. This versatile and flexible molecule interacts with various proteins to fulfill its functions. Here we review recent insights gained from the crystal structure determinations of human, native C3 and its physiological down-regulation product C3c. The data provided, for the first time, a complete and detailed view of the composition and arrangement of the domains in C3. Comparison of C3 with C3c indicates marked flexibility of the molecule, particularly in the alpha-chain. We discuss the observed domain rearrangements, conformational changes and the location of various protein binding sites. These detailed, and structural, insights are important for developing models of the molecular mechanisms underlying the diverse biological activities of this large and complex molecule.

Characterization of Binding Properties of ICAM-1 Peptides to LFA-1: Inhibitors of T-cell Adhesion

In the present study, we characterized the binding site of two intercellular adhesion molecule-1-derived cyclic peptides, cIBC and cIBR, to the LFA-1 on the surface of T cells. These peptides had been able to inhibit LFA-1/intercellular adhesion molecule-1 signal by blocking the signal-2 of immune synapse. Both peptides prefer to bind to the closed form of LFA-1 I-domain, indicating that two peptides act as allosteric inhibitors against intercellular adhesion molecule-1. Binding site mapping using monoclonal antibodies proposes that cIBC binds to around residues 266-272 of LFA-1 I-domain where this site is adjacent to the metal ion-dependent adhesion site. On the other hand, cIBR binds to the pocket called L-site where is distant from metal ion-dependent adhesion site. Cross-inhibition mapping between two peptides show that cIBR could inhibit the binding of cIBC but not vice versa, suggesting that cIBR has some properties that allow this peptide bind to more than one site. Structural comparison between cIBC and cIBR reveals that cIBR is more flexible than cIBC, allowing this peptide bind to exposed region, such as cIBC-binding site as well as cramped pocket like L-site. Our findings are important for understanding the selectivity of cIBC and cIBR peptides; thus, they can be conjugated with drugs and transported specifically to the target.

Dual function for a unique site within the beta2I domain of integrin alphaMbeta2

Integrin activation has been postulated to occur in part via conformational changes in the I domain of the beta subunit (the betaI domain), especially near the F-alpha(7) loop, in response to "inside-out" signaling. However, direct evidence for a role of the F-alpha(7) loop in ligand binding and activity modulation is still lacking. Here, we report our finding that the F-alpha(7) loop (residues 344-358) within the beta(2)I domain has dual functions in ligand binding by alpha(M)beta(2). On the one hand, it supports intercellular adhesion molecule 1 (ICAM-1) binding to alpha(M)beta(2) directly as part of a recognition interface formed by five noncontiguous segments (Pro(192)-Glu(197), Asn(213)-Glu(220), Leu(225)-Leu(230), Ser(324)-Thr(329), and Glu(344)-Asp(348)) on the apex of the beta(2)I domain. On the other hand, it controls the open and closed conformation of the alpha(M)beta(2) receptor, thereby indirectly affecting alpha(M)beta(2) binding to other ligands. Switching the five constituent sequences of the ICAM-1-binding site within the beta(2)I domain to their beta(1) counterparts destroyed ICAM-1 binding but had no effect on the gross conformations of the receptor. Of the five ICAM-1 binding-defective mutants, four had normal or even stronger interaction with Fg and C3bi, as reported in our previous study. Synthetic peptides derived from the identified site inhibited alpha(M)beta(2)-ICAM-1 interaction and supported direct binding to ICAM-1. Most importantly, perturbation of the F-alpha(7) loop caused conformational changes within the beta(2)I domain, which was further propagated to other regions of alpha(M)beta(2). Altogether, our data demonstrate that inside-out signaling could modulate ligand binding directly by changing the ligand-binding pocket per se and/or indirectly by inducing multiple conformational changes within the receptor.

Distinct roles for the alpha and beta subunits in the functions of integrin alphaMbeta2

Integrin alphaMbeta2 (Mac-1, CD11b/CD18) is a noncovalently linked heterodimer of alphaM and beta2 subunits on the surface of leukocytes, where it plays a pivotal role in the adhesion and migration of these cells. Using HEK293 cells expressing alphaMbeta2 or the individual constituent chains on their surface, we analyzed the contributions of the alphaM or beta2 subunits to functional responses mediated by the integrin. In cells expressing only alphaM or beta2, the individual subunits were not associated with the endogenous integrins of the cells, and other partners for the subunits were not detected by surface labeling and immunoprecipitation under a variety of conditions. The alphaM cells mediated adhesion and spreading on a series of alphaMbeta2 ligands (fibrinogen, Factor X, iC3b, ICAM-1 (intercellular adhesion molecule-1), and denatured ovalbumin) but could not support cell migration to any of these. The spreading of the alphaM cells suggested an unanticipated linkage of this subunit to the cytoskeleton. The beta2 cells supported migration and attachment but not spreading on a subset of the alphaMbeta2 ligands. The heterodimeric receptor and its individual subunits were purified from the cells by affinity chromatography and recapitulated the ligand binding properties of the corresponding cell lines. These data indicate that each subunit of alphaMbeta2 contributes distinct properties to alphaMbeta2 and that, in most but not all cases, the response of the integrin is a composite of the functions of its individual subunits.

Characterization of plasminogen as an adhesive ligand for integrins alphaMbeta2 (Mac-1) and alpha5beta1 (VLA-5)

Plasminogen (Pg) has been implicated in many biologic processes involving extracellular proteolysis. We investigated whether Pg, by virtue of its capacity to be deposited within the extracellular matrix, can serve as a ligand for cell surface integrins. We report here that Pg supports cell adhesion by engaging integrins alphaMbeta2 and alpha5beta1. The immobilized Glu-Pg, but not its derivatives with the N-terminal peptide lacking, plasmin and Lys-Pg, supported efficient adhesion that was abolished by anti-alphaMbeta2 and anti-alpha5beta1 integrin-specific monoclonal antibodies (mAbs). In addition, lysine binding sites of Glu-Pg contributed to cell adhesion inasmuch as tranexamic acid and epsilon-aminocaproic acid inhibited cell adhesion. The involvement of alphaMbeta2 and alpha5)beta1 in adhesion to Glu-Pg was demonstrable with blood neutrophils, U937 monocytoid cells, and genetically engineered alphaMbeta2-transfected human embryonic kidney (HEK) 293 cells. In alphaMbeta2, the alphaMI-domain is the binding site for Glu-Pg because the "I-less" form of alphaMbeta2 did not support cell adhesion and the recombinant alphaMI-domain bound Glu-Pg directly. In comparison with cell adhesion, the binding of soluble Glu-Pg to cells and the concomitant generation of plasmin activity was inhibited by anti-alpha5beta1 but not by anti-alphaMbeta2. These findings identify Glu-Pg as an adhesive ligand for integrins alphaMbeta2 and alpha5beta1 and suggest that alpha5beta1 may participate in the binding of soluble Glu-Pg and assist in its activation.

Analysis of the Drosophila betaPS subunit indicates that regulation of integrin activity is a primal function of the C8-C9 loop

Integrin-ligand interactions can be influenced by the sequence in a disulfide-bridged loop between the 8th and 9th beta subunit cysteines. Previous experiments are consistent with C8-C9 loop residues being involved in direct ligand-integrin interactions and/or being important in heterodimer regulation. In betaPS from Drosophila melanogaster and three other dipterans, the C8-C9 loop consists of only two amino acids, and exists in two forms that arise by differential splicing of exon 4. In these species, the betaPS4A isoform has an acidic residue in the first loop position (C8+1), with an alanine or proline in the corresponding position of betaPS4B. Mutations in both isoforms (in combination with alphaPS2) can reduce cell spreading during normal growth, but function is generally restored under conditions that enhance integrin activation. Replacement of the betaPS4A acidic residue with a basic lysine has relatively modest effects on integrin function. Spread cells bearing C8-C9 mutations tend to become less elongated, with reduced frequencies of actin stress fibers. The results indicate that even a minimal, two-residue C8-C9 loop contains structural information that can differentially regulate integrin activity and/or integrin signaling, and that this regulation does not rely on direct molecular interactions involving the variable C8+1 side chains.

Role of ADMIDAS Cation-binding Site in Ligand Recognition by Integrin α5β1

Integrin-ligand interactions are regulated in a complex manner by divalent cations, and multiple cation-binding sites are found in both alpha and beta integrin subunits. A key cation-binding site that lies in the beta subunit A-domain is known as the metal-ion dependent adhesion site (MIDAS). Recent x-ray crystal structures of integrin alpha V beta 3 have identified a novel cation binding site in this domain, known as the ADMIDAS (adjacent to MIDAS). The role of this novel site in ligand recognition has yet to be elucidated. Using the interaction between alpha 5 beta 1 and fibronectin as a model system, we show that mutation of residues that form the ADMIDAS site inhibits ligand binding but this effect can be partially rescued by the use of activating monoclonal antibodies. The ADMIDAS mutants had decreased expression of activation epitopes recognized by 12G10, 15/7, and HUTS-4, suggesting that the ADMIDAS is important for stabilizing the active conformation of the integrin. Consistent with this suggestion, the ADMIDAS mutations markedly increased the dissociation rate of the integrin-fibronectin complex. Mutation of the ADMIDAS residues also reduced the allosteric inhibition of Mn2+-supported ligand binding by Ca2+, suggesting that the ADMIDAS is a Ca2+-binding site involved in the inhibition of Mn2+-supported ligand binding. Mutations of the ADMIDAS site also perturbed transduction of a conformational change from the MIDAS through the C-terminal helix region of the beta A domain to the underlying hybrid domain, implying an important role for this site in receptor signaling.

Integrins, cations and ligands: making the connection

Integrins are cell adhesion receptors that couple extracellular divalent cation-dependent recognition events with intracellular mechanical and biochemical responses and vice versa, thus affecting every function of nucleated cells. The structural basis of this bidirectional signaling and its dependency on cations has been the focus of intensive study over the past three decades. Significant progress made recently in elucidating the three-dimensional structure of the extracellular and cytoplasmic segments of integrins is giving valuable new insights into the tertiary and quaternary changes that underlie activation, ligand recognition and signaling by these receptors.

Conformational changes in the integrin beta A domain provide a mechanism for signal transduction via hybrid domain movement

The ligand-binding head region of integrin beta subunits contains a von Willebrand factor type A domain (betaA). Ligand binding activity is regulated through conformational changes in betaA, and ligand recognition also causes conformational changes that are transduced from this domain. The molecular basis of signal transduction to and from betaA is uncertain. The epitopes of mAbs 15/7 and HUTS-4 lie in the beta(1) subunit hybrid domain, which is connected to the lower face of betaA. Changes in the expression of these epitopes are induced by conformational changes in betaA caused by divalent cations, function perturbing mAbs, or ligand recognition. Recombinant truncated alpha(5)beta(1) with a mutation L358A in the alpha7 helix of betaA has constitutively high expression of the 15/7 and HUTS-4 epitopes, mimics the conformation of the ligand-occupied receptor, and has high constitutive ligand binding activity. The epitopes of 15/7 and HUTS-4 map to a region of the hybrid domain that lies close to an interface with the alpha subunit. Taken together, these data suggest that the transduction of conformational changes through betaA involves shape shifting in the alpha7 helix region, which is linked to a swing of the hybrid domain away from the alpha subunit.

Identification of functional segments within the beta2I-domain of integrin alphaMbeta2

The alpha(M)beta(2) integrin plays an important role in leukocyte biology through its interactions with a diverse set of ligands. Efficient ligand binding requires the involvement of both the alpha(M) and beta(2) subunits. Past ligand binding studies have focused mainly on the alpha(M) subunit, with the beta(2) subunit being largely unexplored. Therefore, in this study we conducted homolog-scanning mutagenesis on the I-domain (residues 125-385) within the beta(2) subunit. We identified four noncontiguous sequences (Arg(144)-Lys(148), Gln(199)-Ala(203), Leu(225)-Leu(230), and Gly(305)-His(309)) that are critical for fibrinogen and C3bi binding to alpha(M)beta(2). Molecular modeling revealed that these four sequences reside within a narrow region on the surface of the beta(2)I-domain, in close proximity to three potential cation-binding sites. Among these sequences, Gln(199)-Ala(203), Leu(225)-Leu(230), and Gly(305)-His(309) are important for the binding of both ligands, whereas Arg(144)-Lys(148) is more critical for fibrinogen than for C3bi binding. These sequences within the beta(2)I-domain are directly involved in ligand binding, since 1) switching these segments to their corresponding beta(1) sequences destroyed ligand binding; 2) loss of function was not due to a nonspecific gross conformational change, since the defective alpha(M)beta(2) mutants reacted well with a panel of conformation-dependent mAbs; 3) mutation of these functional sequences did not effect Ca(2+) binding; and 4) synthetic peptides corresponding to sequences Gln(199)-Ala(203) and Gly(305)-His(309) blocked ligand binding to alpha(M)beta(2), and the peptides interacted directly with fibrinogen and C3bi. Given the similarity among all integrin beta subunits, our results may help us to understand the underlying mechanism of integrin-ligand interactions in general.

Expression and genomic analysis of midasin, a novel and highly conserved AAA protein distantly related to dynein

BACKGROUND

The largest open reading frame in the Saccharomyces genome encodes midasin (MDN1p, YLR106p), an AAA ATPase of 560 kDa that is essential for cell viability. Orthologs of midasin have been identified in the genome projects for Drosophila, Arabidopsis, and Schizosaccharomyces pombe.

RESULTS

Midasin is present as a single-copy gene encoding a well-conserved protein of approximately 600 kDa in all eukaryotes for which data are available. In humans, the gene maps to 6q15 and encodes a predicted protein of 5596 residues (632 kDa). Sequence alignments of midasin from humans, yeast, Giardia and Encephalitozoon indicate that its domain structure comprises an N-terminal domain (35 kDa), followed by an AAA domain containing six tandem AAA protomers (approximately 30 kDa each), a linker domain (260 kDa), an acidic domain (approximately 70 kDa) containing 35-40% aspartate and glutamate, and a carboxy-terminal M-domain (30 kDa) that possesses MIDAS sequence motifs and is homologous to the I-domain of integrins. Expression of hemagglutamin-tagged midasin in yeast demonstrates a polypeptide of the anticipated size that is localized principally in the nucleus.

CONCLUSIONS

The highly conserved structure of midasin in eukaryotes, taken in conjunction with its nuclear localization in yeast, suggests that midasin may function as a nuclear chaperone and be involved in the assembly/disassembly of macromolecular complexes in the nucleus. The AAA domain of midasin is evolutionarily related to that of dynein, but it appears to lack a microtubule-binding site.

Integrin activation involves a conformational change in the alpha 1 helix of the beta subunit A-domain

The ligand-binding region of integrin beta subunits contains a von Willebrand factor type A-domain: an alpha/beta "Rossmann" fold containing a metal ion-dependent adhesion site (MIDAS) on its top face. Although there is evidence to suggest that the betaA-domain undergoes changes in tertiary structure during receptor activation, the identity of the secondary structure elements that change position is unknown. The mAb 12G10 recognizes a unique cation-regulated epitope on the beta(1) A-domain, induction of which parallels the activation state of the integrin (i.e. competency for ligand recognition). The ability of Mn(2+) and Mg(2+) to stimulate 12G10 binding is abrogated by mutation of the MIDAS motif, demonstrating that the MIDAS is a Mn(2+)/Mg(2+) binding site and that occupancy of this site induces conformational changes in the A-domain. The cation-regulated region of the 12G10 epitope maps to Arg(154)/Arg(155) in the alpha1 helix. Our results demonstrate that the alpha1 helix undergoes conformational alterations during integrin activation and suggest that Mn(2+) acts as a potent activator of beta(1) integrins because it can promote a shift in the position of this helix. The mechanism of beta subunit A-domain activation appears to be distinct from that of the A-domains found in some integrin alpha subunits.

Identification and characterization of two cation binding sites in the integrin beta 3 subunit

The midsegment of the beta(3) subunit has been implicated in the ligand and cation binding functions of the beta(3) integrins. This region may contain a metal ion-dependent adhesion site (MIDAS) and fold into an I domain-like structure. Two recombinant fragments, beta(3)-(95-373) and beta(3)-(95-301), were expressed and found to bind fibrinogen. Whereas 0.1 mm Ca(2+) supported ligand binding to both recombinant fragments, 1.0 mm Ca(2+) suppressed binding to the longer but not the shorter fragment. These properties suggest that beta(3)-(95-373) contains both the ligand-competent (LC) and inhibitory (I) cation binding sites, and beta(3)-(95-301) lacks the I site. In equilibrium dialysis experiments, beta(3)-(95-373) contained two divalent cation binding sites, one reactive with either Mg(2+) or Ca(2+) and one Ca(2+)-specific, whereas beta(3)-(95-301) lacked the Ca(2+)-specific site. Mutant forms of beta(3)-(95-373) suggested that the LC site is a MIDAS motif involving Asp(119), Ser(121), Ser(123), Asp(217), and/or Glu(220) as coordination sites, and the I site was dependent upon residues within beta(3)-(301-323). In a molecular model of beta(3)-(95-373), a second Ca(2+) could be docked onto a flexible loop in close proximity to the MIDAS. These results indicate that the ligand competent and Ca(2+)-specific inhibitory cation binding sites are distinct and reside in beta(3)-(95-373).

Small molecule inhibitors induce conformational changes in the I domain and the I-like domain of lymphocyte function-associated antigen-1. Molecular insights into integrin inhibition

The beta(2) integrin lymphocyte function-associated antigen-1 (LFA-1) is a conformationally flexible alpha/beta heterodimeric receptor, which is expressed on the surface of all leukocytes. LFA-1 mediates cell adhesion crucial for normal immune and inflammatory responses. Intracellular signals or cations are required to convert LFA-1 from a nonligand binding to a ligand binding state. Here we investigated the effect of small molecule inhibitors on LFA-1 by monitoring the binding of monoclonal antibodies mapped to different receptor domains. The inhibitors were found to not only induce epitope changes in the I domain of the alpha(L) chain but also in the I-like domain of the beta(2) chain depending on the individual chemical structure of the inhibitor and its binding site. For the first time, we provide strong evidence that the I-like domain represents a target for allosteric LFA-1 inhibition similar to the well established regulatory L-site on the I domain of LFA-1. Moreover, the antibody binding patterns observed in the presence of the various inhibitors establish a conformational interaction between the LFA-1 I domain and the I-like domain in the native receptor that is formed upon activation. Differentially targeting the binding sites of the inhibitors, the L-site and the I-like domain, may open new avenues for highly specific therapeutic intervention in diseases where integrins play a pathophysiological role.

The N-terminal region and the mid-region complex of the integrin beta 2 subunit

In the primary sequence of the integrin beta subunit, the N-terminal region (NTR) and mid-region are separated by the I-like domain. To determine the spatial relationship and functional properties of the integrin beta(2) NTR and mid-region, we constructed beta(2)/beta(7) chimeras in which the NTR, I-like domain, and the mid-region of the beta(2) subunit were replaced by those of beta(7). Changing either the beta(2) NTR or mid-region, but not the I-like domain to that of beta(7) did not affect LFA-1 (alpha(L)beta(2)) formation and surface expression. Thus, the specificity of alpha(L)beta(2) pairing is conferred by the I-like domain but not the NTR or mid-region. Using these chimeras, the epitopes of six anti-beta(2) mAbs (H52, 7E4, AZN-L18, AZN-L27, KIM202, and MEM-148) were mapped. All except H52 require both the NTR and mid-region for epitope expression. Since these mAbs have distinct properties in terms of epitope expression and effect on LFA-1 binding to ICAM-1, we conclude that the beta(2) NTR and mid-region interact extensively. Although the I-like domain is located between the NTR and mid-region, its removal does not affect the folding of the beta(2) NTR/mid-region complex because this complex alone can be expressed as a soluble protein and precipitated by the appropriate mAbs. Finally, the mAbs H52 and 7E4, abrogated KIM185- but not Mg/EGTAinduced LFA-1/ICAM-1 binding and the epitope of MEM-148 is expressed on Mg/EGTA-activated but not resting LFA-1. These results suggest that the NTR/mid-region complex is involved in the regulation of LFA-1 function.