Identity of the amino acid residues involved in C3bi binding to the I-domain supports a mosaic model to explain the broad ligand repertoire of integrin alpha M beta 2

Interactions between the complement degradation product C3bi and leukocyte integrin alpha(M)beta(2) are critical for host defense against foreign pathogens and in tumor cell surveillance. To gain insight into the mechanism by which the alpha(M)I-domain of the integrin interacts with C3bi, detailed mapping of the C3bi binding site was undertaken. Previous mutagenesis studies had implicated five small structural segments within the alpha(M)I-domain in recognition of this ligand. Sets of three amino acids within the five implicated segments were mutated to the corresponding alpha(L)I-domain residues. Then, within the affected mutants, single point mutations were introduced to precisely define the requisite residues. Ultimately, H148, F150, Q204, L205, R208, T211, T213, I256, P257 were identified as being critical for C3bi binding. A synthetic peptide approach confirmed the involvement of the specified residues with the complex midsegment, Q204-I215, in C3bi recognition. Furthermore, the alpha(D)I-domain, which has a low intrinsic affinity for C3bi, acquired high affinity for the ligand when the implicated residues were inserted. The residues necessary to engage C3bi reside on or adjacent to the cation binding MIDAS site of the alpha(M)I-domain. The amino acids involved in C3bi binding are distinct from those involved in interaction of previously mapped ligands with the alpha(M)I-domain. This divergence supports a mosaic model, in which different ligands engage different amino acids to bind to alpha(M)I-domain, accounting for the broad recognition capacity of integrin alpha(M)beta(2).     

Identification of the binding site for fibrinogen recognition peptide gamma 383-395 within the alpha(M)I-domain of integrin alpha(M)beta2

The leukocyte integrin alpha(M)beta(2) (Mac-1, CD11b/CD18) is a cell surface adhesion receptor for fibrinogen. The interaction between fibrinogen and alpha(M)beta(2) mediates a range of adhesive reactions during the immune-inflammatory response. The sequence gamma(383)TMKIIPFNRLTIG(395), P2-C, within the gamma-module of the D-domain of fibrinogen, is a recognition site for alpha(M)beta(2) and alpha(X)beta(2). We have now identified the complementary sequences within the alpha(M)I-domain of the receptor responsible for recognition of P2-C. The strategy to localize the binding site for P2-C was based on distinct P2-C binding properties of the three structurally similar I-domains of alpha(M)beta(2), alpha(X)beta(2), and alpha(L)beta(2), i.e. the alpha(M)I- and alpha(X)I-domains bind P2-C, and the alpha(L)I-domain did not bind this ligand. The Lys(245)-Arg(261) sequence, which forms a loop betaD-alpha5 and an adjacent helix alpha5 in the three-dimensional structure of the alpha(M)I-domain, was identified as the binding site for P2-C. This conclusion is supported by the following data: 1) mutant cell lines in which the alpha(M)I-domain segments (245)KFG and Glu(253)-Arg(261) were switched to the homologous alpha(L)I-domain segments failed to support adhesion to P2-C; 2) synthetic peptides duplicating the Lys(245)-Tyr(252) and Glu(253)-Arg(261) sequences directly bound the D fragment and P2-C derivative, gamma384-402, and this interaction was blocked efficiently by the P2-C peptide; 3) mutation of three amino acid residues within the Lys(245)-Arg(261) segment, Phe(246), Asp(254), and Pro(257), resulted in the loss of the binding function of the recombinant alpha(M)I-domains; and 4) grafting the alpha(M)(Lys(245)-Arg(261)) segment into the alpha(L)I-domain converted it to a P2-C-binding protein. These results demonstrate that the alpha(M)(Lys(245)-Arg(261)) segment, a site of the major sequence and structure difference among alpha(M)I-, alpha(X)I-, and alpha(L)I-domains, is responsible for recognition of a small segment of fibrinogen, gammaThr(383)-Gly(395), by serving as ligand binding site.     

Amino acid sequences within the alpha subunit of integrin alpha M beta 2 (Mac-1) critical for specific recognition of C3bi.

Phagocytosis of opsonized particles by neutrophils and monocytes plays a central role in host defense mechanisms against foreign pathogens. This process depends on the interaction between C3bi, a degradation product derived from activation of the complement system, and the alpha M beta 2 (CD11b/CD18, Mac-1) receptor, the major integrin on neutrophils. Previous studies had established a central role for the I domain, a stretch of approximately 200 amino acids within the alpha M subunit in the binding of C3bi, as well as many other alpha M beta 2 ligands. The present study was undertaken to establish the molecular basis of C3bi recognition by alpha M beta 2. The strategy employed the use of a series of mutant receptors in which short segments of the I domain of alpha M were switched to the corresponding segments of alpha L, which is structurally very similar but does not bind C3bi. We report three major findings: (1) The C3bi binding pocket is composed of three regions, P147-R152, P201-K217, and K245-R261 of alpha M, which surround the cation binding site within the MIDAS motif of the I domain. (2) Within the latter segment, K245 plays a critical role in mediating C3bi binding to alpha M beta 2. Mutation of K245 to Ala significantly reduced C3bi binding but had no effect on binding of another alpha M beta 2 I domain ligand, NIF. (3) Blocking of C3bi binding to alpha M beta 2 by monoclonal antibodies is achieved through two different mechanisms: direct competition for the ligand binding site or induction of conformational changes. Overall, these studies support the hypothesis that many of the ligands of alpha M beta 2 bind to overlapping but not identical sites within the I domain. Although the same short structural segments within the I domain may be involved in binding, different amino acids within these segments may contact different ligands.     

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

The central region (residues 125-385) of the integrin beta(2) subunit is postulated to adopt an I-domain-like fold (the beta(2)I-domain) and to play a critical role in ligand binding and heterodimer formation. To understand structure-function relationships of this region of beta(2), a homolog-scanning mutagenesis approach, which entails substitution of nonconserved hydrophilic sequences within the beta(2)I-domain with their homologous counterparts of the beta(1)I-domain, has been deployed. This approach is based on the premise that beta(1) and beta(2) are highly homologous, yet recognize different ligands. Altogether, 16 segments were switched to cover the predicted outer surface of the beta(2)I-domain. When these mutant beta(2) subunits were transfected together with wild-type alpha(M) in human 293 cells, all 16 beta(2) mutants were expressed on the cell surface as heterodimers, suggesting that these 16 sequences within the beta(2)I-domain are not critically involved in heterodimer formation between the alpha(M) and beta(2) subunits. Using these mutant alpha(M)beta(2) receptors, we have mapped the epitopes of nine beta(2)I-domain specific mAbs, and found that they all recognized at least two noncontiguous segments within this domain. The requisite spatial proximity among these non-linear sequences to form the mAb epitopes supports a model of an I-domain-like fold for this region. In addition, none of the mutations that abolish the epitopes of the nine function-blocking mAbs, including segment Pro(192)-Glu(197), destroyed ligand binding of the alpha(M)beta(2) receptor, suggesting that these function-blocking mAbs inhibit alpha(M)beta(2) function allosterically. Given the recent reports implicating the segment equivalent to Pro(192)-Glu(197) in ligand binding by beta(3) integrins, these data suggest that ligand binding by the beta(2) integrins occurs via a different mechanism than beta(3). Finally, both the conformation of the beta(2)I-domain and C3bi binding activity of alpha(M)beta(2) were dependent on a high affinity Ca(2+) binding site (K(d) = 105 microm), which is most likely located within this region of beta(2).     

"RKKH" peptides from the snake venom metalloproteinase of Bothrops jararaca bind near the metal ion-dependent adhesion site of the human integrin alpha(2) I-domain.

Integrin alpha(1)beta(1) and alpha(2)beta(1) are the major cellular receptors for collagen, and collagens bind to these integrins at the inserted I-domain in their alpha subunit. We have previously shown that a cyclic peptide derived from the metalloproteinase domain of the snake venom protein jararhagin blocks the collagen-binding function of the alpha(2) I-domain. Here, we have optimized the structure of the peptide and identified the site where the peptide binds to the alpha(2) I-domain. The peptide sequence Arg-Lys-Lys-His is critical for recognition by the I-domain, and five negatively charged residues surrounding the "metal ion-dependent adhesion site" (MIDAS) of the I-domain, when mutated, show significantly impaired binding of the peptide. Removal of helix alphaC, located along one side of the MIDAS and suggested to be involved in collagen-binding in these I-domains, does not affect peptide binding. This study supports the notion that the metalloproteinase initially binds to the alpha(2) I-domain at a location distant from the active site of the protease, thus blocking collagen binding to the adhesion molecule in the vicinity of the MIDAS, while at the same time leaving the active site free to degrade nearby proteins, the closest being the beta(1) subunit of the alpha(2)beta(1) cell-surface integrin itself.     

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.     

Crystal structure of the alpha1beta1 integrin I-domain: insights into integrin I-domain function.

The alpha1beta1 integrin is a major cell surface receptor for collagen. Ligand binding is mediated, in part, through a 200 amino acid inserted 'I'-domain contained in the extracellular part of the integrin alpha chain. Integrin I-domains contain a divalent cation binding (MIDAS) site and require cations to interact with integrin ligands. We have determined the crystal structure of recombinant I-domain from the rat alpha1beta1 integrin at 2.2 A resolution in the absence of divalent cations. The alpha1 I-domain adopts the dinucleotide binding fold that is characteristic of all I-domain structures that have been solved to date and has a structure very similar to that of the closely related alpha2beta1 I-domain which also mediates collagen binding. A unique feature of the alpha1 I-domain crystal structure is that the MIDAS site is occupied by an arginine side chain from another I-domain molecule in the crystal, in place of a metal ion. This interaction supports a proposed model for ligand-induced displacement of metal ions. Circular dichroism spectra determined in the presence of Ca2+, Mg2+ and Mn2+ indicate that no changes in the structure of the I-domain occur upon metal ion binding in solution. Metal ion binding induces small changes in UV absorption spectra, indicating a change in the polarity of the MIDAS site environment.     

Characteristics of fibrinogen binding to the domain of CD11c, an alpha subunit of p150,95.

beta2 integrins on leukocytes play important roles on cell-cell or cell-matrix adhesion through their ability to bind multiple ligands. The alpha subunits of leukocyte CD11/CD18 integrins contain an approximately 200-amino-acid inserted domain (I-domain) which is implicated in ligand binding function. To understand the characteristics of ligand binding to the alpha subunit of beta2 integrin p150,95 (CD11c/CD18), a recombinant form of the I-domain of CD11c was generated and analyzed for the interaction with fibrinogen, one of the ligands of p150,95. It was found that the CD11c I-domain bound fibrinogen specifically. Fibrinogen binding to the CD11c I-domain was inhibited by a molar excess of fragment E, a central domain of fibrinogen, and not by that of fragment D, a distal domain of fibrinogen, suggesting that CD11c/CD18 recognizes a central domain of fibrinogen. Divalent cations such as Mg(2+) and Mn(2+) were required for fibrinogen binding to the CD11c I-domain. Also alanine substitutions on the putative metal binding sites of the CD11c I-domain such as Asp(242) and Tyr(209) reduced its ability to bind fibrinogen. These data reinforce the fact that the divalent cation is a prerequisite for ligand binding of the CD11c I-domain.     

Identification of critical residues for plasminogen binding by the alphaX I-domain of the beta2 integrin, alphaXbeta2

The beta2 integrins on leukocytes play important roles in cell adhesion, migration and phagocytosis. One of the beta2 integrins, alphaXbeta2 (CD11c/CD18), is known to bind ligands such as fibrinogen, Thy-1 and iC3b, but its function is not well characterized. To understand its biological roles, we attempted to identify novel ligands. The functional moiety of alphaXbeta2, the alphaX I-domain, was found to bind plasminogen, the zymogen of plasmin, with moderate affinity (1.92 X 10-(6) M) in the presence of Mg(2+) or Mn(2+). The betaD-alpha5 loop of the alphaX I-domain proved to be responsible for binding, and lysine residues (Lys(242), Lys(243)) in the loop were the most important for recognizing plasminogen. An excess amount of the lysine analog, 6-aminohexanoic acid, inhibited alphaX I-domain binding to plasminogen, indicating that binding is lysine-dependent. The results of this study indicate that leukocytes regulate plasminogen activation, and consequently plasmin activities, through an interaction with alphaXbeta2 integrin.     

Micromolar Ca2+ concentrations are essential for Mg2+-dependent binding of collagen by the integrin alpha 2beta 1 in human platelets

Integrin receptor alpha(2)beta(1) requires micromolar Ca(2+) to bind to collagen and to the peptide GPC(GPP)(5)GFOGER(GPP)(5)GPC (denoted GFOGER-GPP, where O represents hydroxyproline), which contains the minimum recognition sequence for the collagen-binding alpha(2) I-domain (Knight, C. G., Morton, L. F., Peachey, A. R., Tuckwell, D. S., Farndale, R. W., and Barnes, M. J. (2000) J. Biol. Chem. 275, 35-40). Platelet adhesion to these ligands is completely dependent on alpha(2)beta(1) in the presence of 2 mm Mg(2+). However, we show here that this interaction was abolished in the presence of 25 microm EGTA. Adhesion of Glanzmann's thrombasthenic platelets, which lack the fibrinogen receptor alpha(IIb)beta(3), was also inhibited by micromolar EGTA. Mg(2+)-dependent adhesion of platelets was restored by the addition of 10 microm Ca(2+), but millimolar Ca(2+) was inhibitory. Binding of isolated alpha(2)beta(1) to GFOGER-GPP was 70% inhibited by 50 microm EGTA but, as with intact platelets, was fully restored by the addition of micromolar Ca(2+). 2 mm Ca(2+) did not inhibit binding of isolated alpha(2)beta(1) to collagen or to GFOGER-GPP. Binding of recombinant alpha(2) I-domain was not inhibited by EGTA, nor did millimolar Ca(2+) inhibit binding. Our data suggest that high affinity Ca(2+) binding to alpha(2)beta(1), outside the I-domain, is essential for adhesion to collagen. This is the first demonstration of a Ca(2+) requirement in alpha(2)beta(1) function.     

Sequence gamma 377-395(P2), but not gamma 190-202(P1), is the binding site for the alpha MI-domain of integrin alpha M beta 2 in the gamma C-domain of fibrinogen

The interaction between the leukocyte integrin alpha(M)beta(2) (CD11b/CD18, Mac-1, CR3) and fibrinogen mediates the recruitment of phagocytes during the inflammatory response. Previous studies demonstrated that peptides P2 and P1, duplicating gamma 377-395 and gamma 190-202 sequences in the gamma C domain of fibrinogen, respectively, blocked the fibrinogen-binding function of alpha(M)beta(2), implicating these sequences as possible binding sites for alpha(M)beta(2). To determine the role of these sequences in integrin binding, recombinant wild-type and mutant gamma C domains were prepared, and their interactions with the alpha(M)I-domain, a ligand recognition domain within alpha(M)beta(2), were tested. Deletion of gamma 383-411 (P2-C) and gamma 377-411 produced gamma C mutants which were defective in binding to the alpha(M)I-domain. In contrast, alanine mutations of several residues in P1 did not affect alpha(M)I-domain binding, and simultaneous mutations in P1 and deletion of P2 did not decrease the binding function of gamma C further. Verifying the significance of P2, inserting P2-C and the entire P2 into the homologous position of the beta C-domain of fibrinogen imparted the higher alpha(M)I-domain binding ability to the chimeric proteins. To further define the molecular requirements for the P2-C activity, synthetic peptides derived from P2-C and a peptide array covering P2-C have been analyzed, and a minimal recognition motif was localized to gamma(390)NRLTIG(395). Confirming a critical role of this sequence, the cyclic peptide NRLTIG retained full activity inherent to P2-C, with Arg and Leu being important residues. Thus, these data demonstrate the essential role of the P2, but not P1, sequence for binding of gamma C by the alpha(M)I-domain and suggest that the adhesive function of P2 depends on the minimal recognition motif NRLTIG.     

Interaction between collagen and the alpha(2) I-domain of integrin alpha(2)beta(1). Critical role of conserved residues in the metal ion-dependent adhesion site (MIDAS) region.

A docking model of the alpha(2) I-domain and collagen has been proposed based on their crystal structures (Emsley, J., King, S., Bergelson, J., and Liddington, R. C. (1997) J. Biol. Chem. 272, 28512-28517). In this model, several amino acid residues in the I-domain make direct contact with collagen (Asn-154, Asp-219, Leu-220, Glu-256, His-258, Tyr-285, Asn-289, Leu-291, Asn-295, and Lys-298), and the protruding C-helix of alpha(2) (residues 284-288) determines ligand specificity. Because most of the proposed critical residues are not conserved, different I-domains are predicted to bind to collagen differently. We found that deleting the entire C-helix or mutating the predicted critical residues had no effect on collagen binding to whole alpha(2)beta(1), with the exception that mutating Asn-154, Asp-219, and His-258 had a moderate effect. We performed further studies and found that mutating the conserved surface-exposed residues in the metal ion-dependent adhesion site (MIDAS) (Tyr-157 and Gln-215) significantly blocks collagen binding. We have revised the docking model based on the mutagenesis data. In the revised model, conserved Tyr-157 makes contact with collagen in addition to the previously proposed Asn-154, Asp-219, His-258, and Tyr-285 residues. These results suggest that the collagen-binding I-domains (e.g. alpha(1), alpha(2), and alpha(10)) bind to collagen in a similar fashion.     

The fourth blade within the beta-propeller is involved specifically in C3bi recognition by integrin alpha M beta 2

Interactions between the complement degradation product C3bi and leukocyte integrin alpha M beta 2 are critical to phagocytosis of opsonized particles in host defense against foreign pathogens and certain malignant cells. Previous studies have mapped critical residues for C3bi binding to the I-domains of the alpha M and the beta2 subunits. However, the role of the alpha M beta-propeller in ligand binding remains less well defined, and the functional residues are still unknown. In the present study, we studied the function of the alpha M beta-propeller in specific ligand recognition by alpha M beta 2 using a number of different approaches, and we report four major findings. 1) Substitution of five individual segments (Asp398-Ala402, Leu412-Leu419, Tyr426-Met434, Phe435-Glu443, and Ser444-Thr451) within the W4 blade of the beta-propeller with their homologous counterparts in integrin alpha2 abrogated C3bi binding, whereas substitution of eight other segments outside this blade had no effect. 2) These five mutants defective in C3bi binding supported strong alpha M beta 2-mediated and cation-dependent cell adhesion to fibrinogen, suggesting that the conformations of these five defective mutants were intact. 3) Polyclonal antibodies recognizing sequences within the W4 blade significantly blocked C3bi binding by wild-type alpha M beta 2. 4) A synthetic peptide corresponding to Gln424-Gly440 within W4 interacted directly with C3bi. In conclusion, our data demonstrate that the W4 blade (residues Asp398 to Thr451) is involved specifically in C3bi but not fibrinogen binding to alpha M beta 2. Altogether, our study supports a model in which three separate domains of alpha M beta 2 (the alpha MI-domain, the alpha M beta-propeller, and the beta 2I-domain) function together and contribute to the formation of the C3bi-binding site.     

Characterization of alphaX I-domain binding to Thy-1

The beta2 integrins are found exclusively in leukocytes and they are composed of a common beta chain, CD18, and one of four unique alpha chains, CD11a (alphaL subunit), CD11b (alphaM subunit), CD11c (alphaX subunit), or CD11d (alphaD subunit). alphaX-beta2 which binds several ligands including fibrinogen and iC3b is expressed in monocytes/macrophages and dendritic cells playing an important role in the host defense. Despite the unique characteristics on expression and regulation, alphaX-beta2 is less functionally characterized than other beta2 integrins. To understand the biological function of alphaX-beta2 more, we tested the possibility that alphaX-beta2 binds Thy-1, a membrane protein involved in cell adhesion and signaling regulation in neurons and T cells. Here we report that a ligand binding moiety of alphaX-beta2, the I-domain, bound Thy-1 in a specific and divalent cation-dependent manner. The dissociation constant (K(D)) of alphaX I-domain binding to Thy-1 was 1.16muM and the affinity of the binding was roughly 2-fold higher than that of alphaM I-domain. Amino acid substitutions on the betaD-alpha5 of alphaX I-domain (D249, KE243/244) showed low affinities for Thy-1 while other point mutations on alpha3-alpha4 and betaE-alpha6 loops of I-domain did not, suggesting that Thy-1 recognizes the portion of a betaD-alpha5 loop, possibly alpha5 helix. Taken together, these results indicate that alphaX-beta2 specifically interacts with Thy-1. Additionally, kinetic analysis reveals a moderate affinity interaction in the presence of divalent cations. Given the reported role of Thy-1 in the regulation of T cell homeostasis and proliferation, it is tempting to speculate that alphaX-beta2 may be involved in Thy-1 function.     

Epitope mapping of antibodies to the C-terminal region of the integrin beta 2 subunit reveals regions that become exposed upon receptor activation

The cysteine-rich repeats in the stalk region of integrin beta subunits appear to convey signals impinging on the cytoplasmic domains to the ligand-binding headpiece of integrins. We have examined the functional properties of mAbs to the stalk region and mapped their epitopes, providing a structure-function map. Among a panel of 14 mAbs to the beta(2) subunit, one, KIM127, preferentially bound to alpha(L)beta(2) that was activated by mutations in the cytoplasmic domains, and by Mn(2+). KIM127 also bound preferentially to the free beta(2) subunit compared with resting alpha(L)beta(2). Activating beta(2) mutations also greatly enhanced binding of KIM127 to integrins alpha(M)beta(2) and alpha(X)beta(2). Thus, the KIM127 epitope is shielded by the alpha subunit, and becomes reexposed upon receptor activation. Three other mAbs, CBR LFA-1/2, MEM48, and KIM185, activated alpha(L)beta(2) and bound equally well to resting and activated alpha(L)beta(2), differentially recognized resting alpha(M)beta(2) and alpha(X)beta(2), and bound fully to activated alpha(M)beta(2) and alpha(X)beta(2). The KIM127 epitope localizes within cysteine-rich repeat 2, to residues 504, 506, and 508. By contrast, the two activating mAbs CBR LFA-1/2 and MEM48 bind to overlapping epitopes involving residues 534, 536, 541, 543, and 546 in cysteine-rich repeat 3, and the activating mAb KIM185 maps near the end of cysteine-rich repeat 4. The nonactivating mAbs, 6.7 and CBR LFA-1/7, map more N-terminal, to subregions 344-432 and 432-487, respectively. We thus define five different beta(2) stalk subregions, mAb binding to which correlates with effect on activation, and define regions in an interface that becomes exposed upon integrin activation.     

Integrin cytoplasmic domains mediate inside-out signal transduction

We analyzed the binding of fibronectin to integrin alpha 5 beta 1 in various cells; in some cells fibronectin bound with low affinity (e.g., K562 cells) whereas in others (e.g., CHO), it bound with high affinity (Kd approximately 100 nM) in an energy-dependent manner. We constructed chimeras of the extracellular and transmembrane domains of alpha IIb beta 3 joined to the cytoplasmic domains of alpha 5 beta 1. The affinity state of these chimeras was assessed by binding of fibrinogen or the monoclonal antibody, PAC1. The cytoplasmic domains of alpha 5 beta 1 conferred an energy-dependent high affinity state on alpha IIb beta 3 in CHO but not K562 cells. Three additional alpha cytoplasmic domains (alpha 2, alpha 6A, alpha 6B) conferred PAC1 binding in CHO cells, while three others (alpha M, alpha L, alpha v) did not. In the high affinity alpha chimeras, cotransfection with a truncated (beta 3 delta 724) or mutated (beta 3(S752-->P)) beta 3 subunit abolished high affinity binding. Thus, both cytoplasmic domains are required for energy-dependent, cell type-specific affinity modulation. In addition, mutations that disrupted a highly conserved alpha subunit GFFKR motif, resulted in high affinity binding of ligands to alpha IIb beta 3. In contrast to the chimeras, the high affinity state of these mutants was independent of cellular metabolism, cell type, and the bulk of the beta subunit cytoplasmic domain. Thus, integrin cytoplasmic domains mediate inside-out signaling. Furthermore, the highly conserved GFFKR motif of the alpha subunit cytoplasmic domain maintains the default low affinity state.     

Regulated unmasking of the cryptic binding site for integrin alpha M beta 2 in the gamma C-domain of fibrinogen

Fibrinogen is a ligand for leukocyte integrin alpha(M)beta2 (CD11b/CD18, Mac-1) and mediates adhesion and migration of leukocytes during the immune-inflammatory responses. The binding site for alpha(M)beta2 resides in gammaC, a constituent subdomain in the D-domain of fibrinogen. The sequence gamma383-395 (P2-C) in gammaC was implicated as the major binding site for alpha(M)beta2. It is unknown why alpha(M)beta2 on leukocytes can bind to immobilized fibrinogen in the presence of high concentrations of soluble fibrinogen in plasma. In this study, we have investigated the accessibility of the binding site in fibrinogen for alpha(M)beta2. We found that the alpha(M)beta2-binding site in gammaC is cryptic and identified the mechanism that regulates its unmasking. Proteolytic removal of the small COOH-terminal segment(s) of gammaC, gamma397/405-411, converted the D100 fragment of fibrinogen, which contains intact gammaC and is not able to inhibit adhesion of the alpha(M)beta2-expressing cells, into the fragment D98, which effectively inhibited cell adhesion. D98, but not D100, bound to the recombinant alpha(M)I-domain, and the alpha(M)I-domain recognition peptide, alpha(M)(Glu253-Arg261). Exposure of the P2-C sequence in fibrinogen, D100, and D98 was probed with a site-specific mAb. P2-C is not accessible in soluble fibrinogen and D100 but becomes exposed in D98. P2-C is also unmasked by immobilization of fibrinogen onto a plastic and by deposition of fibrinogen in the extracellular matrix. Thus, exposure of P2-C by immobilization and by proteolysis correlates with unmasking of the alpha(M)beta2-binding site in the D-domain. These results demonstrate that conformational alterations regulate the alpha(M)beta2-binding site in gammaC and suggest that processes relevant to tissue injury and inflammation are likely to be involved in the activation of the alpha(M)beta2-binding site in fibrinogen.     

Distinct roles of beta1 metal ion-dependent adhesion site (MIDAS), adjacent to MIDAS (ADMIDAS), and ligand-associated metal-binding site (LIMBS) cation-binding sites in ligand recognition by integrin alpha2beta1

Integrin-ligand interactions are regulated in a complex manner by divalent cations, and previous studies have identified ligand-competent, stimulatory, and inhibitory cation-binding sites. In collagen-binding integrins, such as alpha2beta1, ligand recognition takes place exclusively at the alpha subunit I domain. However, activation of the alphaI domain depends on its interaction with a structurally similar domain in the beta subunit known as the I-like or betaI domain. The top face of the betaI domain contains three cation-binding sites: the metal-ion dependent adhesion site (MIDAS), the ADMIDAS (adjacent to MIDAS), and LIMBS (ligand-associated metal-binding site). The role of these sites in controlling ligand binding to the alphaI domain has yet to be elucidated. Mutation of the MIDAS or LIMBS completely blocked collagen binding to alpha2beta1; in contrast mutation of the ADMIDAS reduced ligand recognition but this effect could be overcome by the activating monoclonal antibody TS2/16. Hence, the MIDAS and LIMBS appear to be essential for the interaction between alphaI and betaI, whereas occupancy of the ADMIDAS has an allosteric effect on the conformation of betaI. An activating mutation in the alpha2 I domain partially restored ligand binding to the MIDAS and LIMBS mutants. Analysis of the effects of Ca(2+), Mg(2+), and Mn(2+) on ligand binding to these mutants showed that the MIDAS is a ligand-competent site through which Mn(2+) stimulates ligand binding, whereas the LIMBS is a stimulatory Ca(2+)-binding site, occupancy of which increases the affinity of Mg(2+) for the MIDAS.     

Folding and function of I domain-deleted Mac-1 and lymphocyte function-associated antigen-1

In those integrins that contain it, the I domain is a major ligand recognition site. The I domain is inserted between beta-sheets 2 and 3 of the predicted beta-propeller domain of the integrin alpha subunit. We deleted the I domain from the integrin alpha(M) and alpha(L) subunits to give I-less Mac-1 and lymphocyte function-associated antigen-1 (LFA-1), respectively. The I-less alpha(M) and alpha(L) subunits were expressed in association with the wild-type beta(2) subunit on the surface of transfected cells and bound to all the monoclonal antibodies mapped to the putative beta-propeller and C-terminal regions of the alpha(M) and alpha(L) subunits, suggesting that the folding of these domains is independent of the I domain. I-less Mac-1 bound to the ligands iC3b and factor X, but this binding was reduced compared with wild-type Mac-1. In contrast, I-less Mac-1 did not bind to fibrinogen or denatured bovine serum albumin. Binding to iC3b and factor X by I-less Mac-1 was inhibited by the function-blocking antibody CBRM1/32, which binds to the beta-propeller domain of the alpha(M) subunit. I-less LFA-1 did not bind its ligands intercellular adhesion molecule-1 and -3. Thus, the I domain is not essential for the folding, heterodimer formation, and surface expression of Mac-1 and LFA-1 and is required for binding to some ligands, but not others.     

Interaction of fibrin(ogen) with leukocyte receptor alpha M beta 2 (Mac-1): further characterization and identification of a novel binding region within the central domain of the fibrinogen gamma-module

The fibrinogen gamma-module sequences, gamma190-202 or P1, and gamma377-395 or P2, were implicated in interaction with the alpha(M)I-domain of the leukocyte receptor alpha(M)beta(2). P1 is an integral part of the gamma-module central domain, while P2 is inserted into this domain forming an antiparallel beta-strand with P1. We hypothesized earlier that separation of P2 from P1 may regulate interaction of fibrin(ogen) with leukocytes during the inflammatory response. To test the relative contributions of these sequences to the interaction and the effect of their separation, we prepared the recombinant gamma-module (gamma148-411) and its halves, gamma148-286 and gamma287-411 fragments containing P1 and P2, respectively, and evaluated their affinities for the recombinant alpha(M)I-domain. In a solid-phase binding assay, the immobilized gamma-module exhibited high affinity for alpha(M)I (K(d) = 22 nM), while the affinities of the isolated gamma148-286 and gamma287-411 halves were much lower (K(d)'s = 521 and 194 nM, respectively), indicating that both halves contribute to the interaction in a synergistic manner. This is consistent with the above hypothesis. Further, we prepared the recombinant gamma148-191 and gamma192-286 fragments corresponding to the NH(2)-terminal and central domains, respectively, as well as gamma148-226 containing P1, and tested their interaction with alpha(M)I. The immobilized gamma192-286 fragment bound to alpha(M)I with K(d) = 559 nM, while both gamma148-191 and gamma148-226 failed to bind suggesting that P1 does not contribute substantially to the binding and that the binding occurs mainly through the gamma227-286 region. To further localize a putative binding sequence, we cleaved gamma192-286 and analyzed the resulting peptides. The only alpha(M)I-binding activity was associated with the gamma228-253 peptide, indicating that this region of the central domain contains a novel alpha(M)beta(2)-binding sequence.