Characterization of the beta-chain N-terminus heterogeneity and the alpha-chain C-terminus of human platelet GPIIb. Posttranslational cleavage sites

Evolution of developmental and comparative immunology in poultry: The regulators and the regulated

Avian has a unique immune system that evolved in response to environmental pressures in all aspects of innate and adaptive immune responses, including localized and circulating lymphocytes, diversity of immunoglobulin repertoire, and various cytokines and chemokines. All of these attributes make birds an indispensable vertebrate model for studying the fundamental immunological concepts and comparative immunology. However, research on the immune system in birds lags far behind that of humans, mice, and other agricultural animal species, and limited immune tools have hindered the adequate application of birds as disease models for mammalian systems. An in-depth understanding of the avian immune system relies on the detailed studies of various regulated and regulatory mediators, such as cell surface antigens, cytokines, and chemokines. Here, we review current knowledge centered on the roles of avian cell surface antigens, cytokines, chemokines, and beyond. Moreover, we provide an update on recent progress in this rapidly developing field of study with respect to the availability of immune reagents that will facilitate the study of regulatory and regulated components of poultry immunity. The new information on avian immunity and available immune tools will benefit avian researchers and evolutionary biologists in conducting fundamental and applied research.

Solution properties of full-length integrin alpha(IIb)beta3 refined models suggest environment-dependent induction of alternative bent /extended resting states

The recently published novel integrin alpha(IIb)beta(3) ectodomain crystallographic structure and NMR structures of its transmembrane/cytoplasmic segments were employed to refine previously developed molecular models. Alternative complete alpha(IIb)beta(3) models were built and evaluated, and their shape was compared with EM maps and their computed hydrodynamic/conformational properties were compared with the available experimental data. A partially extended/closed model, or a mixture of bent/closed and extended/closed conformations, are both compatible with the results of a recent small-angle neutron scattering study of Triton X-100-solubilized resting alpha(IIb)beta(3), while new electron microscopy evidence of nanodiscs-embedded alpha(IIb)beta(3) supports the bent/closed resting form. However, only an extended/closed model matches well the hydrodynamics of either octyl-glucoside-solubilized or nanodiscs-embedded resting alpha(IIb)beta(3), suggesting that different solubilization strategies and substrate interactions might operate a conformational selection between alternative, stable states. Furthermore, extended/open models are required to match the electron tomography map and the hydrodynamics following the priming-induced beta(3) hybrid domain swing-out, but without immediate full tail separation. Importantly, both extension and opening transitions can occur by pivoting at the recently identified beta(3) hinge point, which does not appear to be freely flexible. The structure and mechanism of action of integrins thus seem to depend on discrete transitions and to be more tightly coupled to the local environment than previously thought.

NMR analysis of structure and dynamics of the cytosolic tails of integrin alpha IIb beta 3 in aqueous solution

The structural and dynamic properties of the cytosolic tails of the adhesion receptor integrin alphaIIbbeta3, fused to a coiled-coil construct via (Gly)(3) linkers, were studied in aqueous solution by nuclear magnetic resonance (NMR) spectroscopy. Both tails were largely flexible and unstructured, although, in the beta3 tail, residues Arg(724)-Ala(735) have a propensity to form a helical structure and residues Asn(744)-Tyr(747) (NPLY) have a propensity to adopt reverse-turn conformations. The mutation beta3(Y747A) disrupted this reverse-turn tendency and markedly reduced the affinity of the head domain of the cytoskeletal protein, talin for the beta3 tail. Omission of the (Gly)(3) linker connecting the coiled-coiled helices and the integrin tails lead to helix propagation into the beta3 tail extending up to eight residues. A variety of different tail constructs were made and studied to reveal tail-tail interactions, but surprisingly no significant interactions between both tails could be detected within the context of our constructs. These results provide structural insight into a highly conserved beta tail motif (NPXY/F) required for integrin signaling and highlight a second transiently structured region (residues Arg(724)-Ala(735)), which might also be of functional significance.

Identification of the cleavage sites in the alpha6A integrin subunit: structural requirements for cleavage and functional analysis of the uncleaved alpha6Abeta1 integrin

The alpha6A and alpha6B integrin subunits are proteolytically cleaved during biosynthesis into a heavy chain (120 kDa) that is disulphide-linked to one of two light chains (31 or 30 kDa). Analysis of the structure of the alpha6A subunit on the carcinoma cell line T24 and human platelets demonstrated that the two light chains of alpha6 are not differentially glycosylated products of one polypeptide. Rather they possess different polypeptide backbones, which presumably result from proteolytic cleavage at distinct sites in the alpha6 precursor. Mutations were introduced in the codons for the R876KKR879, E883K884, R890K891 and R898K899 sequences, the potential proteolytic cleavage sites, and wild-type and mutant alpha6A cDNAs were transfected into K562 cells. The mutant alpha6A integrin subunits were expressed in association with endogenous beta1 at levels comparable to that of wild-type alpha6Abeta1. A single alpha6 polypeptide chain (150 kDa) was precipitated from transfectants expressing alpha6A with mutations or deletions in the RKKR sequence. Mutations in the EK sequence yielded alpha6A subunits that were cleaved once into a heavy and a light chain, whereas alpha6A subunits with mutations in one of the two RK sequences were, like wild-type alpha6A, cleaved into one heavy and two light chains. Thus a change in the RKKR sequence prevents the cleavage of alpha6. The EK site is the secondary cleavage site, which is used only when the primary site (RKKR) is intact. Microsequencing of the N-termini of the two alpha6A light chains from platelets demonstrated that cleavage occurs after Arg879 and Lys884. Because alpha6(RKKG), alpha6(GKKR) and alpha6(RGGR) subunits were not cleaved it seems that both the arginine residues and the lysine residues are essential for cleavage of RKKR. alpha6A mutants with the RKKR sequence shifted to the EK site, in such a way that the position of the arginine residue after which cleavage occurs corresponds exactly to Lys884, were partly cleaved, whereas alpha6A mutants with the RKKR sequence shifted to other positions in the alpha6A subunit, including one in which it was shifted two residues farther than the EK cleavage site, were not cleaved. In addition, alpha6A mutants with an alpha5-like cleavage site, i.e. arginine, lysine and histidine residues at positions -1, -2 and -6, were not cleaved. Thus both an intact RKKR sequence and its proper position are essential. After activation by the anti-beta1 stimulatory monoclonal antibody TS2/16, both cleaved and uncleaved alpha6Abeta1 integrins bound to laminin-1. The phorbol ester PMA, which activates cleaved wild-type and mutant alpha6Abeta1, did not activate uncleaved alpha6Abeta1. Thus uncleaved alpha6Abeta1 is capable of ligand binding, but not of inside-out signalling. Our results suggest that cleavage of alpha6 is required to generate a proper conformation that enables the affinity modulation of the alpha6Abeta1 receptor by PMA.

Thermal stability of individual domains in platelet glycoprotein IIbIIIa

Thermal denaturation of platelet glycoprotein IIbIIIa (integrin alpha IIb beta 3) was investigated by spectrofluorimetry and differential scanning calorimetry (DSC). Two forms of the protein were compared: active IIbIIIa, i.e., that fraction that binds to RGD-Sepharose, and inactive IIbIIIa, the non-binding fraction. At pH 8.5 in the presence of octyl glucoside and Ca2+ both forms exhibited a broad complex endotherm consisting of a well expressed low-temperature heat-absorption peak in the range of 40-65 degrees C followed by a broad peak stretching over 65-110 degrees C. Each endotherm could be deconvoluted into at least eight transitions reflecting the melting of at least this many independently folded domains. The first two transitions in the region of the low-temperature peak had similar positions in both forms while at least some of the other transitions occurred at higher temperature in the active protein suggesting that some of the domains are more stable in the latter. When both fractions of IIbIIIa were heated in the fluorometer a sigmoidal transition was observed in the region of the first endothermic peak where the two thermolabile domains melt. This transition was destabilized by 15 degrees C in the presence of EDTA, suggesting that these domains are formed by the 243-468 region of the IIb subunit which contains four Ca(2+)-binding motifs. It was further stabilized by 3 degrees C upon addition of the GRGDSPK peptide in the presence of Ca2+ while in EDTA the peptide had no effect. This is consistent with the involvement of Ca(2+)-binding region in the formation of the ligand-binding site. A 66-kDa chymotryptic fragment, containing the 17-kDa NH2-terminal portion of the IIIa subunit disulfide-linked to its 50-kDa COOH-terminal portion including the cysteine-rich core, exhibited a fluorescence-detected Ca(2+)-independent transition in the region where the higher temperature DSC-detected transitions occur suggesting that some of the latter may be connected with the melting of the corresponding portions of IIbIIIa.

Localization of the cross-linking sites of RGD and KQAGDV peptides to the isolated fibrinogen receptor, the human platelet integrin glycoprotein IIb/IIIa. Influence of peptide length

The non-covalent and Ca(2+)-dependent heterodimer GPIIb/IIIa, formed by platelet glycoproteins IIb (GPIIb) and IIIa (GPIIIa), also known as the integrin alpha IIb beta 3, is the inducible receptor for fibrinogen and other adhesive proteins on the surface of activated platelets. A fraction of the isolated GPIIb/IIIa in solution binds RGD or KQAGDV inhibitory peptides and, upon peptide removal, apparently acquires the capacity to bind fibrinogen ('activated' GPIIb/IIIa) [Du, X., Plow, E. F., Frelinger, A. L., III, O'Toole, T. E., Loftus, J. C. & Ginsberg, M. H. (1991) Cell 65, 409-416]. Photoaffinity labelling was used here to study the ligand binding site(s) of GPIIb/IIIa in solution, for which the peptides CKRKRKRKRRGDV (alpha 1), CGRGDF (alpha 2), CYHHLGGAKQAGDV (gamma 1) and CGAKQAGDV (gamma 2) were synthesized with a photoactivable cross-linker group and a fluorescent reporter group attached to the N-terminal cysteine residue. Contrary to the situation in activated platelets, both GPIIb and GPIIIa were equally labelled by the four peptides and the cross-linking sites were localized by protein chemical analyses of the fluorescently labelled tryptic peptides of both subunits. Thus, the localization of the cross-linking sites in GPIIb varies considerably with the peptide length and is very different from that localization observed in activated platelets: alpha 2 and gamma 2 were found cross-linked to the N-terminal of both the heavy (GPIIbH 42-73) and the light (GPIIbL2 30-75) chains of GPIIb; while the longer peptides alpha 1 and gamma 1 were cross-linked to the C-terminal of GPIIbH within the 696-724 and 752-768 peptide stretches, respectively. On the other hand, the cross-linking sites of the four inhibitory peptides in GPIIIa were found mainly within the proteolysis susceptible region, between the N-terminal (GPIIIa 1-52) and the core (GPIIb 423-622) highly disulphide-bonded domains, observing that the longer the peptide the closer the cross-linking site is to the N-terminal of GPIIIa: alpha 1 at GPIIIa 63-87 and 303-350; gamma 1 at GPIIIa 9-37; alpha 2 at GPIIIa 151-191; and gamma 2 at GPIIIa 303-350. These results led us to the following conclusions. (a) The GPIIIa 100-400 region contributes to the ligand-binding domain in GPIIb/IIIa both in solution and in activated platelets.(ABSTRACT TRUNCATED AT 400 WORDS)

Proteolytic dissection of the isolated platelet fibrinogen receptor, integrin GPIIb/IIIa. Localization of GPIIb and GPIIIa sequences putatively involved in the subunit interface and in intrasubunit and intrachain contacts

Human platelet glycoproteins IIb (GPIIb) and IIIa (GPIIIa) form the subunits of the Ca(2+)-dependent heterodimer GPIIb/IIIa, which belongs to the integrin family of phylogenetically related receptors mediating a wide variety of cell-cell and cell-substratum interactions. GPIIb/IIIa plays a central role in haemostasis as a receptor for fibrinogen and other adhesive proteins at the surface of activated platelets. The covalent structure of the subunits is largely known; however, the tertiary and quaternary structures of the heterodimer remain to be determined. To this end, our approach consisted of limited proteolysis of the isolated heterodimer with proteinases of different specificities, followed by protein-chemical and immunochemical analyses of the peptide fragments within each isolated proteolytic product. From the information obtained, we have drawn a rudimentary map which outlines the demarcation of compact domains and the subunit peptide stretches carrying the sequences putatively involved in intrachain, intrasubunit and intersubunit non-covalent connectivity in the heterodimer. Three compact domains have been well defined: one in the heavy (H) chain of GPIIb [GPIIbH-(600-700)], and two in GPIIIa, the N-terminal [GPIIIa-(1-52)] and the core [GPIIIa-(423-622)] domains. Between the latter two domains there is a proteolysis-susceptible region, which is partly involved in ligand binding [GPIIIa-(100-220)] and partly implicated as being in teh subunit interface of the heterodimer. Contrary to GPIIIa, GPIIbH is highly susceptible to proteolysis all along its sequence. Equally susceptible are the extracellular end of the transmembrane segment of both GPIIIa and the light (L) chain of GPIIb (GPIIbL), and the N-terminal end of GPIIbL. Three sequence stretches along the C-terminal half of GPIIbH, one sequence stretch in GPIIbL and three sequence stretches within the GPIIIa-(217-421) region were putatively involved in the subunit interface of the heterodimer. Most likely, the N-terminal end of GPIIbL is folded over the N- and C-terminal regions of GPIIbH, and the N-terminal end of GPIIbH is folded against the GPIIbH-(600-700) domain. This map of GPIIb/IIIa does not fit the current accommodation of the amino acid sequence of GPIIb and GPIIIa in the head/two-tails image of the heterodimer obtained by metal-rotary-shadowing electron microscopy.

Characterisation of the N-linked oligosaccharides of the light chain of human glycoprotein IIb by f.a.b.-m.s

The glycosylation of the light chain (GPIIbL) of glycoprotein IIb, one of the glycoproteins constituting the receptor for fibrinogen, fibronectin, and the von Willebrand factor on platelet cell surfaces, was investigated using fast-atom-bombardment mass spectrometry (f.a.b.-m.s.). Complex-type N-glycans were observed, attached to Asn-60. The most abundant oligosaccharide is a disialylated biantennary structure substituted with fucose on the chitobiose core. Mono-sialylated biantennary, and di- and tri-sialylated triantennary structures were found as minor constituents of the N-glycan population. The amino acid sequence of GPIIbL was fully mapped by f.a.b.-m.s., thereby providing the first direct evidence for the absence of O-glycosylation.

Activation of the fibrinogen receptor on human platelets exposed to alpha chymotrypsin. Relationship with a major proteolytic cleavage at the carboxyterminus of the membrane glycoprotein IIb heavy chain

The serine proteinase alpha chymotrypsin from bovine pancreas (CT) is known to expose fibrinogen binding sites on the surface of human platelets in the absence of cell activation and granular secretion. This is accompanied by the appearance of membrane-bound chymotryptic fragments of both glycoprotein (GP) IIb and GPIIIa, the two subunits of the platelet fibrinogen receptor, the GPIIb-IIIa complex. However, no clear relationship between discrete proteolytic event(s) within GPIIb-IIIa and fibrinogen-binding-site expression has yet been established. We have now evaluated the proteolysis of GPIIb-IIIa by CT by Western blot analyses using a panel of polyclonal and monoclonal antibodies against GPIIb or GPIIIa. The different proteolytic events were then correlated with the kinetics of the expression of active fibrinogen binding sites on platelets, as measured through the binding of 125I-labelled purified fibrinogen and to the capacity of CT-treated platelets to aggregate. Treatment of platelets with CT at 22 degrees C resulted in the expression of fibrinogen binding sites prior to cleavage of GPIIIa (Mr approximately 90,000) into a previously described, major membrane-bound fragment with Mr 60,000. In contrast, fibrinogen receptor expression closely paralleled a proteolytic cleavage at the carboxy terminus of the GPIIb heavy chain (Mr approximately 120,000), which was converted into a faster migrating species with Mr approximately 115,000). This proteolysis resulted in the release of a soluble peptide with an expected molecular mass of less than 3.7 kDa. Quantitation of this peptide using a competitive immunoenzymatic assay, confirmed that its release from the platelet surface correlated with the expression of fibrinogen binding sites and aggregability. When platelets were exposed to CT at 37 degrees C, a prompt increase in fibrinogen binding sites and platelet aggregability was observed, whereas the GPIIb heavy chain was rapidly converted into the carboxy-terminal-cleaved form. However, incubation at 37 degrees C for longer than 10 min resulted in extensive and simultaneous degradation of both the GPIIb heavy and light chains and of GPIIIa, with the latter being converted into the 60-kDa fragment. These later events were associated with a sharp decline of platelet aggregability and a reduction in the number of fibrinogen binding sites. These data allow us to propose that an early and limited proteolytic processing of the GPIIb component of the platelet fibrinogen receptor is associated with a shift of this receptor complex into a state which expresses specific binding sites for fibrinogen. Further cleavage of GPIIIa to generate the 60-kDa fragment results in loss of receptor activity.

A large-scale procedure for the isolation of integrin GPIIb/IIIa, the human platelet fibrinogen receptor

The heterodimer GPIIb/IIIa, formed by the Ca(2+)-dependent association of glycoproteins IIb (GPIIb) and IIIa (GPIIIa), is the major integrin at the platelet surface, where it serves as the receptor for fibrinogen and other adhesive proteins and plays a central role in platelet aggregation and in platelet adhesion to the subendothelium. Here we describe a procedure for the isolation of GPIIb/IIIa using as starting material either the whole particulate fraction, obtained by differential centrifugation after hypoosmotic lysis of glycerol-loaded platelets, or any of the fractions obtained by density gradient centrifugation of the whole particulate fraction. The procedure consists simply of differential extraction with Triton X-100 of the starting particulate fraction, anion-exchange chromatography of the 4% Triton X-100 supernatant, and size-exclusion chromatography of the GPIIb/IIIa-rich fraction retained in the ion-exchange column. The use of particulate fractions instead of whole platelets as the starting material for extraction together with differential extraction with Triton X-100 (two steps that are simple and inexpensive to perform) results in the early removal of many unwanted proteins, which otherwise would have to be removed at later stages at the expense of severely impairing the final yield of GPIIb/IIIa. Pure GPIIb/IIIa is obtained with a yield of about 48%, the highest so far reported, calculated with respect to the GPIIb and GPIIIa content in the starting particulate fraction. The final product can be stored in freeze-dried form without apparent changes in its physical and chemical properties.(ABSTRACT TRUNCATED AT 250 WORDS)

Assignment of disulphide bonds in human platelet GPIIIa. A disulphide pattern for the beta-subunits of the integrin family

Integrins are cell-surface heterodimers formed by the association of one alpha- and one beta-subunit. Glycoprotein IIIa (GPIIIa or beta 3 subunit) is the common beta-subunit of the beta 3 subfamily of integrins, which, when associated with glycoprotein IIb (GPIIb), constitutes the receptor for fibrinogen and other adhesive proteins at the platelet surface (the GPIIb-IIIa complex) and, when associated with the alpha v-subunit, constitutes the vitronectin receptor present in several cell types. Protein chemical analysis of GPIIIa allows us to define the following structural domains: the cysteine-rich and proteinase-resistant N-terminal domain (GPIIIa 1-62); the adhesive-protein-binding domain (GPIIIa 101-422); the cysteine-rich and proteinase-resistant core (GPIIIa 423-622); and the C-terminal domain comprising an extracellular subdomain (GPIIIa 623-692), a transmembrane subdomain (GPIIIa 693-721), and a cytoplasmic subdomain (GPIIIa 722-762). We also assign unambiguously the disulphide bonds within the N-terminal, the fibrinogen-binding and the C-terminal domains, and the two long-range disulphide bonds which join the N-terminus to the proteinase-resistant core (Cys5-Cys435) and the fibrinogen-binding domain to the extracellular side of the C-terminal domain (Cys406-Cys655). In addition, we propose three alternative models for the arrangement of the disulphide bonds within the core and of the disulphide bonds joining the core to the extracellular side of the C-terminal domain, consistent with our experimental findings, favouring temporarily that which imposes less steric hindrance for the formation of these disulphide bonds. On the basis of this information and on the highly conserved overall structure observed in the beta-subunits of the integrin family known so far, except in beta 4, we propose to extend the cysteine-pairing pattern and the structural domains outlined here for GPIIIa to all the beta-subunits of the integrin family.

Further studies on the topography of human platelet glycoprotein IIb. Localization of monoclonal antibody epitopes and the putative glycoprotein IIa- and fibrinogen-binding regions

Glycoprotein IIb (GPIIb) is a major glycoprotein of the human platelet plasma membrane, which together with glycoprotein IIIa (GPIIIa) forms a Ca2(+)-dependent heterodimer, GPIIb/IIIa, which serves as the major fibrinogen receptor in activated platelets. The precise localization of the epitopes for six anti-GPIIb monoclonal antibodies (M1-M6) has been determined by a combination of enzymic and chemical cleavage procedures, peptide isolation, N-terminal sequence analysis, peptide synthesis and enzyme immunoassay. The following localizations were found: M1, beta 1-16-36, beta 2-4-24; M2, alpha 747-755; M alpha 2, alpha 837-843; M3, alpha 849-857; M4, alpha 143-151; M5, alpha 550-558; M6, alpha 657-665. Besides considerations of the degree of exposure of these epitopes, several remarkable features are readily apparent. The earliest and main chymotryptic cleavage site of GPIIb in whole platelets is between alpha cysteine-545 and alpha phenylalanine-551. The epitope for M3 was located within the same sequence (alpha 842-857) as is the epitope for PMI-1 [Loftus, Plow, Frelinger, D'Souza, Dixon, Lacy, Sorge & Ginsberg (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 7114-7118] in spite of the fact that the exposure of the latter in whole platelets is EDTA-dependent whereas that in the former is not. The epitope for M5 shares full homology with the 540-548 peptide stretch of the alpha-subunit of the vitronectin receptor, and this antibody cross-reacts with endothelial cells. The M6 epitope is located in the 25 kDa membrane-bound fragment of GPIIb, which is most epitope is destroyed at an early stage of chymotrypic digestion. This suggests that this region of GPIIb, somewhere between the epitope for M5 (alpha 550-558) and the epitope for M2 (alpha 747-755), may carry the surface of interaction of GPIIb with GPIIIa in the GPIIb/IIIa heterodimer. Finally, the sequence where the epitope for M6 has been located (alpha 657-667) was the only one found to be hydropathically complementary to the gamma 402-411 peptide of fibrinogen within the amino acid sequence of both GPIIb and GPIIIa. This complementariness, the EDTA- or thrombin-dependence of the exposure of the alpha 657-665 stretch in whole platelets to M6 and the ability of this antibody to inhibit platelet aggregation led us to postulate that this peptide stretch is a putative binding site for fibrinogen in the platelet receptor.(ABSTRACT TRUNCATED AT 400 WORDS)