The interaction of C-reactive protein and serum amyloid P component with nuclear antigens

The pentraxins are a family of proteins characterized by cyclic pentameric structure, calcium-dependent ligand binding and sequence homology. The two main representatives of this family are the serum proteins, C-reactive protein (CRP) and serum amyloid P component (SAP). In man CRP is an acute phase reactant which increases up to 1000 fold during the acute phase response whereas SAP is a constitutive protein expressed at about 30 g/ml. These proteins activate complement through the classical pathway and participate in opsonization of particulate antigens and bacteria. In the past several years it has been determined that both of these pentraxins interact with nuclear antigens including chromatin and small nuclear ribonucleoproteins (snRNPs). Both CRP and SAP have nuclear transport signals which facilitate their entry into the nuclei of intact cells. Furthermore, these pentraxins have been shown to affect the clearance of nuclear antigens in vivo. It is now believed that one of the major functions of the pentraxins could be to interact with the nuclear antigens released from apoptotic or necrotic cells. This interaction could mitigate against deposition of these antigens in tissue and autoimmune reactivity.Abbreviations CRP C-reactive protein - HSA human serum albumin - PC phosphocholine - SAP serum amyloid P component - snRNP small nuclear ribonucleoprotein - SLE systemic lupus erythematosus     

The competition of serum amyloid protein and apoprotein E for binding with human serum albumin]

The relationship between the concentration of serum amyloid protein (SAP) isolated from human serum and the parameters of the protein elution during gel-filtration and alos with the efficiency of Ca(2+)-dependent SAP binding with sepharose 4B was studied. The dissociation of the SAP oligomeric form in solution and the interaction of the protein with human serum albumin with fully reduced S--S bridges due to the introduction of the additional hydrophobic surface was shown. Apoprotein E isolated from human plasma very-low-density lipoproteins replaced SAP in the complex with albumin.     

Selective inhibition of platelet activation by the amyloid P-component of serum

One component of amyloid, protein AP, has a characteristic pentameric structure and is identical with a 9.5s serum alpha 1-globulin designated serum amyloid P-component or SAP. Another pentameric molecule, the acute-phase reactant C-reactive protein (CRP), shares major amino acid sequence homology with SAP although, in man, SAP is not an acute-phase reactant. Recently, we demonstrated that heat-aggregated CRP (H-CRP), like heat-aggregated IgG, activates platelets to reactions of aggregation, secretion, and generation of thromboxane A2. We report here that physiologic concentrations of SAP inhibit platelet aggregation stimulated by H-CRP. SAP must be present before platelet challenge with H-CRP to be effective. Native (unaggregated) CRP does not inhibit platelet activation induced by H-CRP, and the platelet inhibitory effect of SAP is restricted because platelet responses to each heat-aggregated IgG, acid-soluble collagen, DNA, ADP, and thrombin remain unaltered in the presence of SAP. Thus, human SAP seems to selectively modulate platelet reactivity to modified CRP, and as such to down-regulate at least one aspect of the biologic capacity of its acute-phase homologue.     

Goodpasture antigen-binding protein/ceramide transporter binds to human serum amyloid P-component and is present in brain amyloid plaques

Serum amyloid P component (SAP) is a non-fibrillar glycoprotein belonging to the pentraxin family of the innate immune system. SAP is present in plasma, basement membranes, and amyloid deposits. This study demonstrates, for the first time, that the Goodpasture antigen-binding protein (GPBP) binds to human SAP. GPBP is a nonconventional Ser/Thr kinase for basement membrane type IV collagen. Also GPBP is found in plasma and in the extracellular matrix. In the present study, we demonstrate that GPBP specifically binds SAP in its physiological conformations, pentamers and decamers. The START domain in GPBP is important for this interaction. SAP and GPBP form complexes in blood and partly colocalize in amyloid plaques from Alzheimer disease patients. These data suggest the existence of complexes of SAP and GPBP under physiological and pathological conditions. These complexes are important for understanding basement membrane, blood physiology, and plaque formation in Alzheimer disease.     

Jeltraxin, a frog egg jelly glycoprotein, has calcium-dependent lectin properties and is related to human serum pentraxins CRP and SAP

The egg jelly that encapsulates amphibian eggs is essential for fertilization, but its molecular composition and roles remain largely unknown. We identified a calcium-dependent lectin from the pentraxin superfamily in the egg jelly coat from the South American burrowing frog, Lepidobatrachus laevis. This lectin, jeltraxin, was related to the host-response acute phase serum proteins C-reactive P component (CRP) and serum amyloid P component (SAP). The amino acid sequence of jeltraxin is 44% identical to that of Xenopus laevis CRP, 31-35% identical to those of mammalian CRP and SAP, and 21-27% identical to those of the large fusion pentraxins. Expression of jeltraxin mRNA was restricted to the oviduct, which distinguishes it as the first serum-related pentraxin not expressed in the liver. Purified jeltraxin was previously shown to exist in an oligomeric complex of approximately 250 kDa comprised of self-associating subunits. We have demonstrated by MALDI-TOF that this configuration is due to a decameric complex of 27.7 kDa subunits. Biotinylated jeltraxin bound to the high-molecular mass components of the egg jelly in a calcium-dependent manner with specificity for beta-galactose residues. On the basis of homology modeling, we predict that jeltraxin will coordinate two calcium ions. The function of jeltraxin will likely be related to its calcium-dependent lectin properties.     

Serum amyloid P component binds to Fc gamma receptors and opsonizes particles for phagocytosis

Serum amyloid P component (SAP) is a member of the pentraxin family of proteins. These proteins are characterized by cyclic pentameric structure, calcium-dependent ligand binding, and frequent regulation as acute-phase serum proteins. SAP is the serum precursor of the P component of amyloid. It binds to a broad group of molecules, including autoantigens, through a pattern recognition binding site. The related pentraxin, C-reactive protein (CRP), is a strong acute-phase reactant in man and an opsonin. We previously determined that the binding of CRP to leukocytes occurs through Fc receptors for IgG (FcgammaR). We now report that SAP also binds to FcgammaR and opsonizes particles for phagocytosis by human polymorphonuclear leukocytes (PMN). Specific, saturable binding of SAP to FcgammaRI, FcgammaRIIa, and FcgammaRIIIb expressed on transfected COS cells was detected using SAP-biotin and PE-streptavidin. Zymosan was used to test the functional consequences of SAP and CRP binding to FcgammaR. Both SAP and CRP bound to zymosan and enhanced its uptake by PMN. This enhanced phagocytosis was abrogated by treatment of PMN with wortmannin, a phosphatidylinositol-3 kinase inhibitor, or with piceatannol, a Syk inhibitor, consistent with uptake through FcgammaR. Treatment of PMN with phosphatidylinositol-specific phospholipase C to remove FcgammaRIIIb also decreased phagocytosis of SAP-opsonized zymosan, but not CRP-opsonized zymosan. These results suggest that SAP may function in host defense. In addition, as SAP binds to chromatin, a major immunogen in systemic lupus erythematosus, it may provide a clearance mechanism for this Ag through FcgammaR bearing cells.     

Ligand-assisted aggregation of proteins. Dimerization of serum amyloid P component by bivalent ligands

A comprehensive series of solution and crystallographic studies reveal how simple, achiral, bivalent ligands of the cyclic pyruvate of glycerol promote face-to-face complex formation of the pentraxin, serum amyloid P component (SAP) into decamers. SAP, a protein of the human innate immune system, is universally present in amyloids, including cerebral amyloid deposits found in the brain of Alzheimer disease patients. Removal of SAP through a specific aggregation mechanism mediated by multivalent ligands appears to provide therapeutic benefit in the progression of this disease. Crystallographic studies reveal that in our novel series of ligands only the methyl and carboxylate moieties of the pyruvate ketal directly interact with the protein, but the geometric constraints imposed by the tether dictate which of two chair conformations are adopted by the pyruvate dioxane ring. Solution studies, as interpreted through a simple thermodynamic model, account for the distribution of pentameric and decameric bound states at different ligand concentrations and indicate that differences in the flexibility of the tether determine the geometry and stability of the specific aggregates formed between SAP and two different bivalent ligands. The factors affecting the design of ligands promoting face-to-face protein dimerization as well as potential biological implications are discussed.     

Structural basis of ligand specificity in the human pentraxins, C-reactive protein and serum amyloid P component

The normal physiological roles of the phylogenetically conserved human plasma proteins C-reactive protein (CRP) and serum amyloid P component (SAP) are not known. Novel drugs targeting their ligand specificities are in clinical development as both proteins have significant pathophysiological effects, SAP in promoting amyloidosis and CRP in exacerbating ischemic injury. Both proteins bind to phosphoethanolamine and we show here that, under physiological conditions, phosphoethanolamine is bound with higher affinity by human SAP than by human CRP. An explanation is provided by X-ray crystal structures that show SAP residue Tyr74 allowing additional hydrophobic protein-ligand interactions compared with the equivalent Thr76 of CRP. Docking simulations show many more low energy positions for phosphoethanolamine bound by CRP than by SAP and are consistent with the crystallographic and functional binding results. These fundamental observations on structure-activity relationships will aid the design of improved pentraxin targeting drugs.     

Heparin influence on the complex of serum amyloid P component and complement C4b-binding protein

Serum amyloid P component (SAP) forms a calcium-dependent complex with C4b-binding protein (C4BP) in human serum. this study demonstrated that heparin interacted with SAP in a calcium-dependent manner and prevented formation of the SAP.C4BP complex. Furthermore, the SAP-heparin interaction interfered with SAP binding to membranes. Therefore, all three of these interactions involved similar sites on SAP, or each interaction sterically obstructed the other binding sites. In addition to heparin, SAP bound to heparan sulfate and chondroitin sulfate. In each case, a distinct multimeric species was generated. Gel filtration and sucrose density gradient ultracentrifugation suggested that heparin and heparan sulfate produced a dimer of SAP. The dimer appeared to be the most stable structure since it was not dissociated by excess heparin. While low molecular weight heparin interacted with SAP and inhibited SAP association with membranes, the SAP dimer was not detected in sucrose density gradient ultracentrifugation studies. Polybrene prevented the interaction between SAP and heparin in both a purified system and in human serum that was enriched in SAP and heparin. In contrast, Polybrene did not seem to alter the SAP.C4BP complex. While the function of the SAP.C4BP complex is unknown, it may be important for regulation of complement and/or transport of SAP to sites in the body. Dissociation of the SAP.C4BP complex by sulfated polysaccharides such as heparin may be a physiological response that could be important during tissue damage or complement activation.     

Serum amyloid P component is the major calcium-dependent specific DNA binding protein of the serum

Serum amyloid P component (SAP), a member of the highly conserved pentraxin family of plasma proteins, was found to be the only protein in whole normal or acute phase serum which underwent specific calcium-dependent binding to either single or double-stranded DNA immobilised on gel. Isolated purified SAP also bound to long chromatin, to H1-stripped chromatin and to native DNA in solution at physiological ionic strength. Pure SAP which had been immobilised on gel, specifically bound nucleosome core particles from solution. These observations strongly suggest that SAP may bind to extracellular chromatin and DNA in vivo and that this may be its physiological role.     

Structure and significance of N-linked sugar unit of human serum amyloid P component

Human serum amyloid P component (SAP) was digested with pronase P and a glycopeptide fraction was obtained by gel-permeation chromatography. Carbohydrate and amino-acid composition of the glycopeptide suggested that each subunit of SAP possesses an N-linked glycan, but no O-linked ones. The N-linked oligosaccharide of SAP was obtained by hydrazynolysis. The structure of the oligosaccharide, which was deduced by sequential digestion with exoglycosidases and subsequent gel filtration, was identical or very similar to that of human transferrin. Removal of sialic acids from SAP reduced the calcium-dependent binding activity for agarose by 7%, suggesting the terminal sialic acids were partially responsible for the binding.     

Pentraxin family of proteins interact specifically with phosphorylcholine and/or phosphorylethanolamine.

Pentraxins are a family of serum proteins characterized by five identical subunits that are noncovalently linked. The two major types of pentraxins are C-reactive protein (CRP) and serum amyloid P component (SAP). CRP proteins are identified by their calcium-dependent interaction with phosphorylcholine. This study showed that SAP also bound to phosphorylated compounds but had a high specificity for phosphorylethanolamine. Thus, human CRP and SAP show high specificity that is complementary for the related compounds, phosphorylcholine and phosphorylethanolamine, respectively. This relationship suggests a complementary and/or related function for the pentraxins. Pentraxins from other species were also examined. Mouse SAP showed binding interactions and specificity similar to human SAP. Female protein (FP) from hamster and rat CRP showed a hybrid specificity and bound to both phosphorylethanolamine and phosphorylcholine. All of the proteins that bound phosphorylethanolamine also associated with human C4b-binding protein (C4BP). With the exception of human and rat CRP, all the proteins also bound to vesicles containing acidic phospholipids. All of these binding interactions were calcium-dependent and mutually exclusive, suggesting that they involved the same site on the protein. These findings suggest possible ways to examine the function of the pentraxins.     

Independent association of serum amyloid P component, protein S, and complement C4b with complement C4b-binding protein and subsequent association of the complex with membranes

C4b-binding protein (C4BP) is a large complex assembly of eight subunits that functions as an inhibitor of the complement cascade. A portion of the C4BP in serum exists as a complex with protein S. This study demonstrated that another protein, serum amyloid P component (SAP), also formed a calcium-dependent complex with C4BP. The C4BP.SAP complex was detected by several methods including light scattering intensity, gel filtration, and sucrose density gradient ultracentrifugation. This complex was of high affinity relative to serum levels of these proteins so that no dissociation was detected at 3% of serum protein concentrations. The C4BP.SAP complex was also detected in normal serum and the results suggested that there was virtually no free SAP or uncomplexed C4BP in normal serum. In addition to its complex with C4BP, SAP underwent other calcium-dependent associations such as binding to phospholipid vesicles and self-aggregation. Self-aggregation was highly cooperative with kinetics corresponding to a reaction that was 6th-order with respect to calcium and required about 1.5 mM calcium. In contrast, formation of the SAP.C4BP complex and interaction of SAP with membranes required only about 0.4 and 1.0 mM calcium, respectively. Thus, selection of the correct conditions allowed study of the SAP.C4BP interaction without interference from self-aggregation. All three of these interactions of SAP were mutually exclusive and the SAP. C4BP interaction appeared to be favored over self-aggregation or binding of SAP to phospholipids. It seems likely that the biologically dominant interaction for SAP is with C4BP. The SAP.C4BP complex interacted with protein S and these binding sites appeared to be entirely independent. Furthermore, SAP had little or no effect on the ability of C4BP to bind C4b. Finally, the entire complex of proteins (C4BP, SAP, protein S, and C4b) could associate with membranes in the presence of calcium. Membrane binding occurred through the protein S component. This rather complicated assemblage of proteins probably functions in a regulatory role for the complement cascade or other biological systems. It is possible that elevated levels of SAP or nonequivalent levels of SAP and C4BP could contribute to certain pathological conditions.     

The interaction of human serum albumin in the native and fully reduced states with apolipoprotein E,serum amiloid protein and very low density lipoproteins from human plasma

• 1.1. Complex formation in a solution of apolipoprotein E (apoE) isolated from human plasma very low density lipoproteins (VLDL) and human serum albumin (HSA) in both native and fully reduced states was studied. The existence of a kinetically unstable complex of apoE and native albumin was shown. The complex became more stable with the reduction of the S—S links in the albumin molecules capable of forming aggregates under these conditions.
• 2.2. The interaction between native HSA as opposed to a fully reduced one and isolated VLDL particles was more pronounced, probably, due to the existence of amphipathic alpha-helical regions.
• 3.3. Dissociation of the serum amyloid protein (SAP) oligomeric form in solution and the interaction of the protein with fully reduced HSA owing to the provision with the additional hydrophobic surface was shown. ApoE displaced SAP from the complex with fully reduced albumin.
• 4.4. It is suggested that the ability of the apolipoprotein to interact with albumin is determined by internal stability of the molecular structure of the latter and the complexes detected in vitro may be a new transport form of apolipoproteins in lipid-free form in serum. It is assumed that competitive interactions in the HSA-SAP-apoE system may be involved in the development of secondary amyloidosis.

     

Effect of divalent metal ions and pH upon the binding reactivity of human serum amyloid P component, a C-reactive protein homologue, for zymosan. Preferential reactivity in the presence of copper and acidic pH

The serum amyloid P component (SAP) has been found to associate in vitro with a variety of polysaccharide and proteinaceous ligands including the yeast cell wall polysaccharide preparation, zymosan, in the presence of calcium at neutral pH. In the present study, we have investigated the role of copper and zinc and other divalent cations and acidic pH on the binding of SAP to zymosan. We report that binding occurs not only in the presence of calcium, but in the presence of copper, zinc, and cadmium as well. No binding occurs in the absence of added metal, or in the presence of barium, cobalt, magnesium, manganese, or nickel. 125I-SAP binding in the presence of metals is inhibited by presaturating the zymosan surface with unlabeled SAP. Whereas calcium-mediated binding decreases by more than 50% as the pH is lowered to 5, copper-mediated binding increases substantially at the more acidic pH values while zinc-mediated binding is essentially unchanged. These data indicate that, in addition to calcium at neutral pH, copper (and zinc) at neutral and particularly acidic pH values mediates SAP binding to polysaccharide ligands. This suggests that SAP may well be considered a copper- as well as a calcium-dependent protein under certain conditions and that this reactivity is favored under those conditions of lowered pH which may result from metabolic processes occurring at local sites of inflammation.     

Calcium-dependent polymerization of human serum amyloid P component is inhibited by heparin and dextran sulfate

The calcium-dependent polymerization of human serum amyloid P component (SAP) was spectrophotometrically monitored in 0.15 M NaCl at pH 7.5. The rate of the polymerization depended on the concentrations of SAP and Ca2+. It was shown for the first time that the calcium-dependent polymerization of SAP was inhibited by some sulfated polysaccharides. Most potent inhibitors were heparin and high molecular weight dextran sulfate of Mr 1.0.10(6). The inhibitory activity of glycosaminoglycans is accordant to their binding affinity for SAP, which was reported previously (Hamazaki, H. (1987) J. Biol. Chem. 262, 1456-1460). The polymerized SAP was reversibly dissociated by heparin and high molecular weight dextran sulfate. The results suggest that heparin and high molecular weight dextran sulfate may be a useful dissociating agent of polymerized SAP in amyloid deposits.     

Effect of Ca2+ ions on hydrodynamic properties of pentamer and decamer of C-reactive protein in solution

The molecular mass and sedimentation coefficient of native C-reactive protein in solution were determined by analytical ultracentrifugation in the presence and absence of calcium ions. Pentameric C-reactive protein was shown to be the major macroscopic form of this protein in solution. The removal of calcium ions from solution caused decompaction of the protein accompanied by changes in its hydrodynamic parameters. The sedimentation coefficient s20(0), w of pentameric C-reactive protein in solution containing 2 mM--Ca2+ (6.6S) exceeded that for C-reactive protein in solution containing 2 mM EDTA (6.4S). Analysis of average molecular masses Mw and Mz obtained from sedimentation data demonstrated that the solution of highly purified protein was not homogeneous. As shown by intermolecular crosslinking, the solution also contained the 241-kDa decamer of C-reactive protein (9.5S) as a separate macroscopic form, whose share hardly reached 10% in the presence of 2 mM Ca2+ and increased after removal of calcium ions. The decamers were shown to result from intermolecular association of the pentamers.     

Identification of Acidic pH-dependent Ligands of Pentameric C-reactive Protein

C-reactive protein (CRP) is a phylogenetically conserved protein; in humans, it is present in the plasma and at sites of inflammation. At physiological pH, native pentameric CRP exhibits calcium-dependent binding specificity for phosphocholine. In this study, we determined the binding specificities of CRP at acidic pH, a characteristic of inflammatory sites. We investigated the binding of fluid-phase CRP to six immobilized proteins: complement factor H, oxidized low-density lipoprotein, complement C3b, IgG, amyloid β, and BSA immobilized on microtiter plates. At pH 7.0, CRP did not bind to any of these proteins, but, at pH ranging from 5.2 to 4.6, CRP bound to all six proteins. Acidic pH did not monomerize CRP but modified the pentameric structure, as determined by gel filtration, 1-anilinonaphthalene-8-sulfonic acid-binding fluorescence, and phosphocholine-binding assays. Some modifications in CRP were reversible at pH 7.0, for example, the phosphocholine-binding activity of CRP, which was reduced at acidic pH, was restored after pH neutralization. For efficient binding of acidic pH-treated CRP to immobilized proteins, it was necessary that the immobilized proteins, except factor H, were also exposed to acidic pH. Because immobilization of proteins on microtiter plates and exposure of immobilized proteins to acidic pH alter the conformation of immobilized proteins, our findings suggest that conformationally altered proteins form a CRP-ligand in acidic environment, regardless of the identity of the protein. This ligand binding specificity of CRP in its acidic pH-induced pentameric state has implications for toxic conditions involving protein misfolding in acidic environments and favors the conservation of CRP throughout evolution.     

Serum amyloid P component controls chromatin degradation and prevents antinuclear autoimmunity.

Serum amyloid P component (SAP), a highly conserved plasma protein named for its universal presence in amyloid deposits, is the single normal circulating protein that shows specific calcium-dependent binding to DNA and chromatin in physiological conditions. The avid binding of SAP displaces H1-type histones and thereby solubilizes native long chromatin, which is otherwise profoundly insoluble at the physiological ionic strength of extracellular fluids. Furthermore, SAP binds in vivo both to apoptotic cells, the surface blebs of which bear chromatin fragments, and to nuclear debris released by necrosis. SAP may therefore participate in handling of chromatin exposed by cell death. Here we show that mice with targeted deletion of the SAP gene spontaneously develop antinuclear autoimmunity and severe glomerulonephritis, a phenotype resembling human systemic lupus erythematosus, a serious autoimmune disease. The SAP-/- mice also have enhanced anti-DNA responses to immunization with extrinsic chromatin, and we demonstrate that degradation of long chromatin is retarded in the presence of SAP both in vitro and in vivo. These findings indicate that SAP has an important physiological role, inhibiting the formation of pathogenic autoantibodies against chromatin and DNA, probably by binding to chromatin and regulating its degradation.     

Complement-dependent acute-phase expression of C-reactive protein and serum amyloid P-component

The acute-phase response (APR) is regulated by TNF-alpha, IL-1beta, and IL-6 acting alone, in combination, or in concert with hormones. The anaphylotoxin C5a, generated during complement activation, induces in vitro the synthesis of these cytokines by leukocytes and of acute-phase proteins by HepG2 cells. However, there is no clear evidence for a role of C5a or any other complement activation product in regulation of the APR in vivo. In this study, using human C-reactive protein (CRP) transgenic mice deficient in C3 or C5, we investigated whether complement activation contributes to induction of the acute-phase proteins CRP and serum amyloid P-component (SAP). Absence of C3 or C5 resulted in decreased LPS-induced up-regulation of the CRP transgene and the mouse SAP gene. Also, LPS induced both the IL-1beta and IL-6 genes in normocomplementemic mice, but in complement-deficient mice it significantly induced only IL-6. Like LPS injection, activation of complement by cobra venom factor led to significant elevation of serum CRP and SAP in normocomplementemic mice but not in complement-deficient mice. Injection of recombinant human C5a into human CRP transgenic mice induced the IL-1beta gene and caused significant elevation of both serum CRP and SAP. However, in human CRP transgenic IL-6-deficient mice, recombinant human C5a did not induce the CRP nor the SAP gene. Based on these data, we conclude that during the APR, C5a generated as a consequence of complement activation acts in concert with IL-6 and/or IL-1beta to promote up-regulation of the CRP and SAP genes.