Role of the property of C-reactive protein to activate the classical pathway of complement in protecting mice from pneumococcal infection

C-reactive protein (CRP) is not an acute-phase protein in mice, and therefore, mice are widely used to investigate the functions of human CRP. It has been shown that CRP protects mice from pneumococcal infection, and an active complement system is required for full protection. In this study, we assessed the contribution of CRP's ability of activating the classical pathway of complement in the protection of mice from lethal infection with virulent Streptococcus pneumoniae type 3. We used two CRP mutants, Y175A and K114A. The Y175A CRP does not bind C1q and does not activate complement in human serum. The K114A CRP binds C1q and activates complement more efficiently than wild-type CRP. Passively administered, both CRP mutants and the wild-type CRP protected mice from infection equally. Infected mice injected with wild-type or mutant CRP had reduced bacteremia, resulting in lower mortality and increased longevity compared with mice that did not receive CRP. Thus, the protection of mice was independent of CRP-mediated activation of the classical pathway of complement. To confirm that human CRP does not differentiate between human and mouse complement, we analyzed the binding of human CRP to mouse C1q. Surprisingly, CRP did not react with mouse C1q, although both mutant and wild-type CRP activated mouse C3, indicating species specificity of CRP-C1q interaction. We conclude that the mouse is an unfit animal for exploring CRP-mediated activation of the classical complement pathway, and that the characteristic of CRP to activate the classical complement pathway has no role in protecting mice from infection.     

Studies on the structure and mechanism of a bacterial protein toxin by analytical ultracentrifugation and small-angle neutron scattering.

Pneumolysin, an important virulence factor of the human pathogen Streptococcus pneumoniae, is a pore-forming toxin which also possesses the ability to activate the complement system directly. Pneumolysin binds to cholesterol in cell membrane surfaces as a prelude to pore formation, which involves the oligomerization of the protein. Two important aspects of the pore-forming activity of pneumolysin are therefore the effect of the toxin on bilayer membrane structure and the nature of the self-association into oligomers undergone by it. We have used analytical ultracentrifugation (AUC) to investigate oligomerization and small-angle neutron scattering (SANS) to investigate the changes in membrane structure accompanying pore formation.Pneumolysin self-associates in solution to form oligomeric structures apparently similar to those which appear on the membrane coincident with pore formation. It has previously been demonstrated by us using site-specific chemical derivatization of the protein that the self-interaction preceding oligomerization involves its C-terminal domain. The AUC experiments described here involved pneumolysin toxoids harbouring mutations in different domains, and support our previous conclusions that self-interaction via the C-terminal domain leads to oligomerization and that this may be related to the mechanism by which pneumolysin activates the complement system.SANS data at a variety of neutron contrasts were obtained from liposomes used as model cell membranes in the absence of pneumolysin, and following the addition of toxin at a number of concentrations. These experiments were designed to allow visualization of the effect that pneumolysin has on bilayer membrane structure resulting from oligomerization into a pore-forming complex. The structure of the liposomal membrane alone and following addition of pneumolysin was calculated by the fitting of scattering equations directly to the scattering curves. The fitting equations describe scattering from simple three-dimensional scattering volume models for the structures present in the sample, whose dimensions were varied iteratively within the fitting program. The overall trend was a thinning of the liposome surface on toxin attack, which was countered by the formation of localized structures thicker than the liposome bilayer itself, in a manner dependent on pneumolysin concentration. At the neutron contrast match point of the liposomes, pneumolysin oligomers were observed. Inactive toxin appeared to bind to the liposome but not to cause membrane alteration; subsequent activation of pneumolysin in situ brought about changes in liposome structure similar to those seen in the presence of active toxin. We propose that the changes in membrane structure on toxin attack which we have observed are related to the mechanism by which pneumolysin forms pores and provide an important perspective on protein/membrane interactions in general. We discuss these results in the light of published data concerning the interaction of gramicidin with bilayers and the hydrophobic mismatch effect.     

An intact phosphocholine binding site is necessary for transgenic rabbit C-reactive protein to protect mice against challenge with platelet-activating factor

C-reactive protein (CRP), an acute phase protein in humans and rabbits, is part of the innate immune system. The role of CRP in host defense has been thought to be largely due to its ability to bind phosphocholine, activate complement, and interact with IgGRs (FcgammaRs). We have shown previously that transgenic rabbit CRP (rbCRP) protects mice from lethal challenges with platelet-activating factor (PAF). To investigate the mechanism of this protection, we created additional lines of transgenic mice that express either wild-type rbCRP, a variant of rbCRP with altered complement activation activity (Y175A), or a variant of rbCRP unable to bind phosphocholine (F66Y/E81K). In the current study, these lines were challenged with a single injection of PAF and their survival monitored. Mice expressing wild-type and Y175A rbCRP were protected against challenge by PAF whereas mice expressing F66Y/E81K rbCRP were not. Treatment with cobra venom factor did not affect survival, confirming the results with the Y175A rbCRP variant and indicating that complement activation was not required to mediate protection. Both wild-type rbCRP and Y175A rbCRP were capable of binding PAF in vitro whereas F66Y/E81K rbCRP was not. Although other interpretations are possible, our results suggest that the protective effect of rbCRP against PAF is due to sequestration of PAF.     

Human C-reactive protein protects mice from Streptococcus pneumoniae infection without binding to pneumococcal C-polysaccharide

Human C-reactive protein (CRP) protects mice from lethality after infection with virulent Streptococcus pneumoniae type 3. For CRP-mediated protection, the complement system is required; however, the role of complement activation by CRP in the protection is not defined. Based on the in vitro properties of CRP, it has been assumed that protection of mice begins with the binding of CRP to pneumococcal C-polysaccharide on S. pneumoniae and subsequent activation of the mouse complement system. In this study, we explored the mechanism of CRP-mediated protection by utilizing two CRP mutants, F66A and F66A/E81A. Both mutants, unlike wild-type CRP, do not bind live virulent S. pneumoniae. We found that passively administered mutant CRP protected mice from infection as effectively as the wild-type CRP did. Infected mice injected with wild-type CRP or with mutant CRP lived longer and had lower mortality than mice that did not receive CRP. Extended survival was caused by the persistence of reduced bacteremia in mice treated with any CRP. We conclude that the CRP-mediated decrease in bacteremia and the resulting protection of mice are independent of an interaction between CRP and the pathogen and therefore are independent of the ability of CRP to activate mouse complement. It has been shown previously that the Fcgamma receptors also do not contribute to such CRP-mediated protection. Combined data lead to the speculation that CRP acts on the effector cells of the immune system to enhance cell-mediated cytotoxicity and suggest investigation into the possibility of using CRP-loaded APC-based strategy to treat microbial infections.     

Collectin CL-P1 utilizes C-reactive protein for complement activation

BackgroundC-reactive protein (CRP) is a plasma pentraxin family protein that is massively induced as part of the innate immune response to infection and tissue injury. CRP and other pentraxin proteins can activate a complement pathway through C1q, collectins, or on microbe surfaces. It has been found that a lectin-like oxidized LDL receptor 1 (LOX-1), which is an endothelial scavenger receptor (SR) having a C-type lectin-like domain, interacts with CRP to activate the complement pathway using C1q. However it remains elusive whether other lectins or SRs are involved in CRP-mediated complement activation and the downstream effect of the complement activation is also unknown.MethodsWe prepared CHO/ldlA7 cells expressing collectin placenta-1 (CL-P1) and studied the interaction of CRP with cells. We further used ELISA for testing binding between proteins. We tested for C3 fragment deposition and terminal complement complex (TCC) formation on HEK293 cells expressing CL-P1.ResultsHere, we demonstrated that CL-P1 bound CRP in a charge dependent manner and the interaction of CRP with CL-P1 mediated a classical complement activation pathway through C1q and additionally drove an amplification pathway using properdin. However, CRP also recruits complement factor H (CFH) on CL-P1 expressing cell surfaces, to inhibit the formation of a terminal complement complex in normal complement serum conditions.General SignificanceThe interaction of collectin CL-P1 with CFH might be key for preventing attack on “self” as a result of complement activation induced by the CL-P1 and CRP interaction.     

Protection from Streptococcus pneumoniae infection by C-reactive protein and natural antibody requires complement but not Fc gamma receptors

Streptococcus pneumoniae is an important human pathogen and the most common cause of community-acquired pneumonia. Both adaptive and innate immune mechanisms provide protection from infection. Innate immunity to S. pneumoniae in mice is mediated by naturally occurring anti-phosphocholine (PC) Abs and complement. The human acute-phase reactant C-reactive protein (CRP) also protects mice from lethal S. pneumoniae infection. CRP and anti-PC Ab share the ability to bind to PC on the cell wall C-polysaccharide of S. pneumoniae and to activate complement. CRP and IgG anti-PC also bind to Fc gamma R. In this study, Fc gamma R- and complement-deficient mice were used to compare the mechanisms of protection conferred by CRP and anti-PC Ab. Injection of CRP protected wild-type, FcR gamma-chain-, Fc gamma RIIb-, and Fc gamma RIII-deficient mice from infection. Complement was required for the protective effect of CRP as cobra venom factor treatment eliminated the effect of CRP in both gamma-chain-deficient and wild-type mice, and CRP failed to protect C3- or C4-deficient mice from infection. Unexpectedly, gamma-chain-deficient mice were extremely sensitive to pneumococcal infection. This sensitivity was associated with low levels of natural anti-PC Ab. Gamma-chain-deficient mice immunized with nonencapsulated S. pneumoniae produced both IgM- and IgG PC-specific Abs, were protected from infection, and were able to clear the bacteria from the bloodstream. The protection provided by immunization was eliminated by complement depletion. The results show that in this model of systemic infection with highly virulent S. pneumoniae, protection from lethality by CRP and anti-PC Abs requires complement, but not Fc gamma R.     

Pneumolysin: a double-edged sword during the host-pathogen interaction

The cholesterol-dependent cytolysins are pore-forming toxins. Pneumolysin is the cytolysin produced by Streptococcus pneumoniae and is a key virulence factor. The protein contains 471 amino acids and four structural domains. Binding to cholesterol is followed by oligomerization and membrane pore formation. Pneumolysin also activates the classical pathway of complement. Mutational analysis of the toxin and knowledge of sequence variation in outbreak strains suggests that additional activities of biologic importance exist. Pneumolysin activates a large number of genes, some by epigenetic modification, in eukaryotic cells and multiple signal transduction pathways. Cytolytic effects contribute to lung injury and neuronal damage while pro-inflammatory effects compound tissue damage. Nevertheless pneumolysin is a focal point of the immune response to pneumococci. Toll-like receptor 4-mediated recognition, osmosensing and T-cell responses to pneumolysin have been identified. In some animal models mutants that lack pneumolysin are associated with impaired bacterial clearance. Pneumolysin, which itself may induce apoptosis in neurones and other cells can activate host-mediated apoptosis in macrophages enhancing clearance. Disease pathogenesis, which has traditionally focused on the harmful effects of the toxin, increasingly recognises that a precarious balance between limited host responses to pneumolysin and either excessive immune responses or toxin-mediated subversion of host immunity exists.     

肺炎链球菌溶血素的研究进展

肺炎链球菌溶血素(Pneumolysin,PLY)是肺炎链球菌的一种重要毒力因子,包含4个结构域,是胆固醇依赖性细胞溶血素(CDCs)的家族成员之一。PLY可广泛作用于宿主组织细胞,发挥细胞毒性作用。PLY可活化补体经典途径,诱导巨噬细胞和单核细胞等产生细胞因子,介导机体免疫应答过程。PLY是肺炎链球菌蛋白疫苗和相关小分子药物研制的重要靶标。本文就PLY的结构、功能及相关疫苗的最新研究进展进行综述。     

Serotype 1 and 8 Pneumococci Evade Sensing by Inflammasomes in Human Lung Tissue

Streptococcus pneumoniae is a major cause of pneumonia, sepsis and meningitis. The pore-forming toxin pneumolysin is a key virulence factor of S. pneumoniae, which can be sensed by the NLRP3 inflammasome. Among the over 90 serotypes, serotype 1 pneumococci (particularly MLST306) have emerged across the globe as a major cause of invasive disease. The cause for its particularity is, however, incompletely understood. We therefore examined pneumococcal infection in human cells and a human lung organ culture system mimicking infection of the lower respiratory tract. We demonstrate that different pneumococcal serotypes differentially activate inflammasome-dependent IL-1β production in human lung tissue and cells. Whereas serotype 2, 3, 6B, 9N pneumococci expressing fully haemolytic pneumolysins activate NLRP3 inflammasome-dependent responses, serotype 1 and 8 strains expressing non-haemolytic toxins are poor activators of IL-1β production. Accordingly, purified haemolytic pneumolysin but not serotype 1-associated non-haemolytic toxin activates strong IL-1β production in human lungs. Our data suggest that the evasion of inflammasome-dependent innate immune responses by serotype 1 pneumococci might contribute to their ability to cause invasive diseases in humans.     

Mapping of the C1q binding site on rituxan, a chimeric antibody with a human IgG1 Fc

Rituxan (Rituximab) is a chimeric mAb with human IgG1 constant domains used in the therapy of non-Hodgkin's B cell lymphomas. This Ab targets B cells by binding to the cell-surface receptor, CD20. In our investigation of the mechanism of B cell depletion mediated by Rituximab, we first constructed mutants of Rituximab defective in complement activation but with all other effector functions intact. Our results demonstrate that the previously described C1q binding motif in murine IgG2b constituting residues E318, K320, and K322 is not applicable to a human IgG1 when challenged with either human, rabbit, or guinea pig complement. Alanine substitution at positions E318 and K320 in Rituximab had little or no effect on C1q binding and complement activation, whereas alanine substitution at positions D270, K322, P329, and P331 significantly reduced the ability of Rituximab to bind C1q and activate complement. We have also observed that concentrations of complement approaching physiological levels are able to rescue >60% of the activity of these mutant Abs with low affinity for C1q. These data localize the C1q binding epicenter on human IgG1 and suggest that there are species-specific differences in the C1q binding site of Igs.     

C4b-binding protein and factor H compensate for the loss of membrane-bound complement inhibitors to protect apoptotic cells against excessive complement attack

Apoptotic cells have been reported to down-regulate membrane-bound complement regulatory proteins (m-C-Reg) and to activate complement. Nonetheless, most apoptotic cells do not undergo complement-mediated lysis. Therefore, we hypothesized that fluid phase complement inhibitors would bind to apoptotic cells and compensate functionally for the loss of m-C-Reg. We observed that m-C-Reg are down-regulated rapidly upon apoptosis but that complement activation follows only after a gap of several hours. Coinciding with, but independent from, complement activation, fluid phase complement inhibitors C4b-binding protein (C4BP) and factor H (fH) bind to the cells. C4BP and fH do not entirely prevent complement activation but strongly limit C3 and C9 deposition. Late apoptotic cells, present in blood of healthy controls and systemic lupus erythematosus patients, are also positive for C4BP and fH. Upon culture, the percentage of late apoptotic cells increases, paralleled by increased C4BP binding. C4BP binds to dead cells mainly via phosphatidylserine, whereas fH binds via multiple interactions with CRP playing no major role for binding of C4BP or fH. In conclusion, during late apoptosis, cells acquire fluid phase complement inhibitors that compensate for the down-regulation of m-C-Reg and protect against excessive complement activation and lysis.     

Activation of classical pathway of complement cascade by soluble oligomers of prion

Mice defective for C1q complement factor show enhanced resistance to peripheral prion inoculation, and previous work demonstrated a direct interaction between C1q and conformationally modified PrP. However, the nature and physiological consequences of this interaction remain uncharacterized. PrP amino acids 141-159 has been identified as a potential C1q binding site; we show, by both surface plasmon resonance (SPR) spectroscopy and ELISA, that C1q and its globular region bind to PrP mutagenized in the region of interest with comparable efficiency to that of wild-type protein. To test PrP's ability to activate complement, soluble oligomers of the PrP constructs were made. Only PrP and mutagenized PrP oligomers activate the classical complement cascade while PrP monomer and the C-terminal domain, both in oligomeric and in monomeric form, failed to induce activation. This suggests that a conformational change in PrP, which occurs both when PrP is bound to an SPR sensor chip and when it undergoes oligomerization, is requisite for PrP/C1q interaction and activation of the complement cascade. We propose that C1q may act as a natural sensor for prions, leading to activation of the classical complement cascade, which could result in local inflammation and subsequent recruitment of the immune cells that prions initially infect.     

Binding and complement activation by C-reactive protein via the collagen-like region of C1q and inhibition of these reactions by monoclonal antibodies to C-reactive protein and C1q

Ligand-complexed C-reactive protein (CRP), like aggregated or complexed IgG, can react with C1q and activate the classical C pathway. Whereas IgG is known to bind to the globular region and not to the collagen-like region (CLR) of C1q, the site of interaction of C1q with CRP has not been defined. CRP-trimers were prepared by cross-linking and found to bind to C1q and to activate the C system. Heat-aggregated IgG (Agg-IgG) did not block the binding of CRP-trimers to C1q, nor did CRP-trimers block binding of Agg-IgG to C1q, suggesting that CRP and IgG bind at different sites. ELISA and Western blot analysis showed that CRP-trimers bound to the CLR, whereas Agg-IgG bound only to the globular region; similarly, anti-CLR mAb inhibited binding of CRP-trimers to C1q whereas anti-globular region mAb did not. Reactivity with CRP-trimers as well as with Agg-IgG was retained after reduction/alkylation and SDS treatment of C1q. A group of 22 anti-CRP mAb directed against at least six distinct native-CRP epitopes and eight distinct neo-CRP epitopes was tested for ability to inhibit the CRP-CLR interaction; one mAb, anti-native CRP mAb 8D8, with strong inhibitory activity was identified. Fab' of 8D8 blocked binding of CRP-trimers to intact C1q as well as CLR, and also inhibited CRP (CRP-trimers and CRP-protamine complexes) induced C activation, but had no effect on C1q binding or C activation by Agg-IgG. These results indicate that a conformation-determined region on CRP binds to a sequence-determined region on the CLR of C1q in an interaction which leads to C activation. Anti-CRP and anti-C1q mAb that specifically inhibit this interaction are described.     

Topology and structure of the C1q-binding site on C-reactive protein

The host defense functions of human C-reactive protein (CRP) depend to a great extent on its ability to activate the classical complement pathway. The aim of this study was to define the topology and structure of the CRP site that binds C1q, the recognition protein of the classical pathway. We have previously reported that residue Asp(112) of CRP plays a major role in the formation of the C1q-binding site, while the neighboring Lys(114) hinders C1q binding. The three-dimensional structure of CRP shows the presence of a deep, extended cleft in each protomer on the face of the pentamer opposite that containing the phosphocholine-binding sites. Asp(112) is part of this marked cleft that is deep at its origin but becomes wider and shallower close to the inner edge of the protomer and the central pore of the pentamer. The shallow end of the pocket is bounded by the 112-114 loop, residues 86-92 (the inner loop), the C terminus of the protomer, and the C terminus of the pentraxin alpha-helix 169-176, particularly Tyr(175). Mutational analysis of residues participating in the formation of this pocket demonstrates that Asp(112) and Tyr(175) are important contact residues for C1q binding, that Glu(88) influences the conformational change in C1q necessary for complement activation, and that Asn(158) and His(38) probably contribute to the correct geometry of the binding site. Thus, it appears that the pocket at the open end of the cleft is the C1q-binding site of CRP.     

The Carbohydrate-linked Phosphorylcholine of the Parasitic Nematode Product ES-62 Modulates Complement Activation

Parasitic nematodes manufacture various carbohydrate-linked phosphorylcholine (PCh)-containing molecules, including ES-62, a protein with an N-linked glycan terminally substituted with PCh. The PCh component is biologically important because it is required for immunomodulatory effects. We showed that most ES-62 was bound to a single protein, C-reactive protein (CRP), in normal human serum, displaying a calcium-dependent, high-avidity interaction and ability to form large complexes. Unexpectedly, CRP binding to ES-62 failed to efficiently activate complement as far as the C3 convertase stage in comparison with PCh-BSA and PCh-containing Streptococcus pneumoniae cell wall polysaccharide. C1q capture assays demonstrated an ES-62-CRP-C1q interaction in serum. The three ligands all activated C1 and generated C4b to similar extents. However, a C2a active site was not generated following ES-62 binding to CRP, demonstrating that C2 cleavage was far less efficient for ES-62-containing complexes. We proposed that failure of C2 cleavage was due to the flexible nature of carbohydrate-bound PCh and that reduced proximity of the C1 complex was the reason that C2 was poorly cleaved. This was confirmed using synthetic analogues that were similar to ES-62 only in respect of having a flexible PCh. Furthermore, ES-62 was shown to deplete early complement components, such as the rate-limiting C4, following CRP interaction and thereby inhibit classical pathway activation. Thus, flexible PCh-glycan represents a novel mechanism for subversion of complement activation. These data illustrate the importance of the rate-limiting C4/C2 stage of complement activation and reveal a new addition to the repertoire of ES-62 immunomodulatory mechanisms with possible therapeutic applications.     

Competitive binding of pentraxins and IgM to newly exposed epitopes on late apoptotic cells

A random distribution of phospholipids among the inner and outer leaflet of the cell membrane occurs during apoptosis and is known as membrane flip-flop. Flip-flopped cells have binding sites for various plasma proteins, such as IgM and the pentraxins C-reactive protein (CRP) and serum amyloid P component (SAP). In this study, we investigated whether pentraxins and IgM antibodies recognize the same binding sites on apoptotic cells, and whether phospholipids constitute these binding sites. Except for SAP which also bound to early apoptotic cells, pentraxins and IgM preferentially bound to late apoptotic cells. Competition experiments with different phosphatemonoesters revealed that CRP and SAP as well as part of the IgM bound to the phospholipids head groups, SAP mainly to phosphorylethanolamine, CRP to phosphorylcholine and phosphorylethanolamine and to a lesser extent to phosphorylserine, and IgM to phosphorylcholine and phosphorylserine. These results were confirmed in experiments in which proteins were adsorbed from plasma with artificial phospholipids particles. IgM and the pentraxins variably competed for the same binding sites on late apoptotic cells, SAP having the highest and CRP the lowest apparent affinity. We conclude that CRP, SAP, and part of the IgM bind to the phospholipid head groups exposed on apoptotic cells. This shared specificity as well as their shared capability to activate complement, suggest that IgM and the pentraxins CRP and SAP exert similar functions in the removal of apoptotic cells.     

Serum amyloid P component binds to histones and activates the classical complement pathway.

Two members of the pentraxin family of proteins, C-reactive protein (CRP) and serum amyloid P component (SAP), bind to chromatin and may be involved in the solubilization and clearance of nuclear material. Previous studies demonstrated that CRP binding to chromatin is mediated by histones. SAP differs from CRP in being able to bind to DNA, but SAP binding to histones has not been reported. CRP is an activator of the classical C pathway, and C-dependent cleavage of chromatin in the presence of CRP and serum has been shown. Oligomers of SAP have recently been found to bind to C1q and consume total C and C4, indicating that SAP can activate C as well. The present study examined CRP and SAP binding to histones H1 and H2A and C activation after binding. SAP binding to histones H1 and H2A was observed as well as SAP binding to chromatin. In contrast to CRP, SAP binding to chromatin did not require H1. SAP partially inhibited CRP binding to chromatin and to H1. However, neither pentraxin inhibited binding of the other to H2A. Binding of either CRP or SAP to H2A activated C in SAP-depleted serum leading to the deposition of C4 and C3. C activation required C1q and produced C4d indicating that it occurred through the classical pathway. These findings demonstrate that CRP and SAP share histone as well as chromatin binding, and that both pentraxins can activate the classical C pathway after ligand binding.     

Three pentraxins C-reactive protein,serum amyloid p component and pentraxin 3 mediate complement activation using Collectin CL-P1

BackgroundPentraxins (PTXs) are a superfamily of multifunctional conserved proteins involved in acute-phase responses. Recently, we have shown that collectin placenta 1 (CL-P1) and C-reactive protein (CRP) mediated complement activation and failed to form terminal complement complex (TCC) in normal serum conditions because of complement factor H inhibition.MethodsWe used CL-P1 expressing CHO/ldlA7 cells to study the interaction with PTXs. Soluble type CL-P1 was used in an ELISA assay for the binding, C3 and TCC deposition experiments. Furthermore, we used our previously established CL-P1 expressing HEK293 cells for the C3 fragment and TCC deposition assay.ResultsWe demonstrated that CL-P1 also bound serum amyloid p component (SAP) and pentraxin 3 (PTX3) to activate the classical pathway and the alternative pathway using factor B. CRP and PTX3 further amplified complement deposition by properdin. We found that CRP and PTX3 recruit CFH, whereas SAP recruits C4 binding protein on CL-P1 expressing cell surfaces to prevent the formation of TCC in normal serum conditions. In addition, depletion of CFH, C4BP and complement factor I (CFI) failed to prevent TCC formation both in ELISA and cell experiments. Furthermore, soluble complement receptor 1, an inhibitor of all complement pathways prevents PTX induced TCC formation.ConclusionOur current study hypothesizes that the interaction of pentraxins with CL-P1 is involved in complement activation.General significanceCL-P1 might generally inhibit PTX induced complement activation and host damage to protect self-tissues.