Amplified gene expression in CD59-transfected Chinese hamster ovary cells confers protection against the membrane attack complex of human complement.

Protection against the pore-forming activity of the human C5b-9 proteins was conferred on a nonprimate cell by transfection with cDNA encoding the human complement regulatory protein CD59. CD59 was stably expressed in Chinese hamster ovary cells using the pFRSV mammalian expression vector. After cloning and selection, the transfected cells were maintained in media containing various concentrations of methotrexate, which induced surface expression of up to 4.2 x 10(6) molecules of CD59/cell. Phosphatidylinositol-specific phospholipase C removed greater than 95% of surface-expressed CD59 antigen, confirming that recombinant CD59 was tethered to the Chinese hamster ovary plasma membrane by a lipid anchor. The recombinant protein exhibited an apparent molecular mass of 21-24 kDa (versus 18-21 kDa for human erythrocyte CD59). After N-glycanase digestion, recombinant and erythrocyte CD59 comigrated with apparent molecular masses of 12-14 kDa, suggesting altered structure of asparagine-linked carbohydrate in recombinant versus erythrocyte CD59. The function of the recombinant protein was evaluated by changes in the sensitivity of the CD59 transfectants to the pore-forming activity of human C5b-9. Induction of cell-surface expression of CD59 antigen inhibited C5b-9 pore formation in a dose-dependent fashion. CD59 transfectants expressing greater than or equal to 1.2 x 10(6) molecules of CD59/cell were completely resistant to human serum complement. By contrast, CD59 transfectants remained sensitive to the pore-forming activity of guinea pig C8 and C9 (bound to human C5b67). Functionally blocking antibody against erythrocyte CD59 abolished the human complement resistance observed for the CD59-transfected Chinese hamster ovary cells. These results confirm that the C5b-9 inhibitory function of the human erythrocyte membrane is provided by CD59 and suggest that the gene for this protein can be expressed in xenotypic cells to confer protection against human serum complement.     

CD59a is the primary regulator of membrane attack complex assembly in the mouse

Gene-deleted mice have provided a potent tool in efforts to understand the roles of complement and complement-regulating proteins in vivo. In particular, mice deficient in the membrane regulators complement receptor 1-related gene/protein y, decay-accelerating factor, or CD59 have demonstrated homeostatic relevance and backcrossing between the strains has revealed cooperativity in regulation. In mouse, genes encoding decay-accelerating factor and CD59 have been duplicated and show differential expression in tissues, complicating interpretation and extrapolation of findings to man. The first described form of CD59, CD59a, is broadly distributed and deletion of the cd59a gene causes a mild hemolytic phenotype with increased susceptibility in complement-mediated disease models. The distribution of the second form, CD59b, was originally described as testis specific, but later by some as widespread. Deletion of the cd59b gene caused a severe hemolytic and thrombotic phenotype. To apply data from these mouse models to man it is essential to know the relative distribution and functional roles of these two forms of CD59. We have generated new specific reagents and used them in sensitive quantitative analyses to comprehensively characterize expression of mRNA and protein and functional roles of CD59a and CD59b in wild-type (wt) and CD59a-negative mice. cd59b mRNA was detected only in testis and, at very low levels, in bone marrow. CD59b protein was present on mature spermatozoa and precursors and, in trace amounts, erythrocytes. Erythrocyte CD59b did not inhibit complement lysis except when CD59a was absent or blocked. These data confirm that CD59a is the primary regulator of complement membrane attack in mouse.     

Further characterization of reproductive abnormalities in mCd59b knockout mice: a potential new function of mCd59 in male reproduction

CD59 is a GPI-linked membrane protein that inhibits formation of the membrane attack complex of complement. We reported recently that mice have two CD59 genes (termed mCd59a and mCd59b), and that the targeted deletion of mCd59b (mCd59b-/-) results in spontaneous hemolytic anemia and progressive loss of male fertility. Further studies of the reproductive abnormalities in mCd59b-/- mice reported in this study revealed the presence of abnormal multinucleated cells and increased apoptotic cells within the walls of the seminiferous tubules, and a decrease in the number, motility, and viability of sperm associated with a significant increase in abnormal sperm morphologies. Both the capacitation-associated tyrosine phosphorylation and the ionophore-induced acrosome reaction as well as luteinizing hormone, follicle-stimulating hormone, and testosterone serum levels were similar in mCd59b-/- and mCd59b+/+. Surprisingly, the functional deficiency of the complement protein C3 did not rescue the abnormal reproductive phenotype of mCd59b-/-, although it was efficient in rescuing their hemolytic anemia. These results indicate that the male reproductive abnormalities in mCd59b-/- are complement-independent, and that mCd59 may have a novel function in spermatogenesis that is most likely unrelated to its function as an inhibitor of membrane attack complex formation.     

Characterization of mouse DAF on transfectant cells using monoclonal antibodies which recognize different epitopes

Several membrane proteins prevent host cells from homologous complement attack. In humans, one such protein, decay-accelerating factor (DAF), exists as two isoforms, a GPI anchored form and a secreted form, which are generated by alternative splicing. DAF in mouse is also expressed as two isoforms, a GPI anchored form (GPI-DAF) and a transmembrane form (TM-DAF), which are produced from two separate genes. In this study, we transfected cDNA of mouse GPI-DAF or TM-DAF into Chinese hamster ovary (CHO) cells. Both isoforms of DAF on CHO cells were shown to regulate mouse complement C3 deposition mediated by the classical and alternative pathways and the inhibitory activity of both isoforms was species restricted. The two mouse DAF isoforms were effective against rat complement but not against human and guinea pig complement. Furthermore, we produced hamster mAbs to mouse DAF using GPI-DAF transfectant cells and established seven unique mAbs (RIKO-1-7). Western blotting analysis using RIKO-3, which reacts with both GPI-DAF and TM-DAF, and RIKO-4, which is an anti-GPI-DAF specific mAb, indicated that GPI-DAF was expressed on erythrocytes, spleen and testis, and that TM-DAF was expressed only in testis.     

Genomic structure, functional comparison, and tissue distribution of mouse Cd59a and Cd59b

CD59 is a crucial complement regulatory protein that inhibits the terminal step of the complement activation cascade by interfering with the binding of C9 to C5b-8, thus preventing the formation of the membrane attack complex (MAC). We recently reported that the mouse genome contains two Cd59 genes, while the human and rat genomes each contain only one Cd59 gene (Qian et al. 2000). Here, we describe the genomic structure, comparative activity, and tissue distribution of these two mouse genes, designated Cd59a and Cd59b. The mouse Cd59 genes encompass a total of 45.6 kb with each gene having four exons. Cd59a spans 19 kb, and Cd59b spans 15 kb, with approximately 11.6 kb of genomic DNA separating the two genes. The overall sequence similarity between Cd59a and Cd59b is approximately 60%. The sequence similarity between exon 2, exon 3, and exon 4 and the respective flanking regions between the two genes is over 85%, but exon 1 and its flanking regions are totally different. Comparative studies of the activity of both genes as inhibitors of MAC formation revealed that Cd59b has a specific activity that is six times higher than that of Cd59a. Using polyclonal antibodies specific to either Cd59a or Cd59b, we showed that Cd59a and Cd59b are both widely expressed in the kidneys, brain, lungs, spleen, and testis, as well as in the blood vessels of most mouse tissues. Interestingly, testicular Cd59a appeared to be expressed exclusively in spermatids, whereas Cd59b was expressed in more mature sperm cells. These results suggest that even though Cd59a and Cd59b are expressed in multiple tissues, they may play some different roles, particularly in reproduction. Received: 9 February 2001 / Accepted: 18 April 2001     

Inhibition of homologous complement by CD59 is mediated by a species-selective recognition conferred through binding to C8 within C5b-8 or C9 within C5b-9.

The capacity of the human complement regulatory protein CD59 to interact with terminal complement proteins in a species-selective manner was examined. When incorporated into chicken E, CD59 (purified from human E membranes) inhibited the cytolytic activity of the C5b-9 complex in a manner dependent on the species of origin of C8 and C9. Inhibition of C5b-9-mediated hemolysis was maximal when C8 and C9 were derived from human (hu) or baboon serum. By contrast, CD59 showed reduced activity when C8 and C9 were derived from dog or sheep serum, and no activity when C8 and C9 were derived from either rabbit or guinea pig (gp) serum. Similar specificity on the basis of the species of origin of C8 and C9 was also observed for CD59 endogenous to the human E membrane, using functionally blocking antibody against this cell surface protein to selectively abrogate its C5b-9-inhibitory activity. When E bearing human CD59 were exposed to C5b-8hu, CD59 was found to inhibit C5b-9-mediated lysis, regardless of the species of origin of C9, suggesting that the inhibitory function of CD59 can be mediated through recognition of species-specific domains expressed by human C8. Consistent with this interpretation, CD59 was found to bind to C5b-8hu but not to C5b67hu or C5b67huC8gp. Although CD59 failed to inhibit hemolysis mediated by C5b67huC8gpC9gp, its inhibitory function was observed for C5b67huC8gpC9hu, suggesting that, in addition to its interaction with C5b-8hu, CD59 also interacts in a species-selective manner with C9hu incorporated into C5b-9. Consistent with this interpretation, CD59 was found to bind both C5b67huC8gpC9hu and C5b-8huC9gp, but not C5b67huC8gpC9gp. Taken together, these data suggest that the capacity of CD59 to restrict the hemolytic activity of human serum complement involves a species-selective interaction of CD59, which involves binding to both the C8 and C9 components of the membrane attack complex. Although CD59 expresses selectivity for C8 and C9 of human origin, this "homologous restriction" is not absolute, and this human complement regulatory protein retains functional activity toward C8 and C9 of some nonprimate species.     

Insights into the human CD59 complement binding interface toward engineering new therapeutics

CD59 is a 77-amino acid membrane glycoprotein that plays an important role in regulating the terminal pathway of complement by inhibiting formation of the cytolytic membrane attack complex (MAC or C5b-9). The MAC is formed by the self assembly of C5b, C6, C7, C8, and multiple C9 molecules, with CD59 functioning by binding C5b-8 and C5b-9 in the assembling complex. We performed a scanning alanine mutagenesis screen of residues 16-57, a region previously identified to contain the C8/C9 binding interface. We have also created an improved NMR model from previously published data for structural understanding of CD59. Based on the scanning mutagenesis data, refined models, and additional site-specific mutations, we identified a binding interface that is much broader than previously thought. In addition to identifying substitutions that decreased CD59 activity, a surprising number of substitutions significantly enhanced CD59 activity. Because CD59 has significant therapeutic potential for the treatment of various inflammatory conditions, we investigated further the ability to enhance CD59 activity by additional mutagenesis studies. Based on the enhanced activity of membrane-bound mutant CD59 molecules, clinically relevant soluble mutant CD59-based proteins were prepared and shown to have up to a 3-fold increase in complement inhibitory activity.     

Live cell imaging of outward and inward vesiculation induced by the complement c5b-9 complex

Cells resist death induced by the complement membrane attack complex (MAC, C5b-9) by removal of the MAC from their surface by an outward and/or inward vesiculation. To gain an insight into the route of MAC removal, human C9 was tagged with Alexa Fluor 488 and traced within live cells. Tagged C9-AF488 was active in lysis of erythrocytes and K562 cells. Upon treatment of K562 cells with antibody and human serum containing C9-AF488, C9-AF488 containing MAC bound to the cells. Within 5-10 min, the cells started shedding C5b-9-loaded vesicles (0.05-1 mum) by outward vesiculation. Concomitantly, C9-AF488 entered the cells and accumulated in a perinuclear, late recycling compartment, co-localized with endocytosed transferrin-Texas Red. Similar results were obtained with fixed cells in which the MAC was labeled with antibodies directed to a C5b-9 neoepitope. Inhibition of protein kinase C reduced endocytosis of C5b-9. Kinetic analysis demonstrated that peripheral, trypsin-sensitive C5b-9 was cleared from cells at a slower rate relative to fully inserted, trypsin-resistant C5b-9. MAC formation is controlled by CD59, a ubiquitously expressed membrane complement regulator. Analysis at a cell population level showed that the amount of C5b-9-AF488 bound to K562 cells after complement activation was highly heterogeneous and inversely correlated with the CD59 level of expression. Efficient C9-AF488 vesiculation was observed in cells expressing low CD59 levels, suggesting that the protective impact of MAC elimination by vesiculation increases as the level of expression of CD59 decreases.     

Isolation of Membrane Attack Complex of Complement from Myelin Membranes Treated with Serum Complement

Abstract: The interaction between complement and myelin membranes and its possible role in myelin damage and in the disposal of damaged myelin in vivo is of interest because activation of complement generates both opsonin(s) and membrane attack complex of complement. In our studies on the role of complement in demyelin-ation, we have shown that isolated myelin activates serum complement in the absence of myelin-specific antibody and that membrane attack complex of complement is the required factor in antibody-mediated demyelination of mouse cerebellar expiant cultures. In the present study, we examined whether activation of serum complement by myelin is associated with the formation of membrane attack complex of complement in myelin membranes. Extracts of myelin-associated proteins following incubation of myelin with fresh serum were studied by ultracentrifugation on a sucrose density gradient for detection of C5b-9 neoantigen. The subunit structure of C5b-9 was determined by sodium dodecyl sulfate-poly-acrylamide gel electrophoresis, electroblotting, and immunostaining. Results indicate that the macromolecular complex consisting of late-acting complement components, C5-C9, was assembled in the target myelin membranes.     

Contribution of the N-linked carbohydrate of erythrocyte antigen CD59 to its complement-inhibitory activity.

The contribution of N-linked carbohydrate to the complement-inhibitory function of the human erythrocyte membrane glycoprotein, CD59, was investigated. Amino acid sequence analysis of tryptic peptides labeled with [3H]borohydride revealed an N-linked carbohydrate moiety at the Asn18 residue. No O-linked carbohydrate was detected, as judged by the failure of asialo-CD59 to bind peanut agglutinin and by its resistance to digestion by O-glycanase. The apparent molecular mass of CD59 was reduced from 18-20 to 14 kDa upon complete digestion with N-glycanase, with no detectable proteolysis. N-glycanase digestion of CD59 was associated with an 88 +/- 4% loss of the complement-inhibitory activity of the protein, as assessed by its capacity to protect chicken erythrocytes from lysis by the human C5b-9 proteins. By contrast, no change in function was observed after digestion of CD59 with neuraminidase, under conditions that removed greater than 60% of [3H]sialic acid residues. Despite loss of functional activity after N-glycanase digestion, we detected no change in the capacity of the deglycosylated CD59 to incorporate into erythrocyte membranes or to bind specifically and with species selectivity to the C8 and C9 components of the membrane attack complex. In order to alter the branched-chain structure of the N-linked carbohydrate of CD59 without enzymatic digestion, Chinese hamster ovary (CHO) cells transfected with cDNA for human CD59 were grown in the alpha-mannosidase inhibitor, 1-deoxymannojirimycin, resulting in conversion of approximately 70% of the membrane glycoprotein to a high mannose. When grown in the presence of 1-deoxymannojirimycin, the C5b-9-inhibitory activity of CD59 expressed on the surface of the transfected CHO cells was reduced by an amount comparable to that observed for the N-glycanase digested protein. Taken together, these data suggest that normal glycosylation of Asn18 in CD59 is required for the normal expression of its complement-inhibitory activity on membrane surfaces, although these N-linked sugar residues do not contribute to CD59's affinity for the C8 and C9 components of the C5b-9 complex.     

Is the membrane attack complex of complement an enzyme?

Summary Recent studies on the functional activities of the membrane attack complex of complement, C5b-9, are reviewed. A new speculative hypothesis has been advanced to account for the ability of complement to mediate lysis of various targets. This hypothesis has three major elements: 1) that the membrane attack complex is an enzyme; 2) that the substrate for this putative enzyme is a membrane constituent; 3) that the substrate specificity of the putative enzyme is dependent on the species source of individual complement components within the C5b-9 complex.Abbreviations E = sheep red cells - A = rabbit IgM anti-Forssman antibody - Hu or hu = human - GP or gp = guinea pig     

Molecular cloning of the C6A form cDNA of the mouse sixth complement component: functional integrity despite the absence of factor I modules

The sixth complement component (C6) is an essential component of the biologically active C5b-9 membrane attack complex of the complement system. The multimolecular C5b-9 complex is an important mediator of the biological effects of the activated complement system through its prominent cell signaling and cytolytic functions. To begin to provide essential information and reagents needed to analyze the functions of the complement system in mouse models of human diseases, the cDNA of the A form of mouse C6, which is present in all mouse strains, was cloned and characterized structurally and functionally. Although strikingly homologous in deduced amino acid sequence and modular structure to human C6 (75% identity), mouse C6 is substantially smaller due to the absence of the two carboxyl-terminal factor I modules (FIMs) found in human C6. Various approaches, including studies with antibody generated to recombinant mouse C6, failed to reveal evidence for FIMs in this form of mouse C6. Despite the absence of these modules in C6A, reported to be important for interactions with C5 in the human system, mouse C6A is functionally active and is readily incorporated into the mouse C5b-9 complex.     

Cutting edge: murine CD59a modulates antiviral CD4+ T cell activity in a complement-independent manner

CD59 blocks formation of the membrane attack complex of complement by inhibiting binding of C9 to the C5b-8 complex. To investigate a role for CD59 in promoting T cell responses, we compared T cell activation in CD59a-deficient (Cd59a-/-) and wild-type (WT) mice after in vitro stimulation and after infection with rVV. Virus-specific CD4+ T cell responses were significantly enhanced in Cd59a-/- mice compared with WT mice. Similarly, Cd59a-/- T cells responded more vigorously to in vitro stimulation with CD3-specific Abs compared with WT mice. This effect of CD59a on T cell proliferation was found to be complement-independent. Collectively, these results demonstrate that CD59a down-modulates CD4+ T cell activity in vitro and in vivo, thereby revealing another link between complement regulators and T cell activation.     

Complement Regulatory Molecules on Human Myelin and Glial Cells: Differential Expression Affects the Deposition of Activated Complement Proteins

Abstract: The expression of decay-accelerating factor CD55, membrane cofactor protein CD46, and CD59 was studied on Schwann cells cultured from human sural nerve and myelin membranes prepared from human cauda equina and spinal cord. These proteins are regulatory membrane molecules of the complement system. CD55 and CD46 are inhibitors of C3 and C5 convertases and CD59 inhibits C8 and C9 incorporation into C5b-9 complex and C9-C9 polymerization. The presence of these proteins was assessed by using antibodies to each of the proteins by fluorescent microscopy, fluorescence-activated cell sorter analysis, and also sodium dodecyl sulfate-polyacrylamide gel electrophoresis and western blot analysis. Schwann cells in culture expressed CD55, CD46, and CD59. It is interesting that only CD59 was detected on myelin from both central and peripheral nerve tissue. The ability of these proteins to limit C3 peptide deposition and C9 polymerization in myelin was studied by western blot analysis. C3b deposition was readily detected on antibody-sensitized myelin incubated with normal human serum used as a source of complement but not with EDTA-treated or heat-inactivated serum. C3b deposition was not affected by anti-CD55 antibody. On the other hand, poly-C9 formation in myelin, which was maximum when 50% normal human serum was used, was increased four- to fivefold when myelin was preincubated with anti-CD59. Our data suggest that complement activation on myelin is down-regulated at the step of the assembly of terminal complement complexes, including C5b-9, due to the presence of CD59.     

Complement-mediated killing of Escherichia coli: dissipation of membrane potential by a C9-derived peptide

The molecular mechanism of complement-mediated killing of Gram-negative bacteria has yet to be resolved, but it is generally accepted that assembly of the membrane attack complex (MAC) of complement on the outer bacterial membrane is a required step. We have now investigated the effect of the MAC and its precursor complex, C5b-8, on the membrane potential (delta Em) across the inner bacterial membrane. Delta Em of whole cells was measured directly by using a lipophilic cation (tetraphenylphosphonium) that equilibrates with the potential or indirectly by measuring transport of solutes (proline and galactoside), which is dependent on delta Em. Our results indicate that the C5b-8 complex caused a transient collapse of delta Em in the absence of cell killing. Addition of C9 to allow formation of the MAC dissipated delta Em irreversibly, and the cells were killed. Since delta Em is generated across the inner membrane in Gram-negative bacteria, inner membrane vesicles were prepared and membrane potentials were generated either by adding D-lactate to energize the electron-transport chain or by creating a K+ diffusion potential with valinomycin. C9 added in the absence of earlier acting complement proteins had no effect on delta Em of isolated, actively respiring vesicles or on K+ diffusion potentials. In contrast, its C-terminal thrombin fragment (C9b), which has been shown earlier to contain the membrane-active domain of C9, efficiently collapsed delta Em in such vesicles. C9b did not require a specific receptor since it was effective on "right-side-out" and "inside-out" vesicles. These results are interpreted to indicate that a C9-derived fragment deenergizes cells and may be the causative agent for cell death.     

Expression of the complement regulatory protein CD59 on human spermatozoa: Characterization and role in gametic interaction

Protectin (CD59) is a complement regulatory protein which blocks the membrane attack complex during complement activation. CD59 was identifield on the human sperm surface by means of H19, an IgG₁ anti-protectin mouse monoclonal antibody. Using Indirect immunofluorescence, flow cytometry and immunoperoxidase, CD59 was found to be present on the whole plasma membrane including the head and tail of fresh ejaculated, capacitated and acrosome-reacted spermatozoa. Immunoperoxidase staining of normal testicular sections indicated that this protein was already present on intraluminal germ cells. Analysis of this sperm protein by gel electrophoresis and immunoblotting revealed that its molecular weight of 20 kDa was comparable to that of CD59 expressed on peripheral blood cells (erythrocytes, lymphocytes) and that it was bound to the membrane through a glycophospholipid tail which could be released after treatment with phosphatidylinositol-specific phospholipase C. Associated to membrane cofactor protein (CD46) and decay accelerating factor (CD55) located in the acrosomal membranes, CD59 may participate to the protection of male gametes against complement-mediated damage as they travel through the female genital tract. Moreover CD59, known as an adhesion molecule involved in lymphocyte rosettes, may also participate in cell to cell adhesion during gametic interaction since H19 inhibited sperm binding and reduced the penetration rate and index during the hamster egg penetration test. © 1994 Wiley-Liss, Inc.     

Exploitation of the Complement System by Oncogenic Kaposi's Sarcoma-Associated Herpesvirus for Cell Survival and Persistent Infection

During evolution, herpesviruses have developed numerous, and often very ingenious, strategies to counteract efficient host immunity. Specifically, Kaposi''s sarcoma-associated herpesvirus (KSHV) eludes host immunity by undergoing a dormant stage, called latency wherein it expresses a minimal number of viral proteins to evade host immune activation. Here, we show that during latency, KSHV hijacks the complement pathway to promote cell survival. We detected strong deposition of complement membrane attack complex C5b-9 and the complement component C3 activated product C3b on Kaposi''s sarcoma spindle tumor cells, and on human endothelial cells latently infected by KSHV, TIME-KSHV and TIVE-LTC, but not on their respective uninfected control cells, TIME and TIVE. We further showed that complement activation in latently KSHV-infected cells was mediated by the alternative complement pathway through down-regulation of cell surface complement regulatory proteins CD55 and CD59. Interestingly, complement activation caused minimal cell death but promoted the survival of latently KSHV-infected cells grown in medium depleted of growth factors. We found that complement activation increased STAT3 tyrosine phosphorylation (Y705) of KSHV-infected cells, which was required for the enhanced cell survival. Furthermore, overexpression of either CD55 or CD59 in latently KSHV-infected cells was sufficient to inhibit complement activation, prevent STAT3 Y705 phosphorylation and abolish the enhanced survival of cells cultured in growth factor-depleted condition. Together, these results demonstrate a novel mechanism by which an oncogenic virus subverts and exploits the host innate immune system to promote viral persistent infection.     

Exceptional resistance of human H2 glioblastoma cells to complement-mediated killing by expression and utilization of factor H and factor H-like protein 1

Of over 20 nucleated cell lines we have examined to date, human H2 glioblastoma cells have turned out to be the most resistant to complement-mediated cytolysis in vitro. H2 cells expressed strongly the membrane attack complex inhibitor protectin (CD59), moderately CD46 (membrane cofactor protein) and CD55 (decay-accelerating factor), but no CD35 (complement receptor 1). When treated with a polyclonal anti-H2 Ab, anti-CD59 mAb, and normal human serum, only 5% of H2 cells became killed. Under the same conditions, 70% of endothelial-like EA.hy 926 cells and 40% of U251 control glioma cells were killed. A combined neutralization of CD46, CD55, and CD59 increased H2 lysis only minimally, demonstrating that these complement regulators are not enough to account for the resistance of H2 cells. After treatment with Abs and serum, less C5b-9 was deposited on H2 than on U251 and EA.hy 926 cell lines. A reason for the exceptional resistance of H2 cells was revealed when RT-PCR and protein biochemical methods showed that the H2 cells, unlike the other cell lines tested, actively produced the soluble complement inhibitors factor H and factor H-like protein 1. H2 cells were also capable of binding human factor H from the fluid phase to their cell surface and promoted the cleavage of C3b to its inactive form iC3b more efficiently than U251 and EA.hy 926 cells. In accordance, anti-factor H mAbs enhanced killing of H2 glioblastoma cells. Taken together, our results show that production and binding of factor H and factor H-like protein 1 is a novel mechanism that these malignant cells utilize to escape complement-mediated killing.