Purification and characterization of RHP (factor H) and study of its interactions with the first component of complement.

RHP has been purified from the plasma of both normal individuals and patients with rheumatoid arthritis (RA). RHP from both these sources was shown to be identical with Factor H by reaction with antisera and N-terminal amino acid sequence analysis. Factor H, from both normal and RA sera, inhibited the solubilization of immune precipitates but did not affect prevention of immune precipitation. Factor H was shown to inhibit the haemolytic activity of fluid-phase C1, but unlike C1-inhibitor, it had little effect on C1 bound to EA (EAC1). Factor H was shown to complex with intact C1, to isolated C1q and to the C1r:C1s tetramer. However, binding of factor H to C1 did not dissociate the C1 macromolecule. A C1-Factor H complex was detected in the serum and plasma from normal individuals and patients with systemic lupus erythematosus and RA. Serum levels of this complex were reduced, by EDTA-treatment of serum and by activation of complement by the classical pathway.

Solution structure of the fifth repeat of factor H: a second example of the complement control protein module.

Modules which share the same consensus sequence are assumed to have common structural features, at the secondary and tertiary level. In order to test the extent of such similarities, it is necessary to examine the structures of several examples from each module family. Recently, the first three-dimensional structure of a complement control protein (CCP) module (the 16th repeat of human factor H, H16) was determined using a combination of two-dimensional NMR and simulated annealing [Norman, D.G., Barlow, P.N., Baron, M., Day, A.J., Sim, R.B., & Campbell, I.D. (1991) J. Mol. Biol. 219, 717-725]. Using the same techniques, the three-dimensional structure of a second CCP module (the 5th repeat of human factor H, H5) has now been determined. The primary sequence of H5 contains 17 residues which are identical and in equivalent position to those in H16. Thirteen of these 17 are part of the consensus sequence. The similarities between the secondary structure of H5 and that of H16 are extensive. This implies that the consensus sequence dictates a particular secondary structure. The tertiary structure of H5, a compact hydrophobic core wrapped in beta-strand and sheet, bears much overall resemblance to that of H16. However, there is a deletion in the first strand of H5, and an insertion in a loop, resulting in slightly shorter overall length. This is associated with a rearrangement of residues within the hydrophobic core. The side chain of the highly conserved Tyr29, which occupies a central position within the core of H16, lies on the periphery of the core of H5.

Purification and characterization of a novel protein that is required for degradation of N-alpha-acetylated proteins by the ubiquitin system.

Anion exchange chromatography of reticulocyte lysates revealed that the ubiquitin cell-free system can be resolved into two essential fractions: unadsorbed material (Fraction I) that contains ubiquitin and a high salt eluate (Fraction II) that contains the conjugating enzymes and the conjugate-degrading protease. Many proteins with exposed NH2 termini are degraded in a ubiquitin-supplemented Fraction II. However, this partially purified and reconstituted system does not degrade N-alpha-acetylated proteins. These proteins are degraded in whole lysates in a ubiquitin-dependent manner (Mayer, A. Siegel, N. R., Schwartz, A. L., and Ciechanover, A. (1989) Science 244, 1480-1483). It appears that a protein factor which is specifically required for the degradation of N-alpha-acetylated proteins is removed or inactivated during the fractionation of the lysate. Here we report the purification and characterization of a novel protein that is required along with the protease for the degradation of ubiquitin conjugates of histone H2A, an N-alpha-acetylated protein. The protein is not required for the degradation of ubiquitin conjugates of proteins with free NH2 termini. The protein, which is found in crude Fraction I, was purified approximately 200-fold by (NH4)2SO4 precipitation, Sephadex G-100 gel-filtration chromatography, Mono Q anion exchange chromatography, and an additional Sephadex G-100 gel filtration chromatography step. The protein is removed from Fraction I during the purification of ubiquitin and has not been previously recognized since the majority of the protein substrates evaluated in the cell-free system have free NH2 termini. The protein has an apparent molecular mass of approximately 92 kDa. It is a homodimer that is composed of two identical 46-kDa subunits. Initial analysis of the mechanism of action of this protein revealed that it must interact with the conjugates in order to allow proteolysis to occur. We designated the protein Factor H (Factor Hedva).

Regulatory system of guinea-pig complement C3b: tests for compatibility of guinea-pig factors H and I with human factors.

Two proteins that are involved in cleavage of methylamine-treated C3 of guinea-pig origin (C3(MA)gp) have been isolated from guinea-pig serum. One of them functioned as a cofactor of human factor I (Ihu) for cleavage of C3(MA)gp and its molecular size was 150 kDa. The other was functionally pure and able to cleave C3(MA)gp together with human factor H (Hhu). They appear to be analogous to human factors H and I in the guinea-pig and will be referred to as Hgp and Igp. Methylamine-treated human C3 [C3(MA)hu] was not a compatible substrate for Hgp or Igp: little cleavage of C3(MA)hu was observed if human factor H (Hhu) or I was substituted with the guinea-pig counterpart. C3(MA)gp, on the other hand, served as a substrate, though less efficiently, for Hhu and Ihu. Human C4b-binding protein (C4bp) and membrane cofactor protein (MCP) as well as Hhu could participate in cleavage of C3(MA)gp by Igp or Ihu. In these assays, C3(MA)gp was degraded again less efficiently than C3(MA)hu. Interestingly, human C3b/C4b receptor (CR1) mediated factor I-dependent cleavage of C3(MA)hu and C3(MA)gp to a similar extent regardless the sources of factor I. These results suggest that factor I-dependent C3b regulatory system is species-specific except in the case of CR1, which may function as a cofactor irrespective of species.

Discrimination between activators and nonactivators of the alternative pathway of complement: regulation via a sialic acid/polyanion binding site on factor H.

The alternative complement pathway is capable of discriminating human cells and tissues from a wide variety of potential pathogens. It has been recently demonstrated that attachment of complement component C3b to activator-derived molecules (e.g., small polysaccharides) restricts inactivation of C3b by factors H and I in a manner similar to activator surfaces. It is now shown that restriction is reversed by certain soluble polyanions (e.g., sialoglycopeptides, heparin, or dextran sulfate) that mimic the effects of sialic acid and glycosaminoglycans on human cells and tissues. Fluid-phase polyanions enhanced binding of factor H to C3b attached to activating particles, indicating that the effect resulted from increased affinity between C3b and factor H. The enhancement was specific for activator-bound C3b since no enhancement was observed on nonactivating particles. While several polyanions could cause this effect, some polyanions could not, indicating specificity. The active polyanions also inhibited lysis of cells via the alternative pathway. The binding site for sialic acid appears to reside on factor H, since factor H bound to heparin-agarose and to sialic acid-bearing fetuinagarose, whereas C3b bound to neither under the same conditions. These observations suggest that occupation of a specific site on factor H by polyanions induces an increase in the C3b-H affinity, resulting in discrimination of host cells and tissues from alternative pathway-activating foreign cells.

Human complement factor H: an additional gene product of 43 kDa isolated from human plasma shows cofactor activity for the cleavage of the third component of complement.

In addition to the 150-kDa factor H protein, we have previously described a 43-kDa factor H molecule in human plasma, which probably represents a translational product of the additional 1.8-kb mRNA for factor H. This factor H was isolated from human plasma by means of immunoaffinity chromatography and high-performance liquid chromatography. When tested for its functional activity, this purified 43-kDa H protein was shown to act as cofactor for factor I- mediated cleavage of fluid-phase C3b to iC3b.

Biosynthesis of complement factor H by human umbilical vein endothelial cells. Regulation by T cell growth factor and IFN-gamma.

The present studies were initiated to characterize a 150-kDa molecule with inhibitory activity for C3bBb formation, which is present in human umbilical vein endothelial cells (HUVEC). Therefore, human endothelial culture supernatants (HECS) were analyzed for the presence of human complement factor H by ELISA. It was found that H was present in HECS. An immunoblot analysis of affinity purified H from HECS showed that the size of HUVEC H was identical to that of plasma H. The mean production of H by HUVEC of first passage cultures was 40 ng/10(6) cells/day. The synthesis of HUVEC H was fully inhibitable by the addition of cycloheximide to the cultures, suggesting that H is de novo synthesized. Additional evidence for de novo synthesis was obtained by using biosynthetic labeling with [35S] methionine, immunoprecipitation, and SDS-PAGE. It was demonstrated that, indeed, HUVEC produce and secrete factor H. Two forms of the protein were identified, the 150-kDa form and also a 45-kDa form, both forms have been identified in plasma. The functional activity of HUVEC H is identical to that of plasma H. IFN-gamma induced enhanced synthesis of H by HUVEC, whereas it had no effect on C3 synthesis. Supernatant from stimulated PBMC, T cell growth factor, enhanced synthesis of both H and C3. The present studies indicate that H is produced by HU-VEC and that H may function as an inhibitor of complement activation at the endothelial cell level and, thereby, together with molecules like decay accelerating factor and membrane cofactor protein, may influence resistance of endothelial cells to complement mediated damage.

Regulation of complement factor H synthesis in U-937 cells by phorbol myristate acetate, lipopolysaccharide, and IL-1.

The capacity of the human monocyte cell line U-937 to synthesize complement factor H was examined. The kinetics of secretion of factor H into cell culture supernatant were followed by a sensitive solid phase RIA capable of measuring 0.1 ng of protein. Daily secretion of factor H was low and almost linear and was approximately 3 ng of factor H per 10(6) cells. Factor H synthesis was inhibited by cycloheximide but returned to the levels seen in untreated cultures after removal of the inhibitor. LPS and IL-1 both effected a time- and dose-dependent enhancement of factor H synthesis. Induction of U-937 cells with PMA to differentiate into macrophage-like cells also resulted in increased factor H synthesis. RIA of cell lysates, immunofluorescence microscopy, as well as FACS analysis all revealed that factor H Ag was also associated with the U-937 cell membrane. The population of U-937 cells bearing membrane-associated factor H was decreased from 77 to 43% after stimulation for 48 h with LPS (1 microgram/ml). [35S]Methionine metabolic labeling and SDS-PAGE analysis of factor H immunoprecipitates from unstimulated and stimulated culture supernatants and cell lysates demonstrated a major polypeptide, m.w. 150,000, and a minor component, m.w. 42,000. Western blot analysis of factor H in fresh normal plasma also detected both 150,000 and 42,000 m.w. factor H proteins. This is in agreement with the recent demonstration of a 4.4- and 1.8-kb mRNA for factor H in human liver. These data demonstrate that U-937 cells synthesize factor H that is structurally and antigenically similar to factor H in normal plasma. The exact nature of the membrane-bound factor H and its functions and mechanism of attachment to the cell membrane remain to be elucidated.

Synthesis and regulation of complement protein factor H in human skin fibroblasts.

The alternative pathway of C activation is Ag-independent and forms a first line of defense against infection before immune response. The C3 convertase, C3bBb, formed during activation of the alternative pathway is tightly regulated, with destabilization produced by factor H. Using metabolic labeling with [35S]methionine, immunoprecipitation, and SDS-PAGE, we demonstrated that human skin fibroblasts synthesized and secreted factor H protein. Two forms of the protein were identified, the approximately 160-kDa form seen more prominently in serum and a 45-kDa form that has also been identified in serum. The cells contained two forms of factor H mRNA, 4.4 and 1.8 kb. IFN-gamma increased factor H protein synthesis and mRNA content. No effect was observed with LPS. Neither HepG2 cells or human peripheral blood monocytes synthesized factor H protein or contained factor H mRNA.

Isolation of bovine complement factor H.

A bovine serum protein, initially recognized by its inhibitory effect on the hemolytic activity of the bovine alternative pathway was isolated from fresh bovine serum by polyethylene glycol precipitation and chromatography on DEAE-Sephacel, CM-Sephadex A-50 and Sephadex G-200. The protein, a single chain polypeptide with an apparent molecular weight of 158,000, was identified as factor H, a regulatory protein of the alternative complement pathway. Functional characterization of this protein as factor H was based on the following properties: binding to C3b, inhibition of factor B binding to C3b, cofactor activity in the cleavage of C3b by factor I, inhibition of fluid phase alternative pathway C3 convertase (C3b.Bb) formation and activity, and species-specific inhibition of the alternative pathway mediated hemolysis of heterologous erythrocytes. A monospecific rabbit antiserum against bovine factor H failed to react with human serum factor H.

Structural analysis of human complement protein H: homology with C4b binding protein, beta 2-glycoprotein I, and the Ba fragment of B2.

We report here a partial primary structure for human complement protein H. Tryptic peptides comprising 27% of the H molecule were isolated by conventional techniques and were sequenced (333 amino acid residues). Several mixed-sequence oligonucleotide probes were constructed, based on the peptide sequence data, and were used to screen a human liver cDNA library. The largest recombinant plasmid (pH1050), which hybridized with two probes, was further characterized. The cDNA insert of this plasmid contained coding sequence (672 bp) for 224 amino acids of H. The 3' end of this clone had a polyadenylated tail preceded by a polyadenylation recognition site (ATTAAA) and a 3'-untranslated region (229 bp). Four regions of internal homology, each about 60 amino acids in length, were observed in the derived protein sequence from this cDNA clone, and a further seven from the tryptic peptide sequences. The consensus sequence for each of the repetitive units of H was four cysteines, two prolines, three glycines, one tryptophan, and two tyrosines/phenylalanines. Based on the mole percent values for each of these amino acids, it is likely that H is composed of about 20 repetitive units of this nature. Furthermore, the repetitive unit of H shows pronounced homology with the Ba fragment of B, the C4b binding protein, and beta 2-glycoprotein I. Therefore, it seems that at least portions of these proteins have evolved from a common ancestral DNA element.

Partial characterization of human complement factor H by protein and cDNA sequencing: homology with other complement and non-complement proteins.

Factor H, a control protein of the human complement system, is closely related in functional activity to two other complement control proteins, C4b-binding protein (C4bp) and complement receptor type 1 (CR1). C4bp is known to have an unusual primary structure consisting of eight homologous units each about 60 amino acids long. Such units also occur in the N-terminal regions of the complement proteins C2 and factor B, and in the non-complement serum glycoprotein beta 2I. Amino acid sequencing, and sequencing of a factor H cDNA clone, show that factor H also contains internal repeating units, and is homologous to the proteins listed above.

Isolation of human complement factors C3, C5 and H.

An improved method for simultaneous purification of complement factors C3, C5 and H from human plasma has been developed. Using an initial batch separation technique with QAE-Sephadex, followed by chromatography on SP-Sephadex and gel filtration in Sephadex G-200, 600 mg of highly pure C3 can be prepared from 1600 ml of plasma. Simultaneously about 70 mg of highly pure factor H and 30 mg of C5 are obtained by chromatography of post SP-Sephadex material on DEAE-Sephacel. A small amount of C3 in the C5 pool is removed by anti-C3-Sepharose. By maleylation or citraconylation of reduced and alkylated C3, the constitutive polypeptide chains are modified in a way that made them separable by ion exchange chromatography.

Isolation of rabbit C3, Factor B, and Factor H and comparison of their properties with those of the human analog.

The rabbit complement components C3, Factor B, and Factor H were isolated and characterized and were compared to the corresponding proteins of human serum. Chromatographic behavior, chemical properties, and functional interactions show great similarities between the components in both species. By SDS polyacrylamide gel electrophoresis, the m.w. were estimated to be 195,000 for C3, 86,000 for Factor B, and 155,000 for Factor H. The amino acid compositions of the rabbit proteins resembled those of the human analog. The total carbohydrate content of rabbit C3 and Factor H was approximately one-half that of the human proteins. In addition, a qualitative difference in the carbohydrate moieties of the C3 proteins was observed. The serum concentration of the rabbit proteins was markedly lower than that of the human proteins. The rabbit C3b,Bb enzyme resembled the human analog with respect to half-life, control by Factor H, and stabilization by nickel ions.

Lysine residues, but not carbohydrates, are required for the regulatory function of H on the amplification C3 convertase of complement.

Lysine epsilon-amino groups of human factor H were selectively converted to guanidino groups by treatment with 0.1 M O-methylisourea at pH 10.4. Guanidination resulted in a dose-dependent decrease in the capacity of the regulatory protein to accelerate decay dissociation of P-stabilized amplification C3 convertase sites, to serve as a co-factor for cleavage of cell-bound C3b by I, and to compete for binding of 125I-untreated H to C3b. Modification of approximately 75% lysine epsilon-amino groups suppressed 97% of H functional activity. Biochemical analysis of native H demonstrated a total carbohydrate content of 18.5% (w/w) and the presence in the molecule of 11 biantennary oligosaccharidic chains of the N-acetyl-lactosaminic type. Total desialation of H by using Clostridium perfringens neuraminidase, and total deglycosylation of desialated H by using beta-endo-N-acetylglucosaminidase resulted in a 1.5- to 2-fold increase in H activity on a weight basis. Deglycosylation did not alter the capacity of H to discriminate between activating and nonactivating surfaces of the alternative pathway. Thus, lysine residues are important determinants of the binding capacity of H for cell-bound C3b, whereas the carbohydrate portion of the molecule is not required for the regulatory function of the protein on the amplification C3 convertase.

Isolation of two molecular populations of human complement factor H by hydrophobic affinity chromatography.

Human complement factor H was prepared in highly purified form from fresh serum by euglobulin precipitation, DEAE-Sephacel chromatography and Sephacryl S-300 gel filtration. This preparation allowed the recovery of 37% of the initial factor H. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis revealed that factor H was homogeneous both in reduced and non-reduced media and exhibited a molecular mass of 150 kDa. Charge-shift experiments clearly showed the presence of hydrophobic sites in the factor H molecule. Charge shifts were observed with two detergent systems (Triton/sodium deoxycholate and Triton/cetyltrimethylammonium bromide). Factor H was able to bind to phenyl-Sepharose. This property allowed us to study two populations of factor H. These two populations exhibited the same physicochemical parameters, but revealed differences in their ability to aggregate in low- and iso-ionic-strength media. The molecular basis and biological significance of this heterogeneity are discussed.

Isolation and characterization of rabbit H of the alternative complement pathway.

Rabbit factor H, a control protein of the alternative complement pathway, was isolated from rabbit serum by polyethylene glycol precipitation, DEAE-Sephacel chromatography, and gel chromatography on Sephadex G200. The protein migrated as a single-chain polypeptide with a molecular weight of 160,000 on sodium dodecyl sulfate-gel electrophoresis with Laemmli's buffer system, but hardly migrated into the gel with Fairbanks' buffer system. Physical and chemical properties of rabbit H were similar to those of human H, except that fragments produced by limited tryptic digestion from rabbit H had different molecular sizes from those produced from human H. Significant species-specificity was observed in the functional activity of factor H; activation of the alternative complement pathway was inhibited more efficiently with homologous H than with heterologous H. In contrast, factor H inhibited the hemolysis of homologous erythrocytes less than that of heterologous erythrocytes.

High resolution isoelectric focusing of immunoprecipitated proteins under denaturing conditions. A simple analytical method applied to the study of complement component polymorphisms.

A simple analytical method for the study of structural protein polymorphisms is described. It consists of the immunoprecipitation of non-radiolabeled proteins using monospecific polyclonal antibodies followed by isoelectric focusing (IEF) under completely denaturing conditions in vertical polyacrylamide slab gels. The method uses small amounts of sample (usually unfractionated plasma or serum), requires no sophisticated equipment and allows the screening of large numbers of samples with comparatively small effort. This method has been applied in the identification of 2 human complement-component polymorphisms, C4-binding protein (C4-bp) and factor H (beta 1H).