Characterization of recombinant human C1 inhibitor secreted in milk of transgenic rabbits.

C1 inhibitor (C1INH) is a single-chain glycoprotein that inhibits activation of the contact system of coagulation and the complement system. C1INH isolated from human blood plasma (pd-hC1INH) is used for the management of hereditary angioedema (HAE), a disease caused by heterozygous deficiency of C1INH, and is a promise for treatment of ischemia-reperfusion injuries like acute myocardial or cerebral infarction. To obtain large quantities of C1INH, recombinant human C1INH (rhC1INH) was expressed in the milk of transgenic rabbits (12 g/l) harboring genomic human C1INH sequences fused to 5' bovine αS(1) casein promoter sequences. Recombinant hC1INH was isolated from milk to a specific activity of 6.1 U/mg and a purity of 99%; by size-exclusion chromatography the 1% impurities consisted of multimers and N-terminal cleaved C1INH species. Mass spectrometric analysis of purified rhC1INH revealed a relative molecular mass (M(r)) of 67,200. Differences in M(r) on SDS PAGE and mass spectrometric analysis between rhC1INH and pd-hC1INH are explained by differential glycosylation (calculated carbohydrate contents of 21% and 28%, respectively), since protein sequencing analysis of rhC1INH revealed intact N- and C-termini. Host-related impurity analysis by ELISA revealed trace amounts of rabbit protein (approximately 10 ppm) in purified batches, but not endogenous rabbit C1INH. The kinetics of inhibition of the target proteases C1s, Factor XIIa, kallikrein and Factor XIa by rhC1INH and pd-hC1INH, indicated comparable inhibitory potency and specificity. Recently, rhC1INH (Ruconest(®)) has been approved by the European Medicines Agency for the treatment of acute attacks of HAE.

Cloning and molecular characterization of lycC1INH genes in large yellow croaker (Pseudosciaena crocea).

Complement component 1 inhibitor (C1INH) is a crucial protein in controlling activation of many plasma mediator pathways and can directly interact with Gram negative bacteria. The full-length cDNA of lycC1INH gene was identified from the large yellow croaker. It is of 2046 nucleotides (nt) encoding a protein of 599 amino acids, with a 5'-untranslated region of 99 nt and a 3'-untranslated region of 147 nt including the poly (A) tail. The deduced protein contains a C-terminal serpin (serine protease inhibitor) domain, and two N-terminus immunoglobulin domains without significant homology to other species. Western blot analysis of the protein expression showed that the expression of lycC1INH was obviously up-regulated in liver, spleen and head kidney of the fish challenged by attenuated live Vibrio anguillarum strain. This indicated that lycC1INH might be involved in the immune response of large yellow croaker to bacterial challenge.

Hereditary angiodema: a current state-of-the-art review, VI: novel therapies for hereditary angioedema.

OBJECTIVE: To provide a comprehensive overview on clinical trial design and results of emerging therapies for the treatment of hereditary angioedema (HAE). DATA SOURCES: MEDLINE or PubMed literature searches were conducted to identify double-blind, placebo-controlled trials investigating C1 esterase replacement, kallikrein inhibitor, and bradykinin receptor 2 antagonist therapies. STUDY SELECTION: Ongoing trials or those just recently completed from all companies developing a product for the treatment of HAE are discussed. RESULTS: All of these agents are believed to be effective when tested in patients in phase 1 or phase 2 trials. The studies have many features in common, including being placebo-controlled and blinded; having a preliminary screening visit at which the diagnosis is confirmed; having either low circulating C1 inhibitor protein levels or low levels of functional C1 inhibitor, low C4 levels, and normal C1q levels; enrolling individuals who are relatively early in attacks (4-6 hours from the onset); and stipulating that patients continue taking the medications that they have been taking in the long term. The type of attack acceptable for each treatment protocol varies from study to study. Some allow peripheral edema attacks, some facial attacks, and in some studies, the Food and Drug Administration has allowed purified serum C1 inhibitor to be used as a rescue medication if the patient remains in difficulty after the study drug has been used and found to be ineffective. CONCLUSION: The outlook for new, effective short-term therapy appears to be excellent. In the near future, a whole new therapeutic armamentarium to care for patients with HAE should be available in the United States.

Inhibition of plasma kallikrein by C1-inhibitor: role of endothelial cells and the amino-terminal domain of C1-inhibitor.

Activation of plasma prekallikein and generation of bradykinin are responsible for the angioedema attacks observed with C1-inhibitor deficiency. Heterozygous individuals with <50% levels of active C1-inhibitor are susceptible to angioedema attacks indicating a critical need for C1-inhibitor to be present at maximum levels to prevent unwanted prekallikrein activation. Studies with purified proteins do not adequately explain this observation. Therefore to investigate why reduction of C1-inhibitor to levels seen in angioedema patients results in excessive kallikrein generation we examined the effect of endothelial cells on the inhibition of kallikrein by C1-inhibitor. Surprisingly, it was found that a C1-inhibitor concentration of greater than 1 microM was needed to inhibit 3 nM kallikrein. We propose that this apparent protection from inhibition was mediated by kallikrein binding to the cells via the heavy chain in a high molecular weight kininogen and zinc independent manner. Protection of kallikrein from inhibition was not observed when C1-inhibitor truncated in the amino-terminal domain by the StcE metalloproteinase was used, which suggests a novel function for this unique domain. The requirement for high concentrations of C1-inhibitor to fully inhibit kallikrein is consistent with the fact that reduced levels of C1-inhibitor result in the kallikrein activation seen in angioedema.

Lymphoma-associated paraneoplastic angioedema with normal C1-inhibitor activity: does danazol work?

A patient with splenic marginal zone lymphoma presented with severe, symptomatic acquired angioedema. Unlike previously reported cases, his serum levels of complement and C1 inhibitor (C1-INH) were not decreased. Nonetheless, he responded clinically to treatment with an attenuated androgen and, after therapeutic splenectomy, has been maintained asymptomatic without androgen therapy for 5 years. Thus stimulation of C1-INH synthesis may overcome paraneoplastic angioedema in patients with lymphoproliferative disorders despite the absence of typical evidence for a quantitative or qualitative defect in C1-INH. Androgens should not be withheld despite a normal level of C1-INH and complement in symptomatic patients.

Complement regulatory protein C1 inhibitor binds to selectins and interferes with endothelial-leukocyte adhesion.

C1 inhibitor (C1INH), a member of the serine proteinase inhibitor (serpin) family, is an inhibitor of proteases in the complement system, the contact system of kinin generation, and the intrinsic coagulation pathway. It is the most heavily glycosylated plasma protein, containing 13 definitively identified glycosylation sites as well as an additional 7 potential glycosylation sites. C1INH consists of two distinct domains: a serpin domain and an amino-terminal domain. The serpin domain retains all the protease-inhibitory function, while the amino-terminal domain bears most of the glycosylation sites. The present studies test the hypothesis that plasma C1INH bears sialyl Lewis(x)-related moieties and therefore binds to selectin adhesion molecules. We demonstrated that plasma C1INH does express sialyl Lewis(x)-related moieties on its N-glycan as detected using mAb HECA-452 and CSLEX1. The data also show that plasma C1INH can bind to P- and E-selectins by FACS and immunoprecipitation experiments. In a tissue culture model of endothelial-leukocyte adhesion, C1INH showed inhibition in a dose-dependent manner. Significant inhibition (>50%) was achieved at a concentration of 250 micro g/ml or higher. This discovery may suggest that C1INH plays a role in the endothelial-leukocyte interaction during inflammation. It may also provide another example of the multifaceted anti-inflammatory effects of C1INH in various animal models and human diseases.

Increased expression of C1-inhibitor mRNA in patients with hereditary angioedema treated with Danazol.

The attenuated androgen Danazol can partially reverse the biochemical defect and prevent angioedema in patients with inherited C1-inhibitor (C1-INH) deficiency (hereditary angioedema, HAE). Though its clinical effectiveness is independent from significant increase of C1-INH plasma levels, its mechanism of action remains unknown. Since angioedema is a local phenomenon, it could be controlled by restoring tissue levels of C1-INH. We measured the expression of C1-INH mRNA in peripheral blood mononuclear cells (PBMCs) of 13 patients with HAE type 1 (seven untreated and asymptomatic, and six on Danazol at the minimal effective dose) and of eight normal controls. mRNA levels were quantitated by computerized optical densitometry of reverse transcriptase-PCR products, normalized for the amount of glyceraldehyde-3-phosphate-dehydrogenase and expressed as percent of normal pooled RNAs. Each determination represented the mean of three separate experiments. Measurement of C1-INH mRNA in two patients before and after 1 month of Danazol 400 mg per day demonstrated a post-treatment increase of 15 and 21%, respectively. When HAE patients and controls were analyzed as groups, C1-INH mRNA levels of patients untreated and asymptomatic (median 73%, range 65-78) were significantly lower (P=0.001) compared to controls (median 101%, range 87-121) and to patients on Danazol (median 91%, range 82-96); the difference among the last two groups was not statistically significant. Our data demonstrate that minimal effective doses of Danazol increase the expression of C1-INH mRNA in PBMC of HAE patients even in the absence of a significant increase of C1-INH plasma levels.

In vivo biosynthesis of endogenous and of human C1 inhibitor in transgenic mice: tissue distribution and colocalization of their expression.

We have produced transgenic mice expressing human C1 inhibitor mRNA and protein under the control of the human promoter and regulatory elements. The transgene was generated using a minigene construct in which most of the human C1 inhibitor gene (C1NH) was replaced by C1 inhibitor cDNA. The construct retained the promoter region extending 1.18 kb upstream of the transcription start site, introns 1 and 2 as well as a stretch of 2.5 kb downstream of the polyadenylation site, and therefore carried all known elements involved in transcriptional regulation of the C1NH gene. Mice with high serum levels of human C1 inhibitor, resulting from multiple tandem integrations of the C1 inhibitor transgene, were selected. Immunohistochemistry in combination with in situ hybridization was applied to localize the sites of C1 inhibitor biosynthesis and to demonstrate its local production in brain, spleen, liver, heart, kidney, and lung. The distribution of human C1 inhibitor-expressing cells was qualitatively indistinguishable from that of its mouse counterpart, but expression levels of the transgene were significantly higher. In the spleen, production of C1 inhibitor was colocalized with that of a specific marker for white pulp follicular dendritic cells. This study demonstrates a stringently regulated expression of both the endogenous and the transgenic human C1 inhibitor gene and reveals local biosynthesis of C1 inhibitor at multiple sites in which the components of the macromolecular C1 complex are also produced.

Complement components, but not complement inhibitors, are upregulated in atherosclerotic plaques.

Complement activation occurs in atherosclerotic plaques. The capacity of arterial tissue to inhibit this activation through generation of the complement regulators C1 inhibitor, decay accelerating factor, membrane cofactor protein (CD46), C4 binding protein (C4BP), and protectin (CD59) was evaluated in pairs of aortic atherosclerotic plaques and nearby normal artery from 11 human postmortem specimens. All 22 samples produced mRNAs for each of these proteins. The ratios of plaque versus normal artery pairs was not significantly different from unity for any of these inhibitors. However, in plaques, the mRNAs for C1r and C1s, the substrates for the C1 inhibitor, were increased 2.35- and 4.96-fold, respectively, compared with normal artery; mRNA for C4, the target for C4BP, was elevated l.34-fold; and mRNAs for C7 and C8, the targets for CD59, were elevated 2.61- and 3.25-fold, respectively. By Western blotting and immunohistochemistry, fraction Bb of factor B, a marker of alternative pathway activation, was barely detectable in plaque and normal arterial tissue. These data indicate that it is primarily the classical, not the alternative pathway, that is activated in plaques and that key inhibitors are not upregulated to defend against this activation.

Expression of active human C1 inhibitor serpin domain in Escherichia coli.

Human C1 inhibitor is a highly glycosylated serine protease inhibitor of the serpin family. The protein contains two disulfide bonds. In this study, an N-terminally truncated form of recombinant C1 inhibitor was overexpressed in Escherichia coli strains BL21(DE3) and AD494(DE3), the latter enabling the formation of disulfide bonds within the cytoplasm. With both strains, a major fraction of the recombinant protein produced appeared to be insoluble. However, the soluble fraction of lysates from strain AD494(DE3) inhibited the C1s target protease in functional assays. Recombinant C1 inhibitor produced in this strain also displayed the ability to complex with C1s in vitro. In contrast, lysates from strain BL21(DE3) displayed no C1 inhibitor activity. These data support the notion that glycosylation is not important, whereas disulfide bond formation appears to be essential for the production of an active recombinant C1 inhibitor. Thus, bacterial strains that permit the formation of disulfide bonds may represent a reliable system for the production of recombinant C1 inhibitor. However, a major obstacle to large-scale production will be to produce the protein in a soluble form. Attempts to increase the yield of soluble protein by coexpression of the GroEL/ES chaperonins resulted in an increase in solubility.

Purification of human ceruloplasmin as a by-product of C1-inhibitor.

Human ceruloplasmin (Cp) has been purified from cryoprecipitate-poor plasma as a by-product of the C1-inhibitor production chain. Highly purified Cp was obtained by subsequent ion-exchange chromatography on sulfate-Fractogel EMD and TMAE-Fractogel EMD. Treatments for viral safety included application of the solvent-detergent method and two nanofiltration steps using 35- and 15-nm pore size filters at the end of the process. Overall antigen yield was 95 (+/-5) %. Purified human ceruloplasmin was studied by electron spin resonance (ESR) to characterize its different types of copper complexes and to check its antioxidant properties. We distinguished three types of complexes: one type-2 Cu(II) with g// = 2.25 and A// = 180 G and two type-I Cu(II) exhibiting different narrow hyperfine splitting (A// = 72 G and A// = 90 G) with close g// (2.20 and 2.21). Purified Cp has a specific activity of 24.5+/-0.2 mU/mg of proteins. This process provides a method for Cp purification that could be easily integrated into modern plasma fractionation.

Regulation of C1 inhibitor synthesis.

The primary biologic roles of C1 inhibitor (C1-INH) are the regulation of activation of the classical complement pathway and of the contact system of kinin formation. Heterozygosity for deficiency or dysfunction of C1-INH results in hereditary angioedema (HAE). This deficiency results in loss of homeostasis with unregulated complement and contact system activation. Due to the consequent C1-INH consumption, plasma levels of C1-INH in patients with HAE are decreased below 50% of normal. In addition, diminished synthesis contributes to the lowered levels in some patients. The hepatocyte is the primary source of C1-INH, although a number of other cell types, including peripheral blood monocytes, microglial cells, fibroblasts, endothelial cells, the placenta, and megakaryocytes also synthesize and secrete the protein both in vivo and in vitro. Interferon-gamma and alpha (IFN), colony stimulating factor-1, interleukin-6 (IL-6) and tumor necrosis factor-alpha (TNF-alpha) all induce C1-INH synthesis in a variety of cell types. The IFN-response elements in the 5'-flanking region and in the first intron have been partially characterized, as have several of the promoter elements that direct basal transcription of the gene. However, although androgen therapy, in vivo, results in an increase in C1-INH plasma levels, a direct effect of androgens on C1-INH synthesis has not been convincingly demonstrated. Although the C1-INH gene contains a potential glucocorticoid/androgen response element, this element does not appear to respond to androgen. Continued analysis of the transcriptional regulation of the C1-INH gene may lead to new approaches to therapy of HAE.

Endothelial cells cultured from human brain microvessels produce complement proteins factor H, factor B, C1 inhibitor, and C4.

The inflammatory mediators, cytokines and complement proteins are believed to regulate the sequential events during the development of lesions secondary to ischaemia and reperfusion. The endothelial cell monolayer of the brain microvasculature is the critical interface between the blood-borne mediators and brain tissue. The involvement of these cells in complement production and regulation has not been well documented. In the present study, expression of complement proteins (C1 inhibitor, factor H, factor B, C4) by cultured endothelial cells obtained from human brain microvessels has been characterized. Interferon gamma upregulates the production of all the complement factors studied. Serine proteases, plasmin and miniplasmin induce the expression of C4, decrease the level of ELISA detectable C1 inhibitor, and do not affect the production of factors H and B. These data indicate that complement proteins are expressed locally by the brain microvessels, and may modulate the inflammatory responses of brain tissue.

[Efficient expression of human C1-inhibitor in CHO cells by using a dicistronic expression vector].

The full-length cDNA fragment encoding human C1-INH was obtained by gene recombination techniques and a stable expression plasmid was constructed by inserting the human C1-INH cDNA into an efficient dicistronic expression vector pED. This plasmid was transfected into DHFR-deficient Chinese Hamster Ovary cells (CHO-dhfr-) by Lipofectin method, and the positive CHO-dhfr+ cell clones which stably express C1-INH was generated. Expression of C1-INH mRNA was detected by Northern blot. Expression of C1-INH protein was confirmed by immunoprecipitation and Western blot analysis. The level of expressed C1-INH was estimated at 0.4 microgram/ml by specific ELISA techniques. The biological activity of recombinant C1-INH was assayed by using the inhibition of C1 estrolytic activity.

Functional characterization of two different Kupffer cell populations of normal rat liver.

BACKGROUND: Kupffer cells of the liver represent the largest population of tissue macrophages. Small and large Kupffer cells were distinguished in normal liver, leading to the suggestion that they have different functions. This study intends to further characterize small and large Kupffer cells of normal rat liver in vivo and in vitro. METHODS: Sections of rat liver were investigated by double-staining immunofluorescence with the monoclonal antibodies ED1 and ED2. Isolated nonparenchymal liver cells were separated according to size to obtain small and large Kupffer cells. In culture, phagocytosis was studied by zymosan ingestion and cell proliferation by incorporation of 3H-thymidine. Synthesis of the proteins C1-inhibitor, apolipoprotein E and interleukin-1 was studied by endogenous labeling of newly synthesized proteins, immunoprecipitation and sodium dodecylsulfate-polyacrylamide gel electrophoresis. RESULTS: ED1+ ED2+ Kupffer cells were located in the liver along the sinusoids. ED1+ ED2+ cells were found mainly located around the central vein and portal vessels. By counterflow elution, small ED1+ ED2- cells were separated from larger ED1+ ED2+ cells and cultured. The larger cells abundantly synthesized C1-inhibitor and apolipoprotein E, while the small cells synthesized only trace amounts of these proteins. Interferon-gamma increased C1-inhibitor synthesis in small (5-fold) and large cells (1.5-fold). 3H-thymidine incorporation was 11-fold higher in small than in large cells. However, lipopolysaccharide-induced pro-interleukin-1 alpha and pro-interleukin-1 beta synthesis and phagocytic activity were similar in both populations. CONCLUSIONS: The data demonstrate two different populations of mononuclear phagocytes in normal rat liver well distinguished by immunocytochemical and functional markers.

Impaired production of both normal and mutant C1 inhibitor proteins in type I hereditary angioedema with a duplication in exon 8.

In the autosomal dominant disorder type I hereditary angioedema, reduced levels of C1 inhibitor may be due in part to increased turnover and decreased synthesis of normal C1 inhibitor protein. A type I hereditary angioedema patient was recently described in whom the C1 inhibitor mutation consisted of a 20-bp duplication of nucleotides 1414 to 1433 in exon 8 that introduced a frame shift predicting the loss of a normal stop codon and the translation of a protein 52 amino acids longer than normal. In this study, we analyzed the expression of C1 inhibitor in fibroblasts obtained from a skin biopsy of this patient. Two proteins of approximately 78 and 94 kDa were found intracellularly, corresponding to the products of normal and mutated alleles, respectively. Pulse-chase analysis showed a complete lack of secretion of the mutated form. In addition, there was decreased extracellular production of the normal C1 inhibitor, suggesting either decreased secretion or increased intracellular catabolism of the normal protein because of the presence of the mutant allele. The production of other complement proteins was normal. This study provides a model for further analysis of autosomal dominant genetic disorders in which production of the functional protein may be affected by the product of the mutated allele.

Phosphatase 2A participates in interferon-gamma's induced upregulation of C1 inhibitor mRNA expression.

C1 inhibitor (C1 INH) is the major inhibitor of the proteolytically active subcomponents of C1, kallikrein, activated forms of factor XII, and factor XIa in plasma. We determined the mechanism(s) how interferon-gamma (IFN-gamma) regulates C1 INH mRNA expression in HepG2 cells. Cycloheximide or anisomycin treatment alone did not increase C1 INH mRNA nor did it potentiate C1 INH mRNA expression after IFN-gamma stimulation. C1 INH mRNA levels on Northern blot from untreated and IFN-gamma-treated cells did not change for more than 20 hours after actinomycin D treatment. Actinomycin D and 5,6-dichloro-1-beta-ribofuranosylbenzimidazole abolished IFN-gamma-induced C1 INH mRNA expression. Relatively more C1 INH mRNA precursor (heterogeneous nuclear RNA [hnRNA]) was detected in total RNA from IFN-gamma-treated HepG2 cells than unstimulated cells. Treatment of HepG2 cells with the phosphatase 1 and 2A inhibitors, okadaic acid (> or = 50 nmol/L) and calyculin (> or = 25 nmol/L), decreased IFN-gamma's ability to upregulated C1 INH mRNA. The phosphatase 2A inhibitor, cantharidin (> or = 10 micromol/L), also blocked the IFN-gamma induction of the C1 INH gene. In HepG2 cells total phosphatase 2A activity was significantly increased by C6 ceramide but not IFN-gamma. However, C6 ceramide itself did not increase C1 INH mRNA expression. These data indicate that phosphatase 2A is required to dephosphorylate a substrate in order for IFN-gamma to induce the transcriptional upregulation of C1 INH mRNA, but phosphatase 2A is not a direct stimulator of C1 INH gene expression.

Synthesis of complement proteins in amnion.

The amnion is a metabolically active tissue that has been identified as a site of synthesis of numerous products. We report that amnion tissue explants and amnion-derived epithelial cells synthesize and secrete six proteins of the complement system, C1r, C1s, C1 inhibitor, factor B, C3, and factor H. Synthesis of C2 was minimal and variable, and C5 was not detected. The six synthesized proteins had size and subunit composition characteristic of proteins synthesized in HEp2, a long term cell line derived from malignant epithelial cells. Constitutive and regulated synthesis of five of the six proteins was similar in amnion tissue and cells. However, synthesis of factor B was different in tissue and cells; constitutive synthesis was 12-fold higher in tissue than in cells, and interleukin-1 did not alter synthesis in tissue, but increased synthesis by 11.7-fold in cells. These results indicate that amnion may be a source of complement proteins present in the amnion fluid and may contribute to local host defense along with endometrial glandular epithelial cells, which synthesize C3. Furthermore, our results suggest that amnion tissue is stimulated in vivo to synthesize factor B and cannot respond to interleukin-1 with a further increase in the synthesis rate.

The effect of WSEWS pentapeptide and WSEWS-specific monoclonal antibodies on constitutive and IL-6 induced acute-phase protein production by a human hepatoma cell line, HEPG-2.

Interleukin-6 receptor (IL-6R) is a member of the cytokine receptor superfamily characterised by the obligatory presence of WSXWS (Trp-Ser-X-Trp-Ser) sequence motif near the transmembrane domain. To more clearly understand the role of this motif, we treated the HepG2 hepatoma cell line with synthetic WSEWS peptide (E is glutamic acid) and checked the spontaneous and IL-6-induced production of acute-phase protein fibrinogen and C1-inhibitor (C1-INH). The peptide revealed a definitely stimulatory effect both on the constitutive synthesis of C1-INH and on the IL-6-induced fibrinogen synthesis of HepG2 cells. Monoclonal antibody specific for WSEWS pentapeptide was stimulatory for the spontaneous secretion of both fibrinogen and C1-INH. However, the IL-6-induced elevations of these acute-phase proteins were oppositely regulated, since the anti-WSEWS monoclonal antibody was inhibitory on the production of fibrinogen induced by IL-6 but strongly augmented the IL-6 induced production of C1-INH. Our study indicates that the WSEWS motif is critical in the effect of IL-6 on the acute-phase protein production influencing either the ligand binding by the WSEWS-containing receptor molecule or the signal transduction.