C1-inhibitor influence on platelet activation by thrombin receptors agonists.

INTRODUCTION: Protease activated receptors 1 (PAR1) and 4 (PAR4) agonists are used to study platelet activation. Data on platelet activation are extrapolated across experimental settings. C1-inhibitor (C1INH) is a protease inhibitor present in plasma but not in isolated platelet suspensions. Here we show that C1INH affects platelet activation through PAR1 and PAR4 agonists. METHODS: Platelets were isolated from healthy donor whole blood and then labeled with anti-CD62P and PAC1 antibodies. The platelet suspensions were exposed to PAR1 agonists SFLLRN, TFLLR and TFLLRN; PAR4 agonists AYPGKF and GYPGQV; ADP and thrombin. Flow-cytometric measurements were performed in 5, 10 and 15 min after activation. RESULTS: 0.25 mg/ml C1INH addition made platelets to faster expose CD62P and glycoprotein IIb/IIIa complex after activation with PAR1 agonists. Conversely, C1INH addition led to inhibition of platelet activation with PAR4 agonists and thrombin. Activation with ADP was not affected by C1INH. CONCLUSIONS: Our results suggest that C1INH can modify platelet activation in the presence of synthetic PAR agonists used in platelet research. These observations may be relevant to the development of new methods to assess platelet function.

Self-administration of icatibant in acute attacks of Type I hereditary angioedema: A case report and review of hereditary angioedema.

Hereditary angioedema (HAE) is a rare group of genetic disease characterized by non-itchy swelling of subcutaneous and submucosal tissues of the extremities, genitalia, gastrointestinal tract, and upper airways, which can be life threatening. Moreover, unpredictability and recurrence of HAE attacks significantly affect patients' quality of life. Short- and long-term prophylaxis is used to decrease the severity and frequency of attacks, but during severe or potentially severe acute episodes, treatment with C1-INH replacement or icatibant is mandatory. Icatibant is a selective bradykinin B2 receptor antagonist that has been licensed for self-administration at home, resulting in earlier treatment of the attack and quicker recovery, less emergency admittance with a significant improvement of patients' quality of life, and decrease of health care costs. The authors present a case of a young woman, affected by Type I HAE, who has been successfully treated with icatibant on demand at home, resulting in reduction of emergency admissions and improvement of quality of life. The authors also review the different types HAE, their clinical aspects, diagnosis, and management.

Hereditary angioedema: the plasma contact system out of control.

The plasma contact system contributes to thrombosis in experimental models. Even though our standard blood coagulation tests are prolonged when plasma lacks contact factors, this enzyme system appears to have a minor (if any) role in hemostasis. In this review, we explore the clinical phenotype of C1 esterase inhibitor (C1-INH) deficiency. C1-INH is the key plasma inhibitor of the contact system enzymes, and its deficiency causes hereditary angioedema (HAE). This inflammatory disorder is characterized by recurrent aggressive attacks of tissue swelling that occur at unpredictable locations throughout the body. Bradykinin, which is considered to be a byproduct of the plasma contact system during in vitro coagulation, is the main disease mediator in HAE. Surprisingly, there is little evidence for thrombotic events in HAE patients, suggesting mechanistic uncoupling from the intrinsic pathway of coagulation. In addition, it is questionable whether a surface is responsible for contact system activation in HAE. In this review, we discuss the clinical phenotype, disease modifiers and diagnostic challenges of HAE. We subsequently describe the underlying biochemical mechanisms and contributing disease mediators. Furthermore, we review three types of HAE that are not caused by C1-INH inhibitor deficiency. Finally, we propose a central enzymatic axis that we hypothesize to be responsible for bradykinin production in health and disease.

Pathogenic mechanisms of bradykinin mediated diseases: dysregulation of an innate inflammatory pathway.

Binding of negatively charged macromolecules to factor XII induces a conformational change such that it becomes a substrate for trace amounts of activated factor present in plasma (less than 0.01%). As activated factor XII (factor XIIa or factor XIIf) forms, it converts prekallikrein (PK) to kallikrein and kallikrein cleaves high molecular weight kininogen (HK) to release bradykinin. A far more rapid activation of the remaining unactivated factor XII occurs by enzymatic cleavage by kallikrein (kallikrein-feedback) and sequential cleavage yields two forms of activated factor XII; namely, factor XIIa followed by factor XII fragment (factor XIIf). PK circulates bound to HK and binding induces a conformational change in PK so that it acquires enzymatic activity and can stoichiometrically cleave HK to produce bradykinin. This reaction is prevented from occurring in plasma by the presence of C1 inhibitor (C1 INH). The same active site leads to autoactivation of the PK-HK complex to generate kallikrein if a phosphate containing buffer is used. Theoretically, formation of kallikrein by this factor XII-independent route can activate surface-bound factor XII to generate factor XIIa resulting in a marked increase in the rate of bradykinin formation as stoichiometric reactions are replaced by Michaelis-Menton, enzyme-substrate, kinetics. Zinc-dependent binding of the constituents of the bradykinin-forming cascade to the surface of endothelial cells is mediated by gC1qR and bimolecular complexes of gC1qR-cytokeratin 1 and cytokeratin 1-u-PAR (urokinase plasminogen activator receptor). Factor XII and HK compete for binding to free gC1qR (present in excess) while cytokeratin 1-u-PAR preferentially binds factor XII and gC1qR-cytokeratin 1 preferentially binds HK. Autoactivation of factor XII can be initiated as a result of binding to gC1qR but is prevented by C1 INH. Yet stoichiometric activation of PK-HK to yield kallikrein in the absence of factor XII can be initiated by heat shock protein 90 (HSP-90) which forms a zinc-dependent trimolecular complex by binding to HK. Thus, endothelial cell-dependent activation can be initiated by activation of factor XII or by activation of PK-HK. Hereditary angioedema (HAE), types I and II, are due to autosomal dominant mutations of the C1 INH gene. In type I disease, the level of C1 INH protein and function is proportionately low, while type II disease has a normal protein level but diminished function. There is trans-inhibition of the one normal gene so that functional levels are 30% or less and severe angioedema affecting peripheral structures, the gastrointestinal tract, and the larynx results. Prolonged incubation of plasma of HAE patients (but not normal controls) leads to bradykinin formation and conversion of PK to kallikrein which is reversed by reconstitution with C1 INH. The disorder can be treated by C1 INH replacement, inhibition of plasma kallikrein, or blockade at the bradykinin B-2 receptor. A recently described HAE with normal C1 INH (based on inhibition of activated C1s) presents similarly; the defect is not yet clear, however one-third of patients have a mutant factor XII gene. We have shown that this HAE has a defect in bradykinin overproduction whether the factor XII mutation is present or not, that patients' C1 INH is capable of inhibiting factor XIIa and kallikrein (and not just activated C1) but the functional level is approximately 40-60% of normal, and that α2 macroglobulin protein levels are normal. In vitro abnormalities can be suppressed by raising C1 INH to twice normal levels. Finally, aggregated proteins have been shown to activate the bradykinin-forming pathway by catalyzing factor XII autoactivation. Those include the amyloid ß protein of Alzheimer's disease and cryoglobulins. This may represent a new avenue for kinin-dependent research in human disease. In allergy (anaphylaxis; perhaps other mast cell-dependent reactions), the oversulfated proteoglycan of mast cells, liberated along with histamine, also catalyze factor XII autoactivation.

Oral medicine case book 64: Some aspects of the pathophysiology of angioedema with special reference to the upper aerodigestive tract.

Angioedema refers to a localized oedematous swelling of subcutaneous or submucosal tissues, caused by dilatation and increased permeability of blood vessels, usually mediated either by histamine or by bradykinin. Deficiency or loss of functional activity of the complement component C1 esterase inhibitor (C1-INH) affects multiple systems, including the kallikrein-kinin, complement, coagulation and fibrinolytic pathways, and in the context of angioedema, the result is increased production and release of bradykinin and other vasoactive substances such as C3a. Owing to impairment of C1-INH, factors Xlla and kallikrein, by a positive feedback mechanism, bring about persistent activation of the kallikrein-kinin pathway with amplification of production of bradykinin, resulting in angioedema. Histamine can cause histaminergic angioedema. As the name implies, this oedema is caused by degranulation of mast cells/basophils as a result of an IgE-dependant allergic reaction to extracts of food, drugs, infectious agents, or to physical stimulation; or as the result of direct degranulation of mast cells/basophils independently of IgE, caused by releasing agents such as opiates, antibiotics or radiocontrast media. As dental, oral and maxillofacial operative procedures may trigger the development of angioederria in susceptible individuals, the dental practitioner should be familiar with its

Complement factors in newly diagnosed Nigerian schizoprenic patients and those on antipsychotic therapy.

The role of Complement factors in the pathogenesis of psychiatric disorders is enormous, but the data on levels and functions of complement factors in patients with schizophrenia are scanty and conflicting. To address this issue, levels of Complement regulators (C1 inhibitor and C3 activator) and complement factors (C1q, C3c, C4 and C5) were determined in the serum of newly diagnosed drug free schizophrenic patients, schizophrenic patients on medication and healthy subjects using immune-plates. C1q was significantly reduced in newly diagnosed schizophrenic patients or schizophrenic patients on medication compared with the controls. C3c was significantly reduced in newly diagnosed schizophrenic patients compared with controls or schizophrenic patients on medication. The levels of C3 activators, C1 inhibitors and C4 were similar in the two groups of schizophrenic patients compared with the controls. It may be concluded from this study that C1q is deficient in schizophrenic patients; and that C3c may differentiate newly diagnosed schizophrenia from schizophrenic patients on medication.

Fatal laryngeal attacks and mortality in hereditary angioedema due to C1-INH deficiency.

BACKGROUND: Hereditary angioedema due to C1 inhibitor deficiency (HAE-C1-INH) is characterized by relapsing skin swellings, abdominal pain attacks, and, less frequently, potentially life-threatening laryngeal attacks. OBJECTIVE: This study determined the mortality of patients with and without the diagnosis of HAE-C1-INH and analyzed fatal laryngeal attacks. METHODS: A cohort of 728 patients from 182 families with HAE-C1-INH was evaluated for death cases by analyzing pedigrees. Detailed information on fatal laryngeal attacks in 36 patients was obtained by questioning relatives and treating physicians. RESULTS: Of the 214 patients who had died, 70 asphyxiated during a laryngeal attack. Mortality by asphyxiation was higher in patients with undiagnosed HAE-C1-INH (63 cases) than in patients with diagnosed HAE-C1-INH (7 cases). The lifespan of asphyxiated patients with undiagnosed HAE-C1-INH was on average ∼31 years shorter than patients with undiagnosed HAE-C1-INH who died of other causes. Three phases were distinguished in the fatal laryngeal attacks. Phase 1, the predyspnea phase, lasted on average for 3.7 ± 3.2 hours (range, 0-11 hours). Phase 2, the dyspnea phase, lasted on average for 41 ± 49 minutes (range, 2 minutes to 4 hours). Phase 3, the loss of consciousness phase, lasted on average for 8.9 ± 5.1 minutes (range, 2-20 minutes). CONCLUSIONS: The high mortality in patients with undiagnosed HAE-C1-INH underscores the need to identify these patients and diagnose their condition. The analysis of fatal laryngeal attacks gives further insight into their course, thus helping to avoid fatalities in the future.

C1-inhibitor: more than a serine protease inhibitor.

C1-inhibitor (C1-inh) is a crucial regulator of the activation of plasmatic cascade systems involved in inflammation contributing to the homeostasis in the generation of proinflammatory mediators. The importance of C1-inh is illustrated by patients with hereditary angioedema where decreased levels of C1-inh lead to an uncontrolled generation of vasoactive peptides resulting in potential life-threatening subcutaneous edema. Recent publications, however, suggest that the anti-inflammatory properties of C1-inh do not strictly depend on its capacity to regulate the complement and contact phase system. This review summarizes the biochemical characteristics of C1-inh and its role in the regulation of plasmatic cascade systems as well as the role of the nonserpin domain.

Bench-to-bedside review: the role of C1-esterase inhibitor in sepsis and other critical illnesses.

The purpose of this bench-to-bedside review is to summarize the literature relating to complement activation in sepsis and other critical illnesses and the role of C1-esterase inhibitor (C1 INH) as a potential therapy.

Mast cells increase vascular permeability by heparin-initiated bradykinin formation in vivo.

Activated mast cells trigger edema in allergic and inflammatory disease. We report a paracrine mechanism by which mast cell-released heparin increases vascular permeability in vivo. Heparin activated the protease factor XII, which initiates bradykinin formation in plasma. Targeting factor XII or kinin B2 receptors abolished heparin-triggered leukocyte-endothelium adhesion and interfered with a mast cell-driven drop in blood pressure in rodents. Intravital laser scanning microscopy and tracer measurements showed heparin-driven fluid extravasation in mouse skin microvessels. Ablation of factor XII or kinin B2 receptors abolished heparin-induced skin edema and protected mice from allergen-activated mast cell-driven leakage. In contrast, heparin and activated mast cells induced excessive edema in mice deficient in the major inhibitor of factor XII, C1 esterase inhibitor. Allergen exposure triggered edema attacks in hereditary angioedema patients, lacking C1 esterase inhibitor. The data indicate that heparin-initiated bradykinin formation plays a fundamental role in mast cell-mediated diseases.

Functional characterization of the recombinant human C1 inhibitor serpin domain: insights into heparin binding.

Variants of the human C1 inhibitor serpin domain containing three N-linked carbohydrates at positions 216, 231, and 330 (C1inhDelta97), a single carbohydrate at position 330 (C1inhDelta97DM), or no carbohydrate were produced in a baculovirus/insect cells system. An N-terminally His-tagged C1inhDelta97 variant was also produced. Removal of the oligosaccharide at position 330 dramatically decreased expression, precluding further analysis. All other variants were characterized chemically and shown to inhibit C1s activity and C1 activation in the same way as native C1 inhibitor. Likewise, they formed covalent complexes with C1s as shown by SDS-PAGE analysis. C1 inhibitor and its variants inhibited the ability of C1r-like protease to activate C1s, but did not form covalent complexes with this protease. The interaction of C1 inhibitor and its variants with heparin was investigated by surface plasmon resonance, yielding K(D) values of 16.7 x 10(-8) M (C1 inhibitor), 2.3 x 10(-8) M (C1inhDelta97), and 3.6 x 10(-8) M (C1inhDelta97DM). C1s also bound to heparin, with lower affinity (K(D) = 108 x 10(-8) M). Using the same technique, 50% inhibition of the binding of C1 inhibitor and C1s to heparin was achieved using heparin oligomers containing eight and six saccharide units, respectively. These values roughly correlate with the size of 10 saccharide units yielding half-maximal potentiation of the inhibition of C1s activity by C1 inhibitor, consistent with a "sandwich" mechanism. Using a thermal shift assay, heparin was shown to interact with the C1s serine protease domain and the C1 inhibitor serpin domain, increasing and decreasing their thermal stability, respectively.

C1, MBL-MASPs and C1-inhibitor: novel approaches for targeting complement-mediated inflammation.

Complement activation is initiated by the pattern-recognition molecules complement component C1q, mannose-binding lectin (MBL) and ficolins (H-, L-, M-ficolin), which typically recognize antibody-antigen complexes or foreign polysaccharides. The associated proteases (C1r, C1s, MASP-1 and MASP-2) then activate the complement system. The serpin C1-inhibitor (C1-inh) blocks activity of all these complexes and has been successfully used in models of disease. Many structures of these components became available recently, including that of C1-inh, facilitating the structure-guided design of drugs targeting complement activation. Here, we propose an approach in which therapeutic proteins are made up of natural protein domains and C1-inh to allow targeting to the site of inflammation and more specific inhibition of complement activation. In particular, engineering a fast-acting C1-inh or fusing it to an 'aiming module' has been shown to be feasible and economical using a humanized yeast expression system. Complement-mediated inflammation has been linked to ischemia-reperfusion injury, organ graft rejection and even neurodegeneration, so targeting this process has direct clinical implications.

Hereditary angioedema in a family presenting as transient periarthritis.

Hereditary angioedema (HAE) is a rare condition known to cause episodic, self-limiting, nonpruritic, nonpitting edema that involves skin and visceral organs. It may affect any external body surface including face, extremities, and genitalia. Most commonly involved viscera are gastrointestinal and respiratory systems. Patients may have severe abdominal pain because of edema of the bowel wall. This disease can cause life threatening laryngeal edema if it involves the airway.We describe a patient with HAE who was initially diagnosed with arthritis after she had recurrent edema around her peripheral joints. Diagnosis of HAE in her led to the same diagnosis in her sister and her father. HAE should be considered in the differential diagnosis of recurrent attacks of periarticular swelling.

Mutation screening of C1 inhibitor gene in 108 unrelated families with hereditary angioedema: functional and structural correlates.

Hereditary angioedema (HAE) is an autosomal dominant disorder characterized by the deficiency of the inhibitor of the first component of complement system (C1-INH), which is due to mutations in its structural gene. There are two phenotypic variants: HAE type I, with reduced plasma antigen levels and HAE type II with normal antigen levels and reduced functional C1 inhibitor activity. The aim of this study was to determine the disease-causing mutations in 108 unrelated HAE families, followed at a single center in Italy, and in 50 normal controls by a genetic screening strategy of the C1-INH gene (SERPIN1G). To detect small mutations we either used fluorescence assisted mismatch analysis, followed by sequencing, or direct sequencing. Patients negative for mutations at this screening were further analyzed by long-range PCR to detect the presence of large deletions or insertions. Overall we identified 81 different mutations possibly responsible for the disease in 102 families, in the remaining 6 families no mutation was detected except for a synonymous substitution in a single probant. Sixty-seven of these mutations (23 missense, 22 frameshift, 8 splicing defects, 8 nonsense and 6 large insertion/deletions) had not been previously published. In addition, 4 rare variants, 2 synonymous alterations and 1 new polymorphism in the 3'UTR of the C1-INH gene were found. Mutations were distributed over all exons, at splice sites and in introns. Our study identified a large number of new mutations related to HAE providing additional evidence of the genetic heterogeneity of this disease. Our results also point toward particular amino acid residues important for protein function that may represent mutation hot spots.