Angioedema induced by a peptide derived from complement component C2

Molecular and Cellular Markers in Chlorhexidine-Induced Peritoneal Fibrosis in Mice

Understanding the tissue changes and molecular mechanisms of preclinical models is essential for creating an optimal experimental design for credible translation into clinics. In our study, a chlorhexidine (CHX)-induced mouse model of peritoneal fibrosis was used to analyze histological and molecular/cellular alterations induced by 1 and 3 weeks of intraperitoneal CHX application. CHX treatment for 1 week already caused injury, degradation, and loss of mesothelial cells, resulting in local inflammation, with the most severe structural changes occurring in the peritoneum around the ventral parts of the abdominal wall. The local inflammatory response in the abdominal wall showed no prominent differences between 1 and 3 weeks. We observed an increase in polymorphonuclear cells in the blood but no evidence of systemic inflammation as measured by serum levels of serum amyloid A and interleukin-6. CHX-induced fibrosis in the abdominal wall was more pronounced after 3 weeks, but the gene expression of fibrotic markers did not change over time. Complement system molecules were strongly expressed in the abdominal wall of CHX-treated mice. To conclude, both histological and molecular changes were already present in week 1, allowing examination at the onset of fibrosis. This is crucial information for refining further experiments and limiting the amount of unnecessary animal suffering.

A New Tool for Complement Research: In vitro Reconstituted Human Classical Complement Pathway

The complement, as part of the innate immune system, represents the first line of defense against Gram-negative bacteria invading the bloodstream. The complement system is a zymogen cascade that ultimately assemble into the so-called membrane attack complex (MAC), which lyses Gram-negative bacteria upon insertion into the outer membrane. Traditionally, serum has been used as complement source, for example to study the bactericidal activity of monoclonal antibodies or antibodies raised upon vaccination. Due to the significant donor to donor variability, as well as susceptibility of complement factors to handling and storage conditions, assay reproducibility using human serum is low. Moreover, the presence of pre-existing antibodies and antimicrobial compounds are confounding factors. To remove antibodies from human serum, we applied κ/λ-light chain specific affinity chromatography, however the method severely reduced the complement activity due to the depletion of complement components. Therefore, we attempted to reconstitute human complement-namely the alternative (rAP) and the classical (rCP) pathways-from purified complement factors. We found that adding C1-inhibitor to the mixture was essential to maintain a stable and functional C1 and thus to generate an active rCP. We further confirmed the functionality of the rCP by testing the complement-dependent bactericidal activity of a human monoclonal antibody, A1124 against an E. coli clinical isolate belonging to the ST131 clonal complex, and that of a polyclonal IVIg against a laboratory E. coli strain (MG1655) not expressing LPS O-antigen and capsule. Although the alternative pathway did not have any bactericidal activity by itself, it enhanced MAC deposition induced by rCP and increased the overall bactericidal activity against the ST131 E. coli strain. In conclusion, we report for the first time the successful in vitro reconstitution of the classical pathway of the human complement to establish a serum-free, complement dependent bactericidal assay. This system offers high level of standardization and could support the study of the complement in different research fields.

The Effect of Acute and Chronic Social Stress on the Hippocampal Transcriptome in Mice

Psychogenic stress contributes to the formation of brain pathology. Using gene expression microarrays, we analyzed the hippocampal transcriptome of mice subjected to acute and chronic social stress of different duration. The longest period of social stress altered the expression of the highest number of genes and most of the stress-induced changes in transcription were reversible after 5 days of rest. Chronic stress affected genes involved in the functioning of the vascular system (Alas2, Hbb-b1, Hba-a2, Hba-a1), injury response (Vwf, Mgp, Cfh, Fbln5, Col3a1, Ctgf) and inflammation (S100a8, S100a9, Ctla2a, Ctla2b, Lcn2, Lrg1, Rsad2, Isg20). The results suggest that stress may affect brain functions through the stress-induced dysfunction of the vascular system. An important issue raised in our work is also the risk of the contamination of brain tissue samples with choroid plexus. Such contamination would result in a consistent up- or down-regulation of genes, such as Ttr, Igf2, Igfbp2, Prlr, Enpp2, Sostdc1, 1500015O10RIK (Ecrg4), Kl, Clic6, Kcne2, F5, Slc4a5, and Aqp1. Our study suggests that some of the previously reported, supposedly specific changes in hippocampal gene expression, may be a result of the inclusion of choroid plexus in the hippocampal samples.

Pathophysiology of Hereditary Angioedema

The genetic deficiency of the C1 inhibitor is responsible for hereditary angioedema (HAE), which is a disease transmitted as an autosomal dominant trait. More than 200 point mutations in the C1 inhibitor gene have been found to be associated with HAE. Patients with this disease suffer from recurrent angioedema, which is mediated by bradykinin derived from activation of the contact system. This system is physiologically controlled at several steps by the C1 inhibitor. In this review, we describe known mechanisms for the development of angioedema in patients with C1 inhibitor deficiency.

New treatment options for acute edema attacks caused by hereditary angioedema

PURPOSE

New treatment options for acute edema attacks caused by hereditary angioedema (HAE) are reviewed.

SUMMARY

HAE is characterized by mutations in the C1 inhibitor gene leading to either a reduced expression of C1 inhibitor in the plasma or expression of a functionally impaired C1 inhibitor. HAE is classified into two major types based on the cause of the C1 inhibitor deficiency. Type I HAE is defined by a reduced expression of C1 inhibitor in the plasma, whereas type II HAE is characterized by the expression of a dysfunctional C1 inhibitor protein. Clinical data were reviewed for C1 inhibitor, ecallantide, and icatibant in the treatment of acute edema attacks caused by HAE. C1 inhibitor leads to a faster onset of edema relief and is effective in decreasing the duration of edema. Dosing strategies include fixed dosing and weight-based dosing. Optimal dosing strategies have not been established, but fixed dosing (500-1000 units) or 20 units/kg has been effective in clinical trials and reports. No comparative trials suggest that one strategy is superior to another; however, the approved labeling for acute treatment is based on weight. Ecallantide is also efficacious for treating acute episodes; however, the available evidence is limited to a single published trial. Icatibant has shown variable effects in two trials with placebo and active controls.

CONCLUSION

In patients with HAE, most edema episodes only involve the skin and gastrointestinal tract, though airway obstruction caused by laryngeal angioedema is the most common cause of death. I.V. C1 inhibitor should be considered first-line treatment for acute edema attacks because of its fast onset of action and effectiveness, though it is not clear whether fixed or weight-based dosing is preferred. Ecallantide can be considered as a second-line treatment option.

The structure of C2b, a fragment of complement component C2 produced during C3 convertase formation

The second component of complement (C2) is a multi-domain serine protease that provides catalytic activity for the C3 and C5 convertases of the classical and lectin pathways of human complement. The formation of these convertases requires the Mg(2+)-dependent binding of C2 to C4b and the subsequent cleavage of C2 by C1s or MASP2, respectively. The crystal structure of full-length C2 is not yet available, although the structure of its C-terminal catalytic segment C2a has been determined. The crystal structure of the N-terminal segment C2b of C2 determined to 1.8 A resolution presented here reveals the arrangement of its three CCP domains. The domains are arranged differently compared with most other CCP-domain assemblies, but their arrangement is similar to that found in the Ba part of the full-length factor B structure. The crystal structures of C2a, C2b and full-length factor B are used to generate a model for C2 and a discussion of the domain association and possible interactions with C4b during formation of the C4b-C2 complex is presented. The results of this study also suggest that upon cleavage by C1s, C2a domains undergo conformational rotation while bound to C4b and the released C2b domains may remain folded together similar to as observed in the intact protein.

Hereditary angioedema: a current state-of-the-art review, III: mechanisms of hereditary angioedema

OBJECTIVE

To review the available evidence on the pathophysiologic mechanism of episodes of edema in hereditary angioedema (HAE).

DATA SOURCES

MEDLINE and PubMed were searched using the following keywords: hereditary angioedema, C1 inhibitor, complement system, contact system, and bradykinin.

STUDY SELECTION

Studies were selected based on their relevance to the pathophysiologic features of HAE.

RESULTS

Early studies from the 1970s and 1980s disagreed as to whether the symptoms in HAE were mediated via complement or contact system activation. Studies have demonstrated that, in vitro, in C1 inhibitor (C1-INH)-deficient plasma, only contact system activation results in generation of a vascular permeability enhancing factor. Furthermore, individuals who express a variant C1-INH that is a normal inhibitor of contact system proteases but is deficient in the ability to inactivate complement system proteases do not develop angioedema. The blood of patients with HAE, during attacks, contains elevated levels of cleaved high-molecular-weight kininogen and bradykinin. Last, C1-INH-deficient mice develop increased vascular permeability that is mediated via contact system activation.

CONCLUSIONS

Hereditary angioedema attacks are mediated by bradykinin generated via contact system activation. The specific factors that trigger attacks remain unclear.

Hereditary angioedema: a current state-of-the-art review, II: historical perspective of non-histamine-induced angioedema

OBJECTIVE

To review the evolution of our understanding of hereditary angioedema (HAE) from the first historical reference to the present day.

DATA SOURCES

MEDLINE and PubMed were searched using the following keywords: history of HAE, C1 inhibitor, complements system, genetics of HAE, mechanisms of HAE, and treatment of HAE.

STUDY SELECTION

Information was selected that outlines the advances made in complementology, the first report of HAE, and subsequent studies that elucidated the underlying mechanisms of this disease, leading to current therapy of this orphan disease.

RESULTS

Generational research efforts in HAE have focused on the following: (1) several new clinical presentations, (2) acquired forms of non-histamine-induced angioedema, (3) the genetic basis for the inherited forms, (4) the effects of C1 inhibitor on contact phases of coagulation-fibrinolytic pathways, and (5) various therapies for short- and long-term control of the disease.

CONCLUSION

The progress made in understanding the pathogenesis and treatment of HAE is an excellent example of the "bench to the bedside" paradigm involving the collaboration between clinicians and researchers.

Critical role of kallikrein in hereditary angioedema pathogenesis: A clinical trial of ecallantide, a novel kallikrein inhibitor

BACKGROUND

Hereditary angioedema (HAE) is a rare, autosomal-dominant disorder caused by C1 inhibitor gene mutation. Patients with HAE experience intermittent attacks of edema affecting the oropharynx, abdomen, gastrointestinal tract, and limbs. C1 inhibitor is the primary endogenous inhibitor of the kallikrein-kinin (contact) cascade. Unregulated kallikrein activation generates bradykinin, the likely mediator of the swelling and pain characterizing HAE attacks. Ecallantide, a novel, recombinant protein, potently inhibits kallikrein. This is the first placebo-controlled assessment in human beings of a therapeutic intervention to improve symptoms of HAE attacks under the hypothesis that the contact cascade is the putative pathway responsible for HAE pathology.

OBJECTIVE

To determine the safety and efficacy of ecallantide in patients with HAE.

METHODS

This double-blind, placebo-controlled, ascending-dose study assessed efficacy and tolerability of ecallantide (5, 10, 20, or 40 mg/m(2) intravenously) in individuals experiencing acute HAE attacks (N = 49). Twelve patients were assigned to each dose level: 10 to ecallantide and 2 to placebo, per cohort.

RESULTS

Ecallantide treatment ameliorated the symptoms of HAE attacks: 72.5% (29/40) of patients treated with ecallantide versus 25.0% (2/8) of placebo patients reported significant improvement in symptoms within 4 hours (P = .0169). Ecallantide was well tolerated at all doses.

CONCLUSION

Ecallantide, a potent, specific inhibitor of plasma kallikrein, significantly improved HAE symptoms over placebo. The trial provides strong support for the role of the kallikrein-kinin cascade and its end product, bradykinin, in the pathophysiology of HAE. Further clinical trials are underway.

CLINICAL IMPLICATIONS

Ecallantide is a promising new therapy for HAE attacks.

Mechanism of angioedema in first complement component inhibitor deficiency

Since shortly after the discovery that hereditary angioedema resulted from deficiency of first complement component (C1) inhibitor, the characterization of the mediator of angioedema has been a major goal. However, because C1 inhibitor regulates activation of both the contract and complement systems, identification of the mediator was not immediately accomplished. For a number of years, some studies appeared to indicate involvement of one system, whereas other studies suggested involvement of the other. However, the vast majority of the evidence accumulated over the past years indicates quite clearly that the major mediator is bradykinin. Therefore, unregulated contact system activation is the defect that leads directly to the development of angioedema.

Hereditary angioedema: the clinical syndrome and its management in the United States

There have been important breakthroughs in the understanding and treatment of hereditary angioedema (HAE). An associated abnormality of the serum protein C1 inhibitor led to purified protein use to end attacks. Consideration of the endocrine functions led to rediscovery of impeded androgen use in disease prophylaxis. Considerations of pathophysiology led to introduction of epsilon aminocaproic and tranexemic acids in prophylaxis and to a resurgence in trials of new therapeutic agents. We have gone from a situation where it was not uncommon for patients to have a severe attack sometime in their lives that led to airway compromise and possible death to a situation where death from disease is highly unusual. Thus HAE is in many ways a success story of modern medicine.

Deficiencies of C1 inhibitor

Hereditary and acquired deficiencies of the C1 inhibitor result in a single prominent symptom, namely angioedema. Angioedema may involve the skin, the gastrointestinal tract or the upper airway. Genetically determined defects in C1INH cause hereditary angioedema. The defect may be acquired as the result of an auto-antibody to C1INH or be due to the generation of anti-idiotypic antibody to monoclonal immunoglobulins as occurs in various B cell lymphoproliferative diseases. Androgens provide prophylaxis against attacks of angioedema. There is no widely approved treatment for acute attacks of angioedema although several promising drugs are now in the final stages of clinical trials.

The pathophysiology of hereditary angioedema

Hereditary angioedema (HAE), characterized by recurrent episodes of angioedema involving the skin, or the mucosa of the upper respiratory or the gastrointestinal tracts, results from heterozygosity for deficiency of the serine proteinase inhibitor (serpin), C1 inhibitor (C1INH). The primary biological role of C1INH is to regulate activation of the complement system, the contact system, and the intrinsic coagulation system. During attacks of angioedema, together with decreasing levels of C1INH, the complement and contact systems are activated: C2 and C4 levels fall and high molecular weight kininogen is cleaved. Although previous data suggested that symptoms in HAE might be mediated via complement system activation, a combination of recent clinical data, in vitro studies, and analysis of C1INH-deficient mice all indicate that the major mediator of angioedema is bradykinin: (1) a vascular permeability enhancing factor can be generated in vitro in C1INH-depleted, C2-deficient plasma, but not from C1INH-depleted, contact system-deficient plasma; this factor was identified by sequence analysis as bradykinin; (2) bradykinin can be detected in the plasma of HAE patients during attacks of angioedema; (3) in several members of one family, expression of a C1INH variant that inhibits contact system proteases but has defective inhibition of C1r and C1s does not result in HAE; (4) C1INH-deficient (C1INH-/-) mice have a defect in vascular permeability that is suppressed by treatment with specific plasma kallikrein inhibitors and by bradykinin type 2 receptor (Bk2R) antagonists, and is eliminated in C1INH-/-, Bk2R-/- double-deficient mice.

Formation of Bradykinin: A Major Contributor to the Innate Inflammatory Response

The plasma kinin-forming cascade can be activated by contact with negatively charged macromolecules leading to binding and autoactivation of factor XII, activation of prekallikrein to kallikrein by factor XIIa, and cleavage of high molecular weight kininogen (HK) by kallikrein to release the vasoactive peptide bradykinin. Once kallikrein formation begins, there is rapid cleavage of unactivated factor XII to factor XIIa, and this positive feedback is favored kinetically over factor XII autoactivation. Examples of surface initiators that can function in this fashion are endotoxin, sulfated mucopolysaccharides, and aggregated Abeta protein. Physiological activation appears to occur along the surface of endothelial cells both by the aforementioned contact-initiated reactions as well as bypass pathways that are independent of factor XII. Factor XII binds primarily to cell surface u-PAR (urokinase plasminogen activator receptor); HK binds to gC1qR via its light chain (domain 5) and to cytokeratin 1 by its heavy chain (domain 3) and, to a lesser degree, by its light chain. Prekallikrein circulates bound to HK (as does coagulation factor XI), and prekallikrein is thereby brought to the surface as HK binds. All cell-binding reactions are dependent on zinc ion. Endothelial cells (HUVECs) have bimolecular complexes of u-PAR-cytokeratin 1 and gC1qR-cytokeratin 1 at the cell surface plus free gC1qR, which is present in substantial molar excess. Factor XII appears to interact primarily with the u-PAR-cytokeratin 1 complex, whereas HK binds primarily to the gC1qR-cytokeratin 1 complex and to free gC1qR. Release of endothelial cell heat shock protein 90 (Hsp90) or the enzyme prolylcarboxypeptidase leads to activation of the bradykinin-forming cascade by activating the prekallikrein-HK complex. In contrast to factor XIIa, neither will activate prekallikrein in the absence of HK, both reactions require zinc ion, and the stoichiometry suggests interaction of one molecule of Hsp90 (for example) with one molecule of prekallikrein-HK complex. The presence of factor XII, however, leads to a marked augmentation in reaction rate via the kallikrein feedback as well as to a change to classic enzyme-substrate kinetics. The circumstances in which activation is initiated by factor XII autoactivation or by these factor XII bypasses are yet to be defined. The pathologic conditions in which bradykinin generation appears important include hereditary and acquired C1 inhibitor deficiency, cough and angioedema due to ACE inhibitors, endotoxin shock, with contributions to conditions as diverse as Alzheimer's disease, stroke, control of blood pressure, and allergic diseases.

Domain structure of bi-functional selenoprotein P

Human selenoprotein P (SeP), a selenium-rich plasma glycoprotein, is presumed to contain ten selenocysteine residues; one of which is located at the 40th residue in the N-terminal region and the remaining nine localized in the C-terminal third part. We have shown that SeP not only catalyses the reduction of phosphatidylcholine hydroperoxide by glutathione [Saito, Hayashi, Tanaka, Watanabe, Suzuki, Saito and Takahashi (1999) J. Biol. Chem. 274, 2866-2871], but also supplies its selenium to proliferating cells [Saito and Takahashi (2002) Eur. J. Biochem. 269, 5746-5751]. Treatment of SeP with plasma kallikrein resulted in a sequential limited proteolysis (Arg-235-Gln-236 and Arg-242-Asp-243). The N-terminal (residues 1-235) and C-terminal (residues 243-361) fragments exhibited enzyme activity and selenium-supply activity respectively. These results confirm that SeP is a bi-functional protein and suggest that the first selenocysteine residue is the active site of the enzyme and the remaining nine residues function as a selenium supplier.

Hereditary and acquired angioedema: problems and progress: proceedings of the third C1 esterase inhibitor deficiency workshop and beyond

Hereditary angioedema (HAE), a rare but life-threatening condition, manifests as acute attacks of facial, laryngeal, genital, or peripheral swelling or abdominal pain secondary to intra-abdominal edema. Resulting from mutations affecting C1 esterase inhibitor (C1-INH), inhibitor of the first complement system component, attacks are not histamine-mediated and do not respond to antihistamines or corticosteroids. Low awareness and resemblance to other disorders often delay diagnosis; despite availability of C1-INH replacement in some countries, no approved, safe acute attack therapy exists in the United States. The biennial C1 Esterase Inhibitor Deficiency Workshops resulted from a European initiative for better knowledge and treatment of HAE and related diseases. This supplement contains work presented at the third workshop and expanded content toward a definitive picture of angioedema in the absence of allergy. Most notably, it includes cumulative genetic investigations; multinational laboratory diagnosis recommendations; current pathogenesis hypotheses; suggested prophylaxis and acute attack treatment, including home treatment; future treatment options; and analysis of patient subpopulations, including pediatric patients and patients whose angioedema worsened during pregnancy or hormone administration. Causes and management of acquired angioedema and a new type of angioedema with normal C1-INH are also discussed. Collaborative patient and physician efforts, crucial in rare diseases, are emphasized. This supplement seeks to raise awareness and aid diagnosis of HAE, optimize treatment for all patients, and provide a platform for further research in this rare, partially understood disorder.

The pathogenesis of hereditary angioedema

Hereditary angioedema (HAE), which is characterized by episodic localized angioedema of the skin or mucosa, results from heterozygous deficiency of the plasma protease inhibitor, C1 inhibitor (C1INH). The most obvious biologic role of C1INH, therefore, is prevention of excessive vascular permeability. A variety of data indicate that this role is primarily a product of regulation of the contact system proteases, factor XIIa and plasma kallikrein. The C1INH deficient mouse, although it does not have episodes of cutaneous angioedema, does have increased vascular permeability which is reversed by treatment with C1INH, with the plasma kallikrein inhibitor, DX88, and with the bradykinin 2 receptor (Bk2R) antagonist, Hoe140. In addition, mice deficient in both C1INH and the Bk2R do not have increased vascular permeability. These analyses strengthen the argument that angioedema is mediated by bradykinin. This mouse also provides a system to test new potential therapeutic approaches. In addition to its role in the regulation of vascular permeability, C1INH also is an important modulator of inflammatory responses via regulation of activation of both the contact and the complement systems, and very likely via activities unrelated to protease inhibition.

Estrogen-dependent inherited angioedema

Classic forms of hereditary angioedema are characterized clinically by recurrent episodes of angioedema, biochemically by reduced C1 inhibitor level and/or function, and genetically by a heterogeneous group of mutations in the C1 inhibitor gene that have an autosomal dominant mode of transmission. Androgens and estrogens have significant clinical effects in patients with hereditary angioedema, and tend to have antagonist effects of the levels of C1 inhibitor protein. Androgens increase the levels of C1 inhibitor protein, reduce attacks of angioedema, and thus are an important therapy for patients. The mechanisms by which the sex steroid hormones achieve these effects are not understood. The recent recognition of a novel estrogen-dependent form of angioedema may offer important insights into the mechanisms by which the sex hormones exert their effects, and the pathogenesis and treatment of both estrogen-dependent and classic forms of hereditary angioedema.

DX-88 and HAE: a developmental perspective

An example of an approach to the developmental philosophy of novel recombinant products is explored by using the exemplar of Hereditary Angioedema (HAE). Plasma kallikrein is believed to be an important mediator of angioedema in patients with genetic deficiency of C1 esterase inhibitor (HAE patients). DX-88, a novel Kunitz domain produced by phage display (a powerful method of generating novel binders to potentially therapeutic targets), is a potent and selective inhibitor of plasma kallikrein which in early clinical studies demonstrates a useful efficacy/safety ratio in the treatment of acute attacks of HAE.

C1 inhibitor infusion modifies platelet activity in hereditary angioedema patients

CONTEXT

C1 inhibitor (C1-INH) is an alpha2-globulin that blocks esterolytic activity of the first component of the classic complement cascade. The alpha-granules of normal human platelets also contain C1-INH, which is expressed on the platelet surface during platelet secretion in healthy patients, but it is clearly reduced in patients with hereditary angioedema (HAE).

OBJECTIVE

To evaluate the effects of in vivo C1-INH concentrate infusion on platelet responsiveness and coagulation system activity in patients with HAE.

DESIGN

Assessment of the platelet activity and plasma levels of C1-INH, activated factor XII (XIIa), and prothrombin fragment F1.2 (F1.2) before and after infusion of 15 U/kg of C1-INH concentrate.

PATIENTS

In 6 patients (4 men and 2 women), HAE was diagnosed according to the accepted clinical and laboratory criteria.

MEASUREMENTS

Platelet aggregation (final concentrations: adenosine diphosphate, 0.5, 1.25, and 2.5 microM; collagen, 5 microg/mL), C1-INH antigen (radial immunodiffusion), C1-INH activity (chromogenic substrates), and XIIa and F1.2 (enzyme-linked immunosorbent assay).

RESULTS

After C1-INH infusion, we observed a prompt increase of C1-INH level and a slow return toward its plasma preinfusion values within 4 to 7 days, a significant decrease of both adenosine diphosphate- and collagen-induced platelet aggregation versus preinfusion values (maximum after 1-2 days; P <.001), and a rapid decrease of high basal values of XIIa and F1.2 in 30 and 120 minutes, respectively.

CONCLUSIONS

These data show a role of C1-INH in the control of platelet activity and that its deficiency increases platelet aggregability and plasma levels of XIIa and F1.2 in patients with HAE.

Increased vascular permeability in C1 inhibitor-deficient mice mediated by the bradykinin type 2 receptor

Heterozygosity for C1 inhibitor (C1INH) deficiency results in hereditary angioedema. Disruption of the C1INH gene by gene trapping enabled the generation of homozygous- and heterozygous-deficient mice. Mating of heterozygous-deficient mice resulted in the expected 1:2:1 ratio of wild-type, heterozygous, and homozygous-deficient offspring. C1INH-deficient mice showed no obvious phenotypic abnormality. However, following injection with Evans blue dye, both homozygous and heterozygous C1INH-deficient mice revealed increased vascular permeability in comparison with wild-type littermates. This increased vascular permeability was reversed by treatment with intravenous human C1INH, with a Kunitz domain plasma kallikrein inhibitor (DX88), and with a bradykinin type 2 receptor (Bk2R) antagonist (Hoe140). In addition, treatment of the C1INH-deficient mice with an angiotensin-converting enzyme inhibitor (captopril) increased the vascular permeability. Mice with deficiency of both C1INH and Bk2R demonstrated diminished vascular permeability in comparison with C1INH-deficient, Bk2R-sufficient mice. These data support the hypothesis that angioedema is mediated by bradykinin via Bk2R.

Assessment of urticaria and angio-oedema

There are many types of urticaria and the principal form of assessment is by clinical history and examination. Urticarial weal formation involves acute, reversible vasodilatation and increased vascular permeability. If the process is deeper the more diffuse swelling is termed angio-oedema. The major types of urticaria include allergic, physical and idiopathic forms. In allergic urticaria, IgE-mediated degranulation of mast cells results in weals of short duration which typically respond well to antihistamines. Physical urticarias are induced by physical insults including pressure, scratch, cold, etc. The distribution and duration of individual weals may suggest the causal factor. Chronic idiopathic urticaria can be very variable, with individual weals lasting between 90 min and 24 hours. Longer-lasting weals are less responsive to anti-histamines and clearly involve other mediators. When long-lasting weals fade leaving a bruised appearance urticarial vasculitis is present which may only respond to systemic corticosteroids. In a proportion of individuals with chronic idiopathic urticaria, auto-antibodies are present with specificity for the high affinity receptor for IgE or sometimes, for IgE itself. In general laboratory tests for allergic factors or other assessments of general health are completely unhelpful.

Pathogenetic and clinical aspects of C1 inhibitor deficiency

People deficient in C1-INH present recurrent angioedema localized to subcutaneous or mucous tissues. The defect can be caused by impaired synthesis, due to a genetic defect (hereditary angioedema), or by increased catabolism (acquired angioedema). In our experience the majority of patients with acquired angioedema (16 of 18) have autoantibodies to C1-INH in their serum. These autoantibodies bind to C1-INH with different and generally low affinity. The vasopermeability mediator responsible for attacks is still undefined: bradykinin (derived from cleavage of high molecular weight kininogen) and a kinin-like peptide (derived from the second component of complement) still remain the two primary candidates. We examined the systems controlled by C1-INH (complement, contact system, fibrinolysis and coagulation) and found that all of them are activated during angioedema attacks. Activation of the coagulation leads to generation of thrombin whose vasoactive effect can thus influence edema formation. Treatment of severe angioedema attacks is satisfactorily performed with C1-INH plasma concentrate although patients with an acquired defect frequently need very high doses. Attenuated androgens effectively prevent attacks in hereditary angioedema, but their safety, on the very long-term, needs to be further assessed. Acquired angioedema generally fail to respond to these drugs, but can be treated prophylactically with antifibrinolytic agents.

Genetic deficiencies of complement

Genetic deficiencies of proteins of the complement system are associated with diverse clinical phenotypes. These clinical manifestations vary as a function of the specific component that is missing. Molecular and cellular biological methods, coupled with more intensive clinical studies, have defined the pathophysiological basis for this set of genetic disorders. Insights into the normal function of complement and its role in immunopathology have been derived from the extensive work in this field during the past few years.

Purification and characterization of a novel substrate for plasma kallikrein (PK-120) in human plasma

A 120 kDa plasma protein, which is susceptible to plasma kallikrein, was purified from human plasma by polyethylene glycol fractionation followed by ion exchange chromatography using Q-Sepharose, S-Sepharose, and hydroxyapatite and gel filtration on Sephacryl S-200. The 120 kDa protein, termed PK-120 in this paper, was a single polypeptide chain containing about 20% sugar by weight and its concentration in plasma was estimated to be 80 micrograms/ml by ELISA. At least three fragments, 100, 70, and 35 kDa, were produced from PK-120 by plasma kallikrein. The N-terminal sequence and Western blot demonstrated that PK-120 was first cleaved to yield the 100 and 35 kDa fragments, then the 100 kDa fragment was cleaved into the 70 kDa fragment. N-Terminal sequence analyses of PK-120 and its fragments demonstrated that it is a novel plasma protein, distinct from high molecular weight kininogen, a natural substrate for plasma kallikrein.

Hereditary angioneurotic oedema: characterization of plasma kinin and vascular permeability-enhancing activities

The mediator(s) responsible for localized enhanced vascular permeability that characterizes an exacerbation of hereditary angioneurotic oedema (HAE) is thought to be a product of either contact or complement system activation. In contrast to normal individuals, plasma from these patients generates both kinin and vascular permeability-enhancing activity following incubation at 37 degrees C. Depletion of C1 inhibitor in both normal and C2-deficient plasma, but not in contact factor-deficient plasmas, resulted in generation of these activities. The kinin activity from incubated HAE plasma was susceptible to kininase inactivation and was blocked by a Bk2 receptor antagonist. Furthermore, this activity was isolated from HAE plasma; amino acid sequence analysis proved it to be bradykinin. Similarly, the vasopermeability-enhancing activity from ethanol-fractionated or boiled HAE plasma, collected during either attack or remission, co-eluted with bradykinin on reverse-phase high performance liquid chromatography (HPLC). These studies conclusively demonstrate that bradykinin is the major kinin and mediator of enhanced vascular permeability generated during incubation of HAE plasma. The role of other bioactive products, such as the C2 kinin, at local sites of oedema formation remains to be further defined.

Recurrent angioedema and urticaria

The case reported here illustrates the life-threatening aspects of angioedema and the need to thoroughly investigate the possible causes of this clinical finding. As discussed, the causes of angioedema are numerous. Commonly implicated in drug-induced angioedema are antihypertensive ACE inhibitor drugs, as was originally thought with this patient. Because of her skin lesions and macrocytic anemia, further studies were done. These studies led to a diagnosis of hypocomplementemic urticarial vasculitis syndrome, an uncommon to rare form of acquired angioedema, urticarial vasculitis, arthritis, and obstructive airway disease associated with the production of autoantibodies to C1q. It is an autoimmune disorder related to but separate from SLE.

Peripheral edema due to increased vascular permeability: a clinical appraisal

The release of vasoactive substances produces reversible changes of endothelial permeability with consequent edematous syndromes. We present 899 patients referred to our clinic for "non-hydrostatic non-hyponcotic" recurrent edema problems. Personal and family histories were recorded and a complete physical examination was carried out for each patient. In chronic situations laboratory tests [blood cell count, cryoglobulins, thyroid hormones, complement components (C3, C4, C1 inhibitor), total IgE, skin testing] were performed. Four subgroups of angioedema are identified for relevant clinical and etiopathogenetic differences. Seventy-three percent of patients had an urticaria-angioedema syndrome responding to antihistamine and/or corticosteroid treatment (histamine-dependent angioedema). Twenty-three percent had an angioedema related to a deficiency in C1 esterase inhibitor (complement-dependent angioedema). In a minority of patients, angioedema was due to the pharmacological effect of a drug (pharmacological angioedema) or was of a totally unknown origin (idiopathic angioedema). A generalized increase in vascular permeability was reported in 3 patients (systemic capillary leak syndrome). A brief survey of the literature is given with the review of our patients.

Acute consumption of C1 inhibitor in a patient with acquired C1-inhibitor deficiency syndrome

Acquired C1-inhibitor (C1 INH) deficiency is usually found in association with an underlying disease that is believed to be responsible for increased C1 INH catabolism, ultimately leading to the development of C1 INH deficiency. We report a remarkable patient with acquired C1 INH deficiency in whom a unique progression of complement- and contact-system abnormalities has been observed. S. G. suffers from recurrent episodes of angioedema and hypotension. Results of repeated complement studies were initially normal, and the patient was diagnosed as having idiopathic anaphylaxis. Two years later, the patient was found to develop acute consumption of C1 INH with activation of the complement and contact systems during episodes of angioedema. The patient continued to have normal C1 INH levels and to have no evidence for complement- or contact-system activation between attacks of angioedema. One year later, her course evolved into a more typical course for acquired C1 INH deficiency consisting of continuously low functional C1 INH levels with evidence of activation of the complement and contact systems. S. G. provides a unique insight into the development of acquired C1 INH deficiency.

Complement deficiency and disease

Complement deficiency is associated with an increased prevalence of pyogenic infections and immune complex disease. The spectrum of disease in deficient individuals depends on the stage in the complement system at which the block in activation occurs. Here, Paul Morgan and Mark Walport review current knowledge of hereditary complement deficiencies in humans, emphasizing the importance of these 'experiments of nature' in defining the roles of complement in vivo.

Clusters of intragenic Alu repeats predispose the human C1 inhibitor locus to deleterious rearrangements

Frequent alterations in the structure of the complement component C1 inhibitor gene have been found in patients affected by the common variant of hereditary angioedema, characterized by low plasma levels of C1 inhibitor. This control protein limits the enzymic activity of the first component of complement and of other plasma serine proteases. Sequence comparisons of a 4.6-kilobase-long segment of the normal gene and the corresponding gene segments isolated from two patients carrying family-specific DNA deletions point to unusually long clusters of tandem repeats of the Alu sequence family as a source of genetic instability in this locus. Unequal crossovers, in a variety of registers, among Alu sequences of the clusters result in deletions of variable length that encompass exon 4. In a third family, exon 4 was instead found to be duplicated along with the same tracts of flanking introns lost in one of the deletions. In addition to undergoing Alu-mediated partial deletions and duplications, the gene is also a target for more recent retroposition events. Gross alterations in the C1 inhibitor gene account for about 20% of the hereditary angioedema chromosomes and consequently make this gene a prime example of the mutagenic liability of Alu repeats.

Angioedema with acquired deficiency of the C1 inhibitor: a constellation of syndromes

Patients with angioedema are often referred to an allergist to rule out an allergic cause. In most of these cases, no allergic cause is identified, and the cases are labeled "idiopathic." Occasionally, a deficiency of the inhibitor of the first component of complement (C1INH) is discovered, which may be either hereditary or acquired. In comparison with the hereditary variant, the acquired deficiency of C1INH is extremely rare, approximately 40 cases having been reported to date. Measurement of the C1q subunit is the key to the differential diagnosis between hereditary and acquired deficiencies of C1INH--it is normal in the former and decreased in the latter. The acquired deficiency of C1INH is usually found in association with benign or malignant B-cell lymphoproliferative disorders, and the angioedema responds to therapy with androgens. A subset of six patients with acquired C1INH deficiency has been reported recently; they had anti-C1INH autoantibodies, no evidence of an underlying disease, a benign course, and variable responses to therapy. Two new cases of angioedema in patients with acquired C1INH deficiency are described in this report. One patient had no evidence of an underlying disease 11 years after the onset of angioedema. The other case was associated with a B-cell lymphoproliferative disorder that became evident 9 months after C1INH deficiency was diagnosed, and androgen therapy stopped the attacks of angioedema. In this second case, the functional activity of C1INH mirrored the clinical response to therapy.