Novel duplication in the F12 gene in a patient with recurrent angioedema

Edema formation is mediated by histamine or bradykinin release and may have several hereditary and acquired causes. In hereditary forms of bradykinin-mediated angioedemas, mutations in the genes encoding C1-inhibitor (SERPING1) as well as coagulation factor XII (F12) have been described. We present a novel F12 gene mutation, a duplication of 18 base pairs (c.892_909dup) in a 37-year-old woman with recurrent angioedema and normal C1-inhibitor level. A single episode of facial edema in the family of the patient showed co-segregation with the mutation. This duplication is causing the repeated presence of 6 amino acids (p.298–303) in the same region of factor XII, as those three mutations described previously in cases of hereditary angioedema with normal C1-INH function. These results may confirm the importance of the proline-rich region of factor XII protein in edema formation.     

A novel mutation in the coagulation factor 12 gene in subjects with hereditary angioedema and normal C1-inhibitor

In hereditary angioedema with normal C1-inhibitor two different missense mutations of codon p.Thr328* in the coagulation factor 12 gene have been reported in some families. In this study a novel factor 12 gene mutation, the deletion of 72 base pairs (bp) (c.971_1018 + 24del72*), was identified in a family of Turkish origin, in two sisters with recurrent skin swellings and abdominal pain attacks and in their symptom-free father. This deletion caused a loss of 48 bp of exon 9 (coding amino acids 324* to 340*) in addition to 24 bp of intron 9, including the authentic donor splice site of exon 9. The large deletion of 72 bp was located in the same F12 gene region as the missense mutations p.Thr328Lys* and p.Thr328Arg* reported previously. Our findings confirm the association between F12 gene mutations modifying the proline-rich region of the FXII protein and hereditary angioedema with normal C1-inhibitor.     

Hereditary angioedema with normal C1 inhibitor activity including hereditary angioedema with coagulation factor XII gene mutations

Until recently it was assumed that hereditary angioedema is a disease that results exclusively from a deficiency of the C1 inhibitor. In 2000, families with hereditary angioedema, normal C1 inhibitor activity, and protein in plasma were described; all patients were women. In many of the affected women, oral contraceptives, hormone replacement therapy containing estrogens, and pregnancies triggered the clinical symptoms. Recently, in some families mutations in the coagulation factor XII (Hageman factor) gene were detected in the affected women.     

Clinical, biochemical, and genetic characterization of a novel estrogen-dependent inherited form of angioedema

BACKGROUND: Two genetic forms of hereditary angioedema (HAE) are currently recognized. Both are transmitted in an autosomal dominant manner and are characterized by recurrent episodes of localized angioedema. Involvement of the gut leads to episodes of severe abdominal pain, and laryngeal involvement can lead to airway obstruction and even death. One type results from heterozygosity for a nonexpressed C1 inhibitor allele, and the other results from heterozygosity for a nonfunctional C1 inhibitor allele. OBJECTIVE: This report identifies a third type of HAE, with a unique estrogen-dependent phenotype. METHODS: Detailed medical histories were obtained from family members, and a pedigree was constructed to ascertain the mode of inheritance. Determination of serum complement factors, C1 inhibitor protein, C1 inhibitor function, coagulation factor XII, plasma prekallikrein, high molecular weight kininogen, and selected DNA sequences were performed in affected members by using standard assays. RESULTS: Episodes of angioedema were clinically indistinguishable from those associated with previously described forms of HAE; however, these occurred only during pregnancy or the use of exogenous estrogens. Patients were otherwise asymptomatic, except for one patient who had acetyl salicylic acid/nonsteroidal anti-inflammatory drug-related angioedema later in life. History was available for members spanning 4 generations, and affected individuals were identified in 3 generations. Of 46 family members, phenotype could be determined in 13 members. Seven were affected, and 6 were not. One male of undetermined phenotype was an obligate carrier. The unique estrogen-dependent nature of the phenotype means that the status of several members in the third and fourth generation remains unknown. The disorder appears to be transmitted in an autosomal dominant fashion, although other modes of inheritance cannot be excluded entirely. C1 inhibitor protein, C1 inhibitor function, C2, C4, C1q, coagulation factor XII, prekallikrein, and high molecular kininogen were normal in 3 affected family members during asymptomatic periods. DNA sequencing revealed no abnormality in 3 patients in the coding region of the gene encoding C1 inhibitor or in the 5' flanking regions of the genes encoding C1 inhibitor and factor XII. CONCLUSIONS: This family appears to have a novel form of inherited angioedema that does not result from C1 inhibitor deficiency or dysfunction. The phenotype is uniquely estrogen dependent. Implications for diagnosis and treatment are discussed. Further studies are required to define the exact nature of the genetic abnormality involved.     

Identification of a C → T Mutation in the Reactive-Site Coding Region of the C1-Inhibitor Gene and its Detection by an Improved Mutation-Specific Polymerase Chain Reaction Method

Mutations in the C1-inhibitor (C1-INH) gene, leading to low functional levels of C1-inhibitor protein, cause hereditary angioedema (HAE). The disease is characterized by episodic edema in a number of organs. Typically, swellings occur in extremities and face, often accompanied by crampy abdominal pain. Laryngeal edema may lead to suffocation. Type II HAE patients have low functional C1-INH values stemming from only one normal allele. Antigenic C1-INH values, however, are normal or increased owing to the presence of a dysfunctional protein from the mutated allele. The mutations are usually found in exon 8 coding for the amino acids near the reactive centre (P1). Previously, no mutations in the C1-INH gene had been published from the Scandinavian countries. In this work, exon 8 of the C1-inhibitor gene was sequenced in members of two different kindreds, from western and northern Norway, who were suffering from HAE type II. A common point mutation was found within the bait region encoding the reactive centre. The codon CGC was converted to TGC at position 17 970, corresponding to an Arg → Cys replacement which reportedly is the second most frequent type II HAE mutation. This information was utilized to develop a mutation-specific polymerase chain reaction (PCR) for the identification of affected family members. The antisense 17-mer primer (5'-AAGACCAGCAGGGTGCA-3') was successfully applied and AmpliTaq Gold was used in the PCR.     

Autoantibody-mediated acquired deficiency of C1 inhibitor

During the past 25 years, three forms of deficiency of the inhibitor of the first component of complement (C1 inhibitor) with angioedema have been recognized; two forms are hereditary and one is acquired. As compared with hereditary angioedema, the syndrome of acquired C1-inhibitor deficiency is rare, and it is usually associated with lymphoproliferative diseases. We report another type of acquired C1-inhibitor deficiency with angioedema. Two patients with recurrent angioedema but no associated diseases were found to have IgG1 autoantibodies against C1 inhibitor. The anti-C1-inhibitor antibodies prevented binding of C1 inhibitor to activated C1s. Both patients had 60 to 70 percent of normal levels of C1 inhibitor, but it was functionally inactive, with a molecular weight of 96,000 (normal C1 inhibitor, 105,000). In vitro studies of the patients' serum revealed degradation of 125I-labeled 105,000-dalton C1 inhibitor into the inactive 96,000-dalton molecule, caused by activated C1s and not found in normal human serum. We conclude that these cases of acquired C1-inhibitor deficiency resulted from a blockade of C1-inhibitor function by the anti-C1-inhibitor antibodies and from subsequent inactivation of C1 inhibitor by the now uncontrolled enzyme, activated C1s. As in other forms of C1-inhibitor deficiency, the unopposed activation of the complement system led to angioedema.     

Prekallikrein activation and high-molecular-weight kininogen consumption in hereditary angioedema

Patients with hereditary angioedema lack C-1 inhibitor, a plasma alpha 2-glycoprotein that inhibits both the proteolytic action of C1, the activated first component of the complement system, and the activity of components of the contact phase of coagulation: kallikrein, factor XIa, and factor XIIa. Such patients have been shown to have low levels of C4 and C2, the natural substrates for C-1, but the levels were not correlated with the presence of symptoms. We studied three patients with angioedema for evidence of activation of the contact system and found that during a symptomatic period they had decreased levels of prekallikrein, a substrate for the activated forms of factor XII, and reductions in high-molecular-weight kininogen, a substrate for plasma kallikrein. These observations suggest that zymogens of the contact system are activated during attacks of hereditary angioedema and that some of the clinical manifestations may be mediated through products of this pathway, such as kinins.     

The value of rocket immunoelectrophoresis for C4 activation in the evaluation of patients with angioedema or C1-inhibitor deficiency

The correct diagnosis and characterization of C1-inhibitor deficiency depends on both clinical observations and laboratory evaluation of complement in plasma. Rocket immunoelectrophoresis for C4d is a sensitive assay for C4 activation in plasma. We have evaluated the value of this assay in identifying patients with C1-inhibitor deficiency. C4 activation was assessed in the plasmas of 15 patients with hereditary angioedema, five patients with variant form of hereditary angioedema, and four patients with acquired C1-inhibitor deficiency. Control groups consisted of 27 patients with chronic idiopathic urticaria and/or angioedema and seven normal volunteers. C4 activation was detected in all 52 plasma samples collected from the 24 patients with C1-inhibitor deficiency. The degree of C4 activation increased during attacks of angioedema and decreased (but remained elevated) during treatment with attenuated androgens. The concentrations of C4, C2, and C1 inhibitor were also measured; however, none of these measurements identified all of the patients with C1-inhibitor deficiency. Thus, we conclude that the measurement of C4 activation is one of the best tests available to evaluate a patient for C1-inhibitor deficiency, and a normal result will exclude the diagnosis of C1-inhibitor deficiency.     

The role of cpg sequences in the induction of anti-DNA antibodies

C1 esterase inhibitor (C1INH) is an important regulatory protein of the classical pathway of complement. Mutations in the gene for this protein cause the autosomal dominant disorder hereditary angioedema (HAE). Approximately 85% of patients with HAE have a Type I defect, characterized by a diminished level of antigenic and functional C1INH. Patients with Type II defects have sufficient protein, but one allele produces dysfunctional protein. We have sequenced the DNA from HAE patients and have discovered four previously unreported mutations. The first mutation is a splice site error at nucleotide 8721, which changes the 3' acceptor splice site AG to GG at the end of intron 5 at nucleotide 8721-8722. The second mutation is a single base insertion in exon 3 between nucleotides 2467 and 2468. The third mutation is a missense error present in the eighth exon of the C1INH; at nucleotide 16867 (amino acid 470), a T to A mutation transforms a Met to a Lys. The fourth mutation closely resembles the third mutation in that it is a missense error occurring in exon 8 in the distal hinge region; a T16827C substitution changes the Phe at amino acid 457 to Leu. This report compiles a list of 97 distinct defects in the C1INH gene that cause hereditary angioedema.     

Hereditary angioedema associated with heterozygous factor V Leiden mutation in a patient with Purpura fulminans

BACKGROUND: Hereditary angioedema (HAE) is an autosomal dominant, quantitative or functional defect of the C1 esterase inhibitor. The main role of the C1 esterase inhibitor is to regulate the activation of the complement system, the contact phase of the intrinsic coagulation system. On the other hand, factor V Leiden is the most common cause of primary and recurrent venous thromboembolism and displays a strong interaction with oral contraceptives. Here we report the case of a patient with HAE associated with the factor V Leiden mutation who had purpura fulminans when put on an oral contraceptive therapy. CASE: A 42-year-old woman presented to the emergency room with a history of livid skin changes on her legs during a flight. On physical examination, the vital signs were normal, but there were edemas in her legs. The livid skin changes tended to increase, eventually leading to skin necrosis on the next day. She had a history of a similar episode two months before and experienced both episodes of necrotic skin lesions just after she had been put on a hormone replacement therapy due to irregular menstruations. She also had a history of recurrent angioedema attacks since her childhood, triggered by stress and physical stimulants such as pressure and heat. Subsequent investigations revealed heterozygous factor V mutation, activated protein C resistance and reduced C1 inhibitor levels. CONCLUSION: Thrombosis is a multifactorial disease. The coexistence of multiple hereditary and acquired factors eases its occurrence. Women with HAE should be screened for the factor V Leiden mutation before pregnancy or the start of a hormone replacement therapy.     

A heparin binding site Arg79Cys missense mutation in the SERPINC1 gene in a Korean patient with hereditary antithrombin deficiency

We describe a case of heparin binding site Arg79Cys mutation in the gene encoding antithrombin, SERPINC1, in a Korean patient with hereditary antithrombin (AT) deficiency. The patient was a 34-year-old Korean man who presented with deep vein thrombosis (DVT) in his right leg without precipitating factors. On outpatient evaluation, coagulation tests without anticoagulation revealed a decreased AT III activity level at 48%, but normal AT III antigen level at 103%, indicating type II AT deficiency. Family studies revealed that his father (62 years of age) had decreased AT activity (48%) but had normal AT antigen levels (116%), indicating that the proband had a paternally inherited type II AT deficiency. Direct sequencing of the SERPINC1 gene in the patient and his father revealed a heterozygotic missense mutation, a cytosine to thymine substitution at nucleotide position 235 in exon 2 of the SERPINC1 gene (p.Arg79Cys). To our knowledge, this is the first report of Arg79Cys heterozygote mutation in family members with venous thromboembolism.     

Human pasteurized C1-inhibitor concentrate for the treatment of hereditary angioedema due to C1-inhibitor deficiency

Hereditary angioedema is a relatively rare genetic disorder affecting between one in 10,000 and one in 50,000 individuals worldwide. The most common clinical symptoms observed are relapsing swelling of the skin and abdominal pain attacks. However, more serious and potentially fatal laryngeal attacks can also occur. Hereditary angioedema is most frequently caused by a deficiency of C1-inhibitor. Replacement therapy with Berinert, an intravenous pasteurized C1-inhibitor concentrate derived from human plasma, is a recommended treatment for rapid resolution of acute attacks of hereditary angioedema due to C1-inhibitor deficiency. Prophylactic therapy with C1-inhibitor is also available. Future advances may improve morbidity and mortality associated with hereditary angioedema.     

Self-administration of C1-inhibitor concentrate in patients with hereditary or acquired angioedema caused by C1-inhibitor deficiency

BACKGROUND: Administration of C1-inhibitor concentrate is effective for prophylaxis and treatment of severe angioedema attacks caused by C1-inhibitor deficiency. The concentrate should be administered intravenously and hence needs to be administered by health care professionals, which might cause considerable delay in treatment and inconvenience for patients. OBJECTIVE: The aim of this study was to investigate the feasibility, efficacy, and safety of on-demand and prophylactic self-administration of C1-inhibitor concentrate in patients with frequent attacks of angioedema. METHODS: Patients with hereditary or acquired C1-inhibitor deficiency who had very frequent angioedema attacks were trained to self-administer C1-inhibitor concentrate. The study consisted of 31 patients using on-demand treatment and 12 patients using prophylaxis with C1-inhibitor concentrate. Mean follow-up was 3.5 years. RESULTS: All patients were capable of self-administering the concentrate, with technical failure rates of self-injection being less than 2%. Times between the onset of the attack and the initiation of relief or complete resolution of symptoms in the on-demand group were significantly shortened (2.2 hours and 7.9 hours, respectively) compared with the situation before the start of self-administration. In the prophylaxis group self-administration of C1-inhibitor concentrate decreased the angioedema attack rate from 4.0 to 0.3 attacks per month. CONCLUSION: Intravenous self-administration of C1-inhibitor concentrate is a feasible and safe option and results in more rapid and more effective treatment or prevention of severe angioedema attacks in patients with C1-inhibitor deficiency. CLINICAL IMPLICATIONS: Self-administration of C1-inhibitor concentrate could be a valuable and convenient treatment modality to prevent or treat angioedema attacks in patients with C1-inhibitor deficiency.     

A Novel Splice Site Mutation in the SERPING1 Gene Leads to Haploinsufficiency by Complete Degradation of the Mutant Allele mRNA in a Case of Familial Hereditary Angioedema

Hereditary angioedema due to C1-inhibitor deficiency (HAE-C1INH) is a rare autosomal-dominant and life-threatening disorder caused by mutations in SERPING1 gene. It is characterized by attacks of angioedema involving the skin and/or the mucosa of the upper airways, as well as the intestinal mucosa. Here we report the case of a patient with HAE-C1INH without family history of angioedema. By sequencing the SERPING1 gene we detected a novel mutation (c.1249?+?5G?>?A) affecting the 5’ donor splice site in intron 7. We analyzed the SERPING1 cDNA expecting a defect in splicing process but only the wild type allele was detected. SNP analysis of the cDNA sequence demonstrated that only one of the two alleles was present, indicating that the mRNA from the mutated allele was completely degraded. This study reinforces the concept of incomplete penetrance of this disorder since the patients’ mother never presented any sign of angioedema despite carrying the same mutation.     

The role of the complement system in hereditary angioedema

Hereditary angioedema (HAE) is a rare, but potentially life-threatening disorder, characterized by acute, recurring, and self-limiting edematous episodes of the face, extremities, trunk, genitals, upper airways, or the gastrointestinal tract. HAE may be caused by the deficiency of C1-inhibitor (C1-INH-HAE) but another type of the disease, hereditary angioedema with normal C1-INH function (nC1-INH-HAE) was also described. The patient population is quite heterogeneous as regards the location, frequency, and severity of edematous attacks, presenting large intra- and inter-individual variation. Here, we review the role of the complement system in the pathomechanism of HAE and also present an overview on the complement parameters having an importance in the diagnosis or in predicting the severity of HAE.     

Enzymatic pathways in the pathogenesis of hereditary angioedema: the role of C1 inhibitor therapy

A functional abnormality of C1 inhibitor (C1INH) is present in types I and II hereditary angioedema (HAE), and normal C1INH may be rendered ineffective in the newly described type III HAE. C1INH inhibits factor XIIa, factor XII fragment (XIIf), kallikrein, and plasmin. Thus, in its absence, there is marked activation of the bradykinin-forming cascade resulting in severe angioedema. Factor XII may autoactivate on binding to endothelial cell surface gC1qR (receptor for the globular heads of C1q) thus initiating the cascade. Alternatively, stimuli that activate endothelial cells may liberate (or express at the cell surface) heat shock protein 90 or the enzyme prolylcarboxypeptidase, either of which can interact with the prekallikrein-high-molecular-weight kininogen complex to convert prekallikrein to kallikrein stoichiometrically. The kallikrein produced can cleave high-molecular-weight kininogen to produce bradykinin and also recruit factor XII by enzymatically activating it. Patients with type I or II HAE have mutant C1INH so that control of C1 activation is lost. Autoactivation of C1r in the absence of C1INH leads to C1s activation followed by C4 cleavage and depletion. An attack of swelling is accompanied by conversion of factor XIIa to factor XIIf and further enzymatic activation of C1r so that C4 levels drop further and C2 is depleted. New therapies for HAE focus on the bradykinin-forming cascade and include a kallikrein inhibitor and a bradykinin B-2 receptor antagonist in addition to administration of purified C1INH.     

Studies of the mechanisms of bradykinin generation in hereditary angioedema plasma

BACKGROUND: Factor XII-dependent bradykinin formation is thought to be responsible for the swelling associated with the various forms of C1 inhibitor deficiency, and complement activation is augmented during attacks of swelling. OBJECTIVES: To further elucidate the interactions of the kinin-forming cascade that lead to complement activation during attacks of swelling and to determine whether fibrinolysis is augmented as well. METHODS: We compared spontaneous and kaolin-induced activation of normal plasma with the plasma of patients with hereditary angioedema. RESULTS: Hereditary angioedema plasma demonstrated augmented factor XII activation, production of factor XIIf, prekallikrein activation, and high-molecular-weight kininogen cleavage, and, as a result, bradykinin formation was markedly increased. Baseline levels of C4a and plasmin-alpha 2 antiplasmin complexes increased, and, on activation with kaolin, levels increased further. CONCLUSIONS: All parameters indicative of activation of the bradykinin-forming cascade are activated in hereditary angioedema plasma vs normal plasma. Production of factor XIIf, demonstrated for the first time in whole plasma, may be responsible for C1 activation based on C4a production. The factor XII-dependent fibrinolytic cascade is also activated.     

双重杂合性突变Arg304Gln和Arg304Trp导致的遗传性凝血因子Ⅶ缺陷症

目的 探讨1例遗传性凝血因子Ⅶ(coagulation factorⅦ，FⅦ)缺陷症及其家系基因突变的类型。方法 检测凝血指标以明确诊断；用DNA直接测序法对先证者及其家庭成员FⅦ基因的全部外显子和其侧翼以及启动子进行分析，寻找基因突变；将含突变序列克隆人pGEM T—easy质粒载体中，对所得两条染色体相应序列分别测序，以确定不同突变在染色体上的分布。应用限制性内切酶Msp Ⅰ对先证者及家系成员相应基因片段进行酶切分析，证实测序所发现的突变。结果 先证者在第8外显子上有两种基因突变：11348位C→T突变和11349位G→A突变。pGEM T—easy质粒克隆测序结果显示上述两种突变位于不同的染色体上。为不同染色体同一编码区Arg(CGG)304Trp(TGG)和Arg(CGG)304Gln(CAG)双重杂合性突变。其父亲、母亲分别为11349位G→A和11348位C→T杂合突变；其弟弟FⅦ基因为正常野生型；其哥哥和先证者的3个子女均为杂合性突变。聚合酶链反应辅助限制性酶切证实了先证者及其家系成员的基因突变。结论 先证者FⅦ基因突变为不同染色体同一编码区Arg304Trp和Arg304Gln双重杂合性突变，此种突变类型的组合尚属首例。     

Hereditary angioedema in a Jordanian family with a novel missense mutation in the C1-inhibitor N-terminal domain

Hereditary angioedema due to C1-inhibitor deficiency (C1-INH-HAE) is an autosomal dominant disease caused by mutations in the SERPING1 gene. A Jordanian family, including 14 individuals with C1-INH-HAE clinical symptoms, was studied. In the propositus and his parents, SERPING1 had four mutations leading to amino acid substitutions. Two are known polymorphic variants (c.167T>C; p.Val34Ala and c.1438G>A; p.Val458Met), the others are newly described. One (c.203C>T; p.Thr46Ile) is located in the N-terminal domain of the C1-inhibitor protein and segregates with angioedema symptoms in the family. The other (c.800C>T; p.Ala245Val) belongs to the serpin domain, and derives from the unaffected father. DNA from additional 24 family members were screened for c.203C>T mutation in the target gene. All individuals heterozygous for the c.203C>T mutation had antigenic and functional plasma levels of C1-inhibitor below 50% of normal, confirming the diagnosis of type I C1-INH-HAE. Angioedema symptoms were present in 14 of 16 subjects carrier for the c.203T allele. Among these subjects, those carrying the c.800T variation had more severe and frequent symptoms than subjects without this mutation. This family-based study provides the first evidence that multiple amino acid substitutions in SERPING1 could influence C1-INH-HAE phenotype.     

rhC1INH: a new drug for the treatment of attacks in hereditary angioedema caused by C1-inhibitor deficiency

Recombinant human C1 esterase inhibitor (rhC1INH) (Ruconest(?), Pharming) is a new drug developed for the relief of symptoms occurring in patients with angioedema due to C1-inhibitor deficiency. Pertinent results have already been published elsewhere; this article summarizes the progress made since then. Similar to the purified C1-inhibitor derived from human plasma, the therapeutic efficacy of rhC1INH results from its ability to block the actions of enzymes belonging to the overactivated bradykinin-forming pathway, at multiple locations. During clinical trials into the management of acute edema, a total of 190 subjects received recombinant C1-inhibitor by intravenous infusion on 714 occasions altogether. Dose-ranging efficacy studies established 50 U/kg as the recommended dose, and demonstrated the effectiveness of this agent in all localizations of hereditary angioedema attacks. Studies into the safety of rhC1INH based on 300 administrations to healthy subjects or hereditary angioedema patients followed-up for 90 days have not detected the formation of autoantibodies against rhC1INH or IgE antibodies directed against rabbit proteins, even after repeated administration on multiple occasions. These findings met favorable appraisal by the EMA, which granted European marketing authorization for rhC1INH. Pharming is expected to file a biological licence with the US FDA by the end of 2010 to obtain marketing approval in the USA. The launch of rhC1INH onto the pharmaceutical market may represent an important progress in the management of hereditary angioedema patients.