A0002154 a2154 No.ofPages:6 SEETHARAMAK Complement:Deficiency Secondary article Diseases Artice Contents erry AWinkelstein,TheJohns Hopkins University Schoolof Medicine,Baltimore,Maryland,USA KathleeSullivan,nivPehidnd USA Genetically determined deficiencies of the complement system result in an increased susceptibility to infection,rheumatic disorders,or angio-oedema. Introduction Noisseria s pecies since serum bactericidal activity is an important host defence against these organisms. til 1960 that the first patient with a genetically determined complment Rheumatic diseases Patients with complement deficiencies may also de ses complement system glomerulonephritis,dermatomyositis.anaphylactoid pur pura and vasculitis.The prevalence of these inflammatory and Pathophysiology C2)n Cdeficiency diseases and just over0%of patients with Individuals with genetically determined complemen C2 deficiency have had a rheumatic disorder.In contrast deficiencies have a variety of clinical presentations.Most fewer than 10%of patients with deficiencies of termina aiedpibtione nd in complement deficiency diseases has to do with the role of even be asymptomatic.The clucidation of the pathophy siological basis for the different clinical presentations of mune comple A number ha ent in lividuals has contributed to ephysiologicalroteotCompke orocess immune complexes in vitro correlates with their Increased susceptibility to infection risk for devel srder.For example. 、f1 of immune complexes as they are forming.has a reduced ies.The mple ability to resolubilize complexes once they have formed, binding of preform ned immune example,the major cleavage product(C3b)of the third nts with component of complement (C3)is an important opsonic ligand components (C5-C9)are normal with respect to these activities. caused hy bacteria for which opsonization is the primary host defence Angio-oedema are Thus.paticn with nt with angi oedema of the skin or muco deficiencies of C5,C6.C7,C8 or C9 are susceptible to membranes(see below).The pathophysiological basis for ENCYCLOPEDIA OF LIFE SCIENCES/ ublishing Group/www.els.net
Complement: Deficiency Diseases Jerry A Winkelstein, The Johns Hopkins University School of Medicine, Baltimore, Maryland, USA Kathleen E Sullivan, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania, USA Genetically determined deficiencies of the complement system result in an increased susceptibility to infection, rheumatic disorders, or angio-oedema. Introduction Although the complement system was first described at the turn of the twentieth century, it was not until 1960 that the first patient with a genetically determined complement deficiency was identified. Since then, deficiencies have been described for nearly all of the components of the complement system. Pathophysiology Individuals with genetically determined complement deficiencies have a variety of clinical presentations. Most patients present with an increased susceptibility to infection, others with a variety of rheumatic diseases, still others with angio-oedema, and in rare instances, patients may even be asymptomatic. The elucidation of the pathophysiological basis for the different clinical presentations of complement-deficient individuals has contributed to a better understanding of the physiological role of complement in normal individuals. Increased susceptibility to infection An increased susceptibility to infection is a common clinical finding in most patients with complement deficiencies. The kinds of infections relate to the biological functions of those components that are missing. For example, the major cleavage product (C3b) of the third component of complement (C3) is an important opsonic ligand. Therefore, patients with a deficiency of C3, or of a component of either of the two pathways that activate C3, are susceptible to infections caused by encapsulated bacteria for which opsonization is the primary host defence (e.g. Streptococcus pneumoniae, Streptococcus pyogenes and Haemophilus influenzae). Similarly, C5–C9 form the membrane attack complex and are responsible for the bactericidal functions of complement. Thus, patients with deficiencies of C5, C6, C7, C8 or C9 are susceptible to Neisseria species since serum bactericidal activity is an important host defence against these organisms. Rheumatic diseases Patients with complement deficiencies may also develop a variety of rheumatic diseases. These include a disorder that resembles systemic lupus erythematosus (SLE) as well as glomerulonephritis, dermatomyositis, anaphylactoid purpura and vasculitis. The prevalence of these inflammatory disorders is highest in those patients with deficiencies of the classical activating pathway (C1, C4 and C2) and of C3. For example, approximately 80% of patients with C4 or C3 deficiency diseases and just over 30% of patients with C2 deficiency have had a rheumatic disorder. In contrast, fewer than 10% of patients with deficiencies of terminal complement components have rheumatic disorders. The most attractive hypothesis linking rheumatic diseases and complement deficiency diseases has to do with the role of the complement system in the clearance and processing of immune complexes. A number of studies have shown that the sera of patients with complement deficiencies have altered and/or reduced abilities to process immune complexes and that the inability of the patients’ sera to process immune complexes in vitro correlates with their risk for developing a rheumatic disorder. For example, serum from patients with genetically determined deficiencies of Clq, C4, C2 and C3 fails to prevent the precipitation of immune complexes as they are forming, has a reduced ability to resolubilize complexes once they have formed, and does not support the binding of preformed immune complexes to C3b receptors on human erythrocytes. In contrast, the serum of patients with deficiencies of terminal components (C5–C9) are normal with respect to these activities. Angio-oedema Patients with a deficiency of one of the control proteins of the classical pathway, C1 esterase inhibitor (C1 INH), usually present with angio-oedema of the skin or mucous membranes (see below). The pathophysiological basis for a2154 No. of Pages: 6 SEETHARAMAK Article Contents Secondary article . Introduction . Pathophysiology . Specific Disorders A0002154 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net 1
A0002154 a2154 No.ofPages:6 SEETHARAMAK Complement:Deficiency Disease of normal)and amo erate reduction of Cls(20 50 app oe。Cls with the abse of Clr i system and the kinin system. patients is unknown.although it may relate to their close Asymptomatic ent 500/ Some patients with Most CIr/Cls-deficient patients ha nted with SLE,although isolated glomerulonephritis has also been developed a serious infection or a rheumatic disorder scribed.In addition,some patients have been ascer- ned as a iefeauene.oi ing fam lves have b y mem because of clinical problems. C4 deficiency There Specific Disorders are two loci (C4A and C4B)within the ajor x that encode for C4.Alth Most of the geneticay the products of the two loci share some functional, etermined deficiencies of the characteristics that identify them eptions:deficiency of ropnoret CI inhibitor has an autosomal dominant mode of identification.Patients with total C4 deficiency are omozygous defcient at both loc and have severel Clq deficiency serm levels of both and ncona C3 and C5-C9 and can mediated via activa The first componer nt of complement is composed of three alternative pathway,such as opsc onic.chemotactic and w ither function he of ar degree or as quickly as in norma In the other form,immunochemical Clq is present,but it The predomn nifestation of lacks function IS deficiency has been an sle-like illness.characterized by unctiona ulin G ive skin rashes,renal disease and occasionally tes Clr and C The most common clinical presentation ofeither form of SLE-like illness is also present Clq deficiency has beenalupus-likesy The clinica Although complete C4 deficiency is rare.individuals mar in patients with Cl deficiency are omozygous nt for either A or C4B are sufficient individuals although theas of on at is s popu what earlier and the disease can be very severe with is deficient in C4B.As mentioned.C4A and C4B difter somewhat in function;C4A binds more efficiently to Patient nave 4B DI ore efficiently in rbohydrate C4A are mis ng h sotype t due to their inability to generate opsonically active C3b via ot be able to clear protein-co ntaining immune complexes activation of the classical pathway normally and be more susceptible to immune complex SLE.In the prevale of h mo CIr/Cls deficiency ygous 10 The genes encoding Clr and Cls map to the short arm of opulation.Individuals who are deficient in C4B lack the chromosome 12,are separated by only 9.5kb and are isotype that is more efficient in interacting with poly re might not be able to ass I pathway ENCYCLOPEDIA OF LIFE SCIENCES/e 2001 Nature Publishing Group /www.els.net
the development of angio-oedema in C1 INH deficiency is not fully understood, but appears to relate to the inability of C1 INH to inhibit the activation of both the complement system and the kinin system. Asymptomatic Some patients with genetically determined complement deficiencies are relatively asymptomatic, never having developed a serious infection or a rheumatic disorder. These asymptomatic patients are usually ascertained as a consequence of screening family members of complementdeficient patients who themselves have been ascertained because of clinical problems. Specific Disorders Most of the genetically determined deficiencies of the complement system are inherited as autosomal recessive traits. There are only two known exceptions: deficiency of C1 inhibitor has an autosomal dominant mode of inheritance, while properdin deficiency is inherited as an X-linked recessive disorder. Clq deficiency The first component of complement is composed of three distinct subunits, Clq, Clr and Cls. There appear to be two distinct forms of Clq deficiency. In one form, Clq cannot be detected by either functional or immunochemical analysis. In the other form, immunochemical Clq is present, but it lacks functional activity, i.e. it is dysfunctional. The dysfunctional C1q is antigenically deficient, and it does not interact with either immunoglobulin G (IgG) or its substrates, Clr and Cls. The most common clinical presentation of either form of Clq deficiency has been a lupus-like syndrome. The clinical manifestations of SLE in patients with Clq deficiency are not markedly different from those seen in complementsufficient individuals, although the age of onset is somewhat earlier and the disease can be very severe with significant central nervous system (CNS) and renal disease. Patients with Clq deficiency also have an increased susceptibility to bloodborne infections with pyogenic organisms, such as sepsis and/or meningitis, presumably due to their inability to generate opsonically active C3b via activation of the classical pathway. Clr/Cls deficiency The genes encoding Clr and Cls map to the short arm of chromosome 12, are separated by only 9.5 kb and are highly homologous. Genetically determined deficiency of Clr is characterized by a marked reduction of Clr (less than 1% of normal) and a moderate reduction of Cls (20–50% of normal). The basis for the association of the moderately reduced levels of Cls with the absence of Clr in these patients is unknown, although it may relate to their close structural and functional similarity. Interestingly, one patient has been described in which Cls is markedly reduced while Clr levels are 50% of normal. Most Clr/Cls-deficient patients have presented with SLE, although isolated glomerulonephritis has also been described. In addition, some patients have been ascertained as part of family studies and have been clinically well. C4 deficiency There are two loci (C4A and C4B) within the major histocompatibility complex that encode for C4. Although the products of the two loci share some functional, structural and antigenic characteristics that identify them as C4, they differ sufficiently with respect to electrophoretic mobility, molecular weight of the a chain, specific epitopes and functional haemolytic activity to allow their separate identification. Patients with total C4 deficiency are homozygous deficient at both loci and have severely depressed serum levels of both antigenic and functional C4 (less than 1%). Those serum activities that depend on C3 and C5–C9 and can be mediated via activation of the alternative pathway, such as opsonic, chemotactic and bactericidal activities, are present but are not generated to the same degree or as quickly as in normal sera because of a lack of an intact classical pathway. The predominant clinical manifestation of complete C4 deficiency has been an SLE-like illness, characterized by photosensitive skin rashes, renal disease and occasionally arthritis. Although some patients have an increased susceptibility to infection, these are patients in whom the SLE-like illness is also present. Although complete C4 deficiency is rare, individuals who are homozygous deficient for either C4A or C4B are relatively common. Approximately 1% of the population is homozygous deficient in C4A and 3% of the population is deficient in C4B. As mentioned, C4A and C4B differ somewhat in function; C4A binds more efficiently to proteins and C4B binds more efficiently in carbohydrates. Individuals who lack C4A are missing the isotype that interacts most efficiently with proteins, and therefore might not be able to clear protein-containing immune complexes normally and be more susceptible to immune complex diseases such as SLE. In fact, the prevalence of homozygous C4A deficiency in SLE is between 10% and 15%, a prevalence at least 10 times higher than that in the general population. Individuals who are deficient in C4B lack the isotype that is more efficient in interacting with polysaccharides and therefore might not be able to assemble the classical pathway C3-cleaving enzyme on bacterial polya2154 No. of Pages: 6 SEETHARAMAK Complement: Deficiency Diseases A0002154 2 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net
A0002154 32154 No.ofPages:6 SEETHARAMAK Complement:Deficiency Diseases saccharide capsules and be more susceptible to bloodborne C3 deficiency include both an increased susceptibility to bacterial infections.In fact,the prevalence of C4B infection and rheumatic disorders.The infections have deficiency is increased in children with bacteraemia and meningitis included pneumonia,bacteraemia,meningitis and oste ied fogeni C2 deficiency to a moreextensiveclinical picture consistent with systemic upus erythen sus Interestingly.as with some othe om have nts, 10000 in Caucasian populations.The gene for C2 lies of lur within the major histocompatibility complex(MHC)and is ferative glomerulonenhritis has also heen seen in c3 not sumrising that over ofC-deficient individuals C5 deficiency are homozygous for the same mutation.a 28 base pair deletion that results in premature termination of transcrip are unable Complement-medi suc activity.Asexpected,serum opsonic activity is intact since the activation of C3can proceed without the participation rC. nor to the nt identified as C5 deficient hac al pathway s of C2 deficier sequent patients have been ascertained because of either from individuals who have either rheumatic diseases and or an increased susceptibility to infection to individual 2 matic ha ving been ascertained as part of asympto- mily stu de Dt C6 deficiency and aggressive arthritis are less common than in comple- C6 deficiency has been reported in nearly 100 individuals ment-suffciem。 LE patients. lesions are many of whom are of African descent.The most common n in en ash.Patie orm of C6 defici with C2 deficiency and SLE have a lower en prevalence of r it The to their is a marked deficiency of serum bactericidal activity.A ibed C2 subtotal deficiency of C6(C6SD for C6 subtotal rized by s derma tomyositis,anaphylactoid purpura and vasculitis.Ap- otein has a lowe molecular weight and although it can proximately C2-d have incorporated into the membrane attack complex.it ections functions less efficiently encapsulated organisms (e.g.pneumococcus.n he major clinica manifest of complete C6 and meningococcus). While most patients have had meningococcal sepsis and meningitis,others have had disseminated gor ococcal C3 deficiency nfections.Patient with C6SD do not appear to have an increased susceptibility to infection Patients with C3 deficiency generally have less than 1%of C7 deficiency er a rectly dep le i C9 (chemotaxis and bactericidal ac are also markedly reduced.The clinical manifestations of (<1%).Serum bactericidal activity is markedly reduced. ENCYCLOPEDIA OF LIFE SCIENCES/2001Na els net
saccharide capsules and be more susceptible to bloodborne bacterial infections. In fact, the prevalence of C4B deficiency is increased in children with bacteraemia and meningitis. C2 deficiency Genetically determined C2 deficiency is the most common of the inherited complement deficiencies, occurring in 1 in 10 000 in Caucasian populations. The gene for C2 lies within the major histocompatibility complex (MHC) and is associated with a conserved MHC haplotype, HLA-B18, C2*QO, Bf*S, C4A*4, C4B*2 and DR*2. Because of its linkage disequilibrium with the conserved haplotype, it is not surprising that over 95% of C2-deficient individuals are homozygous for the same mutation, a 28 base pair deletion that results in premature termination of transcription. Complement-mediated serum activities, such as opsonization and chemotaxis, are present in patients with C2 deficiency, presumably because their alternative pathway is intact, although they are not generated as quickly nor to the same degree as in individuals with an intact classical pathway. The clinical manifestations of C2 deficiency have varied from individuals who have either rheumatic diseases and/ or an increased susceptibility to infection to individuals who are asymptomatic. Approximately 40% of C2- deficient individuals develop SLE or discoid lupus. Patients with C2 deficiency express many of the characteristic features of lupus, although severe nephritis, cerebritis and aggressive arthritis are less common than in complement-sufficient SLE patients. Cutaneous lesions are common in C2-deficient patients with lupus and many have a characteristic annular photosensitive rash. Patients with C2 deficiency and SLE have a lower prevalence of anti-DNA and antinuclear antigen antibodies than do other SLE patients, but their incidence of anti-Ro antibodies is higher. A variety of other rheumatic disorders have also been described in C2 deficiency, including glomerulonephritis, inflammatory bowel disease, dermatomyositis, anaphylactoid purpura and vasculitis. Approximately 50% of C2-deficient patients have an increased susceptibility to bloodborne infections (e.g. sepsis, meningitis, arthritis and osteomyelitis) caused by encapsulated organisms (e.g. pneumococcus, H. influenzae and meningococcus). C3 deficiency Patients with C3 deficiency generally have less than 1% of the normal amount of C3 in their serum. Those serum activities either directly dependent on C3 (opsonization) or indirectly dependent on C3 because of its role in the activation of C5–C9 (chemotaxis and bactericidal activity) are also markedly reduced. The clinical manifestations of C3 deficiency include both an increased susceptibility to infection and rheumatic disorders. The infections have included pneumonia, bacteraemia, meningitis and osteomyelitis caused by encapsulated pyogenic bacteria. The rheumatic disorders have varied from limited clinical involvement, such as arthralgias and vasculitic skin rashes, to a more extensive clinical picture consistent with systemic lupus erythematosus. Interestingly, as with some other complement-deficient patients, C3-deficient patients may not have serological evidence of lupus. Membranoproliferative glomerulonephritis has also been seen in C3- deficient patients. The renal disease may reflect the role of C3 in immune complex clearance. C5 deficiency The sera of patients with C5 deficiency are unable to generate normal amounts of chemotactic or bactericidal activity. As expected, serum opsonic activity is intact, since the activation of C3 can proceed without the participation of C5. Although the initial patient identified as C5 deficient had SLE and membranoproliferative glomerulonephritis, subsequent patients have been ascertained because of either meningococcal meningitis or disseminated gonococcal infections. A few C5-deficient patients have been asymptomatic, having been ascertained as part of family studies. C6 deficiency C6 deficiency has been reported in nearly 100 individuals, many of whom are of African descent. The most common form of C6 deficiency is characterized by absent or nearly absent levels of C6 (5 1% of normal), whether it is assessed immunochemically or functionally. The only abnormality relating to their serum complement system is a marked deficiency of serum bactericidal activity. A subtotal deficiency of C6 (C6SD for C6 subtotal deficiency) has also been described which is characterized by serum levels of C6 that are 1–2% of normal. This truncated C6 protein has a lower molecular weight and although it can be incorporated into the membrane attack complex, it functions less efficiently. The major clinical manifestation of complete C6 deficiency has been disseminated neisserial infections. While most patients have had meningococcal sepsis and meningitis, others have had disseminated gonococcal infections. Patients with C6SD do not appear to have an increased susceptibility to infection. C7 deficiency Only a few patients with C7 deficiency have been identified. Most individuals have severely reduced levels of C7 (5 1%). Serum bactericidal activity is markedly reduced. a2154 No. of Pages: 6 SEETHARAMAK Complement: Deficiency Diseases A0002154 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net 3
A0002154 a2154 No.ofPages:6 SEETHARAMAK Complement:Deficiency Diseases A second typeofC7 defic roir2 study of C9 deficie meningococcal sepsis and meningtis. ove) Factor I deficiency terminal components,systemic neisserial infections have occurred in most C7 deficiency. Factor I controls the assembly and expression of the reported cases of Individual patien have also pres nted with lupus. renosum.Finally.there have been a few patients with C7 ency factor I.there is no controlimposed on the formation and deficiency who have been clinically well therefore,have C8 deficiency Native C8 is composed of three chains(B and )The C3 is not in its native form.but rather in the form of its covalently joined to form one subunit inactive cleavage product,C3b.Those serum activities that id (C8B) oded covalen cy or ind cy depend o the avilability f )a re rec patients lack the Cy subunit.while in the The most common clinical ext ssion of factor I other form,the C8B subunit is deficier deficiency is an incre ased susceptibility to infection.As more common in whit while with primary 3 ces, Th producing a premature stop codon.suggesting a founder responsible for these infections have been encapsulated effect. pyogenic bacteria,such as the streptococcus,pneumococ- d In fi e of the six nu which organism ate ts have premature s op codon.in either c&ory deficienc or C8B evels of circulating immune complexes.There have as yet there s eer factor I deficienc ma n 1 as has been the case has bee and chort components.Meningococcaemia,meningococcal menin ized by fever.rash.arthralgia.haematuria and proteinuria gitis and disseminated gonococcal infections have pre. dominated.but SLE has also rarely been seen Properdin deficiency C9 deficiency Properdin deficiency is the only complement deficiency that is inherited as an X-linked recessive trait.Properdin Only a few patien alternative pathway enzymes th the mos The seruble lence of 0.036-0.095%.The lysis of bacteria can h alternative pathway.There are a number of forms of mediated by a membrane attack complex composed of properdin deficiency.In one form,affected males have Csb-and is ot,therefore.strictly.As rkedly reduced levels of properdin (<1%of normal) icidera e of killing m,prop en ut in redu the ird c deficieney has peen described in which present The first few individuals with C9 deficiency were in normal concentrations but is dysfunctional that C9 any c an ENCYCLOPEDIA OF LIFE SCIENCES/e 2001 Nature Publishing Group /www.els.net
A second type of C7 deficiency has been described in which the quantity of C7 is diminished but not absent. The C7 that is present exhibits an altered isoelectric point. Interestingly, this form of C7 deficiency, termed subtotal C7 deficiency (C7SD), has been seen primarily in association with C6SD (see above). A number of clinical presentations have been associated with C7 deficiency. As with the other deficiencies of terminal components, systemic neisserial infections have occurred in most reported cases of C7 deficiency. Individual patients have also presented with lupus, rheumatoid arthritis, scleroderma and pyoderma gangrenosum. Finally, there have been a few patients with C7 deficiency who have been clinically well. C8 deficiency Native C8 is composed of three chains (a, b and g). The a and g chains are covalently joined to form one subunit (C8ag), which is joined to the other subunit composed of the b chain (C8b) by noncovalent bonds. Each of the C8 polypeptides is encoded by separate genes. In one form of C8 deficiency, patients lack the C8ag subunit, while in the other form, the C8b subunit is deficient. Deficiency of C8b is more common in white populations while C8ag deficiency is more common in Africans. Eighty-six percent of C8b null alleles are due to a C-T transition in exon 9 producing a premature stop codon, suggesting a founder effect. The molecular basis of C8ag deficiency has been identified in three patients. In five of the six null alleles, an intronic mutation alters the splicing of exons 6 and 7 of C8A and creates a 10-bp insertion that generates a premature stop codon. In either C8ag deficiency or C8b deficiency, C8 activity is markedly reduced and there is a marked reduction in bactericidal activity. The clinical presentation of C8 deficiency has been similar to the other deficiencies in terminal complement components. Meningococcaemia, meningococcal meningitis and disseminated gonococcal infections have predominated, but SLE has also rarely been seen. C9 deficiency Only a few patients with C9 deficiency have been identified in Western populations but it appears to be the most common complement deficiency in Japan with a prevalence of 0.036–0.095%. The lysis of bacteria can be mediated by a membrane attack complex composed of C5b-8 and is not, therefore, strictly dependent on C9. As a result, the sera of patients with C9 deficiency possess some bactericidal activity, although the rate of killing is significantly reduced. The first few individuals with C9 deficiency were asymptomatic, suggesting initially that C9 deficiency was not associated with any clinical problems. However, most subsequent patients with C9 deficiency presented with systemic meningococcal infections. In addition, an epidemiological study of C9 deficiency in Japan provided strong evidence for a relationship between C9 deficiency and meningococcal sepsis and meningitis. Factor I deficiency Factor I controls the assembly and expression of the alternative pathway enzyme that activates C3. Factor I deficiency is characterized by uncontrolled activation of C3 via the alternative pathway because, in the absence of factor I, there is no control imposed on the formation and expression of the alternative pathway that activates C3. Patients with factor I deficiency, therefore, have a secondary consumption of C3 resulting in markedly reduced levels of native C3 in their serum. Most of the C3 is not in its native form, but rather in the form of its inactive cleavage product, C3b. Those serum activities that directly or indirectly depend on the availability of native C3 (opsonic activity, chemotactic activity and bactericidal activity) are reduced in patients with factor I deficiency. The most common clinical expression of factor I deficiency is an increased susceptibility to infection. As with primary C3 deficiency (see above), infections have included both localized infections on mucosal surfaces, as well as systemic infections. The organisms most commonly responsible for these infections have been encapsulated pyogenic bacteria, such as the streptococcus, pneumococcus, meningococcus and H. influenzae organisms, for which C3 is an important opsonic ligand. In addition to problems with infection, some patients have had elevated levels of circulating immune complexes. There have as yet been no reports of patients with factor I deficiency developing chronic renal disease as has been the case with C3 deficiency. However, there has been one report of a transient illness resembling serum sickness and characterized by fever, rash, arthralgia, haematuria and proteinuria. Properdin deficiency Properdin deficiency is the only complement deficiency that is inherited as an X-linked recessive trait. Properdin acts to stabilize the alternative pathway enzymes that activate C3 and C5. The serum of patients with properdin deficiency is therefore unable to activate C3 via the alternative pathway. There are a number of forms of properdin deficiency. In one form, affected males have markedly reduced levels of properdin (51% of normal), while in another form, properdin is present but in reduced amounts (10% of normal). A third form of properdin deficiency has been described in which properdin is present in normal concentrations but is dysfunctional. The most common clinical manifestation of properdin deficiency has been fulminant meningococcaemia and a2154 No. of Pages: 6 SEETHARAMAK Complement: Deficiency Diseases A0002154 4 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net
A0002154 32154 No.ofPages:6 SEETHARAMAK Complement:Deficiency Diseases meningococcal meningitis.emphasizing the importance of The gastrointestinal tract can also be affected by hae the alternative pathway in host defence against meningo In fact,gastrointestinal involvement is especially common cocc in children with HAE.Symptomsar )compared de anorex tiant he ment components.SLE and discoid lupus have also been Abdominal symptoms can occur in the absence of described in isolated patients. concurrent cutaneous or pharyngeal involvement ofsymptoms referable to HAEoccurs in more the ado C1 esterase inhibitor deficiency though trauma,anxiety and stress are frequently cited as events that initiate attacks,more than half of patients annot e ns annd cut may follow inherited in an autosomal dominant fashion.There are at least two forms of CI INH deficiency.In the most commor of HAE is divided into prophylaxis f attacks and treatn Long INH P otein (5-30%of r erm prev ho ha the less common form(type )which accounts for the suffered frequent and debilitating att acks.Antifibrinolytic vated protein is con Pof CI INH re activity leads to the angic oedema characteristic of the have been found to be useful in long-term prophylaxis of disorder are still incompletely understood Neither the HAE. These agents have not been used extensively in the ema nor the androgen ne ider oth the ally int ment system and the kinin system in the pathogenesis ofthe may need short-term prophylactic therapy (e.g.before oral oedema surgery).In these circumstances,dana therapy may be he chinical symptoms of HAE are the result of initiated one week before surgery or EACA the day before h ed by A number of drug have bee sed in an attem t to venule dilation. The three mos interrupt an attack of HAE once it has begun.Adrenaline, hal trac nt. ous thr re encouraging e impeded androgens to prevent such episodes.pharyngeal e in nearly two-thir f the Further Reading ay ini a'tightnes Colten HR and Rosen FS (1992)Complement deficiencies.Annual accompanied by hoarseness and stridor, ated with progresses to respiratory obstruction an represents a threatening nd IA and A P1976 emergency. cks usually progress for days and ma:the yndrome and its nent.Annals of Interna Attacks involving the skin may involve an extremity,the Kolble Kand Reid KBM(1993)Genetic deficiencies ofthe omplement face or genitalia.The oedema may vary in size from a few of I 10g6 nent of a whole extremity.The her thanre Tuanc Lokki MLad Colte 5)Genetic deficiencies of complement e rat and are HR045 tightness in the skin caused by Ros and Densen P()Complement deficiency states an neous fluid.but there is no pain. and other infections in an immune deficiency.:243-273. ENCYCLOPEDIA OF LIFE SCIENCES/e2001 Na
meningococcal meningitis, emphasizing the importance of the alternative pathway in host defence against meningococci. These patients appear to have a particularly high mortality rate (75%) compared to complement-sufficient patients or patients with deficiencies of terminal complement components. SLE and discoid lupus have also been described in isolated patients. C1 esterase inhibitor deficiency A genetically determined deficiency of C1 esterase inhibitor (C1 INH) is responsible for the clinical disorder hereditary angio-oedema (HAE). C1 inhibitor deficiency is inherited in an autosomal dominant fashion. There are at least two forms of C1 INH deficiency. In the most common form (type I), which accounts for about 85% of patients, the serum of affected individuals is deficient in both C1 INH protein (5–30% of normal) and C1 INH activity. In the less common form (type II), which accounts for the remaining 15% of patients, a dysfunctional protein is present in normal or elevated concentrations, but its functional activity is markedly reduced. The pathophysiological mechanisms by which the absence of C1 INH activity leads to the angio-oedema characteristic of the disorder are still incompletely understood. Neither the mediators responsible for producing the oedema nor the mechanisms initiating their production have been clearly identified, although evidence implicates both the complement system and the kinin system in the pathogenesis of the oedema. The clinical symptoms of HAE are the result of submucosal or subcutaneous oedema. The lesions are characterized by noninflammatory oedema associated with capillary and venule dilation. The three most prominent areas of involvement are the respiratory tract, skin and gastrointestinal tract. Attacks involving the upper respiratory tract represent a serious threat to the patient with HAE. Before the use of impeded androgens to prevent such episodes, pharyngeal oedema occurred at least once in nearly two-thirds of the patients. The patients may initially experience a ‘tightness’ in the throat and swelling of the tongue, buccal mucosa and oropharynx follow. In some instances, laryngeal oedema, accompanied by hoarseness and stridor, progresses to respiratory obstruction and represents a life-threatening emergency. Attacks usually progress for 1–2 days and resolve over an additional 2–3 days. Attacks involving the skin may involve an extremity, the face or genitalia. The oedema may vary in size from a few centimetres to involvement of a whole extremity. The lesions are pale rather than red, usually not warm, and are characteristically nonpruritic. There may be a feeling of tightness in the skin caused by accumulation of subcutaneous fluid, but there is no pain. The gastrointestinal tract can also be affected by HAE. In fact, gastrointestinal involvement is especially common in children with HAE. Symptoms are secondary to oedema of the bowel wall and may include anorexia, dull aching of the abdomen, vomiting and crampy abdominal pain. Abdominal symptoms can occur in the absence of concurrent cutaneous or pharyngeal involvement. The onset of symptoms referable to HAE occurs in more than half the patients before adolescence, but in some patients, symptoms do not occur until adulthood. Even though trauma, anxiety and stress are frequently cited as events that initiate attacks, more than half of patients cannot clearly identify an event that initiated an attack. Dental extractions and tonsillectomy can initiate oedema of the upper airway, and cutaneous oedema may follow trauma to an extremity. Therapy of HAE is divided into two categories: prophylaxis of attacks and treatment of attacks. Longterm prevention of attacks may be indicated in those patients who have had laryngeal obstruction or have suffered frequent and debilitating attacks. Antifibrinolytic agents such as e-amnocaproic acid (EACA) have been used with some success in the long-term prevention of attacks. More recently, impeded androgens such as danazol and stanozolol, which have attenuated androgenic potential, have been found to be useful in long-term prophylaxis of HAE. These agents have not been used extensively in children, however, because of their androgenic effects. They act by stimulating the synthesis of functionally intact C1 INH by the normal gene. In some instances, patients may need short-term prophylactic therapy (e.g. before oral surgery). In these circumstances, danazol therapy may be initiated one week before surgery or EACA the day before surgery. A number of drugs have been used in an attempt to interrupt an attack of HAE once it has begun. Adrenaline, antihistamines and corticosteroids are of no proven benefit. However, recent trials with partially purified C1 INH are encouraging. Further Reading Colten HR and Rosen FS (1992) Complement deficiencies. Annual Review of Immunology 10: 809–834. Figueroa JE and Densen P (1991) Infectious diseases associated with complement deficiencies. Clinical Microbiological Reviews 4: 359–395. Frank MM, Gelfand JA and Atkinson JP (1976) Hereditary angioedema: the clinical syndrome and its management. Annals of Internal Medicine 84: 580. Kolble K and Reid KBM(1993) Genetic deficiencies of the complement system associated with disease – early components. International Reviews of Immunology 10: 17–36. Lokki ML and Colten HR (1995) Genetic deficiencies of complement. Annals of Medicine 27: 451–459. Ross SC and Densen P (1984) Complement deficiency states and infections: epidemiology, pathogenesis, and consequences of neisserial and other infections in an immune deficiency. Medicine 63: 243–273. a2154 No. of Pages: 6 SEETHARAMAK Complement: Deficiency Diseases A0002154 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net 5
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Schifferli JA, Ng YC and Peters DK (1986) The role of complement and its receptor in the elimination of immune complexes. New England Journal of Medicine 315: 488–495. Tedesco F, Nurnberge W and Perissulti S (1993) Inherited deficiency of the terminal complement components. International Reviews of Immunology 10: 51–64. Waytes AT, Rosen FS and Frank MM (1996) Treatment of hereditary angioedema with a vapor-heated C1 inhibitor concentrate. New EnglandJournal of Medicine 334: 1630–1634. Winkelstein JA, Sullivan K and Colten H (1995) Genetically determined disorders of the complement system. In: Schriver CR, Beaudet AL, Sly WS and Valle D (eds) The Metabolic Basis for InheritedDisease, 7th edn. New York: McGraw-Hill. a2154 No. of Pages: 6 SEETHARAMAK Complement: Deficiency Diseases A0002154 6 ENCYCLOPEDIA OF LIFE SCIENCES / & 2001 Nature Publishing Group / www.els.net
