Complement component C7 deficiency in two Spanish families

Different genetic mutations have been described in complement component C7 deficiency, a molecular defect clinically associated with an increased susceptibility to neisserial recurrent infections. In this work we report the genetic basis of C7 deficiency in two different Spanish families (family 1 and family 2). In family 1, of Gypsy ethnical background, exon-specific polymerase chain reaction and sequencing revealed a not previously described single base deletion of nucleotide 1309 (exon 10) in the patient, as well as in her father, leading to a stop codon that causes the premature truncation of the C7 protein (K416 X 419). Additionally, the patient and her mother displayed a missense mutation at position 1135 (exon 9) located in the first nucleotide of the codon GGG (CGG), resulting in a change of amino acid (G357R). This mutation was firstly described in individuals of Moroccan Sephardic Jewish ancestry and has been also reported among Spaniards. In family 2, another novel mutation was found in homozygosity in two siblings; a two base-pair deletion of nucleotides 1922 and 1923 in exon 14 leading to the generation of a downstream stop codon causing the truncation of the C7 protein product (S620 X 630). Our results provide more evidence for the heterogeneous molecular basis of C7 deficiency as well as for the subsequent susceptibility to meningococcal disease, since different families carry different molecular defects. On the other hand, certain C7 defects appear to be prevalent in individuals from certain populations or living in defined geographical areas.     

Complement component C7 deficiency in a Spanish family

Different genetic mutations have been described in complement component C7 deficiency, a molecular defect which is clinically associated with an increased susceptibility to neisserial recurrent infections, although some cases remain asymptomatic. In this work we report the genetic bases of C7 deficiency in one Spanish family. Exon-specific PCR and sequencing revealed a novel point mutation at nucleotide 615 (exon 6) leading to a stop codon (UGG to UGA) in the patient, his mother, and sister. This transversion causes the premature truncation of the C7 protein (W183X). Additionally, we detected a missense mutation at position 1135 (exon 9) located in the first nucleotide of the codon GGG (CGG), resulting in an amino acid change (G357R) in the patient, his father, as well as in his sister. This latter mutation had been previously described in individuals from Moroccan Sephardic Jewish ancestry. Since both heterozygous mutations were found in the patient as well as in his asymptomatic sister, we analyse other meningococcal defence mechanisms such as polymorphisms of the opsonin receptors on polymorphonuclear cells. Results showed that the patient and his sister bore identical combinations of FcgammaRIIA-H/R131 and FcgammaRIIIB-NA1/2 allotypes. Our results provide further evidence that the molecular pathogenesis of C7 deficiency as well as susceptibility to meningococcal disease are heterogeneous, since different families carry different molecular defects, although many of the C7 defects appear to be homogeneous in individuals from certain geographical areas. The missense mutation G357R would make an interesting topic of analysis with regard to meningococcal disease susceptibility in the Spanish population.     

Protein C deficiency: identification of a novel two-base pair insertion and two point mutations in exon 7 of the protein C gene in Spanish families.

We have applied single-strand conformation polymorphism (SSCP) to the analysis of exon 7 of the anticoagulant protein C (PC) gene, in 13 PC-deficient Spanish families. Abnormal patterns were visualized in three samples from type I or quantitative PC deficient proposita. A previously undescribed mutation due to a TT insertion after nucleotide 6139, between codons Gly-142 and Arg-143 was found in one family. The mutation (6139,ins TT) should result in a frameshift with a stop at codon 156, which agrees with the presence of a type I or quantitative PC deficiency in the affected members of the family. The second mutation identified was a C to T transition at nucleotide 6274, 9 base pairs into intron G. This mutation (6274,C-->T), found for the first time in a Spanish family, is identical to the previously characterized PC Sant Louis. The third mutation was a G to A transition that replaces arginine 178 with glutamine (178,R-->Q). This is the third case of 178,R-->Q mutation in 17 apparently unrelated Spanish families with type I PC deficiency. Furthermore, SSCP analysis allowed the detection of another previously described mutation in a PC-deficient Spanish family (178,R-->W).     

Two novel mutations in the C7 gene in a Korean patient with complement C7 deficiency

Complement C7 deficiency is an autosomal recessive disorder well known to be associated with increased susceptibility to meningococcal infection and has mostly been reported in Caucasians. In the Korean population, no case of C7 deficiency has been reported to date. Recently we experienced an 11-yr-old girl with meningococcal meningitis who was diagnosed as having C7 deficiency based upon the undetectable serum C7 protein on radial immunodiffusion and the undetectable serum total and C7 hemolytic activities. To identify the genetic basis of the C7 deficiency of the patient, we performed a mutation analysis for the C7 gene and found two novel mutations; a point mutation at the 3'' splice acceptor site of intron 4 (c.281-1G>T) and a large deletion mutation encompassing almost the whole C7 gene from exon 1 to exon 17 (c.1-?_2350+?del). A haplotype analysis showed that the large deletion mutation was inherited from the patient''s father. To the best of our knowledge, this is the first confirmed case of C7 deficiency in Korea.     

A novel nonsense mutation at Glu-631 in a Spanish family with complement component 7 deficiency

Deficiency of the seventh component of complement (C7D) is frequently associated with recurrent neisserial infections. We report in the present study the genetic basis for C7D in a Spanish family. We used exon-specific polymerase chain reaction (PCR)/single-strand conformation polymorphism (SSCP) analysis as a screening step for mutations, followed by direct sequencing of the target exon. The mutation in the proband was a homozygous G-to-T transversion at nucleotide 1957, the first nucleotide of the codon GAG for Glu-631, leading to a stop codon TAG (E631X). Our result provides further evidence that the molecular pathogenesis of C7D is heterogeneous. Received: October 20, 1998 / Accepted: December 25, 1998     

The identification of five novel mutations in the lysosomal acid a-(1-4) glucosidase gene from patients with glycogen storage disease type II. Mutations in brief no. 134. Online

The autosomal recessive disorder Glycogen Storage Type II (GSDII) is caused by a deficiency in the lysosomal enzyme acid alpha-glucosidase. We have optimised a procedure to use fluorescent DNA sequencing technology to screen for mutations within the alpha-glucosidase gene from UK patients with GSDII. Five previously unknown mutations in six patients (4 early onset infantile and 2 late adult) have been found. The mutations are an insertion of a C residue in exon 2 (InsC258), an insertion of a G residue in exon 16 (InsG2242), a deletion of 20 nucleotides in exon 4 delta, and a nonsense mutation in exon 16 (G2237A-Trp746Stop). All will result in the introduction of a premature stop codon in the coding region, predicting a truncated and non-functional protein. The final mutation is a duplication of 18 nucleotides in exon 19 (Ins18nt2776) and will result in the insertion of an additional six amino acids into the protein chain after Asn925 (Gly-Val-Pro-Val-Ser-Asn).     

Molecular epidemiology of C9 deficiency heterozygotes with an Arg95Stop mutation of the C9 gene in Japan

Deficiency of the ninth component of human complement (C9) is the most common complement deficiency in Japan, with an incidence of approximately one homozygote in 1000, but is very rare in other countries. Genetic analyses of Japanese C9 deficiency have shown that a C-to-T transition leading to TGA stop codon for Arg95 in exon 4 of the C9 gene (Arg95Stop) is common in Japanese C9 deficiency. To determine the prevalence of heterozygous carriers of the Arg95Stop mutation in a Japanese population, we collected DNA samples from 300 individuals in two of the four main islands of Japan. Heterozygote detection was performed with an allele-specific polymerase chain reaction (PCR) system designed to detect exclusively only one of the normal and mutant alleles, followed by confirmation with PCR/single-strand conformation polymorphism (SSCP) analysis and direct sequencing. Twenty individuals were heterozygous for the Arg95Stop mutation. None was homozygous. The prevalence of carriers of the Arg95Stop mutation was 6.7% (20/300). An estimated frequency (0.12%) of complete C9 deficiency due to homozygous Arg95Stop mutation was consistent with frequencies determined by serological studies. Received: September 22, 1998 / Accepted: November 7, 1998     

New C1q mutation in a Tunisian family

Hereditary C1q deficiency (C1qD) is the most penetrant genetic factor predisposing to the development of lupus pathology with more than 93% of C1q deficient patients developing this autoimmune pathology throughout their life. It is a rare autosomal recessive deficiency, with only 67 cases reported so far including one Tunisian girl who died at the age of three from complications resulting from severe systemic lupus erythematosus. Although C1qD was confirmed in the serum of this patient using C1q ELISA and classical pathway specific functional assays, no DNA sample had been obtained from this patient. Here we report the analysis of sera and DNA of members of this patient's closer family. Our analysis identified a homozygous mutation within the gene encoding the C-chain of C1q leading to a deficiency of C1q in an older sister of our original patient. This mutation, termed g.5580G4C, represents a single basepair substitution in exon 1 of the C1q C chain gene which changes the codon of Gly61 to Arg 61. Amongst the other 14 mutations leading to C1qD, g.5580G4C represents the first reported transversion leading to human C1qD.     

The identification of five novel mutations in the lysosomal acid a-(1,4) glucosidase gene from patients with glycogen storage disease type II

The autosomal recessive disorder Glycogen Storage Disease Type II (GSDII) is caused by a deficiency in the lysosomal enzyme acid α-glucosidase. We have optimised a procedure to use fluorescent DNA sequencing technology to screen for mutations within the α-glucosidase gene from UK patients with GSDII. Five previously unknown mutations in six patients (4 early onset infantile and 2 late onset adult) have been found. The mutations are an insertion of a C residue in exon 2 (InsC258), an insertion of a G residue in exon 16 (InsG2242), a deletion of 20 nucleotides in exon 4 Δ, and a nonsense mutation in exon 16 (G2237A - Trp746Stop). All will result in the introduction of a premature stop codon in the coding region, predicting a truncated and non-functional protein. The final mutation is a duplication of 18 nucleotides in exon 19 (Ins18nt2776) and will result in the insertion of an additional six amino acids into the protein chain after Asn925 (Gly-Val-Pro-Val-Ser-Asn). Hum Mutat 11:413, 1998. © 1998 Wiley-Liss, Inc.     

Mutations in purine nucleoside phosphorylase deficiency

Purine nucleoside phosphorylase deficiency is an inherited disease of purine metabolism characterized clinically as combined immunodeficiency. The molecular defects have been published for 4 different alleles in 3 patients. We report four new mutations including two amino acid substitutions, A 174P and G190V, a single codon deletion, ΔI129, and a point mutation in intron 3 which leads to aberrant splicing and creation of a premature stop codon in exon 4 (286 -18G→A). Of the previously reported mutations, E89K was found in one additional patient, and R234P was found in 3 unrelated patients, making R234P the most common mutation reported to date in this disease. Hum Mutat 9:118–121, 1997. © 1997 Wiley-Liss, Inc.     

Novel mutations of APOB cause ApoB truncations undetectable in plasma and familial hypobetalipoproteinemia

Familial hypobetalipoproteinemia (FHBL) is a genetic disorder characterized by low levels of apoB-100 and LDL cholesterol. Truncation-producing mutations of apoB (chromosome 2) are among several potential causes of FHBL in patients. Ten new families with FHBL linked to chromosome 2 were identified. In Family 8, a 4432delT in exon 26 produces a frame-shift and a premature stop codon predicted to produce a truncated apoB-30.9. Even though this truncation is just 10 amino acid shorter than the well-documented apoB-31, which is readily detectable in plasma, apoB-30.9 is undetectable. Most truncations shorter than apoB-30 are not detectable in plasma. In Family 34, an acceptor splicing mutation at position -1 of exon 14 changes the acceptor splice site AG to AA. Two families (Family 50 and 52) had mutations (apoB-9 and apoB-29) reported previously. In Family 98, a novel point mutation in exon 26 (11163T>G) causes a premature stop codon, and produces a truncated apoB-80.5 readily detectable in plasma. Sequencing of the ApoB gene in families 1, 5, 18, 58, and 59 did not reveal mutations.     

C5 complement deficiency in a Spanish family. Molecular characterization of the double mutation responsible for the defect

The complement C5 deficiency is a recessive autosomal defect associated with recurrent infectious episodes, generally caused by Gram-negative micro-organisms. To date, only two mutations responsible for C5 deficiency have been characterized, both in heterozygosis. In this paper, we evaluate by immunochemical methods the C5 deficiency in a six-member family, in which one member suffered from meningococcal sepsis and several pneumonia episodes; and a second one with two bacterial meningitis episodes and frequent tonsillitis, pneumonia and herpetic episodes. We also characterize the molecular basis of this deficiency. No C5 protein was found in the serum from three of the children. They were found to be homozygous for a double mutation in the exon 40 of the C5 gene. The parents and the other children have half-normal levels of C5, and they were heterozygotes for the double mutation. This mutation modifies the reading frame, leading to a premature stop codon, and the resulting protein lacks 50 amino acids. As a result, homozygotes and heterozygotes have a total or a partial C5 deficiency respectively. This is the first report of a whole molecular characterization of C5 deficiency.     

A Novel Mutation in a Patient with a Deficiency of the Eighth Component of Complement Associated with Recurrent Meningococcal Meningitis

Introduction  Complement component C8 is one of the five terminal complement components required for the formation of the membrane attack complex. Complete absence of C8 results in increased susceptibility to gram-negative bacteria such as Neisseria species. Materials and Methods  Two functionally distinct C8 deficiency states have been described: C8 α–γ deficiency has been predominantly reported amongst Afro-Caribbeans, Hispanics, and Japanese and C8β mainly in Caucasians. Results  We report a case of functional and immunochemical deficiency of the complement component C8, diagnosed in a Caucasian adult following three episodes of meningitis. Western blotting and hemolytic assay demonstrated absence of C8β. In genetic studies, the common exon 9 C > T transition responsible for 85% of C8β deficiencies was not found. Two mutations were identified: a novel duplication mutation, c.1047_1053 dupGGCTGTG in exon 7 that introduces a frame shift, resulting in the addition of seven novel amino acid residues and a premature stop codon, and a previously reported mutation, c.271C > T in exon 3. The parents each expressed one of these mutations, confirming compound heterozygosity. Discussion  This is the first report of a duplication mutation in C8β deficiency and extends the molecular heterogeneity of the disorder.     

Mutations in the protoporphyrinogen oxidase gene in patients with variegate porphyria

Variegate porphyria (VP) is an acute hepatic porphyria with autosomal dominant inheritance due to a partial deficiency of protoporphyrinogen oxidase (PPOX) activity. The molecular defect responsible for VP was investigated by sequencing PPOX gene coding sequence from four patients in three unrelated VP families of French Caucasian origin. In a first patient, a point insertion of a G at position 1022 of the cDNA, produced a frameshift resulting in a premature stop codon. In three other patients from two unrelated families we found a missense point mutation leading to glycine to arginine substitution (G232R) in exon 7. This Gly232 appears to be a strictly conserved residue through evolution. In one VP family, we observed the cosegregation of the G232R missense mutation and the deficient PPOX activity. The mutations reported here are the first to be described in patients with VP and support the conclusion that PPOX gene defects are disease causing mutations in human variegate porphyria.      

Heterozygous C8β complement deficiency does not predispose to meningococcal disease

We have identified 42 Russian patients with homozygous C8β complement component deficiency, all of whom had experienced at least one episode of systemic meningococcal disease. About 90% of these individuals have a C → T exchange in exon 9, leading to a premature stop codon. If, like the homozygous-deficient state, heterozygous C8β deficiency constitutes a risk factor for meningococcal disease, it would be expected to be detected with increased frequency among individuals suffering from this disease. Using allele-specific polymerase chain reaction (PCR)we studied 153 consecutive patients with meningococcal disease admitted to the Moscow Hospital for Infectious Diseases to determine the frequency of C8 null allele. No individuals with heterozygous C → T exchange were identified among these 153 patients, despite the fact that seven persons were detected who had homozygous C8β deficiency, caused by the same C → T exchange in exon 9, and one patient who had C7 component deficiency. Thus, heterozygous deficiency, although more frequent than homozygous deficiency in the general population, does not result in a substantial increase in susceptibility to meningococcal disease.     

Two novel mutations in a purine nucleoside phosphorylase (PNP)-deficient patient

Purine nucleoside phosphorylase (PNP) deficiency is a rare autosomal recessive disease, which presents clinically as severe combined immunodeficiency (SCID). We report here two novel mutations in the PNP gene that result in SCID phenotype, in a single patient. The maternal-derived allele carries a C to T transition in exon 2 resulting in a premature stop codon at amino acid 57. The paternal-derived mutation is a G to A transition at position +1 in intron 3, causing a complete skipping of exon 3 and a reading frameshift at the exon 2-exon 4 junction. The predicted polypeptide encoded by the aberrantly spliced mRNA terminates prematurely after only 89 amino acids. Both mutations predict severely truncated proteins resulting in a complete deficiency of PNP enzymatic activity, yet the development of profound immunodeficiency in this patient is greatly delayed.     

Two Mutations of the C7 Gene, c.1424G > A and c.281-1G > T, in Two Korean Families

Complement C7 deficiency is associated with increased susceptibility to meningococcal infection. The genetic alterations of C7 deficiency are known to be sporadic and heterogeneous worldwide. We investigated molecular basis of C7 deficiency in two unrelated Korean families, in which the index cases suffered from meningococcal meningitis. Exon-specific PCR and direct sequencing of the C7 gene revealed two different mutations: c.1424G > A and c.281-1G > T. In family 1, index case and her brother revealed a homozygous mis-sense mutation (c.1424G > A), a novel mutation, which results in the change of cysteine to tyrosine (C475Y) in exon 10. Index case in family 2 was found to be a homozygote carrying point mutation at the 3′ splice acceptor site of intron 3 (c.281-1G > T), which was previously reported in a Korean C7-deficient subject.     

Primary hyperoxaluria type 1: a cluster of new mutations in exon 7 of the AGXT gene.

Primary hyperoxaluria type 1 (PH1) is a severe autosomal recessive inborn error of glyoxylate metabolism caused by deficiency of the hepatic peroxisomal enzyme alanine:glyoxylate aminotransferase. This enzyme is encoded by the AGXT gene on chromosome 2q37.3. DNA samples from 79 PH1 patients were studied using single strand conformation polymorphism analysis to detect sequence variants, which were then characterised by direct sequencing and confirmed by restriction enzyme digestion. Four novel mutations were identified in exon 7 of AGXT: a point mutation T853C, which leads to a predicted Ile244Thr amino acid substitution, occurred in nine patients. Two other mutations in adjacent nucleotides, C819T and G820A, mutated the same codon at residue 233 from arginine to cysteine and histidine, respectively. The fourth mutation, G860A, introduced a stop codon at amino acid residue 246. Enzyme studies in these patients showed that AGT catalytic activity was either very low or absent and that little or no immunoreactive protein was present. Together with a new polymorphism in exon 11 (C1342A) these findings underline the genetic heterogeneity of the AGXT gene. The novel mutation T853C is the second most common mutation found to date with an allelic frequency of 9% and will therefore be of clinical importance for the diagnosis of PH1.