The molecular basis of cystathionine beta-synthase (CBS) deficiency in UK and US patients with homocystinuria

The molecular basis of cystathionine beta-synthase (CBS) deficiency has been studied in 536 patient alleles with 130 different mutations described. To date, no study has reported on the incidence of any of the reported mutations in patients from the UK and the US. We developed a new antisense oligonucleotide (ASO) PCR/hybridization method to screen for 12 of the most frequent CBS mutations in 14 unrelated patients from the UK and 38 unrelated patients from the US, a total of 104 independent alleles. We determined 16/28 (57%) and 28/76 (37%) of the affected alleles in the UK and US patients, respectively. Four different mutations were identified in the UK patients (c.374G>A, R125Q; c.430G>A, E144K; c.833T>C, I278T; c.919G>A, G307S) and 8 mutations identified in the patients from the US (c.341C>T, A114V; c.374G>A, R125Q; c.785C>T, T262M; c.797G>A, R266K; c.833T>C, I278T; c.919G>A, G307S; g.13217A>C (del ex 12); c.1330G>A, D444N). The I278T was the predominant mutation in both populations, present in 8 (29%) of 28 independent alleles from the UK and in 14 (18%) of 76 independent alleles from the US. The incidence of the G307S mutation was 21% in the UK patients and 8% in the US patients. The spectrum of mutations observed in the patients from the UK and US is closer to that which is observed in Northern Europe and bears less resemblance to that observed in Ireland.     

The cystathionine beta-synthase (CBS) mutation c.1224-2A>C in Central Europe: Vitamin B6 nonresponsiveness and a common ancestral haplotype

In homocystinuria due to cystathionine β‐synthase (CBS) deficiency, vitamin B₆ response has been linked to distinct mutations and ruled out for others. The splice site mutation c.1224‐2A>C leading to the deletion of exon 12 is predominantly found in patients from Central Europe, where it has been found on in average 14% of mutant alleles. In this study we analyzed the clinical picture in 17 CBS deficient carriers of c.1224‐2A>C. Homozygotes for c.1224‐2A>C did not respond to vitamin B₆, while in compound heterozygotes the response to vitamin B₆ depended on the mutation on the second allele. Maximum likelihood analysis revealed one common haplotype of the c.1224‐2A>C alleles. Additionally, we report the four novel CBS mutations c.451G>A (p.Gly151?), c.740_769del (p.Lys247_Gly256del), c.862G>C (p.Ala288Pro) and c.1135C>T (p.Arg379Trp). In summary, the data of this study suggest that the CBS c.1224‐2A>C allele confers vitamin B6 nonresponsiveness and that this mutant allele came from a common ancestor. © 2004 Wiley‐Liss, Inc.     

Molecular analysis of ARSA and PSAP genes in twenty-one Italian patients with metachromatic leukodystrophy: identification and functional characterization of 11 novel ARSA alleles

Metachromatic leukodystrophy (MLD), the demyelinating disorder resulting from impaired sulfatide catabolism, is caused by allelic mutations of the Arylsulfatase A (ARSA) locus except for extremely rare cases of Saposin-B (Sap-B) deficiency. We characterized twenty-one unrelated Italian patients among which seventeen were due to ARSA activity deficiency and 4 others resulted from Saposin-B defect. Overall, we found 20 different mutant ARSA alleles and 2 different Sap-B alleles. The eleven new ARSA alleles (c.53C>A; c.88G>C; c.372G>A; c.409_411delCCC; c.634G>C; [c.650G>A;c.1108C>T]; c.845A>G; c.906G>C; c.919G>T; c.1102-3C>G; c.1126T>A) were functionally characterized and the novel amino acid changes were also modelled into the three-dimensional structure. The present study is aimed at providing a broader picture of the molecular basis of MLD in the Italian population. It also emphasizes the importance of a comprehensive evaluation in MLD diagnosis including biochemical, enzymatic and molecular investigations.     

High prevalence of mutations in LCAT in patients with low HDL cholesterol levels in The Netherlands: identification and characterization of eight novel mutations

Lecithin:cholesterol acyltransferase (LCAT) is crucial to the maturation of high-density lipoprotein (HDL). Homozygosity for LCAT mutations underlies rare disorders characterized by HDL-cholesterol (HDL-c) deficiency while heterozygotes have half normal HDL-c levels. We studied the prevalence of LCAT mutations in referred patients with low HDL-c to better understand the molecular basis of low HDL-c in our patients. LCAT was sequenced in 98 patients referred for HDL-c <5th percentile and in four patients referred for low HDL-c and corneal opacities. LCAT mutations were highly prevalent: in 28 of the 98 participants (29%), heterozygosity for nonsynonymous mutations was identified while 18 patients carried the same mutation (p.T147I). The four patients with corneal opacity were compound heterozygotes. All previously identified mutations are documented to cause loss of catalytic activity. Nine novel mutations-c.402G>T (p.E134D), c.403T>A (p.Y135N), c.964C>T (p.R322C), c.296G>C (p.W99S), c.736G>T (p.V246F), c.802C>T (p.R268C), c.945G>A (p.W315X), c.1012C>T (p.L338F), and c.1039C>T (p.R347C)--were shown to be functional through in vitro characterization. The effect of several mutations on the core protein structure was studied by a three-dimensional (3D) model. Unlike previous reports, functional mutations in LCAT were found in 29% of patients with low HDL-c, thus constituting a common cause of low HDL-c in referred patients in The Netherlands.     

Functional assays testing pathogenicity of 14 cystathionine-beta synthase mutations

In this study, 14 CBS alleles from homocystinuric patients were expressed heterologously in E. coli and their enzyme activities were assayed in vitro. Additionally, mutant CBS proteins were visualized by Western blot from denaturing and non-denaturing polyacrylamide gels. The 14 mutations characterized were: p.R125W (c.373C>T), p.G148R (c.442G>A), p.M173V (c.517A>G), p.T191M (c.572C>T), p.A226T (c.676G>A), p.C275Y (c.824G>A), p.R336C (c.1006C>T), p.R336H (c.1007G>A), p.L338P (c.1013T>C), p.S349N (c.1046G>A), p.R379Q (c.1136G>A), p.L456P (c.1367T>C), p.G522fsX540 (c.1566delG), and p.R548Q (c.1643G>A). Eleven of the mutant alleles exhibited an activity lower than 4% of the wild-type protein. In contrast, mutations p.A226T and p.M173V presented 20% and 40% of the wild-type activity, respectively, whereas the activity of p.R548Q was up to 60% of the wild-type. This suggests that it is a new rare variant rather than a pathogenic mutation. Most of the mutated proteins exhibited a decreased signal in Western blot analyses. The non-denaturing PAGE revealed that the wild-type protein retained the capacity to form a multimeric quaternary structure, whereas in the mutations p.M173V, p.A226T, and p.G548Q, this structure grade was dramatically reduced and was completely absent in the rest of the mutations.     

Identification of 25 new mutations in 40 unrelated Spanish Niemann-Pick type C patients: genotype-phenotype correlations

To better characterize Niemann-Pick type C (NPC) in Spain and improve genetic counselling, molecular analyses were carried out in 40 unrelated Spanish patients. The search identified 70/80 alleles (88%) involving 38 different NPC1 mutations, 26 of which are described for the first time. No patient with NPC2 mutations was identified. The novel NPC1 mutations include 14 amino acid substitutions [R372W (c.1114C>T), P434L (c.1301C>T), C479Y (c.1436G>A), K576R (c.1727G>A), V727F (c.2179G>T), M754K (c.2261T>A), S865L (c.2594C>T), A926T (c.2776G>A), D948H (c.2842G>C), V959E (c.2876T>A), T1036K (c.3107C>A), T1066N (c.3197C>A), N1156I (c.3467A>T) and F1224L (c.3672C>G)], four stop codon [W260X (c.780G>A), S425X (c.1274C>A), C645X (c.1935T>A) and R1059X (c.3175C>T)], two donor splice-site mutations [IVS7+1G>A (g.31432G>A) and IVS21+2insG (g.51871insG)], one in-frame mutation [N961_F966delinsS (c.2882del16bpins1bp)] and five frameshift mutations [V299fsX8 (c.895insT), A558fsX11 (c.1673insG), C778fsX10 (c.2334insT), G993fsX3 (c.2973_78delG) and F1221fsX20 (c.3662delT)]. We also identified three novel changes [V562V (c.1686G>A), A580A (c.1740C>G) and A1187A (c.3561G>T)] in three independent NPC patients and five polymorphisms that have been described previously. The combination of these polymorphisms gave rise to the establishment of different haplotypes. Linkage disequilibrium was detected between mutations C177Y and G993fsX3 and specific haplotypes, suggesting a unique origin for these mutations. In contrast, I1061T mutation showed at least two different origins. The most prevalent mutations in Spanish patients were I1061T, Q775P, C177Y and P1007A (10, 7, 7 and 5% of alleles, respectively). Our data in homozygous patients indicate that the Q775P mutation correlates with a severe infantile neurological form and the C177Y mutation with a late infantile clinical phenotype.     

Haplotyping of wild type and I278T alleles of the human cystathionine beta-synthase gene based on a cluster of novel SNPs in IVS12

Homocystinuria is most frequently due to deficiency of cystathionine beta-synthase (CBS). We identified IVS12 as a polymorphism hot spot of the human CBS gene and report five novel single nucleotide polymorphisms (SNPs): g.13514G>A, g.13617A>G, g.13715C>T, g.13800G>A, and g.13904C>T. Analyzing 50 control DNA samples of unaffected and unrelated subjects of German origin the observed frequencies of heterozygosity were 0.02, 0.36, 0.18, 0.36, and 0.36, respectively. These polymorphic markers were combined into four distinct IVS12-haplotypes A1, A2, B1, and B2, revealing frequencies of 0.75, 0.01, 0.15, and 0.09, respectively, with an observed overall frequency of heterozygosity at 0.38. This haplotype system and the SNP c.699 were employed in the analysis of ten alleles affected by the most prevalent CBS mutation, c.833T>C (exon 8; I278T). We found that the I278T alleles segregate with at least two distinct haplotypes characterized by upstream and downstream polymorphic sites instead of sharing a common ancestral haplotype. This was a remarkable finding even in patients with very similar ethnic background. The novel haplotype system may facilitate future studies on the evolution of the CBS gene and might be suited for genotyping of families affected by homocystinuria.     

McArdle disease: the mutation spectrum of PYGM in a large Italian cohort

Deficiency of the muscle isozyme of glycogen phosphorylase is causative of McArdle disease or Glycogen storage disease type V (GSD-V), the most common autosomal recessive disorder of glycogen metabolism. The typical clinical presentation is characterized by exercise intolerance with cramps, and recurrent myoglobinuria. To date, 46 mutations in the PYGM gene have been detected in GSD-V patients. We report the mutational spectrum in 68 Italian patients. We identified 30 different mutations in the PYGM gene, including 19 mutations that have not been reported previously. The novel mutations include: eight missense mutations (c.475G>A, p.G159R; c.689C>G, p.P230R; c.1094C>T, p.A365E; c.1151C>A, p.A384D; c.1182C>T, p.R428C; c.1471C>T, p.R491C; c.2444A>C, p.D815A; c.2477G>C, p.W826S), two nonsense mutations (c.1475G>A, p.W492X; c.1627A>T, p.K543X), five splice site mutations (c.855 +1G>C; c.1092 +1G>A; c. 1093-1G>T; c.1239 +1G>A; c.2380 +1G>A), and four deletions (c.715_717delGTC, p.V239del; c.304delA, p.N102DfsX4; c.1970_2177del, p.V657_G726; c.2113_2114delGG, p.G705RfsX16). Whereas we confirmed lack of direct correlation between the clinical phenotype and the genotype, we also found that the so-called 'common mutation' (p.R50X) accounted for about 43% of alleles in our cohort and that no population-related mutations are clearly identified in Italian patients.     

Spectrum of novel mutations in the human PKLR gene in pyruvate kinase-deficient Indian patients with heterogeneous clinical phenotypes

Eighteen unrelated pyruvate kinase (PK)-deficient Indian patients were identified in the past 4 years with varied clinical phenotypes ranging from a mild chronic haemolytic anaemia to a severe transfusion-dependent disorder. We identified 17 different mutations in the PKLR gene among the 36 mutated alleles. Ten novel mutations were identified: 427G>A, 499C>A, 1072G>A, 1180G>T, 1216G>A, 1220A>G, 644delG, IVS5 (+20) C>A, IVS9 (+44) C>T, and IVS9 (+93) A>C. A severe syndrome was commonly associated with some mutations, 992A>G, 1436G>A, 1220A>G, 644delG and IVS9 (+93) A>C, in the PKLR gene. Molecular graphics analysis of human red blood cell PK (RPK), based on the crystal structure of human PK, shows that mutations located near the substrate or fructose 1,6-diphosphate binding site may change the conformation of the active site, resulting in very low PK activity and severe clinical symptoms. The mutations target distinct regions of RPK structure, including domain interfaces and catalytic and allosteric sites. In particular, the 1216G>A and 1219G>A mutations significantly affect the interdomain interaction because they are located near the catalytic site in the A/B interface domains. The most frequent mutations in the Indian population appear to be 1436G>A (19.44%), followed by 1456C>T (16.66%) and 992A>G (16.66%). This is the first study to correlate the clinical profile with the molecular defects causing PK deficiency from India where 10 novel mutations that produce non-spherocytic haemolytic anaemia were identified.     

Identification of the bruton tyrosine kinase (BTK) gene mutations in 20 Australian families with X-linked agammaglobulinemia (XLA)

X-linked agammaglobulinemia (XLA) is an immunodeficiency caused by mutations in the Bruton tyrosine kinase (BTK) gene. Twenty Australian patients with an XLA phenotype, from 15 unrelated families, were found to have 14 mutations. Five of the mutations were previously described c.83G>A (p.R28H), c.862C>T (p.R288W), c.904G>A (p.R302G), c.1535T>C (p.L512P), c.700C>T (p.Q234X), while nine novel mutations were identified: four missense c.82C>A (p.R28S), c.494G>A (p.C165Y), c.464G>A (p.C155Y), c.1750G>A (p.G584E), one deletion c.142_144delAGAAGA (p.R48_G50del), and four splice site mutations c.241-2A>G, c.839+4A>G, c.1350-2A>G, c.1566+1G>A. Carrier analysis was performed in 10 mothers and 11 female relatives. The results of this study further support the notion that molecular genetic testing represents an important tool for definitive and early diagnosis of XLA and may allow accurate carrier status and prenatal diagnosis.     

Identification and molecular characterization of alpha-L-iduronidase mutations present in mucopolysaccharidosis type I patients undergoing enzyme replacement therapy

Mucopolysaccharidosis type I (MPS I) is an autosomal recessive lysosomal storage disorder caused by a deficiency of alpha-L-iduronidase (IDUA). Mutations in the gene are responsible for the enzyme deficiency, which leads to the intralysosomal storage of the partially degraded glycosaminoglycans dermatan sulfate and heparan sulfate. Molecular characterization of MPS I patients has resulted in the identification of over 70 distinct mutations in the IDUA gene. The high degree of molecular heterogeneity reflects the wide clinical variability observed in MPS I patients. Six novel mutations, c.1087C>T (p.R363C), c.1804T>A (p.F602I), c.793G>C, c.712T>A (p.L238Q), c.1727+2T>A, and c.1269C>G (p.S423R), in a total of 14 different mutations, and 13 different polymorphic changes, including the novel c.246C>G (p.H82Q), were identified in a cohort of 10 MPS I patients enrolled in a clinical trial of enzyme-replacement therapy. Five novel amino acid substitutions and c.236C>T (p.A79V) were engineered into the wild-type IDUA cDNA and expressed. A p.G265R read-through mutation, arising from the c.793G>C splice mutation, was also expressed. Each mutation reduced IDUA protein and activity levels to varying degrees with the processing of many of the mutant forms also affected by IDUA. The varied properties of the expressed mutant forms of IDUA reflect the broad range of biochemical and clinical phenotypes of the 10 patients in this study. IDUA kinetic data derived from each patient's cultured fibroblasts, in combination with genotype data, was used to predict disease severity. Finally, residual IDUA protein concentration in cultured fibroblasts showed a weak correlation to the degree of immune response to enzyme-replacement therapy in each patient.     

Identification of novel MLC1 mutations in Chinese patients with megalencephalic leukoencephalopathy with subcortical cysts (MLC)

Megalencephalic leukoencephalopathy with subcortical cysts (MLC) is an autosomal, recessively inherited disease caused by mutations in the MLC1 gene. Most of the previously published studies have been carried out in ethnic populations other than the Chinese. In this study, the analysis of clinical features and MLC1 mutation screening were performed in 13 Chinese patients for the first time. A total of 10 MLC1 mutations were identified in these patients, including five novel missense mutations (c.65G>A, p.R22Q; c.95C>T, p.A32V; c.218G>A, p.G73E; c.823G>A, p.A275T; c.832T>C, p.Y278H), one novel splicing mutation (c.772-1G>C in IVS9-1), one novel small deletion (c.907_930del, p.V303_L310del), one known nonsense mutation (c.593delCTCA, p.Y198X) and two known missense mutations (c.206C>T, p.S69L; c.353C>T, p.T118M). Mutation c.772-1G>C in IVS9-1, accounting for 27.3% (3/11) of the total number of genetically confirmed patients found in this study, is thus a putative hot-spot mutation in the present study group. The existence of a unique MLC1 mutation spectrum in Chinese MLC patients was shown. A systemic study to assess the mutation spectra in different populations should be undertaken.     

Mutational spectrum in German patients with phenylalanine hydroxylase deficiency

We report on the spectrum and frequency of mutations in the phenylalanine hydroxylase (PAH) gene in 226 German families with PAH deficiency, most of them from Southern Germany. A total of 88 mutations were identified in 428 out of 438 mutant PAH alleles including one novel stop mutation L293X (c.878T>A). In three families, two phenylketonuria (PKU) mutations were found in cis, and in one family a de novo mutation was observed. A comparison of the results from Southern Germany with those of other parts of Western Germany showed no obvious local mutation clustering. In addition we studied the genotypic spectrum of 39 Turkish families with PAH deficiency. Twenty-three mutations were identified in 73 out of 75 Turkish chromosomes including two novel mutations: E280A (c.839A>G) in Exon 7 and IVS10-7C>A (c.1066-7C>A) in Intron 10. A new polymorphism IVS4+47C/T (c.441+47C>T) was found in mutant and normal PAH alleles. Screening of 170 German and 150 Turkish individuals without family history of PAH deficiency revealed 10 and 12 heterozygotes, respectively, a higher frequency of carriers than expected. A novel mutations of uncertain functional relevance, R169H (c.506G>A) in Exon 5 was found in two Turkish heterozygotes. Most of the Turkish heterozygotes carried mild mutations, indicating that mild forms of PAH deficiency may be more common in that population than previously recognised.     

Characterization of seven novel mutations in seven patients with GAMT deficiency

Guanidinoacetate methyltransferase (GAMT) deficiency is an autosomal recessive error of creatine synthesis characterized by cerebral creatine deficiency, accumulation of guanidinoacetate, mental retardation, epilepsy and extrapyramidal signs. So far, six mutations have been identified in seven patients. We investigated seven new patients by screening the promoter, 3'UTR, and six exons and exon/intron boundaries using direct sequencing and denaturing gradient gel electrophoresis. The clinical and biochemical phenotype was characterized by scoring the degree of main clinical manifestations and by determination of urinary guanidinoacetate concentrations and of GAMT activity in fibroblasts / lymphoblasts, respectively. We identified 7 novel mutations, including c.64dupG (exon 1; 4/14 alleles); c.59G>C (exon 1; 3/14 alleles); c.491delG (exon 5; 2/14 alleles); c.160G>C (exon 1; 2/14 alleles); and c.152A>C (exon 1; 1/14 alleles); c.526dupG (exon 5; 1/14 alleles); c.521G>A (exon 5; 1/14 alleles), and two polymorphisms c.626C>T (exon 6) and c.459+71G>A (intron 4). Frameshift and missense mutations in exon 1 were prevalent in the 4 patients with the severe phenotype, however a clear genotype-phenotype correlation has not been established in the limited number of patients characterized so far.     

Mutational screening of the coding region of growth differentiation factor 9 gene in Indian women with ovarian failure

OBJECTIVE: To establish the risk associated with mutations in the coding region of GDF9 gene in Indian women with ovarian failure. DESIGN: This case-control study was designed for mutational analysis of the GDF9 coding region in a cohort of women with premature ovarian failure (n = 127), primary amenorrhea (n = 58), and secondary amenorrhea (n = 10) compared with controls (n = 220). RESULTS: This case-control study revealed eight mutations in the GDF9 gene, including five novel mutations: c.1-8C>T, c.199A>C (p.Lys67Glu), c. 205C>T, c.646G>A (p.Val216Mat), and c.1353C>T, and three documented mutations: c.398-39C>G, c.447C>T, and c.546G>A. Missense mutation c.199A>C was present in 4 of 127 premature ovarian failure (POF) cases and 1 of 10 secondary amenorrhea cases. The c.646G>A mutation was present in two POF cases. Both missense mutations were absent in controls. Genotype distribution of c.447C>T was significantly different in POF cases than controls (chi(2) = 5.93, P = 0.05). We chose two frequent single-nucleotide polymorphisms (c.398-39C>G, c.447C>T) for haplotyping and found that the C-T haplotype was significantly higher in patients (P = 0.03), whereas the C-C haplotype was representative of the control group. CONCLUSIONS: We report two rare missense mutations, c.199A>C and c.646G>A, which are associated with ovarian failure. The presence of the c.447>T mutation might indicate a higher risk for POF. Haplotype C-T was significantly associated with ovarian failure, whereas the C-C haplotype was representative of the control group.     

Clinical features,BTD gene mutations,and their functional studies of eight symptomatic patients with biotinidase deficiency from Southern China

Biotinidase (BTD) deficiency is a rare autosomal recessive metabolic disease, which develops neurological and cutaneous symptoms because of the impaired biotin recycling. Pathogenic mutations on BTD gene cause BTD deficiency. Clinical features and mutation analysis of Chinese children with BTD deficiency were rarely described. Herein, for the first time, we reported the clinical features, BTD gene mutations and their functional studies of eight symptomatic children with BTD deficiency from southern China. Fatigue, hypotonia, proximal muscular weakness, hearing deficits, rash and respiratory problems are common clinical phenotype of our patients. Seizures are observed only in patients with profound BTD deficiency. Five novel mutations were detected, among which c.637delC (H213TfsTer51) was found in 50% of our patients and might be considered as a common mutation. In vitro studies confirmed three mild mutations c.1368A>C (Q456H), c.1613G>A (R538H), and c.644T>A (L215H) which retained 10–30% of wild type enzyme activity, and six severe mutations c.235C>T (R79C), c.1271G>C (C424S), c.1412G>A (C471Y), c.637delC (H213TfsTer51), c.395T>G (M132W), c.464T>C (L155P), and c.1493dupT (L498FfsTer13) which retained <10% of wild type enzyme activity. c.1330G>C (D444H) decreased the protein expression but not activity of BTD enzyme, and H213TfsTer51 was structurally damaging while L498FfsTer13 was functionally damaging. These results will be helpful in establishing the definitive diagnosis of BTD deficiency at the gene level, offering appropriate genetic counseling, and providing clues to structure/function relationships of the enzyme.

     

Molecular and functional characterization of eight novel GAA mutations in Italian infants with Pompe disease

We characterized 29 unrelated patients presenting with the severe form of Pompe disease (Glycogen Storage Disease Type II, acid maltase deficiency) and identified 26 pathogenic mutations divided over 28 different genotypes. Among the eight new mutations, five were exonic point mutations (c.572A>G, c.1124G>T, c.1202A>G, c.1564C>G and c.1796C>A) leading to codon changes (p.Y191C, p.R375L, p.Q401R, p.P522A and p.S599Y); two were intronic point mutations (c.-32-3C>A and c.1636+5G>C) affecting mRNA processing; one was a single base deletion (c.742delC) generating a truncated protein (p.L248PfsX20). A comprehensive evaluation, based on different methodological approaches, confirmed the detrimental effect of the eight mutations on the protein and its function. Structural alterations potentially induced by the five missense mutations were also predicted through visual inspection of the atomic model of the GAA protein, in terms of both function and spatial orientation of specific residues as well as disturbance generated by amino acid substitutions. Although the remarkable heterogeneity of the mutational spectrum in Pompe disease was already known, our data demonstrate and confirm the power of molecular and functional analysis in predicting the natural course of Pompe disease.     

Clinical characteristics and molecular analysis of 21 Chinese children with congenital agammaglobulinemia

Congenital agammaglobulinemia is a humoral primary immunodeficiency and affected patients have extremely low levels of peripheral B cells and profound deficiency of all immunoglobulin isotypes. Mutations of the Bruton's tyrosine kinase (BTK) gene are responsible for most of the congenital agammaglobulinemia. In this study, the phenotypes of congenital agammaglobulinemia were investigated in 21 male children from 21 unrelated Chinese families. Sixteen different mutations of BTK gene were identified in 18 patients, and three patients did not have BTK gene mutations. Nine mutations had been reported previously including one gross deletion (c.722_2041del), one missense mutation (c.1764G>T), three non-sense mutations (c.194C>A, c.895C>T and c.1821G>A) and four invariant splice-site mutations (c.971+2T>C, c.1481+2T>A, c.1482-2A>G, c.1699-2A>G). Seven novel mutations were identified (c.373_441del, c. 504delG, c.537delC, c.851delA, c.1637G>A, c.1879T>C and c. 1482_1882 del). Ten of the eighteen mutations of BTK gene were located in the TK domain, four in the PH domain, three in the SH3 domain and one spanned the TH, SH3, SH2 and TK domain. Candidate genes of autosomal-recessive agammaglobulinemia, including IGHM, CD79a, CD79b and IGLL1, were screened in three patients without mutations in the BTK gene. A compound heterozygosity mutation in the IGHM gene (c.1956G>A, c.175_176insC) was identified in one patient. The results of our study further support that molecular genetic testing represents an important tool for early confirmed diagnosis of congenital agammaglobulinemia and may allow accurate carrier detection and prenatal diagnosis.