Libor Kozák

Classical galactosemia and mutations at the galactose-1-phosphate uridyl transferase (GALT) gene

Classical galactosemia is caused by a deficiency in activity of the enzyme galactose‐1‐phosphate uridyl transferase (GALT), which, in turn, is caused by mutations at the GALT gene. The disorder exhibits considerable allelic heterogeneity and, at the end of 1998, more than 150 different base changes were recorded in 24 different populations and ethnic groups in 15 countries worldwide. The mutations most frequently cited are Q188R, K285N, S135L, and N314D. Q188R is the most common mutation in European populations or in those predominantly of European descent. Overall, it accounts for 60–70% of mutant chromosomes, but there are significant differences in its relative frequency in individual populations. Individuals homoallelic for Q188R tend to have a severe phenotype and this is in keeping with the virtually complete loss of enzyme activity observed in in vitro expression systems. Globally, K285N is rarer, but in many European populations it can be found on 25–40% of mutant chromosomes. It is invariably associated with a severe phenotype. S135L is found almost exclusively in African Americans. In vitro expression results are discrepant, but some individuals carrying S135L appear to exhibit GALT activity in some tissues. Duarte 1 (or Los Angeles) and Duarte 2 (or Duarte) variants carry the same amino acid substitution, N314D, even though D1 is associated with increased erythrocyte GALT activity and D2 with reduced activity. N314D is in linkage disequilibrium with other base changes that differ on the D1 and D2 alleles. N314D does not impair GALT activity in in vitro expression systems. However, there are differences in the abundance of GALT protein in lymphoblastoid cells lines from D2 and D1 individuals. It is unclear whether the specific molecular changes that distinguish the D1 and D2 alleles account for the different activities. The considerable genetic heterogeneity documented to date undoubtedly contributes to the phenotypic heterogeneity that is observed in galactosemia. The additional effects of nonallelic variation and other constitutional factors on phenotypic variability remain to be elucidated. Hum Mutat 13:417–430, 1999.

Analysis of point mutations in the SMN1 gene in SMA patients bearing a single SMN1 copy

Spinal muscular atrophy (SMA) is caused by homozygous deletion of the SMN1 gene in approximately 96% of cases. Four percent of SMA patients have a combination of the deletion or conversion on one allele and an intragenic mutation on the second one. We performed analysis of point mutations in a set of our patients with suspicion of SMA and without homozygous deletion of the SMN1 gene. A quantitative test determining SMN1 copy number (using real-time PCR and/or MLPA analysis) was performed in 301 patients and only 1 SMN1 copy was detected in 14 of them. When these 14 patients were screened for the presence of point mutations we identified 6 mutations, p.Y272C (in three patients) and p.T274I, p.I33IfsX6, and p.A188S (each in one case). The mutations p.I33IfsX6 and p.A188S were found in two SMAI patients and were not detected previously. Further, evaluation of the relationship between mutation type, copy number of the SMN2 gene and clinical findings was performed. Among our SMA patients with a SMN1 homozygous deletion, we found a family with two patients: the son with SMAII possesses 3 SMN2 copies and the nearly asymptomatic father has a homozygous deletion of SMN1 exon 7 and carries 4 SMN2 copies. Generally, our results illustrate that an increased SMN2 gene copy number is associated with a milder SMA phenotype.

Mutation and haplotype analysis of phenylalanine hydroxylase alleles in classical PKU patients from the Czech Republic: identification of four novel mutations.

Mutations, haplotypes, and other polymorphic markers in the phenylalanine hydroxylase (PAH) gene were analysed in 133 unrelated Czech families with classical phenylketonuria (PKU). Almost 95% of all mutant alleles were identified, using a combination of PCR and restriction analysis, denaturing gradient gel electrophoresis (DGGE), and sequencing. A total of 30 different mutations, 16 various RFLP/VNTR haplotypes, and four polymorphisms were detected on 266 independent mutant chromosomes. The most common molecular defect observed in the Czech population was R408W (54.9%). Each of the other 29 mutations was present in no more than 5% of alleles and 13 mutations were found in only one PKU allele each (0.4%). Four novel mutations G239A, R270fsdel5bp, A342P, and IVS11nt-8g-->a were identified. In 14 (5.1%) alleles, linked to four different RFLP/VNTR haplotypes, the sequence alterations still remain unknown. Our results confirm that PKU is a heterogeneous disorder at the molecular level. Since there is evidence for the gene flow coming from northern, western, and southern parts of Europe into our Slavic population, it is clear that human migration has been the most important factor in the spread of PKU alleles in Europe.

Genotyping microarray as a novel approach for the detection of ATP7B gene mutations in patients with Wilson disease.

Wilson disease (WD) is an autosomal recessive inherited disorder of copper metabolism that is caused by mutations in the ATP7B gene. To date, more than 300 mutations have been described in this gene. Molecular diagnostics of WD utilizes restriction enzyme digestion, multiplex ligation‐dependent probe amplification or a direct sequencing of the whole gene. To simplify and speed up the screening of ATP7B mutations, we have developed a genotyping microarray for the simultaneous detection of 87 mutations and 17 polymorphisms in the ATP7B gene based on the arrayed primer extension reaction. The patient’s DNA is amplified in four multiplex polymerase chain reactions, fragmented products are annealed to arrayed primers spotted on a chip, which enables DNA polymerase extension reactions with fluorescently labeled dideoxynucleotides. The Wilson microarray was validated by screening 97 previously genetically confirmed WD patients. In total, we detected 43 mutations and 15 polymorphisms that represent a majority of the common mutations occurring in the Czech and Slovak populations. All screened sequence variants were detected with 100% accuracy. The Wilson chip appears to be a rapid, sensitive and cost‐effective tool, representing the prototype of a disease chip that facilitates and speeds up the screening of potential WD patients.

Molecular Genetic Analysis of SLC3A1 and SLC7A9 Genes in Czech and Slovak Cystinuric Patients

Cystinuria is a frequently inherited metabolic disorder in the Czech population (frequency 1/5,600) caused by a defect in the renal transport of cystine and dibasic amino acids (arginine, lysine and ornithine). The disease is characterized by increased urinary excretion of the amino acids and often leads to recurrent nephrolithiasis. Cystinuria is classified into two subtypes (type I and type non‐I). Type I is caused predominantly by mutations in the SLC3A1 gene (2p16.3), encoding heavy subunit (rBAT) of the heterodimeric transporter. Cystinuria non‐I type is caused by mutations in the SLC7A9 gene (19q13.1). In this study, we present results of molecular genetic analysis of the SLC3A1 and the SLC7A9 genes in 24 unrelated cystinuria families. Individual exons of the SLC3A1 and SLC7A9 genes were analyzed by direct sequencing. We found ten different mutations in the SLC3A1 gene including six novel ones: three missense mutations (G140R), D179Y and R365P), one splice site mutation (1137‐2A>G), one deletion (1515_1516delAA), and one nonsense mutation (Q119X). The most frequent mutation, M467T; was detected in 36% of all type I classified alleles. In the SLC7A9 gene we found six mutations including three new ones: one missense mutation (G319R), one insertion (611_612insA) and one deletion (205_206delTG). One patient was compound heterozygote for one SLC3A1 and one SLC7A9 mutation. Our results confirm that cystinuria is a heterogeneous disorder at the molecular level, and contribute to the understanding of the distribution and frequency of mutations causing cystinuria in the Caucasian population.

Smith-Lemli-Opitz syndrome: Molecular-genetic analysis of ten families

Smith-Lemli-Opitz syndrome (SLOS; McKusick 270400) is an autosomal recessive inherited metabolic-malformation disorder caused by deficient activity of 7-dehydrocholesterol reductase (DHCR7, E.C. 1.3.1.21), which catalyses the final step in the cholesterol-biosynthesis pathway. The clinical picture is characterized by a combination of congenital anomalies: microcephaly, hypotonia, incomplete development of the male genitalia, polydactyly, syndactyly of toes 2 and 3, cleft palate, heart and kidney malformations, failure to thrive and severe mental and growth retardation (Smith et al 1964). A decrease of plasma cholesterol and the accumulation of its precursor 7-dehydrocholesterol (7-DHC) is the biochemical hallmark in SLOS patients (Tint et al 1994). Cloning and sequncing of DHCR7 cDNA (Moebius et al 1998) and characterization of the human DHCR7 gene (Fitzky et al 1998) enabled investigation of defects of this gene at the DNA level. Several mutations have been described (Wassif et al 1998; Waterham et al 1998). Here we report the results of molecular analysis of the DHCR7 gene in 10 unrelated families with Smith-Lemli-Opitz syndrome. Results of mutation analyses are presented and compared with the clinical and biochemical data.

Phenylketonuria mutations and their relation to RFLP haplotypes at the PAH locus in Czech PKU families

A detailed study of the mutant phenylalanine hydroxylase (PAH) gene from the eastern part of the Czech Republic (Moravia) is reported. A total of 190 mutant alleles from 95 phenylketonuria (PKU) families were analyzed for 21 prevalent Caucasian mutations and restriction fragment length polymorphism /variable number of tandem repeats (RFLP/VNTR) haplotypes. Eighty per cent of all mutant alleles were found to carry 11 mutations. The most common molecular defect was the mutation R408W (55.3%), with a very high degree of homozygosity (34.6%). Each of four other mutations (R158Q, R243X, G272X, IVS12nt1) accounted for more than 3% of PKU alleles. Rarely present were mutations IVS10nt546 (2.6%), R252W (2.6%), L48S (2.1%), R261Q (1.6%), Y414C (1.0%) and I65T (0.5%). Mutations that have been predominantly described in southern Europe (IVS7nt1, A259V, Y277D, R241H, T278N) were not detected. A total of 14 different mutant haplotypes were observed. Three unusual genotype-haplotype associations were identified (R158Q on haplotypes 2.3 and 7.8 and R252W on haplotype 69.3). There was a strong association between the mutation R408W and haplotype 2.3 (54.7%). Heterogeneity was found at mutations R408W (haplotypes 2.3 and 5.9), R158Q (haplotypes 4.3, 2.3 and 7.8) and IVS10nt546 (haplotypes 6.7 and 34.7). The molecular basis of PKU in the Moravian area appears to be relatively homogeneous in comparison with other southern and western European populations, thus providing a good starting point for prenatal diagnosis and early clinical classification.

Identification of mutations in the glucose-6-phosphatase gene in Czech and Slovak patients with glycogen storage disease type Ia, including novel mutations K76N, V166A and 540del5

Mutations in the glucose‐6‐phosphatase (G6Pase) gene are responsible for glycogen storage disease type Ia (GSD Ia). A study of the molecular basis of GSD Ia was carried out in 12 Czech and Slovak GSD Ia patients from 10 unrelated families. Mutation analysis was performed for the entire coding region of G6Pase gene using DGGE, sequencing and PCR/digestion. With the strategy used, all mutant alleles were identified in this study. Three novel mutations (K76N, V166A and 540del5), six previously described mutations (W77R, R83C, G188R, R295C, Q347X and 158delC) and one known polymorphism (1176T→C) were detected. The most common mutation identified was R83C, accounting for 8 out of 20 (40%) mutant alleles. The K76N mutation was found in a Gypsy family: two siblings with GSD Ia were homozygous for this mutation. These findings expand our knowledge of mutations responsible for glycogen storage disease type Ia. Hum Mutat 16:89, 2000.

Mutation spectrum and phenylalanine hydroxylase RFLP/VNTR background in 44 Romanian phenylketonuric alleles.

The mutation spectrum and polymorphic haplotype background in 22 Romanian families have been analysed in this study using the restriction digestion of phenylalanine hydroxylase (PAH) regions specifically amplified or the DGGE/direct sequencing methods. Eleven PAH mutations specifically associated with six mutant haplotypes were detected. In spite of the relative heterogeneity of the molecular defects in the PAH gene, three mutations covered almost 70% of all alleles: R408W, 47.72%, 21/44; K363fsdelG 13.63%, 6/44; and P225T 6.81%, 3/44. Among these, R408W, the most frequent mutation in our population, represented 50% of all the phenylketonuric (PKU) chromosomes. Splice mutation IVS12nt1g→a affected two PAH alleles (4.54%); the remaining seven mutations were rare, each having an effect on just one chromosome (1/44), resulting in a relative frequency of 2.27%. A high frequency was observed in our PKU samples for the relatively uncommon mutations, K363fsdelG and P225T mutation, suggesting a possible founder effect at origin. Within the investigated panel, these mutations, both very rare among other Caucasians were exclusively linked to haplotype 5.8 and 1.7, respectively. These results provide a basis for the development of a routine molecular analysis of Romanian PKU families. Hum Mutat 12:314–319, 1998.© 1998 Wiley‐Liss, Inc.

Identification of three novel mutations in the PHKA2 gene in Czech patients with X-linked liver glycogenosis

Phosphorylase-b kinase (PHK) plays a regulatory role in a cascade of enzymatic reactions controlling glycogen breakdown. Deficiency in PHK activity leads to inactivation of glycogen phosphorylase and accumulation of glycogen in liver. Mutations in the gene for the a-subunit of liver phosphorylase-b kinase (PHKA2) are responsible for X-linked liver glycogenosis (XLG). We analysed molecular defects in the PHKA2 gene in four XLG I patients from three unrelated Czech families by direct sequencing of RT-PCR products. Genomic DNA was used to examine other family members and to verify the results from RT-PCR analysis. Three novel mutations associated with the XLG I phenotype were found. Two of the mutations were missense mutations C91Y and G1210E, located in two highly conserved amino acid regions of the PHKA2 gene. The third was an in-frame deletion 3400delC leading to a premature termination. These findings expand our knowledge of mutations responsible for X-linked liver glycogenosis type I and suggest that XLG may be a highly heterogeneous disorder at the molecular level.