PAH 399 GTA(Val)→GTT(Val), a new silent mutation found in the Chinese

Summary A silent mutation or sequence polymorphism, an A to T substitution at codon 399 in exon 11 of the phenylalanine hydroxylase (PAH) gene has been identified by DNA sequence analysis in the Chinese. The frequencies of this new mutation in normal and abnormal (phenylketonuria; PKU) genes are 0.005 and 0.09, respectively, based on the analyses of 100 apparently normal individuals and 39 PKU patients, as demonstrated by DNA amplification with polymerase chain reaction (PCR) and oligonucleotide hybridization methods. The results suggest that there is linkage disequilibrium between this polymorphism and PKU mutations in the PAH gene; approximately 10% of defect PAH alleles in the Chinese population may be identified with this sequence polymorphic marker.     

Mutations of the phenylalanine hydroxylase gene in patients with phenylketonuria in Shanxi,China

The variation in mutations in exons 3, 6, 7, 11 and 12 of the phenylalanine hydroxylase (PAH) gene was investigated in 59 children with phenylketonuria (PKU) and 100 normal children. Three single nucleotide polymorphisms were detected by sequence analysis. The mutational frequencies of cDNA 696, cDNA 735 and cDNA 1155 in patients were 96.2%, 76.1% and 7.6%, respectively, whereas in healthy children the corresponding frequencies were 97.0%, 77.3% and 8.3%. In addition, 81 mutations accounted for 61.0% of the mutant alleles. R111X, H64 > TfsX9 and S70 del accounted for 5.1%, 0.8% and 0.8% mutation of alleles in exon 3, whereas EX6-96A > G accounted for 10.2% mutation of alleles in exon 6. R243Q had the highest incidence in exon 7 (12.7%), followed by Ivs7 + 2 T > A (5.1%) and T278I (2.5%). G247V, R252Q, L255S, R261Q and E280K accounted for 0.8% while Y356X and V399V accounted for 5.9% and 5.1%, respectively, in exon 11. R413P and A434D accounted for 5.9% and 2.5%, respectively, in exon 12. Seventy-two variant alleles accounted for the 16 mutations observed here. The mutation characteristics and distributions demonstrated that EX6-96A > G and R243Q were the hot regions for mutations in the PAH gene in Shanxi patients with PKU.     

GT to AT transition at a splice donor site causes skipping of the preceding exon in phenylketonuria.

Classical Phenylketonuria (PKU) is an autosomal recessive human genetic disorder caused by a deficiency of hepatic phenylalanine hydroxylase (PAH). We isolated several mutant PAH cDNA clones from a PKU carrier individual and showed that they contained an internal 116 base pair deletion, corresponding precisely to exon 12 of the human chromosomal PAH gene. The deletion causes the synthesis of a truncated protein lacking the C-terminal 52 amino acids. Gene transfer and expression studies using the mutant PAH cDNA indicated that the deletion abolishes PAH activity in the cell as a result of protein instability. To determine the molecular basis of the deletion, the mutant chromosomal PAH gene was isolated from this individual and shown to contain a GT-- greater than AT substitution at the 5' splice donor site of intron 12. Thus, the consequence of the splice donor site mutation in the human liver is the skipping of the preceding exon during RNA splicing.     

Rapid mutation screening of phenylketonuria by polymerase chain reaction-linked restriction enzyme assay and direct sequence of the phenylalanine hydroxylase gene: clinical application in northern Japan and northern China

We describe a simple and technically feasible method for mutation screening of the phenylalanine hydroxylase (PAH) gene and its application to Japanese and Chinese patients with hyperphenylalaninemia. The strategy is based on the identification of a nucleotide substitution by restriction enzyme analysis, coupled with PCR and direct sequencing of exon 7 of the PAH gene. Because the detection of various mutations can proceed simultaneously using the same technique, it is quite rapid and reproducible, making it possible to perform effective molecular diagnosis and carrier screening in most laboratories. Using this procedure, we found that the most common molecular defects were R413P in Hokkaido, Japan (35 %) and R243Q in Heilongjiang, China (50%). R111X, IVS4nt-1, and five mutations in exon 7 (R241C, R243Q, R252W, A259T, and S273P) accounted for 55% of phenylketonuria (PKU) alleles in Hokkaido. In Heilongjiang, the R111X, Y356X, and R408W mutations accounted for 35% of PKU alleles. Clinically, homozygotes or compound heterozygotes of null alleles, which express nonfunctional enzyme activity, were all associated with classic PKU. On the other hand, patients heterozygous for the R241C allele had a benign phenotype of mild hyperphenylalaninemia. The DNA diagnosis in early infancy can predict various PKU phenotypes, and can prove useful in decision-making concerning dietary therapy.     

Identification of three novel missense PKU mutations among Chinese.

Three novel missense mutations have been identified in the phenylalanine hydroxylase (PAH) genes of Chinese individuals afflicted with various degrees of phenylketonuria (PKU). A T-to-C transition was observed in exon 5 of the gene, resulting in the substitution of Phe161 by Ser161. Two substitutions, G-to-T and T-to-G, were observed in exon 7, resulting in the substitution of Gly247 by Val247 and Leu255 by Val255, respectively. Expression analysis demonstrated that these mutant proteins produced between 0 and 15% of normal PAH enzyme activity. Population screening of a Chinese sample population indicates that these mutations are quite rare, together accounting for only about 4% of all PKU alleles among the Chinese. The P161S and G247V mutations were each present on a single PAH RFLP haplotype 4 chromosome in patients form Northern China, while the L255V mutation was present on chromosomes of both haplotypes 18 and 21 in patients from Southern China. These results suggest that the remaining 30% of uncharacterized PKU alleles in the Chinese population may bear a large number of relatively rare PAH mutations.     

Development of a mutation hotspot detection kit for the phenylalanine hydroxylase gene by ARMS-PCR combined with fluorescent probe technology

To develop a screening kit for detecting mutation hotspots of the phenylalanine hydroxylase (PAH) gene. Thirteen exons of the PAH gene were sequenced in 84 cases with phenylketonuria (PKU) diagnosed during neonatal genetic and metabolic disease screening in Shaanxi province, and their mutations were analyzed. We designed and developed a screening kit to detect nine mutation sites covering more than 50% of the PAH mutations found in Shaanxi province (c.728G>A, c.1197A>T, c.331C>T, c.1068C>A, c.611A>G, c.1238G>C, c.721C>T, c.442-1G>A, and c.158G>A) by using amplification refractory mutation system-polymerase chain reaction (ARMS-PCR) combined with fluorescent probe technology. Peripheral blood and dried blood samples from PKU families were used for clinical verification of the newly developed kit. PAH gene mutations were detected in 84 children diagnosed with PKU. A total of 159 mutant alleles were identified, consisting of 100 missense mutations, 28 shear mutations, 24 nonsense mutations, and 7 deletion mutations. Exon 7 had the highest mutation frequency (32.08%). Among them, the mutation frequency of p.R243Q was the highest, accounting for 20.13% of all mutations, followed by p.R111X, IVS4-1G>A, EX6-96A>G, and p.R413P; these five loci accounted for 47.17% (75/159) of all mutations. In addition, we identified three previously unreported PAH gene mutations (p.C334X, p.G46D, and p.G256D). Fifteen mutation sites were identified in the 47 PAH carriers identified by next-generation sequencing (NGS), which were verified by the newly developed kit, with an agreement rate of 100%. This newly developed kit based on ARMS-PCR combined with fluorescent probe technology can be used to detect common PAH gene mutations.     

Missense mutations prevalent in Orientals with phenylketonuria: molecular characterization and clinical implications

Two missense mutations in the phenylalanine hydroxylase (PAH) genes of Orientals with phenylketonuria (PKU) have been identified. A G-to-A transition in exon 7 of the gene results in the substitution of Gln243 for Arg243 (R243Q) and accounts for 18% of all PKU chromosomes among Chinese. An A-to-G transition in exon 6 of the gene results in the substitution of Cys204 for Tyr204 (Y204C) and identifies about 13 and 5% of all PKU chromosomes in the Chinese and Japanese populations, respectively. The R243Q construct produced less than 10% of normal PAH activity in in vitro expression analysis in a eukaryotic cell system, and patients homozygous for this substitution exhibit a severe clinical phenotype. These results are consistent with previous findings in this expression system. The Y204C construct, however, produced near normal levels of PAH enzyme activity and immunoreactivity in this in vitro expression system. Because this substitution is present only on PKU chromosomes, it is a valuable marker for identifying the corresponding mutant allele for carrier screening of PKU. With the characterization of these two substitutions, about 60% of PKU alleles in China can now be identified. The continuing search for additional PKU mutations will permit effective carrier screening and prenatal gene diagnosis of PKU in East Asia.     

Molecular basis for nonphenylketonuria hyperphenylalaninemia.

Nonphenylketonuria hyperphenylalaninemia (non-PKU HPA) is defined as phenylalanine hydroxylase (PAH) deficiency with blood phenylalanine levels below 600 mumol/liter (i.e., within the therapeutic range) on a normal dietary intake. Haplotype analysis at the PAH locus was performed in 17 Danish families with non-PKU HPA, revealing compound heterozygosity in all individuals. By allele-specific oligonucleotide (ASO) probing for common PKU mutations we found 12 of 17 non-PKU HPA children with a PKU allele on one chromosome. To identify molecular lesions in the second allele, individual exons were amplified by polymerase chain reaction and screened for mutations by single-strand conformation polymorphism. Two new missense mutations were identified. Three children had inherited a G-to-A transition at codon 415 in exon 12 of the PAH gene, resulting in the substitution of asparagine for aspartate, whereas one child possessed an A-to-G transition at codon 306 in exon 9, causing the replacement of an isoleucine by a valine in the enzyme. It is further demonstrated that the identified mutations have less impact on the heterozygote's ability to hydroxylate phenylalanine to tyrosine compared to the parents carrying a PKU mutation. The combined effect on PAH activity explains the non-PKU HPA phenotype of the child. The present observations that PKU mutations in combination with other mutations result in the non-PKU HPA phenotype and that particular mutation-restriction fragment length polymorphism haplotype combinations are associated with this phenotype offer the possibility of distinguishing PKU patients from non-PKU individuals by means of molecular analysis of the hyperphenylalaninemic neonate and, consequently, of determining whether a newborn child requires dietary treatment.     

Phenylalanine hydroxylase deficiency caused by a single base substitution in an exon of the human phenylalanine hydroxylase gene

A novel restriction fragment length polymorphism in the phenylalanine hydroxylase (PAH) locus generated by the restriction endonuclease MspI was observed in a German phenylketonuria (PKU) patient. Molecular cloning and DNA sequence analyses revealed that the MspI polymorphism was created by a T to C transition in exon 9 of the human PAH gene, which also resulted in the conversion of a leucine codon to a proline codon. The effect of the amino acid substitution was investigated by creating a corresponding mutation in a full-length human PAH cDNA by site-directed mutagenesis followed by expression analysis in cultured mammalian cells. Results demonstrate that the mutation in the gene causes the synthesis of an unstable protein in the cell corresponding to a CRM- phenotype. Together with the other mutations recently reported in the PAH gene, the data support previous biochemical and clinical observations that PKU is a heterogeneous disorder at the gene level.     

苯丙氨酸羟化酶（PAH）基因外显子7及其两侧内含子的突变研究

为探讨中国苯丙酮尿症（PKU）人群中苯丙氨酸羟化酶（PAH）基因外显子7的突变特征,对147例PKU患儿的294个PAH基因外显子7以及两侧部分内含子序列,应用PCR－单链构象多态性（SSCP）分析及基因序列分析的方法进行了筛查和确定。共发现13种突变基因：G239D、R241C、R241fs、R243Q、G247S、G247V、R252Q、L255S、R261Q、M276K、E280G、P281L、Ivs7+2T>A,其中7 种突变基因在中国PKU人群首次发现：G239D 、R241fs 、G247S 、E280G、L255S、R261Q、P281L,前4种在国际上尚未见到报道,并已提交到国际PAH突变数据库（www.pahdb.mcgill.ca）。突变基因的总频率为30.61%（90 /294）。突变涉及了错义、缺失、移码和剪接位点4种突变类型。结果明确了PAH基因外显子7的突变种类和分布等特征,表明外显子7是中国人PAH基因突变的热点区域。 Abstract: To study mutation in exon 7 of the gene for the phenylalanine hydroxylase（PAH）, the mutations in exon 7 and flanking sequence of PAH gene were detected by means of SSCP analysis and DNA sequencing, in 147 unrelated Chinese children with phynelketonuria and their parents. Thirteen different mutations, including 11 missense, 1 deletion and 1 splice mutation, were revealed in 90/294 mutant alleles (30.61%). The prevalent mutations were R243Q (22.8%) and Ivs7nt2t->a (2.38%). Seven novel mutations were identified: G239D, R241fsdelG, G247S, E280G, L255S, R261Q, P281L. These new mutations have not been described in Chinese PKU population and the first 4 mutants have not been reported and thus been submitted to www.pahdb,mcgill.ca. The missense was the most common type. The deletion and frameshift mutations were detected for the first time in Chinese PKU population. This study showed the mutation characteristics and their distribution in exon 7 of PAH gene and proved that the exon 7 was the hot region of PAH gene mutation in Chinese PKU population .     

The PKU mutation S349P causes complete loss of catalytic activity in the recombinant phenylalanine hydroxylase enzyme

The mutation S349P in exon 10 of the phenylalanine hydroxylase (PAH) gene was identified in one Norwegian and one Polish phenylketonuria (PKU) allele on a haplotype 1.7 background. This missense mutation in PAH codon 349 is a T to C transition in cDNA position 1267. This mutation has been reported both on haplotype 1 and 4, suggesting recurrent mutation. In two different expression systems, the pET and the pMAL systems of Escherichia coli, it was shown that the S349P mutation, introduced by site directed mutagenesis, results in complete loss of enzymatic activity. Thus, protein instability alone does not seem to be the direct cause of the lack of activity of this PKU mutation as previously reported.We have identified mutations in the PAH gene of 118 PKU patients in Norway. To obtain information about how the different mutations affect the catalytic properties of the PAH enzyme we have used two prokaryotic expression systems.We detected the mutation S349P (Forrest et al. 1991) in one Norwegian patient and one of Polish ancestry. This mutation has previously been reported on haplotype 4 in North-African Jews (Weinstein et al. 1993), and on haplotype 1 in French-Canadians (John et al. 1992) and in Danes (Guldberg et al. 1993a). Here we present gene expression data showing that the recombinant mutant enzyme has no measurable residual catalytic activity.     

The identification of two mis-sense mutations at the PAH gene locus in a Turkish patient with phenylketonuria

Summary DNA sequence analysis of the 13 exons and intron/exon boundaries of the phenylalanine hydroxylase (PAH) gene has detected two base transitions, resulting in mis-sense mutations, in the genomic DNA of a Turkish patient (E1) with phenylketonuria (PKU). The Leu⁴⁸Ser amino acid substitution was associated with the mutant haplotype 3 allele and the Glu²²¹Gly amino acid substitution with the mutant haplotype 4 allele of this family. Allele-specific oligonucleotide (ASO) dotblot analysis subsequently detected the Leu⁴⁸Ser mutation in the haplotype 4 PKU alleles of nine (18.8%) of the 48 unrelated Caucasian PKU families investigated. This mutation results in mild PKU in the homozygous state. The Glu²²¹Gly mutation has only been detected within patient E1 and his father.     

Novel compound heterozygous mutations for lipoprotein lipase deficiency. A G-to-T transversion at the first position of exon 5 causing G154V missense mutation and a 5' splice site mutation of intron 8.

We systematically investigated the molecular defects causing a primary LPL deficiency in a Japanese male infant (patient DI) with fasting hyperchylomicronemia (type I hyperlipoproteinemia) and in his parents. Patient DI had neither LPL activity nor immunoreactive LPL mass in the pre- and post-heparin plasma. The patient was a compound heterozygote for novel mutations consisting of a G-to-T transversion at the first nucleotide of exon 5 [+1 position of 3' acceptor splice site (3'-ass) of intron 4] and a T-to-C transition in the invariant GT at position +2 of the 5' donor splice site (5'-dss) of intron 8 (Int8/5'-dss/t(+2)c). The G-to-T transversion, although affecting the 11 nucleotide of the 3'-consensus acceptor splice site, resulted in a substitution of Gly(154) to Val (G154V; GG(716)C(-->)GTC). The mutant G154V LPL expressed in COS-1 cells was catalytically inactive and hardly released from the cells by heparin. The Int8/5'-dss/t(+2)c mutation inactivated the authentic 5' splice site of intron 8 and led to the utilization of a cryptic 5'-dss in exon 8 as an alternative splice site 133 basepairs upstream from the authentic splice site, thereby causing joining of a part of exon 8 to exon 9 with skipping of a 134-bp fragment of exon 8 and intron 8. These additional mutations in the consensus sequences of the 3' and 5' splice sites might be useful for better understanding the factors that are involved in splice site selection in vivo.     

Phenylalanine hydroxylase gene: novel missense mutation in exon 7 causing severe phenylketonuria.

By direct sequence analysis of 94 mutant phenylalanine hydroxylase alleles using polymerase chain reaction-based techniques, we identified a C to T transition in exon 7 of the human phenylalanine hydroxylase gene that is associated with RFLP haplotypes 1 and 4. A leucine for proline substitution at position 281 can be predicted from the nucleotide sequence of the mutant codon. Expression analysis in cultured mammalian cells after site-directed mutagenesis proved that the base substitution is a disease causing gene lesion. Dot-blot hybridization analysis using allele-specific oligonucleotides revealed that 25% of all mutant haplotype 1 alleles in the German population bear this mutation. In addition, this mutation could be detected on one mutant haplotype 4 allele. The fact that this mutation is associated with only 25% of all mutant haplotype 1 alleles suggests that multiple mutations may be associated with this haplotype. The occurrence of several different mutations would be in agreement with the clinical heterogeneity observed in the group of patients whose PKU alleles belong to haplotype 1.