A 3-base pair in-frame deletion of the phenylalanine hydroxylase gene results in a kinetic variant of phenylketonuria.

Phenylketonuria (PKU) is an autosomal recessive disease due to deficiency of a hepatic enzyme, phenylalanine hydroxylase (PAH). The absence of PAH activity results in typical PKU while persistence of a residual enzyme activity gives rise to variant forms of the disease. We report here a 3-base pair in-frame deletion of the PAH gene (delta 194) in a mild variant, with markedly reduced affinity of the enzyme for phenylalanine (Km = 160 nM), and we provide functional evidence for responsibility of the deletion in the mutant phenotype. Since the deletion was located in the third exon of the gene, which presents no homology with other hydroxylases, we suggest that exon 3 is involved in the specificity of the enzyme for phenylalanine. Finally, since none of the 98 PKU patients tested were found to carry this particular deletion, our study suggests that this molecular event probably occurred recently on the background of a haplotype 2 gene in Portugal.     

Mouse Models of Human Phenylketonuria

Phenylketonuria (PKU) results from a deficiency in phenylalanine hydroxylase, the enzyme catalyzing the conversion of phenylalanine (PHE) to tyrosine. Although this inborn error of metabolism was among the first in humans to be understood biochemically and genetically, little is known of the mechanism(s) involved in the pathology of PKU. We have combined mouse germline mutagenesis with screens for hyperphenylalaninemia to isolate three mutants deficient in phenylalanine hydroxylase (PAH) activity and cross-reactive protein. Two of these have reduced PAH mRNA and display characteristics of untreated human PKU patients. A low PHE diet partially reverses these abnormalities. Our success in using high frequency random germline point mutagenesis to obtain appropriate disease models illustrates how such mutagenesis can complement the emergent power of targeted mutagenesis in the mouse. The mutants now can be used as models in studying both maternal PKU and somatic gene therapy.     

L-[1-13C] phenylalanine breath test results reflect the activity of phenylalanine hydroxylase in carbon tetrachloride acute injured rat liver

L-[1-13C] phenylalanine breath tests (PheBTs) have been used to determine the hepatocyte functional capacity of patients. This study investigated the relationship between the PheBT parameter 13C excretion rate constant (PheBT-k) and activity of the phenylalanine metabolic rate-limiting enzyme phenylalanine hydroxylase (PAH) in rat liver. We noted that the time-course curves of 13C excretion presented as a single peak, which appeared 2 min after administration of L-[1-13C] phenylalanine (13C-Phe). 13C excretion during exhalation can be divided into a slow phase and a rapid phase. The PheBT-k in rats with carbon tetrachloride acute liver injury was.significantly lower than that of control rats. The rapid phase 13C disposition constants of the acute liver injured rats did not differ from that of the controls. The peak value of 13C abundance in the breath of the acute liver injured rats was markedly higher than that of the control group. Total liver PAH activity in the acute liver injured rats was significantly lower than that in the control group. PheBT-k was highly correlated with the total activity of liver PAH (r = 0.92, P < 0.001). The present findings indicate that PheBT results reflect PAH activity levels. The PheBT-k parameter is a sensitive index that can be used to evaluate PAH function in the liver. In addition we demonstrated that the rodent model used in this study is a valuable tool for basic research studies of the breath test.     

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.     

Rapid single-base mismatch detection in genotyping for phenylketonuria

Phenylketonuria (PKU) is a metabolic disorder that results from a deficiency of hepatic phenylalanine hydroxylase (PAH). Identification of the PKU genotype is useful for predicting clinical PKU phenotype. More than 400 mutations resulting in PAH deficiency have been reported worldwide. We used a genedetecting instrument to identify the nine prevalent Japanese mutations in the PAH gene among 31 PKU patients as a preliminary study. This instrument can automatically detect mutations through the use of allele-specific oligonucleotide (ASO) capture probes, and gave results comparable to those of sequencing studies. Each country has uniquely prevalent and specific mutations causing PKU, and less than 50 types of such mutations are generally present in each country. Early genotyping of PKU makes it possible to identify the phenotype and select the optimal therapy for the disease. For early genotyping, the instrumental method described here shortens the time required for genotyping based on mRNA and/or genomic DNA of PKU parents.     

Role of Catalase and Superoxide Dismutase Activities on Oxidative Stress in the Brain of a Phenylketonuria Animal Model and the Effect of Lipoic Acid

Phenylketonuria (PKU) is an inherited metabolic disorder caused by deficiency of phenylalanine hydroxylase which leads to accumulation of phenylalanine and its metabolites in tissues of patients with severe neurological involvement. Recently, many studies in animal models or patients have reported the role of oxidative stress in PKU. In the present work we studied the effect of lipoic acid against oxidative stress in rat brain provoked by an animal model of hyperphenylalaninemia (HPA), induced by repetitive injections of phenylalanine and α-methylphenylalanine (a phenylalanine hydroxylase inhibitor) for 7 days, on some oxidative stress parameters. Lipoic acid prevented alterations on catalase (CAT) and superoxide dismutase (SOD), and the oxidative damage of lipids, proteins, and DNA observed in HPA rats. In addition, lipoic acid diminished reactive species generation compared to HPA group which was positively correlated to SOD/CAT ratio. We also observed that in vitro Phe inhibited CAT activity while phenyllactic and phenylacetic acids stimulated superoxide dismutase activity. These results demonstrate the efficacy of lipoic acid to prevent oxidative stress induced by HPA model in rats. The possible benefits of lipoic acid administration to PKU patients should be considered.     

Functional Characterization of Novel Phenylalanine Hydroxylase p.Gln226Lys Mutation Revealed Its Non-responsiveness to Tetrahydrobiopterin Treatment in Hepatoma Cellular Model

Treatment with tetrahydrobiopterin (BH4) is the latest therapeutic option approved for patients with phenylketonuria (PKU)—one of the most frequent inborn metabolic diseases. PKU or phenylalanine hydroxylase (PAH) deficiency is caused by mutations in the PAH gene. Given that some PAH mutations are responsive to BH4 treatment while others are non-responsive, for every novel mutation that is discovered it is essential to confirm its pathogenic effect and to assess its responsiveness to a BH4 treatment in vitro, before the drug is administered to patients. We found a c.676C>A (p.Gln226Lys) mutation in the PAH gene in two unrelated patients with PKU. The corresponding aberrant protein has never been functionally characterized in vitro and its response to BH4 treatment is unknown. Computational analyses proposed that glutamine at position 226 is an important, evolutionary conserved amino acid while the substitution with lysine probably disturbs tertiary protein structure and impacts posttranslational PAH modifications. Using hepatoma cellular model, we demonstrated that the amount of mutant p.Gln226Lys PAH detected by Western blot was only 1.2% in comparison to wild-type PAH. The addition of sepiapterin, intracellular precursor of BH4, did not increase PAH protein yield thus marking p.Gln226Lys as BH4-non-responsive mutation. Therefore, computational, experimental, and clinical data were all in accordance showing that p.Gln226Lys is a severe pathogenic PAH mutation. Its non-responsiveness to BH4 treatment in hepatoma cellular model should be considered when deciding treatment options for PKU patients carrying this mutation. Consequently, our study will facilitate clinical genetic practice, particularly genotype-based stratification of PKU treatment.     

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.     

The Missense p.S231F Phenylalanine Hydroxylase Gene Mutation Causes Complete Loss of Enzymatic Activity In Vitro

Phenylketonuria (PKU), the most frequent disorder of amino acid metabolism, is caused by mutations in human phenylalanine hydroxylase gene (PAH), leading to deficient enzyme activity. Previously reported but uncharacterized PAH gene mutation, p.S231F (c.692C > T), was detected in Serbian patients with classical PKU. We analyzed p.S231F PAH protein in prokaryotic (Escherichia coli) and eukaryotic expression system (hepatoma cells). In both systems the mutant enzyme was unstable. Residual enzyme activity in vitro was ~1%. Mutation p.S231F PAH was not activated by pre-incubation with phenylalanine substrate. We found no GroEL/GroES chaperone effect and slightly positive effect of the (6R)-l-erythro-5,6,7,8-tetrahydrobiopterin (BH₄) on the stabilization of the protein structure. Our findings were in accordance with severe patients’ phenotypes. In conclusion, p.S231F should be classified as a functionally null PAH gene mutation as it drastically reduces stability and activity of the PAH enzyme in vitro.     

DNA haplotype analyses of patients with hyperphenylalaninemia.

Linkage analysis of phenylketonurics has shown a strong association between the DNA haplotype at the phenylalanine hydroxylase (PAH) locus and phenylketonuria (PKU). Similarly, a genetic linkage between less severe forms of hyperphenylalaninemia (HPA) and the PAH locus has been suggested. In the present study we analyzed this linkage in more detail. Haplotypes at the PAH locus were determined for 19 individuals with moderately elevated plasma phenylalanine and normal urinary neopterin/biopterin ratios. Fourteen of these individuals had plasma phenylalanine levels of 4-10 mg/dl (mild HPA), and the other five had plasma phenylalanine levels of 10-19 mg/dl (atypical PKU). Thirteen of the 15 HPA families consisted of an affected child and at least one other sibling. Elevated plasma phenylalanine was seen to genetically segregate with specific PAH alleles in each family. Summation of the LOD scores for both categories of moderate plasma phenylalanine elevation gave a maximum value of 3.556 at theta = 0. At theta = 0 this gives a probability of linkage between the PAH locus and the locus for moderate phenylalanine elevations that is approximately 3,600:1. None of the alleles segregating with either mild HPA or atypical PKU were of haplotype 2 or 3, and 13/20 were of types 1 or 4. This is in agreement with the most deleterious mutations being on haplotypes 2 and 3 and with the less severe mutations being on haplotypes 1 and 4. chi 2 Analyses indicated no statistically significant correlation between HPA and a particular haplotype or restriction-enzyme site.     

Mutations in the regulatory domain of phenylalanine hydroxylase and response to tetrahydrobiopterin

Tetrahydrobiopterin (BH4) is a co-factor that enhances the activity of other enzymes, and this co-factor level is found to be affected in phenylketonuria (PKU), an amino acid metabolism disorder. The present study was aimed at understanding the effect of BH4 on mutations in the regulatory domain of phenylalanine hydroxylase (PAH). Among 14 patients, 5 patients were classical PKU, 3 were atypical PKU, and 6 were mild PKU. All of these patients had at least one mutation in the regulatory domain. Patients were given 10 mg/kg BH4, and the response of blood phenylalanine (Phe) levels was monitored following treatment. The level of blood Phe decreased after BH4 treatment in all of the patients. These studies suggest that mutations in the regulatory domain also responded to BH4 even if the patient had classical PKU.     

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.     

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.     

Predicted effects of missense mutations on native-state stability account for phenotypic outcome in phenylketonuria, a paradigm of misfolding diseases

Phenylketonuria (PKU) is a genetic disease caused by mutations in human phenylalanine hydroxylase (PAH). Most missense mutations result in misfolding of PAH, increased protein turnover, and a loss of enzymatic function. We studied the prediction of the energetic impact on PAH native-state stability of 318 PKU-associated missense mutations, using the protein-design algorithm FoldX. For the 80 mutations for which expression analyses have been performed in eukaryote systems, in most cases we found substantial overall correlations between the mutational energetic impact and both in vitro residual activities and patient metabolic phenotype. This finding confirmed that the decrease in protein stability is the main molecular pathogenic mechanism in PKU and the determinant for phenotypic outcome. Metabolic phenotypes have been shown to be better predicted than in vitro residual activities, probably because of greater stringency in the phenotyping process. Finally, all the remaining 238 PKU missense mutations compiled at the PAH locus knowledgebase (PAHdb) were analyzed, and their phenotypic outcomes were predicted on the basis of the energetic impact provided by FoldX. Residues in exons 7-9 and in interdomain regions within the subunit appear to play an important structural role and constitute hotspots for destabilization. FoldX analysis will be useful for predicting the phenotype associated with rare or new mutations detected in patients with PKU. However, additional factors must be considered that may contribute to the patient phenotype, such as possible effects on catalysis and interindividual differences in physiological and metabolic processes.     

Phenylketonuria in Iranian population: a study in institutions for mentally retarded in Isfahan

Phenylalanine hydroxylase (PAH) deficiency is caused by mutations in the PAH gene (12q22-q24) resulting in a primary deficiency of the PAH enzyme activity, intolerance to the dietary intake of phenylalanine (Phe) and production of the phenylketonuria (PKU) disease. To date there have been no reports on the molecular analysis of PKU in Iranian population. In this study, the states of the PKU disease in terms of prevalence and mutation spectrum among patients reside in the institutions for mentally retarded in Isfahan was investigated. In the first step, 611 out of 1541 patients with PKU phenotype or severe mental retardation were screened for the PKU disease using the Guthrie bacterial inhibition assay (GBIA) followed by HPLC. Among the patients screened 34 (5.56%) were found positive with abnormal serum Phe of above 7mg/dl. In the next step, the presence of 18 common mutations of the PAH gene in 26 of the patients with classical PKU (serum Phe above 20mg/dl) was investigated, using the polymerase chain reaction restriction fragment length polymorphism (PCR-RFLP). Of the 52 independent mutant alleles that were analyzed, 34 (65.38%) were genotyped showing 8 mutations as follows: R252W (15.38%), Q232Q (13.46%), R261Q (7.69%), delL364 (7.69%), IVS10-11g>a (5.77%), L333F (5.77%), V245V (5.77%) and S67P (3.85%). The results from this study may serve as a reference to analyze the PKU mutations in other part of Iran, and to establish diagnostic tests for carrier detection and prenatal diagnosis of the PKU disease in Iranian population.     

Mutational spectrum of phenylalanine hydroxylase deficiency in the population resident in Catalonia: genotype-phenotype correlation

Hyperphenylalaninemia (HPA) is a group of diseases characterized by the persistent elevation of phenylalanine levels in tissues and biological fluids. It is an autosomal recessive disorder affecting 1 in 10,000 individuals in Caucasian populations and about 1 in 6,600 in Catalonia. We report the mutational spectrum of phenylalanine hydroxylase deficiency in the population living in Catalonia and the genotype-phenotype correlation. The molecular study was performed in 383 samples corresponding to 115 patients from 99 unrelated families and 268 relatives. We have characterized 90% of the mutant alleles; there were 57 different mutations, 49 of which have previously been described, 8 being novel mutations and two being large deletions. The 57 mutations detected corresponded to: five nonsense, seven frameshift, and eight splice defects, the remainder being missense mutations. These mutations cause 72 different genotypes in the 83 families characterized, confirming the mutational heterogeneity of phenylketonuria (PKU) in the Mediterranean population. According to our biochemical classification, our HPA population is composed of 40 PKU (35%), 36 variant PKU (31%), and 39 non-PKU HPA (34%). Mutations such as IVS 10, A403 V, and E390G correlated as expected with the phenotype and the predicted residual activity in vitro. However, in four cases (165 T, V388 M, R261Q, and Y414 C), the observed metabolic phenotype was not consistent with the predicted genotypic effect. The identification of the mutations in the PAH gene and the genotype-phenotype correlation should facilitate the evaluation of metabolic phenotypes, diagnosis, implementation of optimal dietary therapy, and determination of prognosis in the patients and genetic counselling for the patient's relatives.     

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.     

Predicting a clinical/biochemical phenotype for PKU/MHP patients with PAH gene mutations

Phenylketonuria (PKU) and mild hyperphenylalaninemia (MHP) are allelic disorders caused by mutations in the gene encoding phenylalanine hydroxylase (PAH). In this study, a total of 218 independent PAH chromosomes (109 unrelated patients with PKU residing in Lithuania) were investigated. All 13 exons of the PAH gene of all PKU probands were scanned for DNA alterations by denaturing gradient gel electrophoresis (DGGE). In the cases of a specific DGGE pattern recognized, mutations were identified by direct fluorescent automated sequencing or by restriction enzyme digestion analysis of relevant exons. Twenty-five different PAH gene mutations were identified in Lithuania. We estimated a connection between individual PAH locus mutations and biochemical and metabolic phenotypes in patients in whom the mutant allele acts on its own, i.e., in functionally hemizygous patients and using the assigned value (AV) method to determine the severity of both common and rare mutant alleles, as well as to check a model to predict the combined phenotypic effect of two mutant PAH alleles. The text was submitted authors English.