Genotype and phenotype correlation of phenylalanine hydroxylase deficiency among patients from Henan北大核心CSCD

Objective: To delineate the mutation spectrum of phenylalanine hydroxylase (PAH) gene among patients affected with phenylalanine hydroxylase deficiency (PAHD) in Henan Province of China, and to explore the correlation between the genotype and the phenotype. Methods: A total of 155 affected children were recruited. Potential mutation of the PAH gene were analyzed by direct sequencing. The genotype - phenotype correlation was analyzed by matching the expected and observed phenotypes. Results: Over 72 mutations and 108 genotypes have been identified. There were 7 homozygous mutations, including 1 case with EX6-96A>G/EX6-96A>G, 1 with R241C/R241C, 1 with R413P/R413P, and 4 with R243Q/R243Q. Among these, 6 patients have presented classic PKU phenotypes, except for a R241C/R241C genotype which has led to mild PKU. In 104 patients carrying compound PAH mutations, 52 were classic, 34 were mild and 39 had mild HPA. Patients who were heterozygous for EX6-96A>G/R241C, R243Q/A434D, EX6-96A>G/R413P and EX6-96A>G/ R241C were found with both the classic PKU and mild PKU phenotypes. Common mutations associated with mild HPA have included R53H, R243Q, V399V and H107R. The common mutations associated with mild PKU included R243Q, R241C, EX6-96A>G, and IVS4-1G>A. The prevalent mutations in classic PKU were R243Q, EX6-96A>G and V399V. The consistency between prediction of the biochemical genotype and observed phenotype was 77.78%, especially in classic PKU, the consistency was up to 82.14%. Significant correlations were disclosed between pretreatment levels of phenylalanine and AV sum (r= -0.6729, P<0.01). Conclusion: The mutation spectrum of PAH gene in Henan seems to differ from that of other regions. Independent assortment of mutant alleles may result in a complex genotype-phenotype correlation, but the genotypes of PAHD patients have correlated with the phenotype. © 2016, West China University of Medical Sciences. All rights reserved.     

Non-phenylketonuria hyperphenylalaninaemia in Northern Ireland: Frequent mutation allows screening and early diagnosis

Up to 10% of newborn children with a positive Guthrie test have non-phenylketonuria hyperphenylalaninaemia, i.e., mild elevation of serum phenylalanine that does not require dietary treatment. Depending on the relative frequencies of different phenylalanine hydroxylase mutations in a particular population, non-PKU HPA is usually caused by the combined effect of a mild HPA mutation and a severe PKU mutation. Presented here is a comprehensive analysis of non-PKU HPA in Northern Ireland. Of particular interest is one prevalent HPA mutation (T380M), which is present in over 70% of non-PKU HPA patients in Northern Ireland. Screening for this mutation is easy and inexpensive and can help confirm the diagnosis of non-PKU hyperphenylalaninaemia in the majority of cases at a very early stage. This may be clinically useful and reassuring for the parents. Other mutations described are V245A, L194P, and E390G. © 1994 Wiley-Liss, Inc.     

PAH gene mutations in the Sicilian population: association with minihaplotypes and expression analysis.

The molecular basis of PAH deficiency in the Sicilian population is characterized by a marked heterogeneity, with 44 mutations at a single locus identified by a "gene-scanning" approach and accounting for a detection rate of 91%. The remaining 9% of PAH alleles does not bear mutations in any of the 13 exons and 24 exon/intron junctions. Three mutations IVS10nt-11 G > A, R261Q, and A300S accounted for 30.5%, whereas the remaining mutations were found at relative frequencies of less than 5% and 20 mutations were observed once only. Five mutations have been detected only in Sicilians so far. By studying the association of mutations with intragenic STR-VNTR haplotypes ("minihaplotypes"), "identity by descent" has been established for 24 mutations also detected in other populations. This finding supports the hypothesis of a multipolar origin for a large proportion of PAH mutant alleles currently detected in Sicilians. In order to improve our understanding of the clinical heterogeneity of PAH deficiency in this population, we have for the first time analyzed three missense mutations L41F, T92I, and P211T in vitro by the pCDNA3/COS-7 eukaryotic expression system and found an activity of 10, 76, and 72%, respectively, compared to normal PAH. In two HPA patients with mild PKU and mild hyperphenylalaninemia (MHP), harboring respectively L41F/R261Q and T92I/P281L genotypes, the predicted biochemical effect of these genotypes appeared to be consistent with the metabolic phenotypes. In contrast, discordant metabolic phenotypes (mild PKU and MHP) were observed in two unrelated patients bearing the same R261Q/P211T genotype, a finding which underscores the complex relationship linking genotype to phenotype in PAH deficiency. Hypotheses on the possible mechanisms responsible for the observed discordance are discussed. The spectrum of PAH gene mutations in Sicily reflects the complex demographic history of this island at the crossroad of prehistoric and historical migrations in the Mediterranean sea. The data presented in this study also add to the present knowledge on the relationship between PAH genotypes and HPA phenotype and are expected to improve PAH genotyping among individuals with hyperphenylalaninemia.     

Two missense mutations causing mild hyperphenylalaninemia associated with DNA haplotype 12.

The genetic defects responsible for most phenylketonuria (PKU) and hyperphenylalaninemia (HPA) cases are located in the phenylalanine hydroxylase (PAH) gene. Approximately 50-60 mutations have been reported in Caucasians and are reflected in a wide range of clinical severities. Most mutations are linked to specific haplotypes, as defined by eight polymorphic restriction sites in the PAH gene. We hypothesized that there is at least one mild mutation linked to haplotype 12 in the Swedish PKU/HPA population, since 7 of 8 patients carrying haplotype 12 had mild HPA. Sequence analysis revealed a C-to-G transversion at the second base of codon 322, resulting in a substitution of glycine for alanine, in four mutant haplotype 12 genes, and a G-to-A transition at the second base of codon 408, resulting in a substitution of glutamine for arginine, in another three mutant haplotype 12 genes. These mutations segregated with mutant haplotype 12 alleles in nuclear families but were not present on normal or other mutant alleles. Both mutations were tested in a eukaryotic expression system in which enzyme activities of different mutant PAH enzymes reflect the relative severities of the mutations, although these in vitro activities cannot be translated directly into in vivo hepatic activities. The A322G mutant PAH had about 75% and the R408Q mutant PAH about 55% of the wild-type PAH enzyme activity. These in vitro activities are the highest reported for mutant PAH enzymes produced in the same expression system.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular Epidemiology of Phenylalanine Hydroxylase Deficiency in Southern Italy: a 96% Detection Rate with Ten Novel Mutations

Hyperphenylalaninemia (HPA) comprises a group of autosomal recessive disorders mainly caused by phenylalanine hydroxylase ( PAH ) gene mutations. We investigated PAH mutations in 126 HPA patients from Southern Italy who were identified in a neonatal screening program. The promoter, coding and exon-flanking intronic sequences of the PAH gene were amplified and sequenced. Mutations were identified in 240/249 alleles (detection rate: 96.4%). We found 60 gene variants; the most frequent were p.R261Q (15.7% of alleles), p.A403V (11.6% of alleles) and c.1066-11G > A (8.8% of alleles). The remaining mutations were rare, and ten are novel. This mutation epidemiology differs from that reported for Northern Italy and other European countries. We also identified several discordant genotype/phenotype correlations. About two-thirds of all mild phenylketonuria patients showed at least one tetrahydrobiopterin (BH₄)-responsive mutation, and are thus candidates for a customized therapeutic approach.     

Three prevalent mutations in a patient with phenylalanine hydroxylase deficiency: implications for diagnosis and genetic counselling.

Mutation analysis in a patient with mild hyperphenylalaninaemia showed three distinct base substitutions in exon 12 of the phenylalanine hydroxylase (PAH) gene. All three mutations, R413P, Y414C, and D415N, have previously been described as being independently associated with PAH deficiency. Family studies and independent analysis of the PAH alleles of the patient showed cosegregation of the R413P and Y414C mutations. Data on the ethnic background of the family provide evidence that the R413P mutation has occurred on a PAH allele carrying the Y414C mutation. Using current methods for mutation identification, the presence of two known mutations on a single PAH allele implies the risk of misdiagnosis of PAH deficiency and complicates genetic counselling. Our results stress the need for comprehensive mutation scanning of the PAH gene in diagnostic settings.     

Molecular analysis of phenylketonuria (PKU) in newborns from Texas

This study describes the mutations at the phenylalanine hydroxylase (PAH) locus in patients with the diagnosis of classic PKU (n=18), hyperphenylalaninemia (HPA) variant (n=9) and benign persistent hyperphenylalaninemia (HPA) (n=13) who were identified by the Texas Newborn Screening Program. Blinded studies were done by sequencing of the 13 exons and exon-intron boundaries of the PAH gene in genomic DNA isolated from dry blood spots. Thirty-six different mutations, including 25 missense mutations, six splice mutations, three deletions and two nonsense mutations were detected in 75 of the 80 mutant alleles (94%). The prevalent mutations were R408W (19%), V388M and IVS10nt-11g->a (6% each), Y414C (5%) and H170D, A403V, T380M and IVS7nt1g->a (4% each). Two novel missense mutations were identified in exon 5 (H170D and N167S). There was genotype/phenotype correlation in 33/40 cases (83%). For this population, exons 12, 11, 7, 5 and 8, which carry 78% of the mutations, would have to be screened first. However, the other exons must be studied when either one or no mutations are found in the primary screening. Hum Mutat 17:523, 2001.     

Two novel genetic lesions and a common BH4-responsive mutation of the PAH gene in Italian patients with hyperphenylalaninemia

Hyperphenylalaninemia (HPA), due to a deficiency of phenylalanine hydroxylase (PAH) enzyme, is caused by mutations in the PAH gene. Molecular analysis in 23 Italian patients with PAH deficiency identified two novel (P281R, L287V) and 20 previously described genetic lesions in the PAH gene. The detection of the A403V amino acid substitution in combination with null mutations in patients with BH4-responsive PAH deficiency leads us to correlate it with BH4 responsiveness.     

Allelic phenotype values: a model for genotype-based phenotype prediction in phenylketonuria

PurposeThe nature of phenylalanine hydroxylase (PAH) variants determines residual enzyme activity, which modifies the clinical phenotype in phenylketonuria (PKU). We exploited the statistical power of a large genotype database to determine the relationship between genotype and phenotype in PKU.MethodsA total of 9336 PKU patients with 2589 different genotypes, carrying 588 variants, were investigated using an allelic phenotype value (APV) algorithm.ResultsWe identified 251 0-variants encoding inactive PAH, and assigned APVs (0 = classic PKU; 5 = mild PKU; 10 = mild hyperphenylalaninaemia) to 88 variants in PAH-functional hemizygous patients. The genotypic phenotype values (GPVs) were set equal to the higher-APV allele, which was assumed to be dominant over the lower-APV allele and to determine the metabolic phenotype. GPVs for 8872 patients resulted in cut-off ranges of 0.0–2.7 for classic PKU, 2.8–6.6 for mild PKU and 6.7–10.0 for mild hyperphenylalaninaemia. Genotype-based phenotype prediction was 99.2% for classic PKU, 46.2% for mild PKU and 89.5% for mild hyperphenylalaninaemia. The relationships between known pretreatment blood phenylalanine levels and GPVs (n = 4217), as well as tetrahydrobiopterin responsiveness and GPVs (n = 3488), were significant (both P < 0.001).ConclusionsAPV and GPV are powerful tools to investigate genotype–phenotype associations, and can be used for genetic counselling of PKU families.     

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.     

Phenylketonuria: variable phenotypic outcomes of the R261Q mutation and maternal PKU in the offspring of a healthy homozygote.

Phenylketonuria (PKU) and benign hyperphenylalaninaemia (HPA) result from a variety of mutations in the gene for the hepatic enzyme phenylalanine hydroxylase. PKU has been found in the Israeli population in two variants, classical and atypical. The two are clinically indistinguishable and require treatment with low phenylalanine diet to prevent mental retardation, but show differences in serum phenylalanine levels and in tolerance to this amino acid. Maternal PKU is a syndrome of congenital anomalies and mental retardation that appears in offspring of PKU mothers as a result of fetal exposure to the high phenylalanine level in the maternal blood. We studied a family in which two children with severe, classical PKU and their unaffected brother showed mild signs of maternal PKU. Their mother had no clinical signs of PKU, but the phenylalanine concentration in her serum reached a level that usually characterises PKU patients. This woman represents a rare phenotype, benign atypical PKU. Such 'hidden' PKU in women may lead to maternal PKU in the offspring, similar to overt PKU. Special attention should therefore be paid to women having children with any of the clinical hallmarks of maternal PKU, and to children born to women known to have benign HPA. The mother was also found to be homozygous for a missense mutation at the phenylalanine hydroxylase locus, R261Q, which does not abolish enzymatic activity completely. In two other families, homozygosity for this mutation resulted in atypical PKU in four children. This observation suggests that mutations that do not completely destroy phenylalanine hydroxylase activity may exhibit variable phenotypic expression which is unpredictable. Compound heterozygosity for R261Q and other mutations led in other patients either to classical PKU or to mild benign HPA.     

Discordant phenylketonuria phenotypes in one family: the relationship between genotype and clinical outcome is a function of multiple effects.

Four members spanning three generations of one family have phenylketonuria of varying degrees of severity. Two first cousins were screened in the neonatal period and have had dietary phenylalanine restriction since diagnosis, the older patient having been classified as having more severe PKU and the younger one as having mild PKU. Their mutual grandfather and his older brother also have a significant hyperphenylalaninaemia and are of normal intelligence despite never having had restricted phenylalanine intake. Mutation analysis of the phenylalanine hydroxylase (PAH) gene has established that there are four different mutations, two in exon 2 (F39L and L48S) and two in exon 3 (R111X and S67P), which give rise to PKU in this family. In order to establish their relative severity, we screened the PKU populations of western Scotland and the south west of England for these mutations. The exon 3 mutations are rare; however, F39L is relatively common in Scotland and L48S in England. A comparison of diagnostic blood phenylalanine concentrations in subjects carrying L48S/null or F39L/null mutations with those carrying two null mutations suggest that these exon 2 mutations are less deleterious. Thus, in this family, the different biochemical phenotypes can be explained, in part, by different genotypes at the PAH locus but our results show that the relationship between genotype and clinical outcome is more complex and is a function of multiple effects.     

河南地区苯丙酮尿症患者苯丙氨酸羟化酶基因突变研究

目的 了解河南地区苯丙酮尿症(phenylketonuria,PKU)患者苯丙氨酸羟化酶(phenylalanine hydroxylase,PAH)基因突变情况,以便为苯丙酮尿症产前诊断和遗传咨询提供理论依据.方法 应用PCR产物直接测序对47例PKU患者及其父母PAH基因第1～13外显子及其两侧内含子进行序列分析.结果 在94条染色体中共检测到了83个PAH基因突变位点,检出率为88.3%(83/94),共发现了25种突变,其中突变E79fX13、H271R和D415Y国内外未见报道,突变VS10-14C＞G为国内首次报道.河南地区PKU患者的PAH基因突变集中在第6、7和11外显子,常见的7种突变是p.R243Q(20.5%)、EX6-96A＞G(12.0%)、p.Y356X(9.6%)、VS4-1G＞A(9.6%)、p.R111X(8.4%)、p.V399V(8.4%)、p.R413P(7.2%).结论 河南地区PKU患者PAH基因突变与中国其他地区相似,通过PAH基因直接测序可对大部分的PKU家系进行产前诊断.

Abstract：

Objective To study the characteristics of the phenylalanine hydroxylase gene (PAH)mutations in patients with phenylketonuria (PKU) in Henan province, in order to provide basic information for genetic counseling and prenatal diagnosis. Methods Mutations of the PAH gene were detected in exons 1-13 with flanking introns of PAH gene by PCR and DNA sequencing in 47 families with PKU. Results A total of 25 different mutations were detected in 83 out of 94 PAH alleles (88. 3%). Among them,E79fX13, H271R and D415Y have not been reported previously. It was the first time that IVS10-14C＞Gmutation was reported in Chinese PKU population. The mutations p. R243Q, EX6-96A＞G, p. Y356X,IVS4-1G＞A, p. R111X, p. V399V and p. R413P, were the prevalent mutations with relative frequencies of 20. 5 %, 12.0%, 9.6%, 9. 6%, 8. 4%, 8. 4% and 7.2% respectively. Conclusion The mutations of the PAH gene in patients with classical phenylketonuria in Henan province were similar to that in other areas of China. Prenatal gene diagnosis for PKU by PAH gene sequencing is efficient for most PKU families.     

Mutation spectrum in Taiwanese patients with phenylalanine hydroxylase deficiency and a founder effect for the R241C mutation

The spectrum of phenylalanine hydroxylase (PAH) gene mutations was determined in 25 families of hyperphenylalaninemia identified by a neonatal screening program in Taiwan. The coding sequence and exon-flanking intron sequences of PAH gene were amplified and sequenced. Mutations were identified in forty-five of the 50 chromosomes. R241C was the most common mutation (36% of the chromosomes), followed by R408Q (14% of the chromosomes). The remaining mutations were rare and seven mutations have not been reported before: p.F233L (c.697T>C), p.R252Q (c.756G>A), p.E286K (c.856G>A), p.G312V (c.935G>T), p.P314T (c.940C>A), p.I95del (c.284_286delTCA), and p.T81fsX6 (c.241_256del). Both p.R241C and p.R408Q are classified as mild phenylketonuria (PKU) or mild hyperphenylalaninemia (MHP) mutation, which may explain the fact that classical PKU is very rare in Taiwan (n=4, or one in 413,035). This strong founder effect for the p.R241C mutation has been described neither in the Caucasian populations, nor in other reports from Chinese. Since most of the populations in Taiwan are derived from Southeastern China, the spectrum of PAH gene mutations in Southeastern China should be different from other Chinese populations. This report not only disclose a specific spectrum of PAH gene mutation in Taiwan, but may also give clues to the movement of populations in Mainland China.     

Eight new mutations of the phenylalanine hydroxylase gene in Italian patients with hyperphenylalaninemia

This report identifies eight new mutations of the phenylalanine hydroxylase gene detected in Italian patients with hyperphenylalaninemia. The trivial name of the mutations, predicted phenotypic effect, and population of origin (Italian region) are as follows: F55L (nonconservative change: classic, moderate, mild PKU ?; Sicily), IVS2nt-13 (splicing defect, classic PKU; Tuscany), I65N (nonconservative change classic, moderate, mild PKU ?; Sicily), H201Y (non-PKU HPA; Sicily), I269L (non-PKU HPA, or polymorphism; Sicily), IVS7nt3 (splicing defect or polymorphism; Sicily), I283N (classic PKU; Sicily), IVS12nt2 (splicing defect, classic PKU; Sicily and Apulia). In Sicily, the relative frequency of mutations F55L, I65N, H201Y, I269L, IVS7nt3, I283N, IVS12nt2 is < 1%. The seven new mutations identified in the Sicilian population increase the remarkable genetic heterogeneity typical of this population with an estimated homozygosity value at the PAH locus of 0.041. Hum Mutat 11:240–243, 1998. © 1998 Wiley-Liss, Inc.     

Phenylalanine hydroxylase variants interact with the co‐chaperone DNAJC12

DNAJC12, a type III member of the HSP40/DNAJ family, has been identified as the specific co‐chaperone of phenylalanine hydroxylase (PAH) and the other aromatic amino acid hydroxylases. DNAJ proteins work together with molecular chaperones of the HSP70 family to assist in proper folding and maintenance of intracellular stability of their clients. Autosomal recessive mutations in DNAJC12 were found to reduce PAH levels, leading to hyperphenylalaninemia (HPA) in patients without mutations in PAH. In this work, we investigated the interaction of normal wild‐type DNAJC12 with mutant PAH in cells expressing several PAH variants associated with HPA in humans, as well as in the Enu^1/1 mouse model, homozygous for the V106A‐Pah variant, which leads to severe protein instability, accelerated PAH degradation and mild HPA. We found that mutant PAH exhibits increased ubiquitination, instability, and aggregation compared with normal PAH. In mouse liver lysates, we showed that DNAJC12 interacts with monoubiquitin‐tagged PAH. This form represented a major fraction of PAH in the Enu^1/1 but was also present in liver of wild‐type PAH mice. Our results support a role of DNAJC12 in the processing of misfolded ubiquitinated PAH by the ubiquitin‐dependent proteasome/autophagy systems and add to the evidence that the DNAJ proteins are important players both for proper folding and degradation of their clients.     

Decreased phenylalanine uptake and turnover in patients with vitiligo

The human epidermis has the full machinery for autocrine L-phenylalanine turnover to L-tyrosine in keratinocytes and melanocytes. Phenylalanine hydroxylase (PAH) activities increase linearly with inherited skin colour (skin phototype I-VI, Fitzpatrick classification) yielding eightfold more activities in black skin compared to white skin. Moreover, UVB irradiation (1 MED) significantly increases epidermal PAH activities 24 h after exposure. Importantly, L-phenylalanine uptake and turnover in the pigment forming melanocytes is vital for initiation of melanogenesis. In this context it was shown that the uptake of this amino acid is regulated by calcium. The depigmentation disorder vitiligo provides a unique model to follow impaired L-phenylalanine turnover in the skin as well as in serum because affected individuals hold an impaired epidermal 6BH4 de novo synthesis/recycling and regulation including low epidermal PAH activities. After overnight fasting and oral loading with L-phenylalanine (100 mg/kg body weight), 29.6% of 970 patients tested (n=287/970) yielded serum phenylalanine/tyrosine ratios >or=4 and 35.3% (n=342/970) had mild to moderate hyperphenylalaninaemia (HPA), while 9.3% (n=90/970) had both serum L-phenylalanine levels >or=2.0 mg/dl and phe/tyr ratios >or=4.0. Isolated HPA was found in 26% (n=252/970), whereas 20.3% had only increased ratios (n=197/970). None of the patients had phenylketonuria and the family history for this metabolic disease was negative. The IQ followed normal Gaussian distribution. In vitro L-phenylalanine uptake/turnover studies on primary epidermal melanocytes originating from these patients demonstrated a significantly decreased calcium dependent L-phenylalanine uptake and turnover compared to healthy control cells. Based on our observation, we would like to propose that phenylalanine uptake/turnover is under tight control by calcium which in turn could offer an additional novel mechanism in the aetiology of HPA.     

CFTR genotypes in patients with normal or borderline sweat chloride levels

In recent years, some patients bearing "atypical" forms of cystic fibrosis (CF) with normal sweat chloride concentrations have been described. To identify the spectrum of mutant combinations causing such atypical CF, we collected the results of CFTR (ABCC7) mutation analysis from 15 laboratories. Thirty patients with one or more typical symptoms of the disease associated with normal or borderline sweat chloride levels and bearing two CFTR mutations were selected. Phenotypes and genotypes of these 30 patients are described. A total of 18 different CFTR mutations were observed in the 60 chromosomes analysed. F508del was present in 31.6 % of the mutated chromosomes and 3849+10kbC>T in 13.3 %. R117H, D1152H, L206W, 3272-26A>G, S1235R, G149R, R1070W, S945L, and the poly-T tract variation commonly called IVS8-5T were also observed. The relative frequency of CFTR mutations clearly differed from that observed in typical CF patients or in CBAVD patients with the same ethnic origin. A mild genotype with one or two mild or variable mutations was observed in all the patients. These findings improve our understanding of the distribution of CFTR alleles in CF with normal or borderline sweat chloride concentrations and will facilitate the development of more sensitive CFTR mutation screening.     

Tetrahydrobiopterin sensitivity in German patients with mild phenylalanine hydroxylase deficiency

We report the results of tetrahydrobiopterin (BH4) loading tests in 10 German patients with mild phenylketonuria. A significant decline of phenylalanine values after application of BH4 was observed in all but one patients. Molecular genetic analyses revealed a range of different PAH gene mutations. Re-testing of one patient previously reported as non-responsive to BH4 loading showed a moderate response with a higher dose of BH4. Nevertheless, there appear to be kinetic differences in phenylalanine hydroxylation in patients with the same genotype. Non-responsiveness to 20 mg/kg BH4 was observed only in a single patient who was compound heterozygous for the novel mutation R176P (c.527G>C) and the common null-mutation P281L. In summary, our data are in line with recent reports indicating that BH4 sensitivity is a normal feature of most mild forms of PAH deficiency but may be influenced by other factors.     

The mutant genotype is the main determinant of the metabolic phenotype in phenylalanine hydroxylase deficiency.

Phenylketonuria and mild hyperphenylalaninemias are allelic disorders caused by mutations in the phenylalanine hydroxylase (PAH) gene. Following identification of the disease-causing mutation in 11 PAH-deficient patients, we tested the activity of the mutant gene products in an eukaryotic expression system. Two mutations markedly reduced PAH activity (A259V and L333F), one mutation mildly altered the enzyme activity (E390G), while the majority of mutant genotypes reduced the in vitro expression of PAH activity to 15-30% of controls. Comparing the predicted residual activity derived from expression studies to the clinical phenotypes of our PAH-deficient patients, we found that homozygosity for the L333F and E390G mutations resulted in severe and mild PAH deficiencies, respectively, both in vivo and in vitro, while compound heterozygosity (L333F/E390G) resulted in an intermediate dietary tolerance. Similarly, in vitro expression studies largely predicted dietary tolerance in compound heterozygotes for the A259V/IVS12nt1 (typical PKU), A259V/A403V, G218V/I65T, and G218V/R158Q mutations (mild variants). Taken together, these results support the view that expression studies are useful in predicting residual enzyme activity and that the mutant genotype at the PAH locus is the major determinant of metabolic phenotype in hyperphenylalaninemias.