四氢生物蝶呤反应性苯丙氨酸羟化酶缺乏症在我国南北地区差异的临床初步研究

目的通过对不同类型高苯丙氨酸血症（hyperphenylalaninemia,HPA）临床特点的分析,探讨我国南、北方四氢生物蝶呤（tetrahydrobiopterin,BH4）反应性苯丙氨酸羟化酶（phenylalanine hydroxylase,PAH）缺乏症患者对BH4的反应性。方法（1）108例HPA患儿,男63例、女45例,平均年龄7.05个月。所有患者都进行口服BH4负荷试验,同时进行尿蝶呤谱分析、红细胞二氢蝶啶还原酶测定。对其中血苯丙氨酸（phenylalanine,Phe）浓度〈600μmol/L者给予口服Phe-BH4联合负荷试验。（2）根据患儿父母双方祖籍,以长江为界将诊断为BH4反应性PAH缺乏症的患儿分为南、北两组。比较南、北方组BH4反应性PAH缺乏症患儿在BH4负荷试验中血Phe浓度的变化。结果（1）HPA中诊断BH4反应性PAH缺乏症36人（33.3%）,BH4无反应性苯丙酮尿症（phenlketonuria,PKU）49人（45.4%）,四氢生物蝶呤缺乏症（BH4D）23人（21.3%）。BH4反应性PAH缺乏症血Phe浓度8h、24h时分别平均下降了49.24%和65.35%。（2）36例BH4反应性患者分为南方组23人、北方组13人。南、北方组BH4反应性患儿服药后24h时血Phe浓度均值分别为（217.02±189.03）μmol/L和（458.75±342.54）μmol/L（P〈0.05）,而两者在服药后2h、4h、8h、24h时血Phe浓度下降的百分数差异均无统计学意义（P〉0.05）。结论部分因PAH缺乏引起的PKU患儿口服BH420mg/kg后24h,血Phe浓度较服药前下降30%以上,其中绝大多数为轻、中度HPA（血Phe120～1200μmol/L）,少数为经典型PKU（血Phe〉1200μmol/L）。本研究中我国南方组BH4反应性PAH缺乏症服药24h时血Phe浓度较北方组低,但是南、北方患者对药物的总体反应性差异无统计学意义。     

Spanish BH4-responsive phenylalanine hydroxylase-deficient patients: evolution of seven patients on long-term treatment with tetrahydrobiopterin

A novel subtype of patients with mutations in the phenylalanine hydroxylase (PAH) gene that show a positive response during a tetrahydrobiopterin (BH4) loading test has recently been recognized. These studies suggest that a number of phenylketonuric (PKU) patients may benefit from BH4 substitution, eliminating the need of life-long dietary restrictions. In our unit, we performed BH4 overload tests in 50 PAH-deficient patients. Overall, 38% of the patients had a positive response, mostly MHP and mild PKU patients, all with at least one missense mutation with presumed residual activity. Seven of the patients that required dietary restrictions have received treatment with BH4 from 5 to 18 months. All the patients included in the long-term treatment protocol had a mild PKU phenotype. BH4 therapy began at 10 mg/kg/day and changes were made over time depending on Phe levels. All patients at least doubled their protein ingestion and some could follow a completely free diet. Patients with a smaller decrease in Phe levels during the BH4 overload required higher BH4 doses and/or dietary restrictions to maintain adequate Phe levels over time. The genotype and the potential mechanisms underlying BH4 responsiveness and interindividual differences in pharmacokinetics of the administered cofactor are probably the basis for the differences in prolonged treatment.     

5-year retrospective analysis of patients with phenylketonuria (PKU) and hyperphenylalaninemia treated at two specialized clinics

BackgroundPhenylketonuria (PKU) is an autosomal recessive disease caused by mutations in the PAH gene, resulting in deficiency of phenylalanine hydroxylase (PAH), an enzyme that converts phenylalanine (Phe) to tyrosine (Tyr). The purpose of this study was to capture real-world data associated with managing PKU under current standard of care and to characterize a representative population for a planned gene therapy trial.MethodsA retrospective chart review was conducted at two U.S. clinics for individuals 10–40 years old diagnosed with PKU-related hyperphenylalaninemia (HPA). Demographics, medical history, treatments and blood Phe data were collected from electronic medical records spanning a five-year period ending in November 2017.Results152 patients were enrolled (65.8% had classical PKU). Although >95% of patients were prescribed a Phe-restricted diet, blood Phe concentrations remained substantially elevated, particularly in patients diagnosed with classical PKU. As the Phe threshold was lowered (Phe < 600, 360, 120 or 30 μmol/L), the number of patients with consecutive lab values below the threshold decreased, suggesting that many patients' Phe levels are inadequately controlled. 62.5% of patients were reported as having a history of at least one neuropsychiatric comorbidity, and adults were more likely than adolescents (69.5% vs. 54.3%). 92 of 98 PAH genotypes collected were distinct mutations; the 6 null-null genotypes were associated with classical PKU. Overall the demographics and clinical data were consistent across both sites.ConclusionDespite dietary restrictions, mean Phe concentrations were > 360 μmol/L (a level considered well-controlled based on current U.S. treatment guidelines) for mild, moderate, and classical PKU patients. There remains an unmet need for therapies to control Phe concentrations.     

Long-term treatment with tetrahydrobiopterin increases phenylalanine tolerance in children with severe phenotype of phenylketonuria

Hyperphenylalaninemia caused by phenylalanine hydroxylase (PAH) deficiency requires lifelong rigorous diet starting in early infancy to prevent severe neurodevelopmental handicap. In a considerable number of children with mild hyperphenylalaninemia, long-term tetrahydrobiopterin (BH4) treatment significantly improves phenylalanine (phe) tolerance, but it has never been investigated in classic phenylketonuria (PKU). We performed a BH4-loading test in 40 consecutive infants with phe serum concentrations exceeding 240 microM, who had been detected by newborn screening programs. Eighteen out of 40 infants were found to be BH4 responsive. Five of them, responding to the neonatal BH4-loading test, showed a phe tolerance of less than 20 mg/kg/day and a phe pretreatment level of >1000 microM. They were treated with BH4 (20 mg/kg/day) over a period of 24 months. All five children had a sustained response to BH4, allowing substantial easing of dietary restrictions. Before BH4 treatment daily phe tolerance was 18-19 mg/kg, increasing to 30-80 mg/kg on BH4 treatment and decreasing again to 12-17 mg/kg after termination of BH4 treatment. Mutation analysis revealed compound heterozygosity for a putative null and a variant PAH mutation in four patients and homozygosity for a variant PAH mutation in one patient. We conclude that BH4 sensitivity is not restricted to mild hyperphenylalaninemia and that long-term BH4 treatment may also improve phenylalanine tolerance in a considerable number of children with a more severe PKU phenotype.     

Long-term treatment of patients with mild and classical phenylketonuria by tetrahydrobiopterin

Tetrahydrobiopterin (BH4), the natural cofactor of phenylalanine hydroxylase (EC 1.14.16.1), can reduce blood phenylalanine (Phe) in BH4 sensitive patients with hyperphenylalaninemia (McKuisick 261600). We report on the long-term treatment of eight patients with mild and classical phenylketonuria (blood Phe levels maximum blood Phe levels between 771 and 1500 micromol/L) using BH4 at a dosage of 8-12 mg/kg BW per day. In all patients reduction of blood Phe was >30% after BH4 loading test. Three patients were treated from birth by BH4 only, five after initial low Phe dietary treatment. Seven of them continue to be on BH4 treatment only, one has a relaxed low protein diet. No side effects could be observed (longest observation time 5 years), somatic and psychomotor development were normal. The main problem of BH4 treatment is finding an optimal dosage at different ages and an under special conditions like infectious diseases. There is evidence that in some patients BH4 treatment may allow a more relaxed low protein diet showing positive effects on weight gain and quality of life. Further controlled studies are necessary not only to rule out any side effects but also for optimizing treatment strategies with BH4 treatment in mild phenylketonuria.     

Tetrahydrobiopterin-responsive phenylalanine hydroxylase deficiency,state of the art

Since 1999 an increasing number of patients with phenylalanine hydroxylase (PAH) deficiency are reported to be able to decrease their plasma phenylalanine (Phe) concentrations after a 6R-tetrahydrobiopterin (BH(4)) challenge. The majority of these patients have mild PKU or MHP (mild hyperphenylalaninemia) and harbour at least one missense mutation in the PAH gene associated with this phenotype. The rate of decrease and the lowest achieved Phe level vary between patients with different genotypes but appears to be similar in patients with the same genotype. A number of the mutations associated with BH(4)-responsiveness have been studied in an 'in vitro' eukaryotic cell expression system leading to biosynthesis of a mutant PAH enzyme with some residual activity. Patients bearing mutations that cause severe structural distortion in the expressed protein (loss of function mutations), leading to undetectable PAH activity, are not responsive to BH(4). These observations suggest that residual PAH activity (in vitro) is a prerequisite for BH(4)-responsiveness. However, an in vitro residual PAH activity is not a guarantee for in vivo BH(4)-responsiveness. Mechanisms behind this responsiveness could be relieve of decreased binding affinity for BH(4), BH(4)-mediated increase of PAH gene expression or stabilization of the mutant enzyme protein by BH(4). BH(4)-responsive PAH-deficient patients have only been reported since 1999. For the western countries this is explained by the fact that the manufacturer changed the diastereoisomeric purity of the BH4 preparation from 69% of the natural 6R-BH4 (31% of 6S-BH4) to 99.5% 6R-BH4. The new findings on BH(4)-responsiveness may be of clinical relevance because these patients can be treated with BH(4) with concomitant relief or withdrawal of the burdensome PKU diet. These observations warrant further clinical studies to assess efficacy, optimal dosage, and safety of BH(4) treatment in this group. The data strongly emphasize the necessity of the BH(4) loading test in patients detected in the newborn PKU screening.     

Extended tetrahydrobiopterin loading test in the diagnosis of cofactor-responsive phenylketonuria: a pilot study

Patients with tetrahydrobiopterin (BH4)-responsive phenylalanine hydroxylase (PAH) deficiency may benefit from BH4 therapy instead or in addition to the low-phenylalanine diet. Different loading test protocols are currently used to detect these patients. As a consequence, data on the rate of BH4-responsiveness within patients with mild phenylketonuria (PKU) and/or more severe phenotypes show high variation and a more sensitive and standardised BH4 loading test protocol needs to be defined. We modified the current standard BH4 loading test (20 mg/kg) to a second administration of 20 mg/kg after 24 h and extended blood sampling to 48 h in 24 patients with PAH deficiency. Using this extended loading test (2 x 20 mg BH4/kg), the rate of BH4-responsiveness was calculated at 8, 24, and 48 h after BH4 administration. We defined three groups of patients: "rapid responders" in 10/24 patients (4 mild HPA, 2 mild PKU, 2 moderate PKU, and 2 classic PKU), "moderate responders" in 4/24 patients (4 classic PKU), and "slow responder" in 4/24 patients (4 mild PKU). Six out of 24 patients (1 mild HPA, 1 moderate PKU, and 4 classic PKU) were found to be "non-responder." Individual phenylalanine profiles show variations in responsiveness at different time points and sampling over 48 h was more informative than over 24h in patients with mild and moderate PKU compared to mild HPA. Analysis of BH4 loading tests in 209 patients with the standard BH4 loading test protocol confirms only minor importance of the 24 h response: the rate of responsiveness to BH4 after 24 h was shown to be equal to or even lower than after 8h among most phenotypes. However, extension of the BH4 loading test to 48 h and repeated BH4 administration seems to be useful to detect BH4-responsiveness in more severe phenotypes and allows detecting "slow responders" who may benefit from BH4 therapy.     

Non-PKU mild hyperphenylalaninemia (MHP)--the dilemma

Recent reviews have suggested that some patients with "non-PKU mild hyperphenylalaninemia" (MHP) might display neuropsychological executive function deficits and should be considered for treatment with tetrahydrobipterin (BH4) and/or phenylalanine (Phe) restricted diet. Patients with phenylketonuria (PKU)--Classical and Mild/Atypical variants--appear to need "mean lifetime phenylalanine (Phe) levels" of 120-360 μmol/L for optimal results. MHP patients, on the other hand, have natural Phe levels of 200-600 μmol/L. Until recently this was thought to be a benign condition. The available literature has been reviewed in detail and no good evidence, to date, has been uncovered to support treatment of MHP. It is suggested that more MHP subjects be tested to confirm this. A plea is made to formulate a consistent world-wide classification of the PKU phenotypes.     

Plasma biopterin levels and tetrahydrobiopterin responsiveness

Tetrahydrobiopterin (BH4) responsive hyperphenylalaninemia (HPA) with a mutant phenylalanine hydroxylase (PAH) gene was found during neonatal screening for PKU. This study determined blood BH4 and phenylalanine in two patients with hyperphenylalaninemia following oral load with BH4 10 mg/kg. Our patients underwent neonatal screening for PKU, had normal biopterin metabolism and their PAH mutations were determined. Peak plasma biopterin levels in Case 1, which were reached at between 2 and 4h after loading, were 612, 297, and 178 nmol/L at age 30 days, 55 days, and 19 months, respectively, and the maximum phenylalanine decreasing rates, which were found at 24h, were 54, 16, and 4%, respectively. In Case 2, peak plasma biopterin levels were 747 and 327 nmol/L at age 20 and 55 days, respectively, and the maximum phenylalanine decreasing rates were 39 and 32%, respectively. In the BH4 loading test, the peaks of BH4 in both patients lowered ( approximately 50%), on the same dose schedule of BH4, as patients got older.     

Tetrahydrobiopterin responsiveness: results of the BH4 loading test in 31 Spanish PKU patients and correlation with their genotype

Tetrahydrobiopterin (BH4) responsiveness in patients with mutations in the phenylalanine hydroxylase (PAH) gene is a recently recognized subtype of hyperphenylalaninemia characterized by a positive BH4 loading test. According to recent estimates, this phenotype may be quite common, suggesting that a large group of individuals may benefit from BH4 substitution, eliminating the need of life-long dietary restrictions. This underscores the importance of identifying BH4-responsive patients in each population, establishing the association with specific PAH mutations. In this work, we describe the results of a pilot study performed with 31 Spanish PAH-deficient patients subjected to a BH4 loading test. Overall, 11/31 (37%) showed a positive response with a 30% decrease in blood Phe levels 8 h after the BH4 challenge, and three additional patients, considered slow responders, showed this decrease only after 12-16 h. We report for the first time a patient homozygous for a splicing mutation with a slow response, suggesting an effect of BH4 supplementation on PAH gene expression. Most of the responsive patients belong to the mild hyperphenylalaninemia (MHP) or mild phenylketonuria phenotypic groups. In MHP patients we report for the first time the results of parallel single Phe doses confirming the utility of these analyses for a better evaluation of the response. Genotype analysis confirms the involvement in the response of specific mutations (D415N, S87R, R176L, E390G, and A309V) present in hemizygous patients, and provide relevant information for the discussion of the potential mechanisms underlying BH4 responsiveness.     

Response of patients with phenylketonuria in the US to tetrahydrobiopterin

Tetrahydrobiopterin (BH4) responsive forms of phenylketonuria (PKU) have been recognized since 1999. Subsequent studies have shown that patients with PKU, especially those with mild mutations, respond with lower blood phenylalanine (Phe) concentrations following oral administration of 6-R-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4). To determine the incidence of BH4 responding PKU patients in the United States and characterize their phenylalanine hydroxylase (PAH) mutations, a study was undertaken at UTMB in Galveston and the Children's Hospital of Los Angeles on 38 patients with PKU. Patients were screened by a single oral dose of BH4, 10 mg/kg and blood Phe and tyrosine were determined at 0, 4, 8, and 24 h. Twenty-two individuals (58%) responded with marked decrease in blood Phe (>30%) at 24h. Some of the patients that responded favourably were clinically described as having Classical PKU. Blood tyrosine concentrations did not change significantly. Twenty subjects with PKU, responsive and non-responsive to BH4, were enrolled in a second study to evaluate blood Phe response to ascending single doses of BH4 with 10, 20, and 40 mg/kg and to evaluate multiple daily doses, for 7 days each, with 10 and 20 mg/kg BH4. The 7-day trial showed a sustained decrease in blood Phe in 14 of 20 patients taking 20 mg/kg BH4 (70%). Of these 14 patients, 10 (71%) responded with a significant decrease in blood Phe following 10 mg/kg BH4 daily. To understand the mechanism of response to BH4, the kinetics and stability of mutant PAH were studied. We found that mutant PAH responds with increase in the residual enzyme activity following BH4 administration. The increase in activity is multi-factorial caused by increased stability, chaperone effect, and correction of the mutant Km. These studies indicate that BH4 can be of help to patients with PKU, including some considered to have Classical PKU. The PKU population in US is heterogeneous and mutations can be varied so mutations need to be characterized and response to BH4 tested. It is more likely that mutations with residual activity should respond to BH4, therefore the clinical definition of "Classical PKU" should be reconciled with the residual activity of PAH mutations.     

Recommendations for evaluation of responsiveness to tetrahydrobiopterin (BH(4)) in phenylketonuria and its use in treatment

Some individuals with phenylketonuria (PKU) respond to pharmacologic treatment with tetrahydrobiopterin (BH(4)) by a reduction in the blood phenylalanine concentration. This can result in increased dietary tolerance for phenylalanine or, in rare instances, replacement of the phenylalanine-restricted diet. BH(4) is now available as sapropterin dihydrochloride under the name KUVAN, a formulation of natural BH(4). This commentary contains recommendations for determining responsiveness to sapropterin dihydrochloride. The recommendations include challenging with an initial daily dose of 20mg/kg and blood phenylalanine determinations pre-challenge and on days 1, 7, and 14 with the option of an additional continuation to day 28 if required to clarify whether a response has occurred. An algorithm depicting this recommendation for the challenge is included. The most widely accepted standard of response is > or = 30% reduction in the blood phenylalanine concentration, but a lower degree of response might also be considered clinically meaningful in some individual circumstances. Issues include the potential treatment of those with mild hyperphenylalaninemia who are not on diet, challenging neonates who have hyperphenylalaninemia identified by newborn screening, and the use of sapropterin dihydrochloride in treatment of maternal PKU pregnancies. These recommendations are intended to provide a basis for the use of sapropterin dihydrochloride in the treatment of PKU but may be altered after close observation of treated patients and carefully performed research.     

四氢生物喋呤负荷试验在高苯丙氨酸血症鉴别诊断中的临床应用

目的探讨四氢生物喋呤（BH4）负荷试验在高苯丙氨酸血症（HPA）鉴别诊断中的应用价值。方法自2005年5月到2007年4月，51例HPA患儿采用口服BH4（20mg／kg）负荷试验。对其中血苯丙氨酸（Phe）浓度小于600μmol／L患儿采用口服Phe—BH4联合负荷试验，结合尿喋呤分析、血红细胞二氢喋呤还原酶（DHPR）活性测定。结果（1）在BH4负荷试验中，不同类型HPA患儿的血Phe浓度表现出各不相同的改变。51例HPA患儿中，共鉴别出5例BH4缺乏症，10例BH4反应性苯丙氨酸羟化酶（PAH）缺乏症，36例BH4无反应性苯丙氨酸羟化酶（PAH）缺乏症。（2）在17例中度苯丙酮尿症（PKU）患儿中，9例（52．9％）为BH4反应性PAH缺乏症。结论BH4负荷试验在HPA早期鉴别诊断中十分重要，部分中度PKU对BH4有反应，可使用BH4替代治疗。     

Biochemical phenotype and its relationship with genotype in hyperphenylalaninemia heterozygotes.

The molecular detection of heterozygotes for hyperphenylalaninemia is difficult due to the large number of mutations in the PAH gene. For this reason, various indexes that measure plasma concentrations of phenylalanine (Phe) and tyrosine (Tyr), as an expression of Phe metabolizing capacity, have been used for the detection of carriers for mutations in the PAH gene. In this study, we contrast the biochemical and the molecular data in order to know if this is an accurate method. Familial genetic analysis of the PAH gene in 93 parents of hyperphenylalaninemia patients allows the study of the biochemical expression of the different mutant alleles. Molecular study was performed by SSCP and DGGE analyses of PAH genes, and plasma amino acid analysis by ion-exchange chromatography. Then the biochemical and molecular data were compared by the Student t test. The results found show a relationship between the severity of PKU/HPA mutations in the PAH gene and their biochemical phenotype (Phe/Tyr, Phe2/Tyr) as an expression of the residual enzymatic activity. The study adds further information about the prevalent Mediterranean allele mutations.     

Recommendations for the use of sapropterin in phenylketonuria

Phenylketonuria (PKU) is an inherited disorder of phenylalanine (Phe) metabolism. Until recently, the only treatment for PKU was a Phe-restricted diet. Increasing evidence of suboptimal outcomes in diet-treated individuals, inconsistent PKU management practices, and the recent availability of tetrahydrobiopterin (BH(4)) therapy have fueled the need for new management and treatment recommendations for this metabolic disorder. BH(4), now available as sapropterin dihydrochloride (sapropterin), may offer the potential for improved metabolic control as well as enhanced dietary Phe tolerance in some PKU patients. A group of metabolic dietitians from North America convened in June 2011 to draft recommendations for the use of sapropterin therapy in PKU. Physicians with extensive experience in PKU management were invited at a later date to contribute to the development of these recommendations. Based on extensive clinical experience and current evidence, the present recommendations provide guidance from patient selection and determination of sapropterin response to the long-term management of patients on sapropterin therapy. Target Phe levels, nutritional adequacy, neurocognitive screening and adherence to treatment are addressed to optimize patient outcomes.     

Optimizing the use of sapropterin (BH4) in the management of phenylketonuria

Phenylketonuria (PKU) is caused by mutations in the phenylalanine hydroxylase (PAH) gene, leading to deficient conversion of phenylalanine (Phe) to tyrosine and accumulation of toxic levels of Phe. A Phe-restricted diet is essential to reduce blood Phe levels and prevent long-term neurological impairment and other adverse sequelae. This diet is commenced within the first few weeks of life and current recommendations favor lifelong diet therapy. The observation of clinically significant reductions in blood Phe levels in a subset of patients with PKU following oral administration of 6R-tetrahydrobiopterin dihydrochloride (BH₄), a cofactor of PAH, raises the prospect of oral pharmacotherapy for PKU. An orally active formulation of BH₄ (sapropterin dihydrochloride; Kuvan^®) is now commercially available. Clinical studies suggest that treatment with sapropterin provides better Phe control and increases dietary Phe tolerance, allowing significant relaxation, or even discontinuation, of dietary Phe restriction. Firstly, patients who may respond to this treatment need to be identified. We propose an initial 48-h loading test, followed by a 1–4-week trial of sapropterin and subsequent adjustment of the sapropterin dosage and dietary Phe intake to optimize blood Phe control. Overall, sapropterin represents a major advance in the management of PKU.     

Phenylalanine ammonia lyase, enzyme substitution therapy for phenylketonuria, where are we now?

Phenylketonuria (PKU) is an autosomal recessive genetic disorder in which mutations in the phenylalanine-4-hydroxylase (PAH) gene result in an inactive enzyme (PAH, EC 1.14.16.1). The effect is an inability to metabolize phenylalanine (Phe), translating into elevated levels of Phe in the bloodstream (hyperphenylalaninemia). If therapy is not implemented at birth, mental retardation can occur. PKU patients respond to treatment with a low-phenylalanine diet, but compliance with the diet is difficult, therefore the development of alternative treatments is desirable. Enzyme substitution therapy with a recombinant phenylalanine ammonia lyase (PAL) is currently being explored. This enzyme converts Phe to the harmless metabolites, trans-cinnamic acid and trace ammonia. Taken orally and when non-absorbable and protected, PAL lowers plasma Phe in mutant hyperphenylalaninemic mouse models. Subcutaneous administration of PAL results in more substantial lowering of plasma and significant reduction in brain Phe levels, however the metabolic effect is not sustained following repeated injections due to an immune response. We have chemically modified PAL by pegylation to produce a protected form of PAL that possesses better specific activity, prolonged half-life, and reduced immunogenicity in vivo. Subcutaneous administration of pegylated molecules to PKU mice has the desired metabolic response (prolonged reduction in blood Phe levels) with greatly attenuated immunogenicity.     

Tetrahydrobiopterin-responsive phenylketonuria: the New South Wales experience

Recent studies have shown that a subgroup of phenylketonuric patients respond to high doses of BH4 (20 mg/kg) by a decrease of plasma phenylalanine. A clinically significant response has been defined as a decrease in phenylalanine by more than 30% within 24 h, after a BH4 challenge. We report our experience with 37 patients diagnosed with hyperphenylalaninemia, mild, moderate, or classical Phenylketonuria (PKU) using a seven day combined BH4 and phenylalanine load. Nine of the 37 patients responded with a 30% decrease in their phenylalanine levels in the first 8 h of treatment. A total of 17 patients (46%) had a decrease of at least 30% during the study period. This study confirms that a significant number of patients with mild to moderate PKU will respond to a BH4 load. Furthermore, it confirms that the seven-day phenylalanine test is more sensitive in detecting BH4 responsive patients.     

Reversal of metabolic and neurological symptoms of phenylketonuric mice treated with a PAH containing helper-dependent adenoviral vector

Phenylketonuria (PKU) is one of the most common inborn errors of metabolism and is due to a deficit of phenylalanine hydroxylase, the enzyme that converts phenylalanine (Phe) into tyrosine (Tyr). The resultant hyperphenylalaninemia (HPA) leads to severe neurological impairment, whose pathogenesis has not been entirely elucidated. Treatment of PKU consists essentially in lifelong protein restriction and, in mild cases, in tetrahydrobiopterin supplementation. However, compliance to both strategies, particularly to the long-term diet, is low and therefore other therapies are desirable. We explored a gene therapy approach aimed at long-term correction of the pathologic phenotype of BTBR-PahEnu2 mice, a mouse model of PKU. To this aim, we developed a helper-dependent adenoviral (HD-Ad) vector expressing phenylalanine hydroxylase and administered it to 3-week-old PKU mice. This resulted in complete normalization of Phe and Tyr levels and reversal of coat hypopigmentation that lasted throughout the observation period of six months. The spatial learning deficits observed in PKU mice were also reversed and hippocampus levels of the N-methyl-D-Aspartate and 2-amino-3-(5-methyl-3-oxo-1,2- oxazol-4-yl) propanoic acid receptor subunits returned to normal. Long-term potentiation, which is impaired in PKU mice, was also restored by treatment. Therefore, HD-Ad vector-mediated gene therapy is a promising approach to PKU treatment.     

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)