Phenylalanine Hydroxylase Mutations Research Articles

A Rare Combination of Compound Heterozygous Mutations in the PAH Gene in Three Unrelated Consanguineous Iranian Families with Classical Phenylketonuria.

The PAH gene mutations have been linked to the development of phenylketonuria (PKU), which is recognized as the most common inborn metabolic disorder, and is caused by a deficiency in the phenylalanine hydroxylase (PAH) enzyme. The Iranian population, known for its diversity and high consanguinity, offers a valuable sample for studying autosomal recessive disorders. Our study investigated three unrelated families with PKU from Iran, utilizing clinical, laboratory, and computational approaches. We performed direct PCR sequencing for 13 exons of the PAH gene on three Iranian patients who were diagnosed with PKU. Then, Sanger sequencing confirmed the segregation of the mutations from parents to probands. Pathogenicity predictor tools, including ACMG, CADD, SIFT, Polyphen-2, and Mutation Taster, were utilized to analyze the identified genetic variants. The three-dimensional structure of the mutant forms of the protein was predicted. We also analyzed the protein-protein interactions of PAH using the STRING database. All three patients exhibited rare compound heterozygosity rearrangements in the PAH gene (NM_000277.3). These included three missense variants: [c.533A>G/c.1222C>T], [c.526C>T/c.1222C>T], and [c.533A> / c.526C>T]. This study adds to the body of evidence establishing the association between PAH mutations and the development of PKU. We speculated that the conjunction of a high consanguinity rate in populations such as Iran, coupled with the founder effect, can give rise to atypical genetic profiles, as observed in the rearrangement of compound heterozygosity in this study Moreover, our research underscores the significance of genetic testing in the precise diagnosis of individuals affected by inborn errors of metabolism.

Phenylketonuria (PKU): Causes, classifications, clinical symptoms, diagnosis and treatment

The autosomal recessive condition phenylketonuria (PKU) is brought on by mutations in the gene that codes for phenylalanine hydroxylase (PAH). Phenylalanine (Phe) builds up in the blood as a result of PAH mutations. Untreated PKU can result in several dangers, including brain damage. Due to factors including enhanced genetic testing and newborn screening, the number of PKU patients is predicted to rise. Therefore, it is necessary to popularize the knowledge of PKU in the society. Additionally, minimizing the occurrence of PKU symptoms is greatly aided by early identification and treatment of PKU. In this context, this review highly summarizes all aspects of knowledge about KPU, focusing on the genetic cause, classification, clinic symptoms, diagnosis, and treatment. Newborn screening and related diagnostic technologies, including the Guthrie test, the McCaman and Robins fluorescence assay, and Tandem mass spectrometry, are introduced in this paper. The dietary measures, PKU Formula, and two effective medications, Kuvan and Palynzio, are involved as well. In addition, state-of-the-art genetic techniques for diagnosis and treatment are also included. With an earlier and more accurate diagnosis, governments around the world should strengthen awareness of PKU and lead to the development of effective diagnostics and therapeutics. Finally, the purpose of this paper is to let more people know about PKU, strive for early detection and treatment, and do everything possible to avoid the occurrence of phenylketonuria symptoms.

Abstract 672: A genetic defect in phenylalanine hydroxylase (PAH) affects the immune system in kidney

Abstract PAH, one of the genes associated with inborn error of metabolism (IEM), codes for phenylalanine hydroxylase and is specifically expressed in the liver and kidney. When PAH is dysfunctional, phenylalanine (Phe) cannot be converted to tyrosine (Tyr), and it produces toxic metabolites such as phenylpyruvate by a metabolic shift. We previously analyzed germline variants of IEM-related genes using public cancer multi-omics data. As a result, there was a high frequency of mutations in the PAH gene, and germline variants were particularly high in renal cell carcinoma (RCC). Based on this data, we suggest that kidney-specific expressed PAH mutations could change the kidney tissue microenvironment, which makes them more vulnerable to chronic kidney disease (CKD) and affects cancer development. We used the PAH enu2 mice model, which has a missense mutation in the PAH gene. PAH homozygous mutant mice display phenylketonuria (PKU) when not maintained on a Phe-free diet. PAH enu2 mice were maintained a normal diet. The concentration of phenylalanine in the mice's serum was measured each week. Then, the proportions of immune cells were analyzed in peripheral blood and kidney. Next, Jurkat cells, which are well-known as human T-cell lines, were applied to the in vitro experiment. Jurkat cells were cultured in a medium containing Phe or PPA and were activated by PHA/PMA or anti-CD3/CD28. Then after, the expression of immune-related markers was evaluated. Additionally, the expression of the PAH enzyme in human RCC and normal tissue was assessed by immunohistochemistry (IHC). The concentration of Phe in mice serum was higher when the PAH gene was defective; homozygous mutant, heterozygous mutant. As PAH-defective mice got older, the T cell population decreased in the blood and kidney immune cells. When Jurkat T cells were cultured with Phe or PPA, the expression of IL-2, a cytokine related to T cell expansion, decreased in the PPA-treated and activated group. There were more significant changes when treated with PPA rather than Phe. IHC data shows the expression of PAH was significantly decreased in RCC tissues compared to non-tumor tissue. These results suggest that the immune system could be changed by PAH dysfunction bearing a germline mutation. Moreover, the kidney tissue microenvironment with PAH defects is vulnerable to the development of kidney disease, which can lead to RCC. This is a novel discovery that can explain the importance of the role PAH gene in kidney disease. Citation Format: Seojeong Kim, Chaelin Kang, Jihyun Park, Seung Seok Han, Youngil Koh, Sung-Soo Yoon. A genetic defect in phenylalanine hydroxylase (PAH) affects the immune system in kidney [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 672.

Metabolic phenotyping in phenylketonuria reveals disease clustering independently of metabolic control.

Phenylketonuria (PKU, MIM #261600) is one of the most common inborn errors of metabolism (IEM) with an incidence of 1:10000 in the European population. PKU is caused by autosomal recessive mutations in phenylalanine hydroxylase (PAH) and manifests with elevation of phenylalanine (Phe) in plasma and urine. Untreated PKU manifests with intellectual disability including seizures, microcephaly and behavioral abnormalities. Early treatment and good compliance result in a normal intellectual outcome in many but not in all patients. This study examined plasma metabolites in patients with PKU (n = 27), hyperphenylalaninemia (HPA, n = 1) and healthy controls (n = 32) by LC- MS/MS. We hypothesized that PKU patients would exhibit a distinct "submetabolome" compared to that of healthy controls. We further hypothesized that the submetabolome of PKU patients with good metabolic control would resemble that of healthy controls. Results from this study show: (i) Distinct clustering of healthy controls and PKU patients based on polar metabolite profiling, (ii) Increased and decreased concentrations of metabolites within and afar from the Phe pathway in treated patients, and (iii) A specific PKU-submetabolome independently of metabolic control assessed by Phe in plasma. We examined the relationship between PKU metabolic control and extended metabolite profiles in plasma. The PKU submetabolome characterized in this study represents the combined effects of dietary adherence, adjustments in metabolic pathways to compensate for defective Phe processing, as well as metabolic derangements that could not be corrected with dietary management even in patients classified as having good metabolic control. New therapeutic targets may be uncovered to approximate the PKU submetabolome to that of healthy controls and prevent long-term organ damage.

Screening and mutation analysis of phenylalanine hydroxylase deficiency in newborns from Jiangxi province.

Background: Phenylalanine hydroxylase deficiency (PAHD) is an autosomal recessive disorder of amino acid metabolism and caused by mutations in the phenylalanine hydroxylase (PAH) gene. Without timely and appropriate dietary management, the disturbance of amino acid metabolism may impair cognitive development and neurophysiological function. Newborn screening (NBS) can aid the early diagnosis of PAHD, which can give accurate therapy to PAHD patients in time. In China, the PAHD incidence and PAH mutation spectrum vary enormously across the provinces. A total of 5,541,627 newborns from Jiangxi province were screened by NBS between 1997 and 2021. Method: One seventy one newborns from Jiangxi province were diagnosed with PAHD. By Sanger sequencing and the multiplex ligation-dependent probe amplification (MLPA) analysis, mutation analysis was performed in 123 PAHD patients. Using an arbitrary values (AV)-based model, we compared the observed phenotype with the predicted phenotype based on the genotype. Results: In this study, we speculated the PAHD incidence of Jiangxi province was about 30.9 per 1,000,000 live births (171/5,541,627). We summarized the PAH mutation spectrum in Jiangxi province for the first time. Two novel variants (c.433G > C, c.706 + 2T > A) were found. The most prevalent variant was c.728G > A (14.1%). The overall prediction rate of the genotype-phenotype was 77.4%. Conclusion: This mutation spectrum is very meaningful to improve the diagnostic rate of PAHD and to increase the accuracy genetic counseling. This study offers data for the genotype-phenotype prediction suitable for Chinese population.

Expanded newborn screening for inherited metabolic disorders by tandem mass spectrometry in a northern Chinese population.

Tandem mass spectrometry (MS/MS) has been developed as one of the most important diagnostic platforms for the early detection and screening of inherited metabolic disorders (IMDs). To determine the disease spectrum and genetic characteristics of IMDs in Suqian city of Jiangsu province in the northern Chinese population, dried blood spots from 2,04,604 newborns, were assessed for IMDs by MS/MS from January 2016 to November 2020. Suspected positive patients were diagnosed through next-generation sequencing (NGS) and validated by Sanger sequencing. One hundred patients with IMDs were diagnosed, resulting in an overall incidence of 1/2,046, of which 56 (1/3,653), 22 (1/9,300), and 22 (1/9,300) were confirmed amino acids disorders (AAs), organic acids disorders (OAs), fatty acid oxidation disorders (FAODs) positive cases, respectively. The highest incidence of IMDs is phenylalanine hydroxylase deficiency (PAHD) (45 cases), with a total incidence of 1:4,546. Hot spot mutations in phenylalanine hydroxylase (PAH)-related genes are c.158G > A (24.44%), c.728G > A (16.67%), c.611A > G (7.78%), and c.331C>T (7.78%). The related hot spot mutation of the MMACHC gene is c.609G > A (45.45%). Short-chain acyl-CoA dehydrogenase deficiency (SCAD)-related ACADS gene hotspot mutations are c.164C > T (33.33%) and c.1031A > G (33.33%). Our work indicated that the overall incidence of IMDs is high, and the mutations in PAH, ACADS, and MMACHC genes are the leading causes of IMDs in Suqian city. The incidence of AAs in Suqian city is higher than in other Chinese areas. The disease spectrum and genetic backgrounds were elucidated, contributing to the treatment and prenatal genetic counseling of these disorders in this region.

Application of the Artificial Intelligence Algorithm Model for Screening of Inborn Errors of Metabolism.

Inborn errors of metabolism (IEMs) are strongly related to abnormal growth and development in newborns and can even result in death. In total, 94,648 newborns were enrolled for expanded newborn screening using tandem mass spectrometry (MS/MS) from 2016 to 2020 at the Neonatal Disease Screening Center of the Maternal and Child Health Hospital in Shaoyang City, China. A total of 23 confirmed cases were detected in our study with an incidence rate of 1:4,115. A total of 10 types of IEM were identified, and the most common IEMs were phenylalanine hydroxylase deficiency (PAHD; 1:15,775) and primary carnitine deficiency (PCD; 1:18,930). Mutations in phenylalanine hydroxylase (PAH) and SLC22A5 were the leading causes of IEMs. To evaluate the application effect of artificial intelligence (AI) in newborn screening, we used AI to retrospectively analyze the screening results and found that the false-positive rate could be decreased by more than 24.9% after using AI. Meanwhile, a missed case with neonatal intrahepatic cholestasis citrin deficiency (NICCD) was found, the infant had a normal citrulline level (31 μmol/L; cutoff value of 6–32 μmol/L), indicating that citrulline may not be the best biomarker of intrahepatic cholestasis citrin deficiency. Our results indicated that the use of AI in newborn screening could improve efficiency significantly. Hence, we propose a novel strategy that combines expanded neonatal IEM screening with AI to reduce the occurrence of false positives and false negatives.

A noncoding RNA modulator potentiates phenylalanine metabolism in mice.

The functional role of long noncoding RNAs (lncRNAs) in inherited metabolic disorders, including phenylketonuria (PKU), is unknown. Here, we demonstrate that the mouse lncRNA Pair and human HULC associate with phenylalanine hydroxylase (PAH). Pair-knockout mice exhibited excessive blood phenylalanine (Phe), musty odor, hypopigmentation, growth retardation, and progressive neurological symptoms including seizures, which faithfully models human PKU. HULC depletion led to reduced PAH enzymatic activities in human induced pluripotent stem cell-differentiated hepatocytes. Mechanistically, HULC modulated the enzymatic activities of PAH by facilitating PAH-substrate and PAH-cofactor interactions. To develop a therapeutic strategy for restoring liver lncRNAs, we designed GalNAc-tagged lncRNA mimics that exhibit liver enrichment. Treatment with GalNAc-HULC mimics reduced excessive Phe in Pair -/- and Pah R408W/R408W mice and improved the Phe tolerance of these mice.

RNA solution for a genetic problem

Phenylketonuria Phenylketonuria is a classic example of the benefit of newborn metabolic screening: It is a single-gene disease that can be detected at birth, and its neurological effects can be prevented by dietary therapy. Unfortunately, this is not always straightforward because the disease-causing mutations in phenylalanine hydroxylase vary between patients and affect the severity of the phenotype, such that some patients' symptoms do not fully respond to the available interventions. Li et al. identified two long noncoding RNAs, one in mice and one in humans, that interact with phenylalanine hydroxylase and modulate its function (see the Perspective by Ben-Tov Perry and Ulitsky). Administration of modified RNAs mimicking their effects ameliorated the disease phenotype in mouse models of phenylketonuria. Science , aba4991, this issue p. [662][1]; see also abj7969, p. [623][2] [1]: /lookup/doi/10.1126/science.aba4991 [2]: /lookup/doi/10.1126/science.abj7969

Molecular diagnosis of phenylketonuria in 157 Chinese families and the results of prenatal diagnosis in these families.

Molecular diagnosis of phenylketonuria in 157 Chinese families and the results of prenatal diagnosis in these families.

The Pah-R261Q mouse reveals oxidative stress associated with amyloid-like hepatic aggregation of mutant phenylalanine hydroxylase

Phenylketonuria (PKU) is caused by autosomal recessive variants in phenylalanine hydroxylase (PAH), leading to systemic accumulation of L-phenylalanine (L-Phe) that may reach neurotoxic levels. A homozygous Pah-R261Q mouse, with a highly prevalent misfolding variant in humans, reveals the expected hepatic PAH activity decrease, systemic L-Phe increase, L-tyrosine and L-tryptophan decrease, and tetrahydrobiopterin-responsive hyperphenylalaninemia. Pah-R261Q mice also present unexpected traits, including altered lipid metabolism, reduction of liver tetrahydrobiopterin content, and a metabolic profile indicative of oxidative stress. Pah-R261Q hepatic tissue exhibits large ubiquitin-positive, amyloid-like oligomeric aggregates of mutant PAH that colocalize with selective autophagy markers. Together, these findings reveal that PKU, customarily considered a loss-of-function disorder, can also have toxic gain-of-function contribution from protein misfolding and aggregation. The proteostasis defect and concomitant oxidative stress may explain the prevalence of comorbid conditions in adult PKU patients, placing this mouse model in an advantageous position for the discovery of mutation-specific biomarkers and therapies.

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.

A joint method for the screening of pharmacological chaperones for phenylalanine hydroxylase.

Phenylalanine hydroxylase (PAH) deficiency (PAHD) is an autosomal recessive disorder that causes severe injury to the nervous system, the treatment of which mainly depends on dietary therapy. The limited treatment options for PAHD are an incentive to develop new methods to identify more efficient therapeutic drugs, such as agonists which could improve PAH activity. In this study, we aimed to establish a rapid and convenient method for the screening and verification of PAH agonists. We compared fluorospectrophotometry and tandem mass spectrometry for detection of enzymatic formation of tyrosine, finding that the latter was a more sensitive method. We optimized immunoprecipitation purification conditions and measurement conditions of PAH activity. The optimal ratio between PAH protein and magnetic beads was 500 μg protein per 20 μL beads, and the optimized conditions for the detection of PAH enzymatic activity included the presence of 75 μM coenzyme ((6R)-l-erythro-5,6,7,8-tetrahydrobiopterin) and 30 min reaction time. Based on virtual screening, we screened ten candidate agonists from the FDA drug library. Three of these (nefopam, fluocinonide, and risperidone) were found to activate the enzyme in a dose-dependent manner (0.1-10 μM) by the joint method. We tested the efficacy of the three agonists on three PAH mutations (p.I65T, p.H107R, and p.D101N) that influence enzyme activity, and found that risperidone could specifically activate D101N-mutated enzyme. In conclusion, we established a joint method that is highly reliable, cost-effective, labor-saving, and time-saving. And we also found a specific agonist for D101N-mutated PAH by this joint method which may assist the development of clinical treatment for PAHD patients with different enzyme deficiencies.

Mutation Spectrum of the Phenylalanine Hydroxylase Gene in Phenylketonuria Patients in Golestan Province, Iran

Background. As an autosomal recessive disease, phenylketonuria (PKU) is caused by deficiency in phenylalanine hydroxylase (PAH) gene. The incidence of different mutations in phenylalanine hydroxylase is associated with differences in race and ethnicity. The aim of this study is to investigate the mutation spectrum in hotspot region of PAH gene in PKU patients. Materials and Method. For this purpose, we studied exons 6, 7, 10–11 and 12 and adjacent flanking regions of PAH gene from a total of 26 unrelated hyperphenylalaninemia patients (13 males and 13 females) in Golestan province using PCR-sequencing method. Results. Among 26 analyzed patients, 11 distinct mutations were found in combinations of 18 genotypes. A mutation detection rate of 64% was achieved. The high heterogeneity of PKU was reported in this study. The most prevalent mutations were IVS10-11G>A (19.23%), followed by IVS11+1G>C, p.P416HfsX36 and p.R261Q which accounted for 66.67% of mutant alleles. IVS9-1G>T and p.P416HfsX36 are novel mutations. Exonic polymorphisms L385L and Q232Q and intronic polymorphisms IVS10+155T>C, IVS10+156T>G, and IVS10-193G>C were found to have high frequency. Conclusion. A mutation spectrum with high frequency was predicted in Northern region of Iran due to its ethnic heterogeneity. Furthermore, it seems that the presence of some mutations in Golestan province indicates gene flow between Iran and the neighboring countries.

A novel Pah-exon1 deleted murine model of phenylalanine hydroxylase (PAH) deficiency

Phenylalanine hydroxylase (PAH) deficiency, colloquially known as phenylketonuria (PKU), is among the most common inborn errors of metabolism and in the past decade has become a target for the development of novel therapeutics such as gene therapy. PAH deficient mouse models have been key to new treatment development, but all prior existing models natively express liver PAH polypeptide as inactive or partially active PAH monomers, which complicates the experimental assessment of protein expression following therapeutic gene, mRNA, protein, or cell transfer. The mutant PAH monomers are able to form hetero-tetramers with and inhibit the overall holoenzyme activity of wild type PAH monomers produced from a therapeutic vector. Preclinical therapeutic studies would benefit from a PKU model that completely lacks both PAH activity and protein expression in liver. In this study, we employed CRISPR/Cas9-mediated gene editing in fertilized mouse embryos to generate a novel mouse model that lacks exon 1 of the Pah gene. Mice that are homozygous for the Pah exon 1 deletion are viable, severely hyperphenylalaninemic, accurately replicate phenotypic features of untreated human classical PKU and lack any detectable liver PAH activity or protein. This model of classical PKU is ideal for further development of gene and cell biologics to treat PKU.

Pathogenic variants of DNAJC12 and evaluation of the encoded cochaperone as a genetic modifier of hyperphenylalaninemia.

Biallelic variants of the gene DNAJC12, which encodes a cochaperone, were recently described in patients with hyperphenylalaninemia (HPA). This paper reports the retrospective genetic analysis of a cohort of unsolved cases of HPA. Biallelic variants of DNAJC12 were identified in 20 patients (generally neurologically asymptomatic) previously diagnosed with phenylalanine hydroxylase (PAH) deficiency (phenylketonuria [PKU]). Further, mutations of DNAJC12 were identified in four carriers of a pathogenic variant of PAH. The genetic spectrum of DNAJC12 in the present patients included four new variants, two intronic changes c.298-2A>C and c.502+1G>C, presumably affecting the splicing process, and two exonic changes c.309G>T (p.Trp103Cys) and c.524G>A (p.Trp175Ter), classified as variants of unknown clinical significance (VUS). The variant p.Trp175Ter was detected in 83% of the mutant alleles, with 14 cases homozygous, and was present in 0.3% of a Spanish control population. Functional analysis indicated a significant reduction in PAH and its activity, reduced tyrosine hydroxylase stability, but no effect on tryptophan hydroxylase 2 stability, classifying the two VUS as pathogenic variants. Additionally, the effect of the overexpression of DNAJC12 on some destabilizing PAH mutations was examined and a mutation-specific effect on stabilization was detected suggesting that the proteostasis network could be a genetic modifier of PAH deficiency and a potential target for developing mutation-specific treatments for PKU.

Screening of PAH Common Mutations in Chinese Phenylketonuria Patients Using iPLEX MALDI-TOF MS.

Phenylketonuria (PKU) is caused by phenylalanine hydroxylase (PAH) gene variants. Previous research has identified some PAH mutation hotspots in Chinese patients with PKU. In this study, we introduce a novel MassArray panel for screening the 29 common PAH gene mutations in Chinese patients using iPLEX MALDI-TOF MS. 105 Patients with PKU and known PAH gene mutations were genotyped using this MassArray panel. All of the 29 mutations screened were detected, and MassArray panel results were consistent with those obtained by Sanger sequencing. Fifty patients newly diagnosed with PKU were recruited in the double-blind experiment. PAH gene variants were detected in these 50 patients using the MassArray panel, and the results were verified with Sanger sequencing and Multiplex Ligation-dependent Probe Amplification (MLPA) methods. Our results show that the mutation detection rate using the MassArray panel with 29 mutations is 74% (95% CI, 65–83%), and the clinical genetic diagnosis rate is 54% (95% CI, 40–68%). This panel can be used as a high throughput, low cost, and rapid method for screening and diagnosing PAH gene mutations. The establishment of this approach provides proof-of-concept for future large-scale PAH mutation carrier screening in areas with high rates of PKU.

The molecular epidemiology of hyperphenylalaninemia in Uygur population: incidence from newborn screening and mutational spectra.

Neonatal hyperphenylalaninemia (HPA) screening did not begin until 2009 in the Uygur population because of poor medical and economic conditions. This study intended to investigate HPA incidence rate and characterize mutation spectrum of phenylalanine hydroxylase (PAH) gene within the Uygur population. Cross-sectional data of National Direct Reporting System database from 2009 to 2016 were used to calculate incidence rate. All HPA positive newborns were diagnosed and confirmed by Sanger sequencing. A low Phe diet was implemented. A total of 580,608 Uygur neonates were screened, 111 were diagnosed with HPA with an incidence rate of 1:5,230, 58 different mutations in PAH gene were detected. Eight novel variants were found, including two nonsense mutations (L11*, L197*), two splicing mutations (IVS12-2A > C, IVS13-1G > A), one frameshift mutation (K115 > Hfs) and three missense mutations (E368K, E370G, D435V), distributing in twenty patients. A104D was the most frequent mutation in this study, and the other hot spot of R413P was found in 4 patients in a same Uygur village with a carrier rate of 1:2.1. This is the first study to investigate HPA incidence rate in the Uygur population. Our study highlights regional differences in PAH genotypes and mutation rates.

Mutation spectrum and new mutation of phenylalanine hydroxylase gene in Guangxi region

Objective To investigate the characteristics of the phenylalanine hydroxylase(PAH) gene mutations in patients with phenylketonuria(PKU) in Guangxi region, in order to provide clinical data for genetic counseling and prenatal gene diagnosis. Methods Thirty-seven children diagnosed as PKU in the Maternal and Children′s Hospital of Guangxi Zhuang Autonomous Region were enrolled in the study between January 2009 and December 2017. Venous blood was collected and the PAH gene sequence was determined by Sanger sequencing after amplification with the polymerase chain reaction technique. The new gene mutations were defined based on the national and international literature review and databases.Meanwhile, 100 healthy individuals were selected as the control group for gene sequencing to confirm whether the mutation was a new one. Results Thirty-seven cases of PKU were detected for 68 mutations, with the detection rate being 91.89% (68/74). Six mutations were identified in exon 7, which accounted for 31.08% of all, exon 12(18.92%), exon 8(10.81%) and exon 6 (10.81%) followed.A total of 25 different mutations were identified which including 14 missense mutations(56.00%), 7 nonsense mutations(28.00%), 3 splicing junction mutations(12.00%), and 1 deletion mutation(4.00%). The most common mutations included c. 1223G>A(p.R408Q), c.728G>A(p.R243Q) and c. 721C>T(p.R241C), accounting for 14.86%, 13.51%, and 10.81%, respectively.After querying international databases, including PAH mutation database and Human Gene Mutation Database and forecasting software, three kinds of mutations c. 314C> T (p.T105I), c.583A> G (p.K195E), c .851G> A(p.C284Y) were verified as novel PAH gene mutations. Conclusions The mutation spectrum of the PAH gene in Guangxi has been identified.And 3 kinds of mutations have been identified.This may accumulate valuable information for gene diagnosis and prenatal diagnosis of PKU in Guangxi region. Key words: Phenylketonuria; Phenylalanine hydroxylase; Gene mutation

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 Enu1/1 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 Enu1/1 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.