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Phenylketonuria (PKU) is a rare genetic disease that causes brain toxicity due to the inability of the body to convert dietary phenylalanine to tyrosine by the action of phenylalanine hydroxylase. The only treatment for PKU so far is lifelong dietary intervention to ensure normal human growth and neurodevelopment. However, in adults, low long-term adherence to this type of dietary intervention has been observed. Given the important role of the intestinal microbiota in the process of digestion and disease prevention, probiotics could be a therapeutic strategy to help degrade dietary phenylalanine, reducing its levels before ingestion. Genetically modified probiotics designed as live biotherapeutic agents for the treatment of specific diseases are sophisticated alternative therapeutic strategies. In this review, the focus is on demonstrating what has been elucidated so far about the use of next-generation probiotics as a therapeutic strategy in the treatment of individuals with PKU. The results described in the literature are encouraging and use genetically modified engineered probiotics showing efficacy both in vitro and in vivo. These probiotics appear to be suitable for meeting the unmet need for new drugs for PKU.

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Introducción: la fenilcetonuria (PKU) es el error congénito del metabolismo de las proteínas más frecuente. El tratamiento dietético consiste en un plan de alimentación con una ingesta de proteínas naturales restringida, un sustituto proteico libre o de bajo contenido en fenilalanina (Phe) y el aporte de alimentos muy bajos en proteínas. El objetivo principal de este trabajo fue investigar si es posible aumentar la ingesta de proteína natural (PN) que se indica a los pacientes con PKU manteniendo los dosajes de Phe en sangre en rangos de seguridad. Materiales y método: se buscaron en 6 bases de datos electrónicas artículos publicados. Se identificaron un total de 154 artículos de Pub Med por intervalo de años desde 1999 a 2020. Se eligieron 15 artículos que se adaptaron a los criterios de inclusión y exclusión y respondían al objeto de estudio de esta revisión bibliográfica. Resultados: hay varios factores que pueden influenciar la estimación de la tolerancia de Phe como la severidad del fenotipo del paciente, la edad, el rango de seguridad de Phe en sangre, la prescripción de Phe y la adherencia al sustituto proteico. Si los niveles de Phe en sangre se mantienen en forma constante dentro del rango adecuado y por un período determinado, se debería considerar un incremento de la ingesta de Phe. El aumento de la ingesta de PN deberá ser realizado de manera controlada, individual y evaluando en forma constante el impacto en los dosajes de Phe en sangre. Conclusión: optimizar la ingesta de PN ofrece una mejora en la calidad de vida de pacientes con PKU, facilita la capacidad del paciente para socializar y contribuye a una mejor adherencia a la dieta(AU).

Introduction: phenylketonuria (PKU) is the most frequent inborn error of protein metabolism. The dietary treatment consists of a diet with a restricted natural protein intake, a free or low phenylalanine (Phe) protein substitute, and the intake of low protein food. The main objective of this work is to analyze if it is possible to increase the natural protein (NP) intake prescribed to PKU patients while maintaining blood Phe dosages within safe range. Materials and method: studies published were searched in 6 electronic data- basis. A total of 154 Pub Med articles were identified by range of years from 1999 to 2020. Fifteen articles which met the inclusion and exclusion criteria and responded to the objective of this bibliographic review were chosen. Results: several factors may influence Phe tolerance, such as severity of the patient´s phenotype, age, blood Phe safe range, Phe prescription and adherence to protein substitute. If Phe blood levels remain constantly within safe range and for a certain period, an increase of Phe intake should be considered. Increase of NP intake must be carried out in a controlled manner, individually and constantly evaluating blood Phe levels. Conclusion: optimizing NP intake offers the PKU patient an improvement in quality of life, facilitates the patient´s ability to socialize and contributes to a better adherence to the diet(AU).

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Phenylketonuria (PKU) is a common inborn error of amino acid metabolism in which the enzyme phenylalanine hydroxylase, which converts phenylalanine to tyrosine, is functionally impaired due to pathogenic variants in the PAH gene. Thirty-four Brazilian patients with a biochemical diagnosis of PKU, from 33 unrelated families, were analyzed through next-generation sequencing in the Ion Torrent PGM™ platform. Phenotype-genotype correlations were made based on the BioPKU database. Three patients required additional Sanger sequencing analyses. Twenty-six different pathogenic variants were identified. The most frequent variants were c.1315+1G>A (n = 8/66), c.473G>A (n = 6/66), and c.1162G>A (n = 6/66). One novel variant, c.524C>G (p.Pro175Arg), was found in one allele and was predicted as likely pathogenic by the American College of Medical Genetics and Genomics (ACMG) criteria. The molecular modeling of p.Pro175Arg indicated that this substitution can affect monomers binding in the PAH tetramer, which could lead to a change in the stability and activity of this enzyme. Next-generation sequencing was a fast and effective method for diagnosing PKU and is useful for patient phenotype prediction and genetic counseling.

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BACKGROUND: Accumulation of phenylalanine (Phe) due to deficiency in the enzyme phenylalanine hydroxylase (PAH), responsible for the conversion of Phe into tyrosine leads to Phenylketonuria (PKU), a rare autosomal recessive inborn error of metabolism with a mean prevalence of approximately 1:10,000 to 1:15,000 newborns. Physical, neurocognitive and psychiatric symptoms include neurodevelopmental disorder as intellectual disability and autism spectrum disorder. The most common treatments such as low-Phe diet and supplements may decrease blood Phe concentrations, but neuropsychological, behavioral and social issues still occur in some patients. This study aimed to better understand (i) the Brazilian population's knowledge about newborn screening (NBS), the main diagnostic method for PKU, as well as (ii) the impacts of phenylketonuria in the daily lives of patients and parents. METHODS: Two surveys in Real World Data format gathering of Brazilian residents by online questionnaires with (i) 1000 parents of children up to 5 years old between March and April 2019; (ii) 228 PKU patients and caregivers in March 2019. The survey was conducted in partnership with Abril Publisher and two Brazilian patient associations: Metabolic Mothers and SAFE Brasil, for families with rare diseases and PKU patients, respectively. RESULTS: The first questionnaire shows that 93% of parents recognize the importance of NBS and 92% report that their children have undergone the test. Still, two out of ten participants did not know what the exam is or what it is for. From the second questionnaire nine out of ten patients had their PKU diagnosis by NBS. Although strict dietary controls for PKU were claimed by 44% of respondents from second questionnaire, 55% assume not following all nutritionist recommendations and 52% did not maintain routinely Phe control levels. In addition, 53% said they had high spending on medical appointments, therapies and purchase of special foods. CONCLUSIONS: Despite the lack of understanding, the awareness of NBS importance is present in the studied population. The early diagnosis of most PKU patients in the study corroborates with neonatal screening central role of PKU early detection. The difficulty in adhering to dietary adjustments and the possibility that current and new therapeutic strategies other than diet could be determinant to achieve the recommended Phe levels.

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BACKGROUND: Genetic heterogeneity and compound heterozygosis give rise to a continuous spectrum of phenylalanine hydroxylase deficiency and metabolic phenotypes in phenylketonuria (PKU). The most used parameters for evaluating phenotype in PKU are pretreatment phenylalanine (Phe) levels, tolerance for dietary Phe, and Phe overloading test. Phenotype can vary from a "classic" (severe) form to mild hyperphenylalaninemia, which does not require dietary treatment. A subset of patients is responsive to treatment by the cofactor tetrahydrobiopterin (BH4 ). Genotypes of PKU patients from Rio de Janeiro, Brazil, were compared to predicted and observed phenotypes. Genotype-based estimations of responsiveness to BH4 were also conducted. METHODS: Phenotype was defined by pretreatment Phe levels. A standard prediction system based on arbitrary assigned values was employed to measure genotype-phenotype concordance. Patients were also estimated as BH4 -responders according to the responsiveness previously reported for their mutations and genotypes. RESULTS: A 48.3% concordance rate between genotype-predicted and observed phenotypes was found. When the predicted phenotypes included those reported at the BIOPKU database, the concordance rate reached 77%. A total of 18 genotypes from 30 patients (29.4%) were estimated as of potential or probable BH4 responsiveness. Inconsistencies were observed in genotypic combinations including the common "moderate" mutations p.R261Q, p.V388M, and p.I65T and the mild mutations p.L48S, p.R68S, and p.L249F. CONCLUSION: The high discordance rate between genotype-predicted and observed metabolic phenotypes in this study seems to be due partially to the high frequency of the so-called "moderate" common mutations, p.R261Q, p.V388M, and p.I65T, which are reported to be associated to erratic or more severe than expected metabolic phenotypes. Although our results of BH4 estimated responsiveness must be regarded as tentative, it should be emphasized that genotyping and genotype-phenotype association studies are important in selecting patients to be offered a BH4 overload test, especially in low-resource settings like Brazil.

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Abstract Phenylketonuria (PKU, OMIM 261600) is predominantly caused by mutations in the PAH gene. One hundred and three Argentine PKU patients were studied by Sanger sequencing; 101 were completely characterized (90.3% were compound heterozygotes). Fifty-four different pathogenic variants were identified. Mutations were distributed all along the PAH gene but concentrated in exon 7 (26%), 12 (12%), 11 (10%), and 6 (10%). 77% were missense, and 77% affected the enzyme catalytic domain, nine mutations accounted for 57% of 179 studied alleles: p.Arg261Gln (Allele frequency(AF):10.6%), c.1066-11G>A (AF:9,5%), p.Arg408Trp (AF:8,3%), p.Tyr414Cys (AF:5,5%), p.Ala403Val, p.Val388Met, and p.Arg158Gln (AF: 5% each), p.Leu48Ser, and p.Ile65Thr (AF:4% each). The predicted phenotype was assigned by Guldberg´s arbitrary value (AV) and compared with the clinical phenotype based in tolerance to Phe intake. 29.1% (n:30) were hyperphenylalaninemias, 18.5% (n:19) mild-PKU, 27.2% (n:28) moderate-PKU and 25.2 % (n:26) classical-PKU. Genotype/phenotype correlation was statistically significant (p<0.001) Overall concordance was 62,5%: 93.3% in hyperphenylalaninemia, 64.7% in mild-PKU and 65.4% in classical patients. The moderate-PKU showed a weak concordance (17%) with milder AV prediction than clinical assessment. 74% of discordant moderate patients harbored p.Arg261Gln, and p.Val388Met. Our cohort is highly heterogeneous, with predominant Mediterranean influence (mainly Spanish), but with differences with other Latin-American countries.

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RESUMEN Las mutaciones del gen PAH generan deficiencia de la enzima fenilalanina hidroxilasa. Su actividad final varía desde una actividad casi nula o indetectable en la fenilcetonuria clásica hasta una actividad residual del 10 al 35% de la normal. Esta alteración corresponde al error innato del metabolismo de los aminoácidos más frecuente, afectando a 1 de cada 10.000 personas. Las diferentes cantidades de fenilalanina en sangre se traducen en un espectro amplio de manifestaciones clínicas que incluyen retraso global del desarrollo, discapacidad intelectual, convulsiones, rasgos autistas y comportamiento agresivo en los casos más graves. El diagnóstico temprano a través de los programas de tamizaje neonatal se considera prioritario pues las intervenciones oportunas evitan el daño del sistema nervioso central. Conclusiones: El diagnóstico en Colombia es tardío, las intervenciones realizadas a partir de ese momento son fútiles pues el deterioro cognitivo es irreparable, por lo tanto es imperativa la realización de pruebas diagnósticas tempranas cuando aún las intervenciones médicas pueden impactar la mejoría clínica del paciente con disminución importante de la morbilidad propia de esta patología, convirtiéndose en una necesidad la ampliación del programa de tamizaje neonatal, el cual estaría amparado bajo la ley colombiana de enfermedades huérfanas.

ABSTRACT Mutations in the PAH gene generate phenylalanine hydroxylase enzyme deficiency. Its final activity varies from almost null or undetectable in classical phenylketonuria to a residual activity of 10 to 35% of normal activity. This alteration corresponds to the innate more frequent error of the metabolism of the amino acids, affecting 1 of every 10,000 people. Different amounts of phenylalanine in blood translate into a broad spectrum of clinical manifestations including global developmental delay, intellectual disability, seizures, autistic traits, and aggressive behavior in the most severe cases. Early diagnosis through neonatal screening programs is considered a priority because timely interventions avoid damage to the central nervous system. Conclusions: The diagnosis in Colombia is belated, the interventions made from that moment are futile because the cognitive deterioration is irreparable. Therefore, it is imperative to carry out early diagnostic tests when medical interventions can still impact the clinical improvement of the patient with an important decrease of the morbidity characteristic of this pathology, making it necessary to expand the neonatal screening program which would be protected under the Colombian law of orphan diseases.

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La fenilcetonuria es un error innato del metabolismo, producido por mutaciones en el gen de la fenilalanina hidroxilasa. Se describe el caso de un adolescente de 15 años con diagnóstico tardío de fenilcetonuria, quien presenta retardo mental severo, convulsiones e hipopigmentación. En este estudio se realizó el diagnóstico molecular de fenilcetonuria y se detectó la mutación p.R252W en homocigosis en el gen que codifica para la fenilalanina hidroxilasa. La presencia de esta variante nos permitió inferir la falta de respuesta a la terapia con sapropterina, medicamento que actúa como cofactor de la enzima, por la ausencia de actividad enzimática residual reportada para esta variante. Debido al retraso psicomotor del paciente, se decidió aplicar terapia lúdica y fortalecimiento muscular a través de la intervención fisioterapéutica; sin embargo, no se observó una mejoría permanente al aplicar este tratamiento, motivado por la falta de continuidad.

Phenylketonuria is an inborn error of metabolism due to mutations on the phenylalanine hydroxylase gene. We described the case of a 15 years old-adolescent with late diagnosis of phenylketonuria, who presents severe mental retardation, convulsions and hypopigmentation. In this study, the molecular diagnosis of phenylketonuria was performed, detecting p.R252W mutation in homozygous state on the phenylalanine hydroxylase gene. The presence of this variant allowed us to infer the lack of response to drug therapy with sapropterina which works as an enzyme cofactor, due to the absence of residual enzymatic activity reported for the p.R252W variant. Physical therapy was applied through playful therapy and muscular strengthening, because of the psychomotor retardation present in the patient. The failing in continuing with the physical therapy program stopped the patient´s improvement.

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Phenylketonuria (PKU) is an autosomal recessive disorder caused by a defective phenylalanine hydroxylase (PAH), which catalyzes the hydroxylation of l-phenylalanine (l-Phe) to l-tyrosine (l-Tyr) in presence of the cofactor tetrahydrobiopterin (BH4). Defective PAH causes accumulation of phenylalanine, which has neurotoxic effects and leads to dermatological, behavioral, and neurocognitive problems. Treatments for this disease consist in life-long diets that are hard for patients to keep, or supplementation with BH4. In this study, we propose a system where a probiotic lactic acid bacteria (LAB) can be used as vehicle to express in situ an engineered human PAH. Engineered PAHs contain a secretion peptide, a gastrointestinal signal (GI), the human PAH, and a flexible glycine linker followed by the fluorescence protein mEGFP. Engineered constructs were successfully transformed, expressed, and secreted in Lactobacillus plantarum CM_PUJ411. PAH construct containing either the signal peptide GI1 or GI2 were transported through a Caco-2 cell monolayer. Nevertheless, the one containing GI1 allowed the highest transport through the cell monolayer. Co-culture of L. plantarum and Caco-2 cells showed that engineered PAH is produced in-situ and transported through the cell monolayer. Finally, the activity test showed that the engineered PAH secreted by L. plantarum CM_PUJ411 is active, leading to a reduction in l-Phe and an increase in l-Tyr levels, respectively. These results show the potential of this system as a new therapeutic alternative for the treatment of PKU patients.

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Abstract Nearly half of all patients diagnosed with phenylalanine hydroxylase (PAH) deficiency, also known as phenylketonuria, are lost to follow-up (LTFU); most are adults who stopped attending clinic after the age of 18 years. To understand why adult patients with PAH deficiency disengage from their clinic, a focus group of 8 adults with PAH deficiency who had been LTFU for 2 or more years was held in March 2016. Ten clinicians observed the focus group and discussed strategies for successfully reengaging adult patients and encouraging lifelong management of PAH deficiency. Four strategies were proposed: (1) create a safe, supportive environment, (2) acknowledge patients as partners in their care, (3) develop individualized management plans, and (4) provide patients with additional resources. These strategies provide a framework to motivate change in clinical practice to meet the unique needs of adults with PAH deficiency.