MT-ATP6 mitochondrial disease identified by newborn screening reveals a distinct biochemical phenotype.

Although decreased citrulline is used as a newborn screening (NBS) marker to identify proximal urea cycle disorders (UCDs), it is also a feature of some mitochondrial diseases, including MT-ATP6 mitochondrial disease. Here we describe biochemical and clinical features of 11 children born to eight mothers from seven separate families who were identified with low citrulline by NBS (range 3-5 µM; screening cutoff >5) and ultimately diagnosed with MT-ATP6 mitochondrial disease. Follow-up testing revealed a pattern of hypocitrullinemia together with elevated propionyl-(C3) and 3-hydroxyisovaleryl-(C5-OH) acylcarnitines, and a homoplasmic pathogenic variant in MT-ATP6 in all cases. Single and multivariate analysis of NBS data from the 11 cases using Collaborative Laboratory Integrated Reports (CLIR; https://clir.mayo.edu) demonstrated citrulline <1st percentile, C3 > 50th percentile, and C5-OH >90th percentile when compared with reference data, as well as unequivocal separation from proximal UCD cases and false-positive low citrulline cases using dual scatter plots. Five of the eight mothers were symptomatic at the time of their child(ren)'s diagnosis, and all mothers and maternal grandmothers evaluated molecularly and biochemically had a homoplasmic pathogenic variant in MT-ATP6, low citrulline, elevated C3, and/or elevated C5-OH. All molecularly confirmed individuals (n = 17) with either no symptoms (n = 12), migraines (n = 1), or a neurogenic muscle weakness, ataxia, and retinitis pigmentosa (NARP) phenotype (n = 3) were found to have an A or U mitochondrial haplogroup, while one child with infantile-lethal Leigh syndrome had a B haplogroup.

Asymptomatic 3-methylglutaconic aciduria type 1 detected by high C5-OH on newborn screening.

3-Methylglutaconic aciduria type 1 (MGCA1) is an inborn error of leucine catabolism caused by pathogenic variants of the AUH gene. MGCA1 can be identified by newborn screening (NBS) with elevated C5-OH levels. We herein report a girl with MGCA1 detected by NBS. On day 5 after birth, NBS detected high C5-OH levels of 1.17 µmol/L (1.56 µmol/L [retest]). A urinary organic acid analysis revealed the abnormal excretion of 3-methylglutaconic, 3-methylglutaric, and 3-hydroxyisovaleric acids. Two novel heterozygous loss-of-function variants in the AUH gene were identified by genetic testing. We observed the patient without any treatment, such as a leucine-restricted diet. She had episodes of febrile illness several times in infancy but did not develop febrile convulsions or encephalopathy. She is now two years and six months old, and her physical growth and psychomotor development have progressed normally. In a review of the literature and our case, four children with MGCA1 identified during the neonatal period were asymptomatic or exhibited speech delay, regardless of whether or not they had been managed with specific treatments. Treatments such as dietary leucine restriction and carnitine supplementation may have little effect on MGCA1 in childhood; however, further investigation is warranted to evaluate the benefits of specific treatments to prevent potential long-term neurological complications.

3-Methylglutaconyl-CoA hydratase deficiency: When ascertainment bias confounds a biochemical diagnosis.

3-Methylglutaconyl-CoA hydratase deficiency (MGA1) is a defect in leucine catabolism, which causes the accumulation of urinary 3-methylglutaconate, with or without 3-hydroxyisovalerate and 3-methylglutarate. It is an ultra-rare condition, with <30 cases published in the literature. It is unclear whether the clinical features seen in reported patients are caused by the biochemical abnormalities, or whether they simply represent an ascertainment bias in patients that come to clinical attention. We reviewed the collective Australian experience of patients with confirmed MGA1, four of whom were diagnosed when asymptomatic through newborn screening (NBS). When our cohort is considered alongside the broader literature, there is no clear evidence of a specific childhood-onset clinical phenotype associated with this disorder. Some patients have non-specific clinical features (such as autism spectrum disorder [ASD]); however, there are also other family members with ASD in the absence of MGA1, suggesting a multifactorial aetiology. Importantly, all four patients diagnosed through NBS (including three with over 18 years of clinical follow-up) remain asymptomatic in the absence of treatment. Based on the available literature, we suggest that MGA1 represents a biochemical phenotype, with an absence of a childhood clinical phenotype. The burdens of sustained treatment (particularly with intensive dietary leucine restriction) in asymptomatic individuals may be of little benefit, and likely to result in poor compliance. Longer-term follow-up of patients detected via NBS (or biochemical screening of large cohorts of asymptomatic adult individuals) will be required to conclusively prove or disprove the association with adult-onset leukoencephalopathy.

Diagnosis and management of symptomatic profound biotinidase deficiency in a tertiary care center in Lebanon.

Neonatal screening for biotinidase deficiency is still lacking in several countries worldwide, although this neurocutaneous disorder is treatable and preventable. Therefore, unscreened patients are diagnosed when symptomatic; treatment with Biotin is known to reverse cutaneous symptoms and improve neurological outcome. We describe a series of five symptomatic patients diagnosed with profound biotinidase deficiency and followed at a tertiary care center in Lebanon, for a variable period from 16 months to 11 years. Adjustment of Biotin therapy is correlated to clinical response and biochemical profile including 3-hydroxyisovalerylcarnitine on dried blood spots and urine organic acids. A previously unreported mutation is also reported in a patient who displayed an unusual outcome with reversible hearing loss on Biotin therapy. Clinical responsiveness to Biotin may be related to the underlying genetic mutation, although no clear genotype-phenotype correlation in biotinidase deficiency is proven. Furthermore, in the absence of systematic newborn screening for this disorder in several countries, identification of a reliable blood biomarker of Biotin responsiveness is warranted for better management of late diagnosed symptomatic patients.

High frequency of biotinidase deficiency in Italian population identified by newborn screening.

The biotinidase (BTD) enzyme is essential for recycling biotin, a water-soluble B-complex vitamin that is the coenzyme of four carboxylases involved in fatty acid synthesis, amino acid catabolism and gluconeogenesis. If untreated, total or partial BTD deficiencies lead to an autosomal recessive inherited organic aciduria whose clinical features, mainly presenting in the first years of life, include, seizures, skin rash, and alopecia. Based on residual BTD enzyme activity it is possible to identify partial or total biotinidase deficiency. The incidence of profound and partial biotinidase deficiency worldwide is estimated to be about 1 in 60.000. We report twelve years of experience in the newborn screening of biotinidase deficiency on 466.182 neonates. When a positive screening result occurred, a clinical evaluation was made of the patient and genetic counselling was offered to the family. Molecular analysis the BTD gene was carried out in all recalled neonates. Newborn screening lead to the identification of 75 BTD deficiencies with an incidence of about 1:6.300 births, ten times higher than the reported worldwide incidence. BTD deficiency was confirmed at a genomic level in all patients, demonstrating a high frequency of the p.(Asp444His) amino acid substitution and the complex allele p.(Ala171Thr)/p.(Asp444His) in the analyzed Italian newborns. Four new mutations (two small deletions, one stop mutation and one missense mutation) and a new combined allelic alteration were identified. Our data suggests that there is a high incidence of the biotinidase defect in the Italian population, most likely due to the high frequency of certain mutations.

Precocious puberty in a girl with 3-methylglutaconic aciduria type 1 (3-MGA-I) due to a novel AUH gene mutation.

3-methylglutaconic aciduria type 1 (3-MGA-I) (MIM ID #250950) is an ultra-rare, autosomal recessive organic aciduria, resulting from mutated AUH gene, leading to the deficient 3-methylglutaconyl-CoA hydratase (3-MGH). Only around 40 cases are previously reported, caused by a spectrum of 10 mutations. The clinical spectrum of 3-MGA-I in children is heterogeneous, varying from asymptomatic individuals to mild neurological impairment, speech delay, quadriplegia, dystonia, choreoathetoid movements, severe encephalopathy, psychomotor retardation, basal ganglia involvement. Early dietary treatment with leucine restriction and carnitine supplementation may be effective in improving neurological state in pediatric patients with 3-MGA-I. We presented a girl with 3-MGA-I due to novel AUH gene mutation (homozygous variant c.330 + 5G > A) and confirmed by almost undetectable 3-MGH-enzyme activity, who initially presented with central precocious puberty at an early age of 4.5 years. Precocious puberty might be associated with the 3-MGA-I, as is reported previously in some other metabolic disorders that result in pathologic accumulation of metabolites or toxic brain damage. Therapy with GnRH agonist triptorelin effectively arrested pubertal development.

Metabolic encephalopathy in beta-ketothiolase deficiency: the first report from India.

Beta-ketothiolase deficiency, or mitochondrial acetoacetyl-CoA thiolase (T2) deficiency, is a rare autosomal recessive disorder affecting isoleucine catabolism and ketone body metabolism. A patient from South India presented with acute ketoacidosis at 11 months of age. During the acute crisis the C5OH (2-methyl-3-hydroxybutyryl) carnitine and C5:1 (tiglyl) carnitine were elevated and large amounts of 2-methyl-3-hydroxybutyrate, tiglylglycine, and 2-methylacetoacetate were excreted. Brain CT showed bilateral basal ganglia lesions. Potassium ion-activated acetoacetyl-CoA thiolase activity was deficient in the patient's fibroblasts. The patient is a homozygote for a novel c.578T>G (M193R) mutation. This is the first report of T2 deficiency confirmed by enzyme and molecular analysis from India.