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2. A second case of glutaminase hyperactivity: Expanding the phenotype with epilepsy.

Author

Rumping L, Pouwels PJW, Wolf NI, Rehmann H, Wamelink MMC, Waisfisz Q, Jans JJM, Prinsen HCMT, van de Kamp JM, and van Hasselt PM

Abstract

Glutaminase (GLS) hyperactivity was first described in 2019 in a patient with profound developmental delay and infantile cataract. Here, we describe a 4-year-old boy with GLS hyperactivity due to a de novo heterozygous missense variant in GLS , detected by trio whole exome sequencing. This boy also exhibits developmental delay without dysmorphic features, but does not have cataract. Additionally, he suffers from epilepsy with tonic clonic seizures. In line with the findings in the previously described patient with GLS hyperactivity, in vivo 3 T magnetic resonance spectroscopy (MRS) of the brain revealed an increased glutamate/glutamine ratio. This increased ratio was also found in urine with UPLC-MS/MS, however, inconsistently. This case indicates that the phenotypic spectrum evoked by GLS hyperactivity may include epilepsy. Clarifying this phenotypic spectrum is of importance for the prognosis and identification of these patients. The combination of phenotyping, genetic testing, and metabolic diagnostics with brain MRS and in urine is essential to identify new patients with GLS hyperactivity and to further extend the phenotypic spectrum of this disease., Competing Interests: The authors declare no conflict of interest., (© 2023 The Authors. JIMD Reports published by John Wiley & Sons Ltd on behalf of SSIEM.)

Published
2023
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3. Clinical, neuroradiological, and biochemical features of SLC35A2-CDG patients.

Author

Vals MA, Ashikov A, Ilves P, Loorits D, Zeng Q, Barone R, Huijben K, Sykut-Cegielska J, Diogo L, Elias AF, Greenwood RS, Grunewald S, van Hasselt PM, van de Kamp JM, Mancini G, Okninska A, Pajusalu S, Rudd PM, Rustad CF, Salvarinova R, de Vries BBA, Wolf NI, Ng BG, Freeze HH, Lefeber DJ, and Õunap K

Subjects
Adolescent, Atrophy, Child, Child, Preschool, Female, Glycosylation, Humans, Infant, Internationality, Magnetic Resonance Imaging, Male, Mass Spectrometry, Mutation, Young Adult, Brain Diseases pathology, Congenital Disorders of Glycosylation genetics, Congenital Disorders of Glycosylation pathology, Monosaccharide Transport Proteins genetics, Spasms, Infantile pathology
Abstract

SLC35A2-CDG is caused by mutations in the X-linked SLC35A2 gene encoding the UDP-galactose transporter. SLC35A2 mutations lead to hypogalactosylation of N-glycans. SLC35A2-CDG is characterized by severe neurological symptoms and, in many patients, early-onset epileptic encephalopathy. In view of the diagnostic challenges, we studied the clinical, neuroradiological, and biochemical features of 15 patients (11 females and 4 males) with SLC35A2-CDG from various centers. We describe nine novel pathogenic variations in SLC35A2. All affected individuals presented with a global developmental delay, and hypotonia, while 70% were nonambulatory. Epilepsy was present in 80% of the patients, and in EEG hypsarrhythmia and findings consistent with epileptic encephalopathy were frequently seen. The most common brain MRI abnormality was cerebral atrophy with delayed myelination and multifocal inhomogeneous abnormal patchy white matter hyperintensities, which seemed to be nonprogressive. Thin corpus callosum was also common, and all the patients had a corpus callosum shorter than normal for their age. Variable dysmorphic features and growth deficiency were noted. Biochemically, normal mucin type O-glycosylation and lipid glycosylation were found, while transferrin mass spectrometry was found to be more specific in the identification of SLC35A2-CDG, as compared to routine screening tests. Although normal glycosylation studies together with clinical variability and genetic results complicate the diagnosis of SLC35A2-CDG, our data indicate that the combination of these three elements can support the pathogenicity of mutations in SLC35A2., (© 2019 SSIEM.)

Published
2019
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4. The role of the clinician in the multi-omics era: are you ready?

Author

van Karnebeek CDM, Wortmann SB, Tarailo-Graovac M, Langeveld M, Ferreira CR, van de Kamp JM, Hollak CE, Wasserman WW, Waterham HR, Wevers RA, Haack TB, Wanders RJA, and Boycott KM

Subjects
Epigenomics, Female, Glycomics methods, Humans, Infant, Newborn, Male, Neonatal Screening methods, Neonatal Screening psychology, Neonatal Screening trends, Proteomics, Systems Biology methods, Genomics methods, Metabolomics methods, Molecular Diagnostic Techniques methods, Physician's Role
Abstract

Since Garrod's first description of alkaptonuria in 1902, and newborn screening for phenylketonuria introduced in the 1960s, P4 medicine (preventive, predictive, personalized, and participatory) has been a reality for the clinician serving patients with inherited metabolic diseases. The era of high-throughput technologies promises to accelerate its scale dramatically. Genomics, transcriptomics, epigenomics, proteomics, glycomics, metabolomics, and lipidomics offer an amazing opportunity for holistic investigation and contextual pathophysiologic understanding of inherited metabolic diseases for precise diagnosis and tailored treatment. While each of the -omics technologies is important to systems biology, some are more mature than others. Exome sequencing is emerging as a reimbursed test in clinics around the world, and untargeted metabolomics has the potential to serve as a single biochemical testing platform. The challenge lies in the integration and cautious interpretation of these big data, with translation into clinically meaningful information and/or action for our patients. A daunting but exciting task for the clinician; we provide clinical cases to illustrate the importance of his/her role as the connector between physicians, laboratory experts and researchers in the basic, computer, and clinical sciences. Open collaborations, data sharing, functional assays, and model organisms play a key role in the validation of -omics discoveries. Having all the right expertise at the table when discussing the diagnostic approach and individualized management plan according to the information yielded by -omics investigations (e.g., actionable mutations, novel therapeutic interventions), is the stepping stone of P4 medicine. Patient participation and the adjustment of the medical team's plan to his/her and the family's wishes most certainly is the capstone. Are you ready?

Published
2018
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5. X-linked creatine transporter deficiency: clinical aspects and pathophysiology.

Author

van de Kamp JM, Mancini GM, and Salomons GS

Subjects
Amino Acid Metabolism, Inborn Errors diagnosis, Amino Acid Metabolism, Inborn Errors drug therapy, Amino Acid Metabolism, Inborn Errors pathology, Animals, Brain Diseases, Metabolic, Inborn complications, Brain Diseases, Metabolic, Inborn genetics, Creatine genetics, Humans, Intellectual Disability genetics, Membrane Transport Proteins genetics, X-Linked Intellectual Disability complications, X-Linked Intellectual Disability genetics, Mice, Plasma Membrane Neurotransmitter Transport Proteins genetics, Amino Acid Metabolism, Inborn Errors genetics, Brain Diseases, Metabolic, Inborn physiopathology, Creatine deficiency, Genetic Diseases, X-Linked genetics, Intellectual Disability etiology, Membrane Transport Proteins deficiency, X-Linked Intellectual Disability physiopathology, Plasma Membrane Neurotransmitter Transport Proteins deficiency
Abstract

Creatine transporter deficiency was discovered in 2001 as an X-linked cause of intellectual disability characterized by cerebral creatine deficiency. This review describes the current knowledge regarding creatine metabolism, the creatine transporter and the clinical aspects of creatine transporter deficiency. The condition mainly affects the brain while other creatine requiring organs, such as the muscles, are relatively spared. Recent studies have provided strong evidence that creatine synthesis also occurs in the brain, leading to the intriguing question of why cerebral creatine is deficient in creatine transporter deficiency. The possible mechanisms explaining the cerebral creatine deficiency are discussed. The creatine transporter knockout mouse provides a good model to study the disease. Over the past years several treatment options have been explored but no treatment has been proven effective. Understanding the pathogenesis of creatine transporter deficiency is of paramount importance in the development of an effective treatment.

Published
2014
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7. Long-term follow-up and treatment in nine boys with X-linked creatine transporter defect.

Author

van de Kamp JM, Pouwels PJ, Aarsen FK, ten Hoopen LW, Knol DL, de Klerk JB, de Coo IF, Huijmans JG, Jakobs C, van der Knaap MS, Salomons GS, and Mancini GM

Subjects
Amino Acid Transport Disorders, Inborn genetics, Arginine metabolism, Arginine therapeutic use, Brain pathology, Child, Child, Preschool, Creatine therapeutic use, Genes, X-Linked, Glycine therapeutic use, Humans, Infant, Intelligence Tests, Magnetic Resonance Spectroscopy methods, Male, Neurons metabolism, Amino Acid Transport Disorders, Inborn therapy, Chromosomes, Human, X, Membrane Transport Proteins genetics
Abstract

The creatine transporter (CRTR) defect is a recently discovered cause of X-linked intellectual disability for which treatment options have been explored. Creatine monotherapy has not proved effective, and the effect of treatment with L-arginine is still controversial. Nine boys between 8 months and 10 years old with molecularly confirmed CRTR defect were followed with repeated (1)H-MRS and neuropsychological assessments during 4-6 years of combination treatment with creatine monohydrate, L-arginine, and glycine. Treatment did not lead to a significant increase in cerebral creatine content as observed with H(1)-MRS. After an initial improvement in locomotor and personal-social IQ subscales, no lasting clinical improvement was recorded. Additionally, we noticed an age-related decline in IQ subscales in boys affected with the CRTR defect.

Published
2012
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