We identified biallelic mutations in NANS, the gene encoding the synthase for N-acetylneuraminic acid (NeuNAc; sialic acid), in nine individuals with infantile-onset severe developmental delay and skeletal dysplasia. Patient body fluids showed an elevation in N-acetyl-D-mannosamine levels, and patient-derived fibroblasts had reduced NANS activity and were unable to incorporate sialic acid precursors into sialylated glycoproteins. Knockdown of nansa in zebrafish embryos resulted in abnormal skeletal development, and exogenously added sialic acid partially rescued the skeletal phenotype. Thus, NANS-mediated synthesis of sialic acid is required for early brain development and skeletal growth. Normal sialylation of plasma proteins was observed in spite of NANS deficiency. Exploration of endogenous synthesis, nutritional absorption, and rescue pathways for sialic acid in different tissues and developmental phases is warranted to design therapeutic strategies to counteract NANS deficiency and to shed light on sialic acid metabolism and its implications for human nutrition. DOI: https://doi.org/10. 1038/ng.3578 Posted at the Zurich Open Repository and Archive, University of Zurich ZORA URL: https://doi.org/10.5167/uzh-130493 Accepted Version Originally published at: van Karnebeek, Clara D M; Bonafé, Luisa; Wen, Xiao-Yan; Tarailo-Graovac, Maja; Balzano, Sara; RoyerBertrand, Beryl; Ashikov, Angel; Garavelli, Livia; Mammi, Isabella; Turolla, Licia; Breen, Catherine; Donnai, Dian; Cormier, Valerie; Heron, Delphine; Nishimura, Gen; Uchikawa, Shinichi; Campos-Xavier, Belinda; Rossi, Antonio; Hennet, Thierry; Brand-Arzamendi, Koroboshka; Rozmus, Jacob; Harshman, Keith; Stevenson, Brian J; Girardi, Enrico; Superti-Furga, Giulio; Dewan, Tammie; Collingridge, Alissa; Halparin, Jessie; Ross, Colin J; Van Allen, Margot I;et al (2016). NANS-mediated synthesis of sialic acid is required for brain and skeletal development. Nature Genetics, 48 (7) insights into the molecular basis of neurocognitive impairment allows for the development and 89 application of targeted therapeutic strategies 5 . Although less frequent than IDD, genetic disorders 90 affecting skeletal development and growth (commonly called the "skeletal dysplasias") are a 91 group of over 500 distinct disorders 6 . Studying their molecular basis has provided precious 92 insights into the many factors necessary for skeletal development, ranging from minerals and 93 structural molecules to enzymes, to signaling molecules and transcription factors 6,7 . We report 94here a genetic disorder presenting with a combination of severe IDD with skeletal dysplasia and 95 short stature. Our data show that its pathogenic basis is an inborn error of metabolism that 96 affects the endogenous synthesis of N-acetyl neuraminic acid (NeuNAc; sialic acid). Exploration 97 of the biochemical and molecular features of this disorder provides new information on the role 98 of sialic acid in the development of brain and bone. 99 100 RESULTS 101 Clinical and radiographic phenotype of N...
The most common mutation in the nephropathic cystinosis (CTNS) gene is a homozygous 57-kb deletion that also includes an adjacent gene carbohydrate kinase-like (CARKL). The latter gene encodes a protein that is predicted to function as a carbohydrate kinase. Cystinosis patients with the common 57-kb deletion had strongly elevated urinary concentrations of sedoheptulose (28-451 mmol/mol creatinine; controls and other cystinosis patients <9) and erythritol (234-1110 mmol/mol creatinine; controls and other cystinosis patients <148). Enzyme studies performed on fibroblast homogenates derived from patients carrying the 57-kb deletion revealed 80% reduction in their sedoheptulose phosphorylating activity compared to cystinosis patients with other mutations and controls. This indicates that the CARKL-encoded protein, sedoheptulokinase (SHK), is responsible for the reaction: sedoheptulose + ATP --> sedoheptulose-7-phosphate + ADP and that deletion of CARKL causes urinary accumulation of sedoheptulose and erythritol.
Sialic acids are important components of glycoproteins and glycolipids essential for cellular communication, infection, and metastasis. The importance of sialic acid biosynthesis in human physiology is well illustrated by the severe metabolic disorders in this pathway. However, the biological role of sialic acid catabolism in humans remains unclear. Here, we present evidence that sialic acid catabolism is important for heart and skeletal muscle function and development in humans and zebrafish. In two siblings, presenting with sialuria, exercise intolerance/muscle wasting, and cardiac symptoms in the brother, compound heterozygous mutations [chr1:182775324C>T (c.187C>T; p.Arg63Cys) and chr1:182772897A>G (c.133A>G; p.Asn45Asp)] were found in the N-acetylneuraminate pyruvate lyase gene (NPL). In vitro, NPL activity and sialic acid catabolism were affected, with a cell-type-specific reduction of N-acetyl mannosamine (ManNAc). A knockdown of NPL in zebrafish resulted in severe skeletal myopathy and cardiac edema, mimicking the human phenotype. The phenotype was rescued by expression of wild-type human NPL but not by the p.Arg63Cys or p.Asn45Asp mutants. Importantly, the myopathy phenotype in zebrafish embryos was rescued by treatment with the catabolic products of NPL: N-acetyl glucosamine (GlcNAc) and ManNAc; the latter also rescuing the cardiac phenotype. In conclusion, we provide the first report to our knowledge of a human defect in sialic acid catabolism, which implicates an important role of the sialic acid catabolic pathway in mammalian muscle physiology, and suggests opportunities for monosaccharide replacement therapy in human patients.
Background Sedoheptulose, arabitol, ribitol, and erythritol have been identified as key diagnostic metabolites in TALDO deficiency. Method Urine from 6 TALDO-deficient patients and TALDO-deficient knock-out mice were analyzed using 1H-NMR spectroscopy and GC–mass spectrometry. Results Our data confirm the known metabolic characteristics in TALDO-deficient patients. The β-furanose form was the major sedoheptulose anomer in TALDO-deficient patients. Erythronic acid was identified as a major abnormal metabolite in all patients and in knock-out TALDO mice implicating an as yet unknown biochemical pathway in this disease. A putative sequence of enzymatic reactions leading to the formation of erythronic acid is presented. The urinary concentration of the citric acid cycle intermediates 2-oxoglutaric acid and fumaric acid was increased in the majority of TALDO-deficient patients but not in the knock-out mice. Conclusion Erythronic acid is a novel and major hallmark in TALDO deficiency. The pathway leading to its production may play a role in healthy humans as well. In TALDO-deficient patients, there is an increased flux through this pathway. The finding of increased citric acid cycle intermediates hints toward a disturbed mitochondrial metabolism in TALDO deficiency.
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