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http://dx.doi.org/10.3339/jkspn.2018.22.2.37

Novel SLC5A2 Mutations and Genetic Characterization in Korean Patients with Familial Renal Glucosuria  

Lee, Weon Kyung (Department of Pediatrics, Inje University College of Medicine)
Oh, Seung Hwan (Department of Laboratory Medicine, Inje University College of Medicine)
Chung, Woo Yeong (Department of Pediatrics, Inje University College of Medicine)
Publication Information
Childhood Kidney Diseases / v.22, no.2, 2018 , pp. 37-41 More about this Journal
Abstract
Purpose: Familial renal glucosuria (FRG, OMIM #233100) is a rare but relatively benign genetic condition characterized by persistent isolated glucosuria with a normal blood glucose level. We report three additional SLC5A2 mutations and examine their phenotypic and genetic characteristics in a Korean FRG cohort. We also reviewed the literature and summarized the genotypes of all Korean patients with FRG. Methods: A genetic analysis was conducted by directly sequencing all 14 exons of the SLC5A2 gene and their flanking regions in six unrelated Korean children with FRG and their family members. Novel non-synonymous single-nucleotide polymorphisms were identified and compared with known mutations that are repeatedly detected in the Korean population. Results: We found two novel mutations [c.274G>A (G92S) and c.1168C>T (L390F)] and one known [c.1382G>A (S461N)] mutation in each family and one recurrent mutation [c.1346G>A (G449D) (rs768392222)] in two pedigrees. The recurrent G449D was predicted to be "possibly damaging," with a score of 0.883 in Polyphen-2, while G92S, L390F, and S461N were predicted to be "probably damaging," with scores of 1.000, 0.999, and 0.996, respectively. Conclusions: Two novel, one previously reported, and one recurrent mutation were identified in six Korean FRG pedigrees as causative mutations of renal glucosuria. Sequence variations in the SLC5A2 gene were frequently detected in children with persistent isolated glucosuria. A long-term follow-up of this FRG cohort is needed to understand how these specific SGLT2 mutations impair kidney function and energy homeostasis.
Keywords
SGLT2; Glucose; Glucosuria; Mutation;
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