Effect of riboflavin deficiency on development of the cerebral cortex in Slc52a3 knockout mice

Riboflavin transporter 3 (RFVT3), encoded by the SLC52A3 gene, is important for riboflavin homeostasis in the small intestine, kidney, and placenta. Our previous study demonstrated that Slc52a3 knockout (Slc52a3−/−) mice exhibited neonatal lethality and metabolic disorder due to riboflavin deficiency. Here, we investigated the influence of Slc52a3 gene disruption on brain development using Slc52a3−/− embryos. Slc52a3−/− mice at postnatal day 0 showed hypoplasia of the brain and reduced thickness of cortical layers. At embryonic day 13.5, the formation of Tuj1+ neurons and Tbr2+ intermediate neural progenitors was significantly decreased; no significant difference was observed in the total number and proliferative rate of Pax6+ radial glia. Importantly, the hypoplastic phenotype was rescued upon riboflavin supplementation. Thus, it can be concluded that RFVT3 contributes to riboflavin homeostasis in embryos and that riboflavin itself is required during embryonic development of the cerebral cortex in mice

Complete Deletion of Slc52a2 Causes Embryonic Lethality in Mice

Riboflavin (vitamin B2) plays an important role in cellular growth and function. Riboflavin transporter 2 (RFVT2) is widely expressed in several tissues, especially in the brain and salivary glands, and plays an important role in the tissue disruption of riboflavin. During the last 10 years, mutations in SLC52A2 have been documented in patients with a rare neurological disorder known as Brown-Vialetto-Van Laere syndrome. However, no suitable animal model of this disease has been reported. Here, we aimed to clarify the physiological role of RFVT2 using Slc52a2-mutant mice. The appearance, body weight, and plasma riboflavin concentration of Slc52a2 heterozygous mutant (Slc52a2+/-) mice were similar to those of wild-type (WT) mice. However, intercrossing between Slc52a2+/- mice failed to generate Slc52a2 homozygous mutant (Slc52a2-/-) mice. This suggested that Slc52a2 gene deficiency results in early embryonic lethality. Our findings suggested that RFVT2 is essential for growth and development, and its deletion may influence embryonic survival

Riboflavin transporters RFVT/SLC52A mediate translocation of riboflavin, rather than FMN or FAD, across Plasma Membrane

Riboflavin (vitamin B2) plays a role in various biochemical oxidation-reduction reactions. Flavin mononucleotide (FMN) and FAD, the biologically active forms, are made from riboflavin. Riboflavin transporters (RFVTs), RFVT1-3/Slc52a1-3, have been identified. However, the roles of human (h)RFVTs in FMN and FAD homeostasis have not yet been fully clarified. In this study, we assessed the contribution of each hRFVT to riboflavin, FMN and FAD uptake and efflux using in vitro studies. The transfection of hRFVTs increased cellular riboflavin concentrations. The uptake of riboflavin by human embryonic kidney cells transfected with hRFVTs was significantly increased, and the efflux was accelerated in a time-dependent manner. However, the uptake and efflux of FMN and FAD hardly changed. These results strongly suggest that riboflavin, rather than FMN or FAD, passes through plasma membranes via hRFVTs. Our findings could suggest that hRFVTs are involved in riboflavin homeostasis in the cells, and that FMN and FAD concentrations are regulated by riboflavin kinase and FAD synthase