Association of embryonic inositol status with susceptibility to neural tube defects, metabolite profile, and maternal inositol intake

Abstract

AbstractMaternal nutrition contributes to gene–environment interactions that influence susceptibility to common congenital anomalies such as neural tube defects (NTDs). Supplemental myo‐inositol (MI) can prevent NTDs in some mouse models and shows potential for prevention of human NTDs. We investigated effects of maternal MI intake on embryonic MI status and metabolism in curly tail mice, which are genetically predisposed to NTDs that are inositol‐responsive but folic acid resistant. Dietary MI deficiency caused diminished MI in maternal plasma and embryos, showing that de novo synthesis is insufficient to maintain MI levels in either adult or embryonic mice. Under normal maternal dietary conditions, curly tail embryos that developed cranial NTDs had significantly lower MI content than unaffected embryos, revealing an association between diminished MI status and failure of cranial neurulation. Expression of inositol‐3‐phosphate synthase 1, required for inositol biosynthesis, was less abundant in the cranial neural tube than at other axial levels. Supplemental MI or d‐chiro‐inositol (DCI) have previously been found to prevent NTDs in curly tail embryos. Here, we investigated the metabolic effects of MI and DCI treatments by mass spectrometry‐based metabolome analysis. Among inositol‐responsive metabolites, we noted a disproportionate effect on nucleotides, especially purines. We also found altered proportions of 5‐methyltetrahydrolate and tetrahydrofolate in MI‐treated embryos suggesting altered folate metabolism. Treatment with nucleotides or the one‐carbon donor formate has also been found to prevent NTDs in curly tail embryos. Together, these findings suggest that the protective effect of inositol may be mediated through the enhanced supply of nucleotides during neural tube closure.