Abstract
Dietary folate deficiency (FD) is associated with the occurrence of birth defects. However, the mechanisms underlying this association remain elusive. In particular, how FD affects genome stability is unknown. To examine whether a folate-deficient diet can affect genome stability, C57BL/6 mice were maintained on a synthetic diet lacking of folic acid (FA) for two generations. F0 mice received the FD diet beginning at 3 weeks of age, and their offspring (F1) began the FD diet after weaning. Both male and female F1 mice fed the FD diet were intentionally crossed with F1 mice fed the normal diet to produce F2 mice. F2 embryos were dissected and collected at E14.5 and E18.5. The malformation ratio was significantly increased in F2 embryos fed the FD diet for two generations compared to those fed the normal diet. Whole-genome sequencing of multiple sibship with F1 males on the FD diet showed that the de novo mutation (DNM) rate in F2 embryos was three times of the reported spontaneous rate in mice. Furthermore, many DNMs observed in the F2 mice exhibited an allele ratio of 1:3 instead of 2:2, suggesting that these mutations are likely to accumulate in gamete cells as a form of mismatch in the DNA duplex. Our study indicated that FD for two generations significantly enhances DNM accumulation during meiosis, which might contribute to the increased negative birth outcomes among F2 mice. Not only maternal but also paternal FA supplementation is probably also necessary and beneficial to prevent birth defects.
Highlights
Dietary folate is an essential micronutrient for life
In groups A, B, and C, F1 males (F1♂) on the folate deficiency (FD) diet were crossed with females on the FS diet to generate F2 embryos; while in groups A’, B’, and C’, F1 females (F1♀) on the FD diet were crossed with males on the FS diet to generate F2 embryos
It remains elusive whether a FD diet causes de novo mutation (DNM) and whether this contributes to negative reproductive outcomes
Summary
Dietary folate is an essential micronutrient for life. It is required for epigenetic regulation of gene expression through methylation, and for cell proliferation, as it is involved in de novo nucleotide synthesis. It has been shown that gestational folate deficiency (FD) is associated with poor reproductive outcomes and birth defects[1], especially neural tube defects (NTDs)[2,3], orofacial clefts[4,5], and congenital heart diseases (CHDs)[2,6]. The mechanism by which FD causes an increased rate of birth defects is still unclear. It is uncertain whether paternal folate supplementation can contribute to birth defect prevention. In addition to affecting methylation, it has been proposed that FD can affect DNA stability/
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