Formate supplementation enhances folate-dependent nucleotide biosynthesis and prevents spina bifida in a mouse model of folic acid-resistant neural tube defects.

Sonia Sudiwala,Andrew J Copp,Nicholas D.E Greene,Kevin Mills,John T Brosnan,Sandra C.P De Castro,Kit-Yi Leung,Margaret E Brosnan

doi:10.1016/j.biochi.2016.02.010

Sonia Sudiwala, Andrew J Copp + Show 6 more

Open Access

https://doi.org/10.1016/j.biochi.2016.02.010

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Abstract

The curly tail mouse provides a model for neural tube defects (spina bifida and exencephaly) that are resistant to prevention by folic acid. The major ct gene, responsible for spina bifida, corresponds to a hypomorphic allele of grainyhead-like 3 (Grhl3) but the frequency of NTDs is strongly influenced by modifiers in the genetic background. Moreover, exencephaly in the curly tail strain is not prevented by reinstatement of Grhl3 expression. In the current study we found that expression of Mthfd1L, encoding a key component of mitochondrial folate one-carbon metabolism (FOCM), is significantly reduced in ct/ct embryos compared to a partially congenic wild-type strain. This expression change is not attributable to regulation by Grhl3 or the genetic background at the Mthfd1L locus. Mitochondrial FOCM provides one-carbon units as formate for FOCM reactions in the cytosol. We found that maternal supplementation with formate prevented NTDs in curly tail embryos and also resulted in increased litter size. Analysis of the folate profile of neurulation-stage embryos showed that formate supplementation resulted in an increased proportion of formyl-THF and THF but a reduction in proportion of 5-methyl THF. In contrast, THF decreased and 5-methyl THF was relatively more abundant in the liver of supplemented dams than in controls. In embryos cultured through the period of spinal neurulation, incorporation of labelled thymidine and adenine into genomic DNA was suppressed by supplemental formate, suggesting that de novo folate-dependent biosynthesis of nucleotides (thymidylate and purines) was enhanced. We hypothesise that reduced Mthfd1L expression may contribute to susceptibility to NTDs in the curly tail strain and that formate acts as a one-carbon donor to prevent NTDs.

Highlights

The network of reactions that comprises folate one-carbon metabolism (FOCM) supplies one carbon units for a number of downstream biosynthetic pathways including nucleotide biosynthesis and methylation reactions [1,2]
FA does not prevent NTDs in curly tail mice, we found that intervening downstream of FOCM, at the level of nucleotide biosynthesis may influence the rate of NTDs
Spina bifida occurs in 10e15% of ct/ct embryos and can be principally attributed to reduced expression of grainyhead-like 3 (Grhl3), being fully rescued by transgenic Grhl3 expression [13]

Summary

Introduction

The network of reactions that comprises folate one-carbon metabolism (FOCM) supplies one carbon units for a number of downstream biosynthetic pathways including nucleotide biosynthesis and methylation reactions [1,2]. Sudiwala et al / Biochimie xxx (2016) 1e8 biosynthesis was identified in a subset of cell lines from NTD patients [7] Together these data suggest that there is a contribution of abnormal FOCM to NTDs, it is currently unclear whether this corresponds to NTDs that are preventable by or resistant to folic acid. Among mouse models of NTDs, some are responsive to folic acid, including splotch (Sp2H, Pax3) and Cited null strains [8e10], while others are resistant [11]. Homozygous ct/ct embryos develop partially penetrant NTDs comprising spina bifida and/or exencephaly These defects arise due to failure in completion of neural tube closure in the spinal and cranial regions respectively. A polymorphic variant of Lmnb was found to influence the frequency of both cranial and spinal NTDs [16]

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