4.7 Article

One-carbon metabolism is required for epigenetic stability in the mouse placenta

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FRONTIERS MEDIA SA
DOI: 10.3389/fcell.2023.1209928

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DNA methylation; folate; histone methylation; MTRR; sperm; transposable elements; trophoblast; epigenetic inheritance

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One-carbon metabolism plays a crucial role in fetal development, but its molecular function is complex and unclear. This study reveals genome-wide epigenetic instability in Mtrr ( gt/gt ) placentas and identifies abnormal DNA methylation and expression of key genes, suggesting a role for histone modifications in epigenetic inheritance.
One-carbon metabolism, including the folate cycle, has a crucial role in fetal development though its molecular function is complex and unclear. The hypomorphic Mtrr ( gt ) allele is known to disrupt one-carbon metabolism, and thus methyl group availability, leading to several developmental phenotypes (e.g., neural tube closure defects, fetal growth anomalies). Remarkably, previous studies showed that some of the phenotypes were transgenerationally inherited. Here, we explored the genome-wide epigenetic impact of one-carbon metabolism in placentas associated with fetal growth phenotypes and determined whether specific DNA methylation changes were inherited. Firstly, methylome analysis of Mtrr ( gt/gt ) homozygous placentas revealed genome-wide epigenetic instability. Several differentially methylated regions (DMRs) were identified including at the Cxcl1 gene promoter and at the En2 gene locus, which may have phenotypic implications. Importantly, we discovered hypomethylation and ectopic expression of a subset of ERV elements throughout the genome of Mtrr ( gt/gt ) placentas with broad implications for genomic stability. Next, we determined that known spermatozoan DMRs in Mtrr ( gt/gt ) males were reprogrammed in the placenta with little evidence of direct or transgenerational germline DMR inheritance. However, some spermatozoan DMRs were associated with placental gene misexpression despite normalisation of DNA methylation, suggesting the inheritance of an alternative epigenetic mechanism. Integration of published wildtype histone ChIP-seq datasets with Mtrr ( gt/gt ) spermatozoan methylome and placental transcriptome datasets point towards H3K4me3 deposition at key loci. These data suggest that histone modifications might play a role in epigenetic inheritance in this context. Overall, this study sheds light on the mechanistic complexities of one-carbon metabolism in development and epigenetic inheritance.

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