Project description:Maternal dietary insufficiencies can reshape the offspring epigenome during gestation, contributing to birth defects and developmental disorders. Vitamin C (VitC) is a critical co-factor for Ten-Eleven-Translocation (TET) DNA demethylases, but the impact of its deficiency on embryonic development remains unclear. Here, we show that insufficient maternal VitC combined with genetic susceptibility can give rise to congenital malformations, including neural tube defects (NTDs), through dysregulation of DNA methylation. We previously reported NTDs in Tet1 knockout (KO) mice at low penetrance in C57BL/6J (B6) congenic inbred strains, but at two- to three-fold higher rates when outbred or highly backcrossed (incipient congenic) on a 129S6.B6 background. Similarly, maternal VitC deficiency in L-gulonolactone oxidase (Gulo) KO mice, which like humans are unable to synthesize VitC, resulted in highly penetrant congenital malformations in non-inbred mice, during a vulnerable window coinciding with gastrulation. DNA hypermethylation is a signature of VitC-deprived 129S6.B6-Gulo-/- embryonic headfold tissues, being absent in B6 embryos which are grossly normal. In outbred Gulo-/- embryonic brains, genomic regions harboring hypermethylation – hallmarks of TET dysfunction - increased with the severity of embryonic pathologies. A moderate reduction in VitC status is sufficient to induce hypermethylated regions and cause NTDs. Severe embryonic defects in VitC-deprived embryos can be rescued by timely re-supplementation of VitC at the onset of gastrulation, which normalized DNA methylation at most loci. Our results suggest that promoting timely VitC supplementation by at-risk pregnant mothers may prevent many birth defects currently refractory to folic acid supplementation and enhance the “health-span” of future generations.

Project description:Maternal dietary insufficiencies can reshape the offspring epigenome during gestation, contributing to birth defects and developmental disorders. Vitamin C (VitC) is a critical co-factor for Ten-Eleven-Translocation (TET) DNA demethylases, but the impact of its deficiency on embryonic development remains unclear. Here, we show that insufficient maternal VitC combined with genetic susceptibility can give rise to congenital malformations, including neural tube defects (NTDs), through dysregulation of DNA methylation. We previously reported NTDs in Tet1 knockout (KO) mice at low penetrance in C57BL/6J (B6) congenic inbred strains, but at two- to three-fold higher rates when outbred or highly backcrossed (incipient congenic) on a 129S6.B6 background. Similarly, maternal VitC deficiency in L-gulonolactone oxidase (Gulo) KO mice, which like humans are unable to synthesize VitC, resulted in highly penetrant congenital malformations in non-inbred mice, during a vulnerable window coinciding with gastrulation. DNA hypermethylation is a signature of VitC-deprived 129S6.B6-Gulo-/- embryonic headfold tissues, being absent in B6 embryos which are grossly normal. In outbred Gulo-/- embryonic brains, genomic regions harboring hypermethylation – hallmarks of TET dysfunction - increased with the severity of embryonic pathologies. A moderate reduction in VitC status is sufficient to induce hypermethylated regions and cause NTDs. Severe embryonic defects in VitC-deprived embryos can be rescued by timely re-supplementation of VitC at the onset of gastrulation, which normalized DNA methylation at most loci. Our results suggest that promoting timely VitC supplementation by at-risk pregnant mothers may prevent many birth defects currently refractory to folic acid supplementation and enhance the “health-span” of future generations.

Project description:Maternal dietary insufficiencies can reshape the offspring epigenome during gestation, contributing to birth defects and developmental disorders. Vitamin C (VitC) is a critical co-factor for Ten-Eleven-Translocation (TET) DNA demethylases, but the impact of its deficiency on embryonic development remains unclear. Here, we show that insufficient maternal VitC combined with genetic susceptibility can give rise to congenital malformations, including neural tube defects (NTDs), through dysregulation of DNA methylation. We previously reported NTDs in Tet1 knockout (KO) mice at low penetrance in C57BL/6J (B6) congenic inbred strains, but at two- to three-fold higher rates when outbred or highly backcrossed (incipient congenic) on a 129S6.B6 background. Similarly, maternal VitC deficiency in L-gulonolactone oxidase (Gulo) KO mice, which like humans are unable to synthesize VitC, resulted in highly penetrant congenital malformations in non-inbred mice, during a vulnerable window coinciding with gastrulation. DNA hypermethylation is a signature of VitC-deprived 129S6.B6-Gulo-/- embryonic headfold tissues, being absent in B6 embryos which are grossly normal. In outbred Gulo-/- embryonic brains, genomic regions harboring hypermethylation – hallmarks of TET dysfunction - increased with the severity of embryonic pathologies. A moderate reduction in VitC status is sufficient to induce hypermethylated regions and cause NTDs. Severe embryonic defects in VitC-deprived embryos can be rescued by timely re-supplementation of VitC at the onset of gastrulation, which normalized DNA methylation at most loci. Our results suggest that promoting timely VitC supplementation by at-risk pregnant mothers may prevent many birth defects currently refractory to folic acid supplementation and enhance the “health-span” of future generations.

Project description:Folic acid (FA) prevents neural tube defects (NTDs), but it remains unclear why many cases of human NTDs still occur despite FA supplementation. Here, we investigate how the DNA demethylase TET1 interacts with maternal dietary FA status to regulate embryonic brain development. We determined that cranial NTDs in Tet1-/- embryos display higher penetrance in non-inbred than in inbred genetic backgrounds and are resistant to FA supplementation across strains. Maternal diets that are either too rich or deficient in FA are linked to an increased incidence of mild cranial deformities in wild type and Tet1+/- offspring and altered DNA hypermethylation in Tet1-/- embryos primarily at neurodevelopmental loci. Excess FA in Tet1-/- embryos results in phospholipid metabolite loss and reduced expression of multiple membrane solute carriers, including a FA transporter gene which exhibits increased promoter DNA methylation, thus mimicking a pseudo-FA deficiency. FA deficiency reveals an impact of Tet1 haploinsufficiency that contributes to DNA hypermethylation and susceptibility to NTDs. Overall, our study reveals that epigenetic dysregulation may underlie the resistance of NTDs to FA supplementation.

Project description:Folic acid (FA) prevents neural tube defects (NTDs), but it remains unclear why many cases of human NTDs still occur despite FA supplementation. Here, we investigate how the DNA demethylase TET1 interacts with maternal dietary FA status to regulate embryonic brain development. We determined that cranial NTDs in Tet1-/- embryos display higher penetrance in non-inbred than in inbred genetic backgrounds and are resistant to FA supplementation across strains. Maternal diets that are either too rich or deficient in FA are linked to an increased incidence of mild cranial deformities in wild type and Tet1+/- offspring and altered DNA hypermethylation in Tet1-/- embryos primarily at neurodevelopmental loci. Excess FA in Tet1-/- embryos results in phospholipid metabolite loss and reduced expression of multiple membrane solute carriers, including a FA transporter gene which exhibits increased promoter DNA methylation, thus mimicking a pseudo-FA deficiency. FA deficiency reveals an impact of Tet1 haploinsufficiency that contributes to DNA hypermethylation and susceptibility to NTDs. Overall, our study reveals that epigenetic dysregulation may underlie the resistance of NTDs to FA supplementation.

Project description:Folic acid (FA) is well known to prevent neural tube defects (NTDs), but we do not know why many human NTD cases still remain refractory to FA supplementation. Here, we investigate how the DNA demethylase TET1 interacts with maternal FA status to regulate mouse embryonic brain development. We determined that cranial NTDs display higher penetrance in non-inbred than in inbred Tet1-/- embryos and are resistant to FA supplementation across strains. Maternal diets that are either too rich or deficient in FA are linked to an increased incidence of cranial deformities in wild type and Tet1+/- offspring and to altered DNA hypermethylation in Tet1-/- embryos, primarily at neurodevelopmental loci. Excess FA in Tet1-/- embryos results in phospholipid metabolite loss and reduced expression of multiple membrane solute carriers, including a FA transporter gene that exhibits increased promoter DNA methylation and thereby mimics FA deficiency. Moreover, FA deficiency reveals that Tet1 haploinsufficiency can contribute to DNA hypermethylation and susceptibility to NTDs. Overall, our study suggests that epigenetic dysregulation may underlie NTD development despite FA supplementation.

Project description:Neural tube defects (NTDs) are one of the most severe congenital abnormalities. Maternal folate deficiency could impact the occurrence of NTDs. Histone H3 methyltransferase disruptor of telomeric silencing 1-like (DOT1L) expression was significantly downregulated, and low levels of H3K79me2 were found in the corresponding NTDs samples with their maternal serum folate under low levels. Using ChIP-seq assays, we found that a decrease of H3K79me2 downregulates the expression of Shh and Sufu in mouse embryonic stem cells (mESC) under folate deficiency. Our results indicate that abnormal Shh and Sufu genes expression reduced by aberrant Dot1l-mediated H3K79me2 levels could be the cause of NTDs occurrence.

Project description:Neural tube defects (NTDs) are serious birth defects with an estimated worldwide incidence of 1 per 1,000 live births. The multifactorial nature of NTDs in humans has made it difficult to elucidate pathogenesis mechanisms. However, a strong relationship has been established between folate-homocysteine metabolism and NTD risk. Prevention of a substantial proportion of fetal NTDs can be achieved through maternal folic acid (FA) supplementation. However the mechanism by which FA exerts its beneficial effect remains unclear. METHODS: To improve our understanding of the underlying mechanisms of NTD pathogenesis and the ways in which folate exerts its beneficial effect, we analyzed mRNA profiles as well as folate and vitamin B12 levels in five NTD mouse mutants whose response to dietary FA was previously established. RESULTS: Differentially expressed genes representing the effect of each NTD-causing mutation were identified and associated with biologic pathways. Interestingly, the panel of NTD mutants collectively revealed pathways related to two nuclear receptors, retinoid X receptor (RXR) and pregnane X receptor (PXR), suggesting that these pathways may be related to a shared mechanism of NTD development. Moreover, the NTD-causing mutations that were associated with FA responsiveness had expression profiles that were related to folate-homocysteine metabolic pathways. These pathways were not strongly associated with mutants that do not respond to FA supplementation, implying that FA may be beneficial when the NTD mutation affects pathways related to folate-homocysteine metabolism. 5 groups of NTD mutants were studied. From each mutant group Heterozygous (test) and wild-type (control) female pups were used for this study at 6-8 weeks of age. 4 biological replicates were used for each of the test and control groups of each mutant. All mice used for the experiments were fasted 4-5 hours before dissection. A total of 36 samples were analyzed.

Project description:Neural Tube Defects (NTDs) are a class of severe congenital developmental defects caused by abnormal closure of the neural tube during early embryonic development, including conditions such as anencephaly, spina bifida, and encephalocele. Currently, NTDs are considered to result from the combined effects of genetic and environmental factors, particularly maternal folate intake during pregnancy, leading to widespread epigenetic dysregulation. However, the role of N6-methyladenine (N6-mA) in embryonic neural development remains largely unknown. Here, we found significant upregulation of Alkbh1 and concomitant significant downregulation of overall 6mA in brain tissue of a mouse model of NTDs. Further investigation through MeDIP, CUT&TAG, and single-cell sequencing revealed crosstalk between N6-mA and H3K9me3-marked heterochromatin, primarily impacting the involvement of embryonic glial cells in the formation of the hindbrain during embryonic neural tube development. These findings collectively suggest a potential epigenetic role of N6-mA in mammalian brain development, potentially exhibiting cell type specificity.

Project description:Neural Tube Defects (NTDs) are a class of severe congenital developmental defects caused by abnormal closure of the neural tube during early embryonic development, including conditions such as anencephaly, spina bifida, and encephalocele. Currently, NTDs are considered to result from the combined effects of genetic and environmental factors, particularly maternal folate intake during pregnancy, leading to widespread epigenetic dysregulation. However, the role of N6-methyladenine (N6-mA) in embryonic neural development remains largely unknown. Here, we found significant upregulation of Alkbh1 and concomitant significant downregulation of overall 6mA in brain tissue of a mouse model of NTDs. Further investigation through RNA-seq，MeDIP, CUT&TAG, and single-cell sequencing revealed crosstalk between N6-mA and H3K9me3-marked heterochromatin, primarily impacting the involvement of embryonic glial cells in the formation of the hindbrain during embryonic neural tube development. These findings collectively suggest a potential epigenetic role of N6-mA in mammalian brain development, potentially exhibiting cell type specificity.