Project description:Maternal 5-HT1A-receptor (R) is required for the timely development of the hippocampus and the establishment of emotional behaviors in Swiss-Webster (SW) mice. A partial and/or complete loss of maternal 5-HT1AR results in delayed ventral dentate granule cell (v-DGC) development and subsequent anxiety-like phenotype in the wild-type offspring by a non-genetic, presumably epigenetic mechanism. Here we tested v-DGCs for genome-wide DNA methylation changes elicited by the receptor deficient maternal environment. We identified a set of hypomethylated regions in the offspring of receptor deficient mothers. A significant fraction of these maternal-differentially methylated regions (m-DMRs) mapped to strong CpG islands, sequences that are typically not methylated or if methylated, resistant to environmental-induced changes. Many m-DMRs mapped to exons and some were associated with expression changes. Their hypomethylation was due to an arrest in de novo methylation and, to a lesser extent, to demethylation during postnatal life indicating that the perturbation in methylation coincides with the developmental delay in DGC maturation in the offspring of receptor deficient mothers. Inhibiting methylation in differentiating neurons impaired their maturation further suggesting a link between de novo methylation and neuronal differentiation. These data suggest that methylation at specific exonic CpG-islands may contribute to the mechanism through which maternal 5-HT1AR modulates hippocampal development and consecutively the level of anxiety in the SW offspring. Reduced 5-HT1AR-binding has been reported in individuals, particularly in association with anxiety/depression, including peri/postpartum depression. Therefore, maternal receptor deficit may contribute, via a non-genetic mechanism, to the high prevalence and heritability of anxiety disorders in human. Examined transcriptomes of 5HT1A wild type offspring with 5HT1A wild type/heterozygous mother or 5HT1A KO offspring with 5HT1A of heterozygous/knock out mother

Project description:Maternal 5-HT1A-receptor (R) is required for the timely development of the hippocampus and the establishment of emotional behaviors in Swiss-Webster (SW) mice. A partial and/or complete loss of maternal 5-HT1AR results in delayed ventral dentate granule cell (v-DGC) development and subsequent anxiety-like phenotype in the wild-type offspring by a non-genetic, presumably epigenetic mechanism. Here we tested v-DGCs for genome-wide DNA methylation changes elicited by the receptor deficient maternal environment. We identified a set of hypomethylated regions in the offspring of receptor deficient mothers. A significant fraction of these maternal-differentially methylated regions (m-DMRs) mapped to strong CpG islands, sequences that are typically not methylated or if methylated, resistant to environmental-induced changes. Many m-DMRs mapped to exons and some were associated with expression changes. Their hypomethylation was due to an arrest in de novo methylation and, to a lesser extent, to demethylation during postnatal life indicating that the perturbation in methylation coincides with the developmental delay in DGC maturation in the offspring of receptor deficient mothers. Inhibiting methylation in differentiating neurons impaired their maturation further suggesting a link between de novo methylation and neuronal differentiation. These data suggest that methylation at specific exonic CpG-islands may contribute to the mechanism through which maternal 5-HT1AR modulates hippocampal development and consecutively the level of anxiety in the SW offspring. Reduced 5-HT1AR-binding has been reported in individuals, particularly in association with anxiety/depression, including peri/postpartum depression. Therefore, maternal receptor deficit may contribute, via a non-genetic mechanism, to the high prevalence and heritability of anxiety disorders in human. Examined 4 samples: 5HT1A wild type offspring with 5HT1A wild type/heterozygous mother or 5HT1A KO offspring with 5HT1A of heterozygous/knock out mother

Project description:Maternal 5-HT1A-receptor (R) is required for the timely development of the hippocampus and the establishment of emotional behaviors in Swiss-Webster (SW) mice. A partial and/or complete loss of maternal 5-HT1AR results in delayed ventral dentate granule cell (v-DGC) development and subsequent anxiety-like phenotype in the wild-type offspring by a non-genetic, presumably epigenetic mechanism. Here we tested v-DGCs for genome-wide DNA methylation changes elicited by the receptor deficient maternal environment. We identified a set of hypomethylated regions in the offspring of receptor deficient mothers. A significant fraction of these maternal-differentially methylated regions (m-DMRs) mapped to strong CpG islands, sequences that are typically not methylated or if methylated, resistant to environmental-induced changes. Many m-DMRs mapped to exons and some were associated with expression changes. Their hypomethylation was due to an arrest in de novo methylation and, to a lesser extent, to demethylation during postnatal life indicating that the perturbation in methylation coincides with the developmental delay in DGC maturation in the offspring of receptor deficient mothers. Inhibiting methylation in differentiating neurons impaired their maturation further suggesting a link between de novo methylation and neuronal differentiation. These data suggest that methylation at specific exonic CpG-islands may contribute to the mechanism through which maternal 5-HT1AR modulates hippocampal development and consecutively the level of anxiety in the SW offspring. Reduced 5-HT1AR-binding has been reported in individuals, particularly in association with anxiety/depression, including peri/postpartum depression. Therefore, maternal receptor deficit may contribute, via a non-genetic mechanism, to the high prevalence and heritability of anxiety disorders in human. Comparison of methylation patterns in ventral Dentate Gyrus cells of wild type mice versus 5HT1A receptor knockouts, as well as the effect of the maternal 5HT1A genotype

Project description:Maternal 5-HT1A-receptor (R) is required for the timely development of the hippocampus and the establishment of emotional behaviors in Swiss-Webster (SW) mice. A partial and/or complete loss of maternal 5-HT1AR results in delayed ventral dentate granule cell (v-DGC) development and subsequent anxiety-like phenotype in the wild-type offspring by a non-genetic, presumably epigenetic mechanism. Here we tested v-DGCs for genome-wide DNA methylation changes elicited by the receptor deficient maternal environment. We identified a set of hypomethylated regions in the offspring of receptor deficient mothers. A significant fraction of these maternal-differentially methylated regions (m-DMRs) mapped to strong CpG islands, sequences that are typically not methylated or if methylated, resistant to environmental-induced changes. Many m-DMRs mapped to exons and some were associated with expression changes. Their hypomethylation was due to an arrest in de novo methylation and, to a lesser extent, to demethylation during postnatal life indicating that the perturbation in methylation coincides with the developmental delay in DGC maturation in the offspring of receptor deficient mothers. Inhibiting methylation in differentiating neurons impaired their maturation further suggesting a link between de novo methylation and neuronal differentiation. These data suggest that methylation at specific exonic CpG-islands may contribute to the mechanism through which maternal 5-HT1AR modulates hippocampal development and consecutively the level of anxiety in the SW offspring. Reduced 5-HT1AR-binding has been reported in individuals, particularly in association with anxiety/depression, including peri/postpartum depression. Therefore, maternal receptor deficit may contribute, via a non-genetic mechanism, to the high prevalence and heritability of anxiety disorders in human.

Project description:Maternal 5-HT1A-receptor (R) is required for the timely development of the hippocampus and the establishment of emotional behaviors in Swiss-Webster (SW) mice. A partial and/or complete loss of maternal 5-HT1AR results in delayed ventral dentate granule cell (v-DGC) development and subsequent anxiety-like phenotype in the wild-type offspring by a non-genetic, presumably epigenetic mechanism. Here we tested v-DGCs for genome-wide DNA methylation changes elicited by the receptor deficient maternal environment. We identified a set of hypomethylated regions in the offspring of receptor deficient mothers. A significant fraction of these maternal-differentially methylated regions (m-DMRs) mapped to strong CpG islands, sequences that are typically not methylated or if methylated, resistant to environmental-induced changes. Many m-DMRs mapped to exons and some were associated with expression changes. Their hypomethylation was due to an arrest in de novo methylation and, to a lesser extent, to demethylation during postnatal life indicating that the perturbation in methylation coincides with the developmental delay in DGC maturation in the offspring of receptor deficient mothers. Inhibiting methylation in differentiating neurons impaired their maturation further suggesting a link between de novo methylation and neuronal differentiation. These data suggest that methylation at specific exonic CpG-islands may contribute to the mechanism through which maternal 5-HT1AR modulates hippocampal development and consecutively the level of anxiety in the SW offspring. Reduced 5-HT1AR-binding has been reported in individuals, particularly in association with anxiety/depression, including peri/postpartum depression. Therefore, maternal receptor deficit may contribute, via a non-genetic mechanism, to the high prevalence and heritability of anxiety disorders in human.

Project description:Maternal stress, anxiety, and depression increase the risk of psychiatric disorders in the progeny. These maternal effects can extend beyond the first generation and affect the grandchildren. In contrast to paternal, maternal effects can impact the offspring not only during gametogenesis, but also through fetal and early-postnatal life, increasing phenotypic complexity and the overall impact. To better understand its non-genetic structure, we dissected a complex maternally-transmitted phenotype to elementary behaviors and their corresponding transmission mechanisms. Chronic stress and depression are associated with reduced serotonin1A receptor (5-HT1AR) levels, and we reported that 5-HT1AR+/- dams transmit anxiety/stress-reactivity traits to their wild-type offspring. Here we show that the maternal effect is propagated to multiple generations, and that the behavioral traits are not transmitted in unison, but rather via parallel and segregated mechanisms, each with generation-dependent penetrance and gender specificity. The “risk-avoidance” and “hypoactivity” traits of anxiety were transmitted, via a neuro-immune pathway, consecutively from mother to the wild-type F1, F2, and occasionally F3 generation by iterative non-gametic-programming, while the “increased stress-reactivity” trait was transmitted to the F2 generation by gametic-programming. Iterative non-gametic-programming of anxiety was linked, via gene expression changes and clustered DNA hypo/hypermethylation at intragenic enhancers, to sphingolipid metabolism and GPCRs in the F1/F2 hippocampus, suggesting dysregulated lipid raft functioning/transmembrane signaling. Conversely, gametic-programming of behavior was predominantly associated with hypomethylation at different promoter-enhancing sequences within a set of genes with diverse neuronal functions. Since differential methylation appeared only postnatally in F2 neurons and was absent in F3 neurons, it is secondary to earlier F2 gametic changes that survive reprogramming in the early embryo, but are erased in F3 germ-cells. Our data introduce parallel and segregated non-genetic transmission of traits as a mechanism that may explain the propagation and pleiotropy of complex behavioral and psychiatric disease phenotypes across generations. Compared three generations of male offspring from wild-type and 5HT1A-R-/+ Swiss Webster mothers with two replicates per sample. Included as well is F2 embryo transfer from wild-type and het parents in wild-type surogates

Project description:Maternal stress, anxiety, and depression increase the risk of psychiatric disorders in the progeny. These maternal effects can extend beyond the first generation and affect the grandchildren. In contrast to paternal, maternal effects can impact the offspring not only during gametogenesis, but also through fetal and early-postnatal life, increasing phenotypic complexity and the overall impact. To better understand its non-genetic structure, we dissected a complex maternally-transmitted phenotype to elementary behaviors and their corresponding transmission mechanisms. Chronic stress and depression are associated with reduced serotonin1A receptor (5-HT1AR) levels, and we reported that 5-HT1AR+/- dams transmit anxiety/stress-reactivity traits to their wild-type offspring. Here we show that the maternal effect is propagated to multiple generations, and that the behavioral traits are not transmitted in unison, but rather via parallel and segregated mechanisms, each with generation-dependent penetrance and gender specificity. The “risk-avoidance” and “hypoactivity” traits of anxiety were transmitted, via a neuro-immune pathway, consecutively from mother to the wild-type F1, F2, and occasionally F3 generation by iterative non-gametic-programming, while the “increased stress-reactivity” trait was transmitted to the F2 generation by gametic-programming. Iterative non-gametic-programming of anxiety was linked, via gene expression changes and clustered DNA hypo/hypermethylation at intragenic enhancers, to sphingolipid metabolism and GPCRs in the F1/F2 hippocampus, suggesting dysregulated lipid raft functioning/transmembrane signaling. Conversely, gametic-programming of behavior was predominantly associated with hypomethylation at different promoter-enhancing sequences within a set of genes with diverse neuronal functions. Since differential methylation appeared only postnatally in F2 neurons and was absent in F3 neurons, it is secondary to earlier F2 gametic changes that survive reprogramming in the early embryo, but are erased in F3 germ-cells. Our data introduce parallel and segregated non-genetic transmission of traits as a mechanism that may explain the propagation and pleiotropy of complex behavioral and psychiatric disease phenotypes across generations.

Project description:Microarray study of iBAT gene expression comparing a) adult male offspring of control and 3,3’,5-triiodothyronine (T3)-treated mothers during pregnancy and b) adult male offspring of control and maternal thyroid hormone receptor (TR) β signaling (TRb) treated mothers during pregnancy. Microarrays were conducted by Atlas Biolabs (Berlin, Germany) on GeneChip Clariom S arrays (Affymetrix/Thermofisher, Germany).

Project description:Maternal care is associated with long-term effects on behavior and epigenetic programming of the NR3C1 (GLUCOCORTICOID RECEPTOR) gene in the hippocampus of both rats and humans. However, epigenetic changes at a single gene promoter are unlikely to account for the range of responses to the early life environment and the persistent change in expression of hundreds of additional genes in adult rats in response to differences in maternal care. Here we show that natural variations in maternal care are associated with coordinate changes in DNA methylation, chromatin, and gene expression spanning over a hundred kilobase pairs in the hippocampus of adult rats. The offspring of high compared to low maternal care mothers show epigenetic changes in promoters, exons, and gene ends and higher transcriptional activity across many genes, suggesting that a broad epigenetic regulation of gene expression may form part of a coordinated response to early maternal care. We obtained hippocampal samples from adult offspring of rat mothers that differed in the frequency of pup licking/grooming in the first week of life. Using custom-designed microarrays with probes tiling the 7 million base pair region of rat chromosome 18 centered at the NR3C1 gene at 100 bp spacing, we obtained DNA methylation and H3K9 acetylation profiles by ChIP-on-chip. Each profile was generated in triplicate, each type of profile from 3 high frequency and 3 low frequency mothers.

Project description:Maternal care is associated with long-term effects on behavior and epigenetic programming of the NR3C1 (GLUCOCORTICOID RECEPTOR) gene in the hippocampus of both rats and humans. However, epigenetic changes at a single gene promoter are unlikely to account for the range of responses to the early life environment and the persistent change in expression of hundreds of additional genes in adult rats in response to differences in maternal care. Here we show that natural variations in maternal care are associated with coordinate changes in DNA methylation, chromatin, and gene expression spanning over a hundred kilobase pairs in the hippocampus of adult rats. The offspring of high compared to low maternal care mothers show epigenetic changes in promoters, exons, and gene ends and higher transcriptional activity across many genes, suggesting that a broad epigenetic regulation of gene expression may form part of a coordinated response to early maternal care. We obtained hippocampal samples from adult offspring of rat mothers that differed in the frequency of pup licking/grooming in the first week of life, 4 from high frequency and 4 from low frequency mothers. Using custom-designed microarrays with probes tiling the 7 million base pair region of rat chromosome 18 centered at the NR3C1 gene at 100 bp spacing, we obtained transcription profiles by hybridizing cDNA to microarrays. Each profile was generated in duplicate.