DNA methylation patterns are set up in a relatively fixed programmed manner during normal embryonic development and are then stably maintained. Using genome-wide analysis, we discovered a postnatal pathway involving gender-specific demethylation that occurs exclusively in the male liver. This demodification is programmed to take place at tissue-specific enhancer sequences, and our data show that the methylation state at these loci is associated with and appears to play a role in the transcriptional regulation of nearby genes. This process is mediated by the secretion of testosterone at the time of sexual maturity, but the resulting methylation profile is stable and therefore can serve as an epigenetic memory even in the absence of this inducer. These findings add a new dimension to our understanding of the role of DNA methylation in vivo and provide the foundations for deciphering how environment can impact on the epigenetic regulation of genes in general.
There is ample evidence that somatic cell differentiation during development is accompanied by extensive DNA demethylation of specific sites that vary between cell types. Although the mechanism of this process has not yet been elucidated, it is likely to involve the conversion of 5mC to 5hmC by Tet enzymes. We show that a Tet2/ Tet3 conditional knockout at early stages of B-cell development largely prevents lineage-specific programmed demethylation events. This lack of demethylation affects the expression of nearby B-cell lineage genes by impairing enhancer activity, thus causing defects in B-cell differentiation and function. Thus, tissue-specific DNA demethylation appears to be necessary for proper somatic cell development in vivo.NA methylation takes place at almost all stages of development including the early embryo as well as during lineage commitment and is mediated through a combination of active and passive processes. Recent studies have raised the possibility that demethylation can occur through the involvement of the teneleven-translocation family (Tet1, Tet2, and Tet3) that catalyzes the oxidation of 5-methylcytosine (5mC) to 5-hydroxymethylcytosine (5hmC) as a first step in the pathway (1, 2). Removal of this unusual base may then be accomplished either by further oxidation followed by base excision repair (3) or through replication dilution (4-6). Genetic experiments have demonstrated that Tet enzymes are key players during early development, with Tet3-mediated DNA hydroxylation being involved in epigenetic programming of the zygotic paternal DNA (7, 8), whereas combinations of Tet1 and Tet2 play a role in the demethylation process that takes place during embryonic stem cell differentiation in vitro (2, 9-12).Tet enzymes also contribute to lineage development. Thus, changes in the pattern of 5hmC have been shown to accompany neurogenesis in vivo (13) (21)] appear to alter global 5hmC and 5mC distribution, perturb stem cell self-renewal, cause altered differentiation, and predispose to malignancies (refs. 19, 22, reviewed in ref. 23). None of these studies, however, has addressed the key question of whether demethylation itself is actually required for gene activation and proper lineage differentiation. To this end, we generated a Tet2/Tet3 knockout specific to B-lymphoid development, isolated cells at different stages of differentiation, and analyzed their methylation patterns. Because this approach targets the demethylation machinery in an exclusive manner, it allowed us to evaluate the role of this modification independently of the many transcription factors that drive the process of B-cell differentiation. ResultsIt has already been shown that both Tet2 and Tet3 are highly expressed in B lineage cells (24). With this in mind, we generated Tet2F mice (18, 23) and crossed them with animals expressing Cre under control of the early B-cell-specific Mb1 promoter (25) to obtain mice with a conditional knockout of these enzymes specifically in the B-cell lineage (Materials and Methods). Reduced repres...
Fundamental aspects of embryonic and post-natal development, including maintenance of the mammalian female germline, are largely unknown. Here we employ a retrospective, phylogenetic-based method for reconstructing cell lineage trees utilizing somatic mutations accumulated in microsatellites, to study female germline dynamics in mice. Reconstructed cell lineage trees can be used to estimate lineage relationships between different cell types, as well as cell depth (number of cell divisions since the zygote). We show that, in the reconstructed mouse cell lineage trees, oocytes form clusters that are separate from hematopoietic and mesenchymal stem cells, both in young and old mice, indicating that these populations belong to distinct lineages. Furthermore, while cumulus cells sampled from different ovarian follicles are distinctly clustered on the reconstructed trees, oocytes from the left and right ovaries are not, suggesting a mixing of their progenitor pools. We also observed an increase in oocyte depth with mouse age, which can be explained either by depth-guided selection of oocytes for ovulation or by post-natal renewal. Overall, our study sheds light on substantial novel aspects of female germline preservation and development.
Development in mammals is accompanied by specific de novo and demethylation events that are thought to stabilize differentiated cell phenotypes. We demonstrate that a large percentage of the tissue-specific methylation pattern is generated postnatally. Demethylation in the liver is observed in thousands of enhancer-like sequences associated with genes that undergo activation during the first few weeks of life. Using a conditional gene ablation strategy we show that the removal of these methyl groups is stable and necessary for assuring proper hepatocyte gene expression and function through its effect on chromatin accessibility. These postnatal changes in methylation come about through exposure to hormone signaling. These results define the molecular rules of 5-methyl-cytosine regulation as an epigenetic mechanism underlying cellular responses to a changing environment.
Stem cell dynamics in vivo are often being studied by lineage tracing methods. Our laboratory has previously developed a retrospective method for reconstructing cell lineage trees from somatic mutations accumulated in microsatellites. This method was applied here to explore different aspects of stem cell dynamics in the mouse colon without the use of stem cell markers. We first demonstrated the reliability of our method for the study of stem cells by confirming previously established facts, and then we addressed open questions. Our findings confirmed that colon crypts are monoclonal and that, throughout adulthood, the process of monoclonal conversion plays a major role in the maintenance of crypts. The absence of immortal strand mechanism in crypts stem cells was validated by the age-dependent accumulation of microsatellite mutations. In addition, we confirmed the positive correlation between physical and lineage proximity of crypts, by showing that the colon is separated into small domains that share a common ancestor. We gained new data demonstrating that colon epithelium is clustered separately from hematopoietic and other cell types, indicating that the colon is constituted of few progenitors and ruling out significant renewal of colonic epithelium from hematopoietic cells during adulthood. Overall, our study demonstrates the reliability of cell lineage reconstruction for the study of stem cell dynamics, and it further addresses open questions in colon stem cells. In addition, this method can be applied to study stem cell dynamics in other systems.
The depth of a cell of a multicellular organism is the number of cell divisions it underwent since the zygote, and knowing this basic cell property would help address fundamental problems in several areas of biology. At present, the depths of the vast majority of human and mouse cell types are unknown. Here, we show a method for estimating the depth of a cell by analyzing somatic mutations in its microsatellites, and provide to our knowledge for the first time reliable depth estimates for several cells types in mice. According to our estimates, the average depth of oocytes is 29, consistent with previous estimates. The average depth of B cells ranges from 34 to 79, linearly related to the mouse age, suggesting a rate of one cell division per day. In contrast, various types of adult stem cells underwent on average fewer cell divisions, supporting the notion that adult stem cells are relatively quiescent. Our method for depth estimation opens a window for revealing tissue turnover rates in animals, including humans, which has important implications for our knowledge of the body under physiological and pathological conditions.
The FoxA transcription factors are critical for liver development through their pioneering activity, which initiates a highly complex regulatory network thought to become progressively resistant to the loss of any individual hepatic transcription factor via mutual redundancy. To investigate the dispensability of FoxA factors for maintaining this regulatory network, we ablated all FoxA genes in the adult mouse liver. Remarkably, loss of FoxA caused rapid and massive reduction in the expression of critical liver genes. Activity of these genes was reduced back to the low levels of the fetal prehepatic endoderm stage, leading to necrosis and lethality within days. Mechanistically, we found FoxA proteins to be required for maintaining enhancer activity, chromatin accessibility, nucleosome positioning, and binding of HNF4α. Thus, the FoxA factors act continuously, guarding hepatic enhancer activity throughout adult life.
Mammalian reproduction depends on the release of a mature oocyte from the ovarian follicle. Maturation of the oocyte and rupture of the follicle wall constitute part of the responses to the preovulatory surge of LH, which also include cumulus expansion and granulosa cell luteinization. It was previously shown that the epidermal growth factor receptor (EGFR) mediates the ovulatory response to LH in the ovarian follicle. We hypothesized that it is a sustained activity of the EGFR that generates oocyte maturation and cumulus expansion. We demonstrated that, whereas a transient exposure of rat isolated, intact, preovulatory follicles to either LH or forskolin was sufficient to induce oocyte maturation and cumulus expansion, these LH-induced responses were only generated upon a prolonged activity of the EGFR. In addition, the continuous activity of the EGFR is essential for the chronic phosphorylation of the ERK1/2 downstream signaling molecules, which were shown to be essential for oocyte maturation and cumulus expansion. Interestingly, EGFR-sustained activity was also necessary to maintain the up-regulation of Ptgs2, a gene essential for cumulus expansion. The unusual prolonged duration of ERK1/2 activity may possibly be attributed to the late induction of the ERK-specific phosphatase 3, demonstrated herein. These new data shed light on the unique characteristics of EGFR-ERK1/2 activity in the ovarian follicle and emphasize the fact that the ovulatory process involves a nonclassical activation of this pathway.
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