Developmental iron deficiency dysregulates TET activity and DNA hydroxymethylation in the rat hippocampus and cerebellum

Iron deficiency (ID) during neurodevelopment is associated with lasting cognitive and socioemotional deficits, and increased risk for neuropsychiatric disease throughout the lifespan. These neurophenotypical changes are underlain by gene dysregulation in the brain that outlasts the period of ID; however, the mechanisms by which ID establishes and maintains gene expression changes are incompletely understood. The epigenetic modification 5-hydroxymethylcytosine (5hmC), or DNA hydroxymethylation, is one candidate mechanism because of its dependence on iron-containing TET enzymes. The aim of the present study was to determine the effect of fetal-neonatal ID on regional brain TET activity, Tet expression, and 5hmC in the developing rat hippocampus and cerebellum, and to determine whether changes are reversible with dietary iron treatment. Timed pregnant Sprague-Dawley rats were fed iron deficient diet (ID; 4 mg/kg Fe) from gestational day (G)2 to generate iron deficient anemic (IDA) offspring. Control dams were fed iron sufficient diet (IS; 200 mg/kg Fe). At postnatal day (P)7, a subset of ID-fed litters was randomized to IS diet, generating treated IDA (TIDA) offspring. At P15, hippocampus and cerebellum were isolated for subsequent analysis. TET activity was quantified by ELISA from nuclear proteins. Expression of Tet1, Tet2, and Tet3 was quantified by qPCR from total RNA. Global %5hmC was quantified by ELISA from genomic DNA. ID increased DNA hydroxymethylation (p=0.0105), with a corresponding increase in TET activity (p<0.0001) and Tet3 expression (p<0.0001) in the P15 hippocampus. In contrast, ID reduced TET activity (p=0.0016) in the P15 cerebellum, with minimal effect on DNA hydroxymethylation. Neonatal dietary iron treatment resulted in partial normalization of these changes in both brain regions. These results demonstrate that the TET/DNA hydroxymethylation system is disrupted by developmental ID in a brain region-specific manner. Differential regional disruption of this epigenetic system may contribute to the lasting neural circuit dysfunction and neurobehavioral dysfunction associated with developmental ID.

DNA hydroxymethylation in high-grade gliomas

Background and Study Aims Since the new WHO classification of nervous system tumors (2016 revised 4th edition) has been released, gliomas are classified depending on molecular and genetic markers in connection with histopathology, instead of histopathology itself as it was in the previous classification. Over the last years, epigenetic analysis has taken on increased importance in the diagnosis and treatment of different cancers. Multiple studies confirmed that DNA methylation and hydroxymethylation play an important role in the regulation of gene expression during carcinogenesis. In this review, we aim to present the current state of knowledge on DNA hydroxymethylation in human high-grade gliomas (WHO grade III and IV). Results The correlation of DNA hydroxymethylation and survival in glioblastoma patients was evaluated by different studies. The majority of them showed that the expression of 5-hydroxymethylcytosine (5-hmC) and Ten-eleven translocation (TET) enzymes were significantly reduced, sometimes almost undetectable in high-grade gliomas in comparison with the control brain. A decreased level of 5-hmC was associated with poor survival in patients, but high expression of the TET3 enzyme was related to a better prognosis for GBM patients. This points to the relevance of DNA hydroxymethylation in molecular diagnostics of human gliomas, including survival estimation or differentiating patients in terms of response to the treatment. Conclusion Future studies may shed some more light on this epigenetic mechanism involved in the pathogenesis of human high-grade gliomas and help to develop new targeted therapies.

TET1-Mediated Tumor Inhibition and Dox Resistance in Colon Cancer by Blocking WNT / β-Catenin Pathway

BackgroundAs DNA demethylation protein, Ten-eleven translocation 1 (TET1) has been widely reported that is related to tumorigenesis and tumor metastasis. This study is to investigate the role and regulation mechanism of TET1 in colon cancer.Methods The TET1 and Catenin beta-1 (CTNNB1) expression level in colon cancer samples and cancer cell lines HCT116/SW480 were observed to discover the relationship between these two genes. Knockdown and overexpression of TET1 through shRNA and CRISPR technology were used to elucidate the effect of TET1 on WNT/β-catenin pathway. The 5-hmC/5-mC level were explored by bisulfate sequencing (BSP) and Chromatin immunoprecipitation (ChIP) to further explain the regulation mechanism. Combined with the reverse assay and transwell invasion assay, the cell migration and invasion ability were tested. Finally, the role of TET1 on DOX resistance was analyzed.Results TET1 downregulated in colon cancer and showed an opposite expression trend with WNT pathway associated gene CTNNB1. TET1 bound to CTNNB1 promotor and catalyzed demethylation to activate transcription of CTNNB1, inhibiting WNT/β‐catenin signaling pathways. Colon cancer cells proliferation was promoted by TET1 downregulation, which was further verified as shTET1 could upregulate the tumor invasion. The DOX addition could rescue the cell migration, compared with normal expression of TET1. Meanwhile, TET1 down-regulation was related to DOX resistances.Conclusion TET1 played as a DNA hydroxymethylation activates inhibitors of the WNT/β-catenin signaling pathway in colon tumor and TET1 down-regulation contributed to DOX-resistance, which might provide reference to targeting therapy in clinical practice.

Targeting DNA Methylation in the Adult Brain through Diet

Metabolism and nutrition have a significant role in epigenetic modifications such as DNA methylation, which can influence gene expression. Recently, it has been suggested that bioactive nutrients and gut microbiota can alter DNA methylation in the central nervous system (CNS) through the gut–brain axis, playing a crucial role in modulating CNS functions and, finally, behavior. Here, we will focus on the effect of metabolic signals in shaping brain DNA methylation during adulthood. We will provide an overview of potential interactions among diet, gastrointestinal microbiome and epigenetic alterations on brain methylation and behavior. In addition, the impact of different diet challenges on cytosine methylation dynamics in the adult brain will be discussed. Finally, we will explore new ways to modulate DNA hydroxymethylation, which is particularly abundant in neural tissue, through diet.

Evaluation of Seasonal Heat Stress on Transcriptomic Profiles and Global DNA Methylation of Bovine Oocytes

Heat stress affects oocyte developmental competence and is a major cause of reduced fertility in heat stressed cattle. Negative effects of heat stress on the oocyte have been observed at morphological, biochemical and developmental levels. However, the mechanisms by which heat stress affects the oocyte at the transcriptional and epigenetic levels remain to be further elucidated. Here we aimed to investigate the effect of heat stress on oocyte quality, transcriptomic profiles and DNA methylation of oocytes collected through the transition from spring to summer under Louisiana conditions. Summer season resulted in a lower number of high quality oocytes obtained compared to the spring season. There was no difference in in vitro maturation rates of oocytes collected during spring as compared to summer. RNA sequencing analysis showed that a total of 211 and 92 genes were differentially expressed as a result of heat stress in GV and MII oocytes, respectively. Five common genes (E2F8, GATAD2B, BHLHE41, FBXO44, and RAB39B) were significantly affected by heat in both GV and MII oocytes. A number of pathways were also influenced by heat stress including glucocorticoid biosynthesis, apoptosis signaling, and HIPPO signaling in GV oocytes, and Oct4 pluripotency, Wnt/beta-catenin signaling, and melatonin degradation I in MII oocytes. In addition, fluorescent immunocytochemistry analysis showed no difference in global levels of DNA methylation and DNA hydroxymethylation at either the GV or MII stage between spring and summer oocytes. The results of this study contribute to a better understanding of the effect of heat stress on the molecular mechanisms altered in bovine oocytes.