DNA modifications in the mammalian brain

DNA methylation is a crucial epigenetic mark in mammalian development, genomic imprinting, X-inactivation, chromosomal stability and suppressing parasitic DNA elements. DNA methylation in neurons has also been suggested to play important roles for mammalian neuronal functions, and learning and memory. In this review, we first summarize recent discoveries and fundamental principles of DNA modifications in the general epigenetics field. We then describe the profiles of different DNA modifications in the mammalian brain genome. Finally, we discuss roles of DNA modifications in mammalian brain development and function.

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Involvement of Thyroid Hormones in Brain Development and Cancer

Cancers ◽

10.3390/cancers13112693 ◽

2021 ◽

Vol 13 (11) ◽

pp. 2693

Author(s):

Gabriella Schiera ◽

Carlo Maria Di Liegro ◽

Italia Di Liegro

Keyword(s):

Nervous System ◽

Thyroid Hormones ◽

Brain Development ◽

Placental Transfer ◽

Regulation Of Gene Expression ◽

Mammalian Brain ◽

Cancer Proliferation ◽

Fetal Thyroid ◽

Genomic Effects ◽

And Function

The development and maturation of the mammalian brain are regulated by thyroid hormones (THs). Both hypothyroidism and hyperthyroidism cause serious anomalies in the organization and function of the nervous system. Most importantly, brain development is sensitive to TH supply well before the onset of the fetal thyroid function, and thus depends on the trans-placental transfer of maternal THs during pregnancy. Although the mechanism of action of THs mainly involves direct regulation of gene expression (genomic effects), mediated by nuclear receptors (THRs), it is now clear that THs can elicit cell responses also by binding to plasma membrane sites (non-genomic effects). Genomic and non-genomic effects of THs cooperate in modeling chromatin organization and function, thus controlling proliferation, maturation, and metabolism of the nervous system. However, the complex interplay of THs with their targets has also been suggested to impact cancer proliferation as well as metastatic processes. Herein, after discussing the general mechanisms of action of THs and their physiological effects on the nervous system, we will summarize a collection of data showing that thyroid hormone levels might influence cancer proliferation and invasion.

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Placental, Matrilineal, and Epigenetic Mechanisms Promoting Environmentally Adaptive Development of the Mammalian Brain

Neural Plasticity ◽

10.1155/2016/6827135 ◽

2016 ◽

Vol 2016 ◽

pp. 1-8 ◽

Cited By ~ 4

Author(s):

Kevin D. Broad ◽

Eridan Rocha-Ferreira ◽

Mariya Hristova

Keyword(s):

Genomic Imprinting ◽

Neural Plasticity ◽

Information Transfer ◽

Developing Brain ◽

Mammalian Brain ◽

Neural Function ◽

Mammalian Development ◽

Intrauterine Development ◽

Epigenetic Information ◽

Ultimate Control

The evolution of intrauterine development, vivipary, and placentation in eutherian mammals has introduced new possibilities and constraints in the regulation of neural plasticity and development which promote neural function that is adaptive to the environment that a developing brain is likely to encounter in the future. A range of evolutionary adaptations associated with placentation transfers disproportionate control of this process to the matriline, a period unique in mammalian development in that there are three matrilineal genomes interacting in the same organism at the same time (maternal, foetal, and postmeiotic oocytes). The interactions between the maternal and developing foetal hypothalamus and placenta can provide a template by which a mother can transmit potentially adaptive information concerning potential future environmental conditions to the developing brain. In conjunction with genomic imprinting, it also provides a template to integrate epigenetic information from both maternal and paternal lineages. Placentation also hands ultimate control of genomic imprinting and intergenerational epigenetic information transfer to the matriline as epigenetic markers undergo erasure and reprogramming in the developing oocyte. These developments, in conjunction with an expanded neocortex, provide a unique evolutionary template by which matrilineal transfer of maternal care, resources, and culture can be used to promote brain development and infant survival.

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Mammalian Brain Development is Accompanied by a Dramatic Increase in Bipolar DNA Methylation

Scientific Reports ◽

10.1038/srep32298 ◽

2016 ◽

Vol 6 (1) ◽

Cited By ~ 8

Author(s):

Ming-an Sun ◽

Zhixiong Sun ◽

Xiaowei Wu ◽

Veena Rajaram ◽

David Keimig ◽

...

Keyword(s):

Dna Methylation ◽

Brain Development ◽

Mammalian Brain

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Whole genome bisulfite sequencing reveals a sparse, but robust pattern of DNA methylation in the Dictyostelium discoideum genome

10.1101/166033 ◽

2017 ◽

Cited By ~ 1

Author(s):

Jacob L. Steenwyk ◽

James St. Denis ◽

Jacqueline M. Dresch ◽

Denis A. Larochelle ◽

Robert A. Drewell

Keyword(s):

Dna Methylation ◽

Dictyostelium Discoideum ◽

Dna Methyltransferase ◽

Model Organism ◽

Epigenetic Mark ◽

Whole Genome ◽

Protein Coding ◽

Genome Bisulfite Sequencing ◽

Chromatin Structural ◽

And Function

AbstractDNA methylation, the addition of a methyl (CH3) group to a cytosine residue, is an evolutionarily conserved epigenetic mark involved in a number of different biological functions in eukaryotes, including transcriptional regulation, chromatin structural organization, cellular differentiation and development. In the slime mold Dictyostelium, previous studies have shown the existence of a DNA methyltransferase (DNMA) belonging to the DNMT2 family, but the extent and function of 5-methyl-cytosine in the genome is unclear. Here we present the whole genome DNA methylation profile of Dictyostelium discoideum using deep coverage, replicate sequencing of bisulfite converted gDNA extracted from post-starvation cells. We find an overall very low level of DNA methylation, occurring at only 462 out of the ~7.5 million (0.006%) cytosines in the genome. Despite this sparse profile, significant methylation can be detected at 51 of these sites in replicate experiments, suggesting they are robust targets for DNA methylation. These 5-methyl-cytosines are associated with a broad range of protein-coding genes, tRNA-encoding genes and retrotransposable elements. Our data provides evidence of a minimal, but functional, methylome in Dictyostelium, thereby making Dictyostelium a candidate model organism to further investigate the evolutionary function of DNA methylation.

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Editorial—Role of DNA Methyltransferases in the Epigenome

Genes ◽

10.3390/genes10080574 ◽

2019 ◽

Vol 10 (8) ◽

pp. 574 ◽

Cited By ~ 1

Author(s):

Jeltsch ◽

Gowher

Keyword(s):

Dna Methylation ◽

Phenotypic Diversity ◽

Rapid Development ◽

Cell Types ◽

Dna Methyltransferases ◽

Mammalian Development ◽

Exciting Field ◽

Post Translational Modifications ◽

And Function ◽

Future Work

DNA methylation, a modification found in most species, regulates chromatin functions in conjunction with other epigenome modifications, such as histone post-translational modifications and non-coding RNAs. In mammals, DNA methylation has essential roles in development by orchestrating the generation and maintenance of the phenotypic diversity of human cell types. This Special Issue of Genes contains eight review articles, which cover several aspects of epigenome regulation by DNA methyltransferases (DNMTs), the enzymes responsible for the introduction of DNA methylation. The manuscripts present the most recent advances regarding the structure and function of DNMTs, their targeting and regulation by interacting factors and chromatin modifications, and the roles of DNMTs in mammalian development and human diseases. However, many aspects of these important enzymes are still insufficiently understood. Potential directions of future work are the regulation of DNMTs by post-translational modifications and their connection to cellular signaling and second messenger cascades on one hand and to large multifactorial epigenetic chromatin circuits on the other. Additionally, technical advancements, including the availability of designer nucleosomes and the rapid development of cryo-electron microscopy are expected to trigger breakthrough discoveries in this exciting field.

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Genomic patterns of DNA methylation: targets and function of an epigenetic mark

Current Opinion in Cell Biology ◽

10.1016/j.ceb.2007.04.011 ◽

2007 ◽

Vol 19 (3) ◽

pp. 273-280 ◽

Cited By ~ 225

Author(s):

Michael Weber ◽

Dirk Schübeler

Keyword(s):

Dna Methylation ◽

Epigenetic Mark ◽

And Function ◽

Genomic Patterns

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Loss of SETD1B results in the redistribution of genomic H3K4me3 in the oocyte

10.1101/2021.03.11.434836 ◽

2021 ◽

Author(s):

Courtney W. Hanna ◽

Jiahao Huang ◽

Christian Belton ◽

Susanne Reinhardt ◽

Andreas Dahl ◽

...

Keyword(s):

Gene Expression ◽

Dna Methylation ◽

Gene Expression Analysis ◽

Cpg Islands ◽

Conditional Knockout ◽

Epigenetic Mark ◽

Gene Promoters ◽

Downregulated Gene ◽

Mammalian Development ◽

Histone 3

SummaryHistone 3 lysine 4 trimethylation (H3K4me3) is an epigenetic mark found at gene promoters and CpG islands. H3K4me3 is essential for mammalian development, yet mechanisms underlying its genomic targeting are poorly understood. H3K4me3 methyltransferases SETD1B and MLL2 are essential for oogenesis. We investigated changes in H3K4me3 in Setd1b conditional knockout (cKO) GV oocytes using ultra-low input ChIP-seq, in conjunction with DNA methylation and gene expression analysis. Setd1b cKO oocytes showed a redistribution of H3K4me3, with a marked loss at active gene promoters associated with downregulated gene expression. Remarkably, many regions gained H3K4me3 in Setd1b cKOs, in particular those that were DNA hypomethylated, transcriptionally inactive and CpG-rich - hallmarks of MLL2 targets. Thus, loss of SETD1B appears to enable enhanced MLL2 activity. Our work reveals two distinct, complementary mechanisms of genomic targeting of H3K4me3 in oogenesis, with SETD1B linked to gene expression in the oogenic program and MLL2 to CpG content.

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DNA co-methylation networks outline the structure and remodeling dynamics of colorectal cancer epigenome

10.1101/428730 ◽

2018 ◽

Cited By ~ 2

Author(s):

Izaskun Mallona ◽

Susanna Aussó ◽

Anna Díez-Villanueva ◽

Víctor Moreno ◽

Miguel A. Peinado

Keyword(s):

Colorectal Cancer ◽

Dna Methylation ◽

Colon Cancer ◽

Genome Organization ◽

Tumor Tissue ◽

Network Modeling ◽

Genome Architecture ◽

Epigenetic Mark ◽

And Function ◽

Unique Signature

AbstractEpigenomic plasticity is interconnected with chromatin structure and gene regulation. In tumor progression, orchestrated remodeling of genome organization accompanies the acquisition of malignant properties. DNA methylation, a key epigenetic mark extensively altered in cancer, is also linked to genome architecture and function. Based on this association, we postulate that the dissection of long-range co-methylation structure unveils cancer cell’s genome architecture remodeling.We applied network-modeling of DNA methylation co-variation in two colon cancer cohorts and found abundant and consistent transchromosomal structures in both normal and tumor tissue. Normal-tumor comparison indicated substantial remodeling of the epigenome covariation and revealed novel genomic compartments with a unique signature of DNA methylation rank inversion.

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The exploration of N6-deoxyadenosine methylation in mammalian genomes

Protein & Cell ◽

10.1007/s13238-021-00866-3 ◽

2021 ◽

Author(s):

Xuwen Li ◽

Zijian Zhang ◽

Xinlong Luo ◽

Jacob Schrier ◽

Andrew D. Yang ◽

...

Keyword(s):

Dna Methylation ◽

Regulatory Mechanism ◽

Epigenetic Mark ◽

Dna Modification ◽

Biological Processes ◽

Environmental Stress Response ◽

Mammalian Genomes ◽

Higher Eukaryotes ◽

And Function ◽

Major Progress

AbstractN6-methyladenine (N6-mA, m6dA, or 6mA), a prevalent DNA modification in prokaryotes, has recently been identified in higher eukaryotes, including mammals. Although 6mA has been well-studied in prokaryotes, the function and regulatory mechanism of 6mA in eukaryotes are still poorly understood. Recent studies indicate that 6mA can serve as an epigenetic mark and play critical roles in various biological processes, from transposable-element suppression to environmental stress response. Here, we review the significant advances in methodology for 6mA detection and major progress in understanding the regulation and function of this non-canonical DNA methylation in eukaryotes, predominantly mammals.

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Evolutionary analysis of DNA methyltransferases in microeukaryotes: Insights from the model diatom Phaeodactylum tricornutum

10.1101/2021.06.11.447926 ◽

2021 ◽

Author(s):

ANTOINE HOGUIN ◽

Ouardia Ait Mohamed ◽

Chris Bowler ◽

Auguste Genovesio ◽

Fabio RJ Vieira ◽

...

Keyword(s):

Dna Methylation ◽

Transposable Elements ◽

Phaeodactylum Tricornutum ◽

Dna Methyltransferase ◽

Transcriptional Control ◽

Dna Methyltransferases ◽

Epigenetic Mark ◽

Evolutionary Analysis ◽

And Function ◽

Dnmt Family

Cytosine DNA methylation is an important epigenetic mark in eukaryotes that is involved in the transcriptional control of mainly transposable elements in mammals, plants, and fungi. Eukaryotes encode a diverse set of DNA methyltransferases that were iteratively acquired and lost during evolution. The Stramenopiles-Alveolate-Rhizaria (SAR) lineages are a major group of ecologically important marine microeukaryotes that include the main phytoplankton classes such as diatoms and dinoflagellates. However, little is known about the diversity of DNA methyltransferases and their role in the deposition and maintenance of DNA methylation in microalgae. We performed a phylogenetic analysis of DNA methyltransferase families found in marine microeukaryotes and show that they encode divergent DNMT3, DNMT4, DNMT5 and DNMT6 enzymes family revisiting previously established phylogenies. Furthermore, we reveal a novel group of DNMTs with three classes of enzymes within the DNMT5 family. Using a CRISPR/Cas9 strategy we demonstrate that the loss of the DNMT5 gene correlates with a global depletion of DNA methylation and overexpression of transposable elements in the model diatom Phaeodactylum tricornutum. The study provides a pioneering view of the structure and function of a DNMT family in the SAR supergroup.

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