DNA Methyltransferase Activity Research Articles

Aberrant promoter methylation, expression and function of RASSF1A gene in a series of Italian parathyroid tumors.

Aberrant epigenetic features are key events involved in parathyroid tumorigenesis, including DNA methylation, histone methylation, and non-coding RNAs. Ras Association Domain Family Protein1 Isoform A (RASSF1A) and Adenomatous Polyposis of Colon (APC) are frequently downregulated in human cancers. Here, we investigated their deregulated expression and the potential role in parathyroid neoplasms. methylation of RASSF1A and APC promoters was analyzed in a series of parathyroid adenomas (PAds, n = 80) and parathyroid carcinomas (PCas, n = 9) from Italian patients with primary hyperparathyroidism, RESULTS: RASSF1A and APC promoter methylation occurred in about 90% of PAds samples. PCas displayed RASSF1A promoter methylation, while APC promoter was methylated only in 2 samples. Of note, RASSF1A promoter methylation negatively correlated with PAds tumor size. However, RASSF1A transcript and protein levels were reduced in PAds and PCas compared with parathyroid normal glands. Investigating the potential mechanism involved in RASSF1A promoter methylation, we found that DNA methyltransferases (DNMTs) activity was variable in PAds and inversely correlated with RASSF1A protein levels. In addition, the RASSF1A promoter methylation negatively correlated with long-non-coding Antisense Intronic Noncoding RASSF1A (ANRASSF1A) mRNA levels, excluding the involvement of ANRASSF1 in RASSF1A regulation. In HEK293A cells transfected with the calcium sensing receptor (CASR), loss of RASSF1A increased basal phosphorylated Extracellular signal-regulated kinase (pERK/ERK) levels blunting the CASR-induced increases. RASSF1A and APC promoter methylation is a hallmark of parathyroid tumors; deregulation of DNMTs activity contributes to modulation of RASSF1A expression. Loss of RASSF1A may be involved in the tuning of ERK pathway in parathyroid tumors.

DNA Hypomethylation Is One of the Epigenetic Mechanisms Involved in Salt-Stress Priming in Soybean Seedlings.

Salt-stress priming enhances the tolerance of plants against subsequent exposure to a similar stress. Priming-induced transcriptomic reprogramming is mediated by multiple epigenetic mechanisms, the best known of which is histone modifications. However, not much is known about other epigenetic responses. In this study, salt-stress priming resulted in global DNA hypomethylation in the leaves of soybean seedlings. The DNA methyltransferase activities in primed seedlings were reduced, contributing to the overall DNA hypomethylation. Genes associated with the hypomethylated DNA regions in primed seedlings also showed a higher mean level of the active histone mark, histone 3 lysine 4 trimethylation (H3K4me3), and a lower mean level of the repressive histone mark, H3K4me2. Transcriptomic analyses supported that DNA hypomethylation played a role in fine-tuning the chromatin status in primed seedlings to potentiate gene expressions. Motif and transcriptional network analyses revealed that DNA hypomethylation may facilitate the responses mediated by key transcription factors in the abscisic acid (ABA)-dependent pathway. A pre-treatment using a DNA methyltransferase inhibitor, 5-azacytidine, could enhance salt tolerance in non-primed soybean seedlings, similar to the priming effect, suggesting the role of DNA hypomethylation in salt-stress priming. Overall, this research furthers our understanding of the epigenetic mechanisms involved in salt-stress priming in soybean.

Promotor Hypomethylation Mediated Upregulation of VCAN Targets Twist1 to Promote EndMT in Hypoxia-Induced Pulmonary Hypertension.

Hypoxia-induced pulmonary hypertension (HPH) is a severe vascular disorder that is characterized by the involvement of endothelial-to-mesenchymal transition (EndMT) in its pathogenesis. Our previous research has suggested that the gene versican may have a crucial role in the development of HPH. However, the exact function of versican in HPH requires further investigation. The expression of versican and markers of EndMT was assessed using Western blot, immunohistochemistry, and immunofluorescence. Vascular remodeling and right ventricular hypertrophy in patients with HPH and mice were evaluated through hematoxylin and eosin staining, Masson's staining, and hemodynamic measurements. Protein interactions were validated using co-immunoprecipitation, and the DNA methylation level of versican was examined using methylation-specific polymerase chain reaction. Compared with the control, EndMT was observed in patients with HPH, HPH mouse models, and hypoxia-treated human pulmonary artery endothelial cells, accompanied by a significant increase of versican. Endothelium-specific knockdown of versican reversed HPH progression and effectively prevented EndMT in mouse models and human pulmonary artery endothelial cells. We further confirmed that versican participated in EndMT by targeting the key transcription factor Twist1. Additionally, the upregulation of versican may be attributed to promoter hypomethylation, which was mediated by reduced DNA methyltransferases activity under hypoxic conditions. This study provides the initial evidence showcasing the role of promoter hypomethylation-mediated versican upregulation in promoting EndMT by targeting Twist1, which facilitates vascular remodeling and the progression of HPH. These findings offer a promising new target for the treatment of HPH.

Exploring the impact of childhood maltreatment on epigenetic and brain-derived neurotrophic factor changes in bipolar disorder and healthy control.

Childhood maltreatment may be linked to epigenetics and brain-derived neurotrophic factor (BDNF) changes, which are mechanisms altered in several psychiatric conditions, including bipolar disorder (BD). However, the specific mechanisms connecting childhood maltreatment to the pathophysiology of BD remain unclear. The present study aims to examine the effects of childhood maltreatment on epigenetic and neurotrophic outcomes in BD patients and health controls. History of childhood maltreatment was obtained using the Childhood Trauma Questionnaire (CTQ) from 36 BD outpatients and 46 healthy subjects. DNA methyltransferase (DNMT) activity, HMTH3K9 activity, histone 3 lysine 9 tri-methylation (H3K9me3) levels, histone deacetylase (HDAC)1 levels, HDAC2 levels, histone 3 lysine 14 acetylation (H3K14ac) levels, and mRNA of BDNF were evaluated in peripheral blood mononuclear cells. Plasma BDNF levels were also measured. Total scores of CTQ, as well as the subscale scores of emotional abuse, sexual abuse, and emotional neglect, were predictive of changes in DNMT and HMTh3k9 activity, H3K9m3 levels, BDNF mRNA expression, and BDNF levels. These findings were observed in all our samples and, in some cases, among BD patients. Emotional abuse was the main childhood maltreatment subtype associated with epigenetic alterations in BD. Our results elucidate some mechanisms by which childhood maltreatment can alter epigenetic and neurotrophic markers. Especially in BD subjects, our results suggest childhood maltreatment per se is not a direct cause for epigenetic alterations. In another way, we suppose that the effect of childhood maltreatment could be cumulative and interact with other factors associated with the pathophysiology of BD.

The Impact of Alcohol-Induced Epigenetic Modifications in the Treatment of Alcohol use Disorders.

Alcohol use disorders are responsible for 5.9% of all death annually and 5.1% of the global disease burden. It has been suggested that alcohol abuse can modify gene expression through epigenetic processes, namely DNA and histone methylation, histone acetylation, and microRNA expression. The alcohol influence on epigenetic mechanisms leads to molecular adaptation of a wide number of brain circuits, including the hypothalamus-hypophysis-adrenal axis, the prefrontal cortex, the mesolimbic-dopamine pathways and the endogenous opioid pathways. Epigenetic regulation represents an important level of alcohol-induced molecular adaptation in the brain. It has been demonstrated that acute and chronic alcohol exposure can induce opposite modifications in epigenetic mechanisms: acute alcohol exposure increases histone acetylation, decreases histone methylation and inhibits DNA methyltransferase activity, while chronic alcohol exposure induces hypermethylation of DNA. Some studies investigated the chromatin status during the withdrawal period and the craving period and showed that craving was associated with low methylation status, while the withdrawal period was associated with elevated activity of histone deacetylase and decreased histone acetylation. Given the effects exerted by ethanol consumption on epigenetic mechanisms, chromatin structure modifiers, such as histone deacetylase inhibitors and DNA methyltransferase inhibitors, might represent a new potential strategy to treat alcohol use disorder. Further investigations on molecular modifications induced by ethanol might be helpful to develop new therapies for alcoholism and drug addiction targeting epigenetic processes.

Epigenetic Mechanisms of Aluminum-Induced Neurotoxicity and Alzheimer's Disease: A Focus on Non-Coding RNAs.

Aluminum (Al) is known to induce neurotoxic effects, potentially contributing to Alzheimer's disease (AD) pathogenesis. Recent studies suggest that epigenetic modification may contribute to Al neurotoxicity, although the mechanisms are still debatable. Therefore, the objective of the present study was to summarize existing data on the involvement of epigenetic mechanisms in Al-induced neurotoxicity, especially AD-type pathology. Existing data demonstrate that Al exposure induces disruption in DNA methylation, histone modifications, and non-coding RNA expression in brains. Alterations in DNA methylation following Al exposure were shown to be mediated by changes in expression and activity of DNA methyltransferases (DNMTs) and ten-eleven translocation proteins (TETs). Al exposure was shown to reduce histone acetylation by up-regulating expression of histone deacetylases (HDACs) and impair histone methylation, ultimately contributing to down-regulation of brain-derived neurotrophic factor (BDNF) expression and activation of nuclear factor κB (NF-κB) signaling. Neurotoxic effects of Al exposure were also associated with aberrant expression of non-coding RNAs, especially microRNAs (miR). Al-induced patterns of miR expression were involved in development of AD-type pathology by increasing amyloid β (Aβ) production through up-regulation of Aβ precursor protein (APP) and β secretase (BACE1) expression (down-regulation of miR-29a/b, miR-101, miR-124, and Let-7c expression), increasing in neuroinflammation through NF-κB signaling (up-regulation of miR-9, miR-125b, miR-128, and 146a), as well as modulating other signaling pathways. Furthermore, reduced global DNA methylation, altered histone modification, and aberrant miRNA expression were associated with cognitive decline in Al-exposed subjects. However, further studies are required to evaluate the contribution of epigenetic mechanisms to Al-induced neurotoxicity and/or AD development.

Mapping DNA Methylation to Cardiac Pathologies Induced by Beta-Adrenergic Stimulation in a Large Panel of Mice.

Heart failure (HF) is a leading cause of morbidity and mortality worldwide, with over 18 million deaths annually. Despite extensive research, genetic and environmental factors contributing to HF remain complex and poorly understood. Recent studies suggest that epigenetic modifications, such as DNA methylation, may play a crucial role in regulating HF-associated phenotypes. In this study, we leverage the Hybrid Mouse Diversity Panel (HMDP), a cohort of over 100 inbred mouse strains, to investigate the role of DNA methylation in HF progression. We aim to identify epigenetic modifications associated with HF by integrating DNA methylation data with gene expression and phenotypic traits. Using isoproterenol (ISO)-induced cardiac hypertrophy and failure in HMDP mice, we explore the relationship between methylation patterns and HF susceptibility. We performed reduced representational bisulfite sequencing (RRBS) to capture DNA methylation at single-nucleotide resolution in the left ventricles of 90 HMDP mouse strains under both control and ISO-treated conditions. We identified differentially methylated regions (DMRs) and performed an epigenome-wide association study (EWAS) using the MACAU algorithm. We identified likely candidate genes within each locus through integration of our results with previously reported sequence variation, gene expression, and HF-related phenotypes. In vitro approaches were employed to validate key findings, including gene knockdown experiments in neonatal rat ventricular myocytes (NRVMs). We also examined the effects of preventing DNA methyltransferase activity on HF progression. Our EWAS identified 56 CpG loci significantly associated with HF phenotypes, including 18 loci where baseline DNA methylation predicted post-ISO HF progression. Key candidate genes, such as Prkag2, Anks1, and Mospd3, were identified based on their epigenetic regulation and association with HF traits. In vitro follow-up on a number of genes confirmed that knockdown of Anks1 and Mospd3 in NRVMs resulted in significant alterations in cell size and blunting of ISO-induced hypertrophy, demonstrating their functional relevance in HF pathology.Furthermore, treatment with the DNA methyltransferase inhibitor RG108 in ISO-treated BTBRT mice significantly reduced cardiac hypertrophy and preserved ejection fraction compared to mice only treated with ISO, highlighting the therapeutic potential of targeting DNA methylation in HF. Differential expression analysis revealed that RG108 treatment restored the expression of several methylation-sensitive genes, further supporting the role of epigenetic regulation in HF. Our study demonstrates a clear interplay between DNA methylation, gene expression, and HF-associated phenotypes. We identified several novel epigenetic loci and candidate genes that contribute to HF progression, offering new insights into the molecular mechanisms of HF. These findings underscore the importance of epigenetic regulation in cardiac disease and suggest potential therapeutic strategies for modifying HF outcomes through targeting DNA methylation.

Epigenome Reprogramming Through H3K27 and H3K4 Trimethylation as a Resistance Mechanism to DNA Methylation Inhibition in BRAFV600E-Mutated Colorectal Cancer.

BRAFV600E-mutated colorectal cancer exhibits a strong correlation with DNA hypermethylation, suggesting that this subgroup of tumors presents unique epigenomic phenotypes. Nonetheless, 5-azacitidine, which inhibits DNA methyltransferase activity, is not efficacious in BRAFV600E colorectal cancer in vivo. We randomized and treated mice implanted with patient-derived tumor xenografts harboring BRAFV600E mutation with control, 5-azacitidine, vemurafenib (BRAF inhibitor), or the combination. Comprehensive epigenomic profiling was conducted on control and 5-azacitidine-treated tumor samples, including DNA methylation, histone modifications, chromatin accessibility, and gene expression. Combinations of epigenetic agents were explored in preclinical BRAFV600E colorectal cancer models. A profound reduction of DNA methylation levels upon 5-azacitidine treatment was confirmed, however, transcriptional repression was not relieved. This study unbiasedly explored the adaptive engagement of other epigenomic modifications upon 5-azacitidine treatment. A loss of histone acetylation and a gain of histone methylations, including H3K27 and H3K4 trimethylation, were observed around these hypomethylated regions, suggesting the involvement of polycomb repressive complex (PRC) activity around the genome with loss of DNA methylation, therefore maintaining the repression of key tumor-suppressor genes. Combined inhibition of PRC activity through EZH2 inhibition with 5-azacitidine treatment additively improved efficacies in BRAFV600E colorectal cancer cells. In conclusion, DNA hypomethylation by 5-azacitidine exhibits a close association with H3K27me3 and PRC activity in BRAFV600E colorectal cancer, and simultaneous blockade of DNA methyltransferase and EZH2 holds promise as a potential therapeutic strategy for patients with BRAFV600E-mutated colorectal cancer.

An epigenetically mediated double negative cascade from EFD to HB21 regulates anther development

Epigenetic modifications are crucial for plant development. EFD (ExineFormationDefect) encodes a SAM-dependent methyltransferase that is essential for the pollen wall pattern formation and male fertility in Arabidopsis. In this study, we find that the expression of DRM2, a de novo DNA methyltransferase in plants, complements for the defects in efd, suggesting its potential de novo DNA methyltransferase activity. Genetic analysis indicates that EFD functions through HB21, as the knockout of HB21 fully restores fertility in efd mutants. DNA methylation and histone modification analyses reveal that EFD represses the transcription of HB21 through epigenetic mechanisms. Additionally, we demonstrate that HB21 directly represses the expression of genes crucial for pollen formation and anther dehiscence, including CalS5, RPG1/SWEET8, CYP703A2 and NST2. Collectively, our findings unveil a double negative regulatory cascade mediated by epigenetic modifications that coordinates anther development, offering insights into the epigenetic regulation of this process.

The type of DNA damage response after decitabine treatment depends on the level of DNMT activity.

Decitabine and azacytidine are considered as epigenetic drugs that induce DNA methyltransferase (DNMT)-DNA crosslinks, resulting in DNA hypomethylation and damage. Although they are already applied against myeloid cancers, important aspects of their mode of action remain unknown, highly limiting their clinical potential. Using a combinatorial approach, we reveal that the efficacy profile of both compounds primarily depends on the level of induced DNA damage. Under low DNMT activity, only decitabine has a substantial impact. Conversely, when DNMT activity is high, toxicity and cellular response to both compounds are dramatically increased, but do not primarily depend on DNA hypomethylation or RNA-associated processes. By investigating proteome dynamics on chromatin, we show that decitabine induces a strictly DNMT-dependent multifaceted DNA damage response based on chromatin recruitment, but not expression-level changes of repair-associated proteins. The choice of DNA repair pathway hereby depends on the severity of decitabine-induced DNA lesions. Although under moderate DNMT activity, mismatch (MMR), base excision (BER), and Fanconi anaemia-dependent DNA repair combined with homologous recombination are activated in response to decitabine, high DNMT activity and therefore immense replication stress induce activation of MMR and BER followed by non-homologous end joining.

Pramel15 facilitates zygotic nuclear DNMT1 degradation and DNA demethylation

In mammals, global passive demethylation contributes to epigenetic reprogramming during early embryonic development. At this stage, the majority of DNA-methyltransferase 1 (DNMT1) protein is excluded from nucleus, which is considered the primary cause. However, whether the remaining nuclear activity of DNMT1 is regulated by additional mechanisms is unclear. Here, we report that nuclear DNMT1 abundance is finetuned through proteasomal degradation in mouse zygotes. We identify a maternal factor, Pramel15, which targets DNMT1 for degradation via Cullin-RING E3 ligases. Loss of Pramel15 elevates DNMT1 levels in the zygote pronuclei, impairs zygotic DNA demethylation, and causes a stochastic gain of DNA methylation in early embryos. Thus, Pramel15 can modulate the residual level of DNMT1 in the nucleus during zygotic DNA replication, thereby ensuring efficient DNA methylation reprogramming in early embryos.

DNA hypomethylation in wood frog liver under anoxia and dehydration stresses

Wood frogs are freeze-tolerant vertebrates that can endure weeks to months frozen during the winter without breathing and with as much as 65% of total body water frozen as extracellular ice. Underlying tolerances of anoxia and of cellular dehydration support whole body freezing. One pro-survival mechanism employed by these frogs is epigenetic modifications via DNA hypomethylation processes facilitating transcriptional repression or activation. These processes involve proteins such as DNA Methyltransferases (DNMTs), Methyl Binding Domain proteins (MBDs), Ten-Eleven Translocases (TETs), and Thymine Deglycosylase (TDG). The present study evaluates the responses of these proteins to dehydration and anoxia stresses in wood frog liver. DNMT relative protein expression was reduced in liver, but nuclear DNMT activity did not change significantly under anoxia stress. By contrast, liver DNMTs and nuclear DNMT activity were upregulated under dehydration stress. These stress-specific differences were speculated to arise from Post-Translational Modifications (PTMs). DNMT3A and DNMT3B showed increased relative protein expression during recovery from dehydration and anoxia. Further, MBD1 was elevated during both conditions suggesting transcriptional repression. TET proteins showed varying responses to anoxia likely due to the absence of oxygen, a main substrate required by TETs. Similarly, TDG, an enzyme that corrects DNA damage, was downregulated under anoxia potentially due to lower levels of reactive oxygen species that damage DNA, but levels returned to normal during reperfusion of oxygen. Our results indicate differential stress-specific responses that indicate the need for more research in the DNA hypomethylation mechanisms employed by the wood frog during stress.

Catechin-Induced changes in PODXL, DNMTs, and miRNA expression in Nalm6 cells: an integrated in silico and in vitro approach

BackgroundThis study explored the impact of predicted miRNAs on DNA methyltransferases (DNMTs) and the PODXL gene in Nalm6 cells, revealing the significance of these miRNAs in acute lymphocytic leukemia (ALL).MethodsA comprehensive approach was adopted, integrating bioinformatic analyses encompassing protein structure prediction, molecular docking, dynamics, and ADMET profiling, in conjunction with evaluations of gene and miRNA expression patterns. This methodology was employed to elucidate the therapeutic potential of catechin compounds in modulating the activity of DNA methyltransferases (DNMTs) and the PODXL gene.ResultsThe findings from our investigation indicate that catechins possess the capability to inhibit DNMT enzymes. This inhibitory effect is associated with the upregulation of microRNAs miR-200c and miR-548 and a concurrent downregulation of PODXL gene expression. These molecular interactions culminate in an augmented apoptotic response within ALL (Nalm6) cells.ConclusionThe study posits that catechins may represent a viable therapeutic avenue for inducing apoptosis in ALL cells. This is achieved through the modulation of epigenetic mechanisms and alterations in gene expression profiles, highlighting the potential of catechins as agents for cancer therapy.

In vitro reconstitution of epigenetic reprogramming in the human germ line

Epigenetic reprogramming resets parental epigenetic memories and differentiates primordial germ cells (PGCs) into mitotic pro-spermatogonia or oogonia. This process ensures sexually dimorphic germ cell development for totipotency1. In vitro reconstitution of epigenetic reprogramming in humans remains a fundamental challenge. Here we establish a strategy for inducing epigenetic reprogramming and differentiation of pluripotent stem-cell-derived human PGC-like cells (hPGCLCs) into mitotic pro-spermatogonia or oogonia, coupled with their extensive amplification (about >1010-fold). Bone morphogenetic protein (BMP) signalling is a key driver of these processes. BMP-driven hPGCLC differentiation involves attenuation of the MAPK (ERK) pathway and both de novo and maintenance DNA methyltransferase activities, which probably promote replication-coupled, passive DNA demethylation. hPGCLCs deficient in TET1, an active DNA demethylase abundant in human germ cells2,3, differentiate into extraembryonic cells, including amnion, with de-repression of key genes that bear bivalent promoters. These cells fail to fully activate genes vital for spermatogenesis and oogenesis, and their promoters remain methylated. Our study provides a framework for epigenetic reprogramming in humans and an important advance in human biology. Through the generation of abundant mitotic pro-spermatogonia and oogonia-like cells, our results also represent a milestone for human in vitro gametogenesis research and its potential translation into reproductive medicine.

Enhancing Temozolomide (TMZ) chemosensitivity using CRISPR-dCas9-mediated downregulation of O6-methylguanine DNA methyltransferase (MGMT).

Glioblastoma (GBM) stands out as the most prevalent and aggressive intracranial tumor, notorious for its poor prognosis. The current standard-of-care for GBM patients involves surgical resection followed by radiotherapy, combined with concurrent and adjuvant chemotherapy using Temozolomide (TMZ). The effectiveness of TMZ primarily relies on the activity of O6-methylguanine DNA methyltransferase (MGMT), which removes alkyl adducts from the O6 position of guanine at the DNA level, thereby counteracting the toxic effects of TMZ. In this study, we employed fusions of catalytically-inactive Cas9 (dCas9) to DNA methyltransferases (dCas9-DNMT3A) to selectively downregulation MGMT transcription by inducing methylation at MGMT promoter and K-M enhancer. Our findings demonstrate a significant reduction in MGMT expression, leading to intensified TMZ sensitivity in the HEK293T cell line. This study serves as a proof of concept for the utilization of CRISPR-based gene suppression to overcome TMZ resistance and enhance the lethal effect of TMZ in glioblastoma tumor cells.

Abstract PO2-28-02: ROR1 regulates CREB3L1 via a novel signaling pathway in triple negative breast cancer

Abstract Triple negative breast cancer (TNBC) is the most aggressive subtype of breast cancer; it is highly metastatic and incredibly difficult to treat due to its lack of the hormone receptors (estrogen, progesterone, and human epidermal growth factor receptor 2) that are used as therapeutic targets to treat breast cancer patients. TNBC patients are left with limited treatment options besides potent chemotherapy drugs that often leave them with undesirable side effects. My work intends to reveal a novel oncogenic signaling pathway that could be used to specifically target and eliminate TNBC in patients. Our lab is focused on a surface receptor that is found to be highly expressed only in cancerous tissue and during fetal development, Receptor tyrosine kinase-like orphan receptor 1 (ROR1). TNBC patients with high ROR1 expression are found to have poor prognosis and decreased overall survival rate compared to patients with low expression. ROR1 is thought to be a good drug target because it activates various oncogenic pathways such as PI3K/AKT and STAT3 in order to increase TNBC metastasis and chemoresistance. Previous single cell RNA sequencing data showed that TNBC tumors with high ROR1 expression also had reduced expression of cAMP responsive element binding protein 3 like 1 (CREB3L1). Often TNBC patients are found to have low CREB3L1 expression, a transcription factor is thought to play a tumor suppressive role in TNBC by increasing the expression of genes associated with the unfolded protein response (UPR) when ER stress occurs. CREB3L1 silencing in TNBC is due to hypermethylation of its promoter region by DNA methyltransferases (DNMTs). We hypothesize that ROR1 regulates CREB3L1 by influencing DNMT activity. This project aims to reveal the tumor suppressors that are downregulated in TNBC by ROR1 activation. Citation Format: Victoria Reed, Eric Lalu, Bela Peethambaran. ROR1 regulates CREB3L1 via a novel signaling pathway in triple negative breast cancer [abstract]. In: Proceedings of the 2023 San Antonio Breast Cancer Symposium; 2023 Dec 5-9; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2024;84(9 Suppl):Abstract nr PO2-28-02.

A High-Affinity Methyl-CpG-Binding Protein for Endonuclease-Free and Label-Free DNA Methyltransferase Activity Detection

A High-Affinity Methyl-CpG-Binding Protein for Endonuclease-Free and Label-Free DNA Methyltransferase Activity Detection

Elevation of miR-150-5p in Brain Microvascular Endothelial Cells as a Result of Prenatal Alcohol Exposure Is Mediated by Transcriptional Mechanisms

Fetal Alcohol Spectrum Disorders (FASD) encompass a variety of conditions impacting development in children exposed to alcohol in utero. Vascular alterations such as defective angiogenesis, blood brain barrier permeability, vessel reactivity, and blood flow have been found in various animal models of prenatal alcohol exposure (PAE). The underlying mechanisms of these vascular defects are not fully understood. Our lab previously showed that miR-150-5p was upregulated in brain microvascular endothelial cells (BMVECs) isolated from embryonic mouse cortices following moderate PAE. We identified downstream vascular targets of miR-150-5p in BMVECs and demonstrated that miR-150-5p inhibition could counter alcohol-mediated effects on BMVECS and the cortical microvasculature in vitro and in vivo, respectively. Here, we investigate upstream mechanisms that contribute to miR-150-5p elevation in BMVECs following PAE. We hypothesized that multiple mechanisms, including pathways at the transcriptional level, contribute to increased miR-150-5p abundance in BMVECs following ethanol (EtOH) exposure. Overall transcriptional activity at the miR-150 promoter was increased in BMVECs with EtOH treatment, and pri-miR-150, the primary transcript for miR-150-5p, was elevated in EtOH-treated BMVECs. Additionally, miR-150 promoter methylation was decreased in PAE cortices compared to saccharine-exposed controls (SAC). Current work aims to confirm the role of DNA methylation in transcriptional regulation of the miR-150 promoter in BMVECs and characterize DNA methyltransferase activity in BMVECs during PAE. We also assessed transcription factor binding at the miR-150 promoter and found that miR-150 promoter activation by several transcription factors was blunted with EtOH treatment. Current work involves the investigation of global transcription factor activation in BMVECs in PAE versus SAC. In summary, our research sheds light on multiple mechanisms of miR-150-5p regulation that may contribute to brain microvascular defects as a result of PAE. American Physiological Society Porter Physiology Development Fellowship University of New Mexico Health School of Medicine Department of Cell Biology and Physiology. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Combinatorial quantification of 5mC and 5hmC at individual CpG dyads and the transcriptome in single cells reveals modulators of DNA methylation maintenance fidelity.

Inheritance of 5-methylcytosine from one cell generation to the next by DNA methyltransferase 1 (DNMT1) plays a key role in regulating cellular identity. While recent work has shown that the activity of DNMT1 is imprecise, it remains unclear how the fidelity of DNMT1 is tuned in different genomic and cell state contexts. Here we describe Dyad-seq, a method to quantify the genome-wide methylation status of cytosines at the resolution of individual CpG dinucleotides to find that the fidelity of DNMT1-mediated maintenance methylation is related to the local density of DNA methylation and the landscape of histone modifications. To gain deeper insights into methylation/demethylation turnover dynamics, we first extended Dyad-seq to quantify all combinations of 5-methylcytosine and 5-hydroxymethylcytosine at individual CpG dyads. Next, to understand how cell state transitions impact maintenance methylation, we scaled the method down to jointly profile genome-wide methylation levels, maintenance methylation fidelity and the transcriptome from single cells (scDyad&T-seq). Using scDyad&T-seq, we demonstrate that, while distinct cell states can substantially impact the activity of the maintenance methylation machinery, locally there exists an intrinsic relationship between DNA methylation density, histone modifications and DNMT1-mediated maintenance methylation fidelity that is independent of cell state.

Micronutrient regulation of the DNA methylome

The formation, inheritance, and removal of DNA methylation in the genome of mammalian cells is directly regulated by two families of enzymes–DNA methyltransferases (DNMTs) and Ten-Eleven Translocation proteins (TETs). DNMTs generate and maintain the inheritance of 5-methylcytosine (5mC), which is the substrate targeted by the TET enzymes for conversion to 5-hydroxymethylcytosine (5hmC) and its downstream oxidized derivatives. The activity of DNMT and TET is dependent on the availability of micronutrients and metabolite co-factors, including essential vitamins, amino acids, and trace metals, highlighting how DNA methylation levels can be directly enhanced, suppressed, or remodeled via metabolic and nutritional perturbations. Dynamic changes in DNA methylation are required during embryonic development, lineage specification, and maintenance of somatic cell function that can be fine-tuned based on the influence of essential micronutrients. As we age, DNA methylation and hydroxymethylation levels drift in patterning, leading to epigenetic dysregulation and genomic instability that underlies the formation and progression of multiple diseases including cancer. Understanding how DNA methylation can be regulated by micronutrients will have important implications for the maintenance of normal tissue function upon aging, and in the prevention and treatment of diseases for improved health and lifespan.