PARP-1 is required for retrieval of cocaine-associated memory by binding to the promoter of a novel gene encoding a putative transposase inhibitor.

Reward-related memory is an important factor in cocaine seeking. One necessary signaling mechanism for long-term memory formation is the activation of poly(ADP-ribose) polymerase-1 (PARP-1), via poly(ADP-ribosyl)ation. We demonstrate herein that auto-poly(ADP-ribosyl)ation of activated PARP-1 was significantly pronounced during retrieval of cocaine-associated contextual memory, in the central amygdala (CeA) of rats expressing cocaine-conditioned place preference (CPP). Intra-CeA pharmacological and short hairpin RNA depletion of PARP-1 activity during cocaine-associated memory retrieval abolished CPP. In contrast, PARP-1 inhibition after memory retrieval did not affect CPP reconsolidation process and subsequent retrievals. Chromatin immunoprecipitation sequencing revealed that PARP-1 binding in the CeA is highly enriched in genes involved in neuronal signaling. We identified among PARP targets in CeA a single gene, yet uncharacterized and encoding a putative transposase inhibitor, at which PARP-1 enrichment markedly increases during cocaine-associated memory retrieval and positively correlates with CPP. Our findings have important implications for understanding drug-related behaviors, and suggest possible future therapeutic targets for drug abuse.

Astrocytic abnormalities and global DNA methylation patterns in depression and suicide.

Astrocytes are glial cells specific to the central nervous system and involved in numerous brain functions, including regulation of synaptic transmission and of immune reactions. There is mounting evidence suggesting astrocytic dysfunction in psychopathologies such as major depression, however, little is known about the underlying etiological mechanisms. Here we report a two-stage study investigating genome-wide DNA methylation associated with astrocytic markers in depressive psychopathology. We first characterized prefrontal cortex samples from 121 individuals (76 who died during a depressive episode and 45 healthy controls) for the astrocytic markers GFAP, ALDH1L1, SOX9, GLUL, SCL1A3, GJA1 and GJB6. A subset of 22 cases with consistently downregulated astrocytic markers was then compared with 17 matched controls using methylation binding domain-2 (MBD2) sequencing followed by validation with high-resolution melting and bisulfite Sanger sequencing. With these data, we generated a genome-wide methylation map unique to altered astrocyte-associated depressive psychopathology. The map revealed differentially methylated regions (DMRs) between cases and controls, the majority of which displayed reduced methylation levels in cases. Among intragenic DMRs, those found in GRIK2 (glutamate receptor, ionotropic kainate 2) and BEGAIN (brain-enriched guanylate kinase-associated protein) were most significant and also showed significant correlations with gene expression. Cell-sorted fractions were investigated and demonstrated an important non-neuronal contribution of methylation status in BEGAIN. Functional cell assays revealed promoter and enhancer-like properties in this region that were markedly decreased by methylation. Furthermore, a large number of our DMRs overlapped known Encyclopedia of DNA elements (ENCODE)-identified regulatory elements. Taken together, our data indicate significant differences in the methylation patterns specific to astrocytic dysfunction associated with depressive psychopathology, providing a potential framework for better understanding this disease phenotype.

S-adenosylmethionine blocks tumorigenesis and with immune checkpoint inhibitor enhances anti-cancer efficacy against BRAF mutant and wildtype melanomas.

Despite marked success in treatment with immune checkpoint inhibitor (CPI), only a third of patients are responsive. Thus, melanoma still has one of the highest prevalence and mortality rates; which has led to a search for novel combination therapies that might complement CPI. Aberrant methylomes are one of the mechanisms of resistance to CPI therapy. S-adenosylmethionine (SAM), methyl donor of important epigenetic processes, has significant anti-cancer effects in several malignancies; however, SAM's effect has never been extensively investigated in melanoma. We demonstrate that SAM modulates phenotype switching of melanoma cells and directs the cells towards differentiation indicated by increased melanogenesis (melanin and melanosome synthesis), melanocyte-like morphology, elevated Mitf and Mitf activators' expression, increased antigen expression, reduced proliferation, and reduced stemness genes' expression. Consistently, providing SAM orally, reduced tumor growth and progression, and metastasis of syngeneic BRAF mutant and wild-type (WT) melanoma mouse models. Of note, SAM and anti-PD-1 antibody combination treatment had enhanced anti-cancer efficacy compared to monotherapies, showed significant reduction in tumor growth and progression, and increased survival. Furthermore, SAM and anti-PD-1 antibody combination triggered significantly higher immune cell infiltration, higher CD8+ T cells infiltration and effector functions, and polyfunctionality of CD8+ T cells in YUMMER1.7 tumors. Therefore, SAM combined with CPI provides a novel therapeutic strategy against BRAF mutant and WT melanomas and provides potential to be translated into clinic.

The early-life social environment and DNA methylation.

DNA methylation is a chemical modification of DNA that confers, upon identical sequences, different identities that are reflected in different gene expression programming. DNA methylation has a well-established role in cellular differentiation by providing a mechanism for one genome to express multiple phenotypes in a multicellular organism. Recent data point however to the possibility that in addition to the innate process of cellular differentiation, DNA methylation can serve as a genome adaptation mechanism, adapting genome function to changing environmental contexts including social environments. A critical time point for this process is early life when cues from the social and physical environments define lifelong trajectories of physical and mental health. DNA methylation and additional epigenetic modifications could therefore serve as molecular links between 'nurture' and 'nature'. Data that are consistent with this new role for DNA methylation as a mechanism for conferring an 'environment' specific identity to DNA will be discussed.

Building knowledge, optimising physical and mental health and setting up healthier life trajectories in South African women (Bukhali): a preconception randomised control trial part of the Healthy Life Trajectories Initiative (HeLTI).

INTRODUCTION: South Africa's evolving burden of disease is challenging due to a persistent infectious disease, burgeoning obesity, most notably among women and rising rates of non-communicable diseases (NCDs). With two thirds of women presenting at their first antenatal visit either overweight or obese in urban South Africa (SA), the preconception period is an opportunity to optimise health and offset transgenerational risk of both obesity and NCDs. METHODS AND ANALYSIS: Bukhali is the first individual randomised controlled trial in Africa to test the efficacy of a complex continuum of care intervention and forms part of the Healthy Life Trajectories Initiative (HeLTI) consortium implementing harmonised trials in Canada, China, India and SA. Starting preconception and continuing through pregnancy, infancy and childhood, the intervention is designed to improve nutrition, physical and mental health and health behaviours of South African women to offset obesity-risk (adiposity) in their offspring. Women aged 18-28 years (n=6800) will be recruited from Soweto, an urban-poor area of Johannesburg. The primary outcome is dual-energy X-ray absorptiometry derived fat mass index (fat mass divided by height2) in the offspring at age 5 years. Community health workers will deliver the intervention randomly to half the cohort by providing health literacy material, dispensing a multimicronutrient supplement, providing health services and feedback, and facilitating behaviour change support sessions to optimise: (1) nutrition, (2) physical and mental health and (3) lay the foundations for healthier pregnancies and early child development. ETHICS AND DISSEMINATION: Ethical approval has been obtained from the Human Ethics Research Committee University of the Witwatersrand, Johannesburg, South Africa (M1811111), the University of Toronto, Canada (19-0066-E) and the WHO Ethics Committee (ERC.0003328). Data and biological sample sharing policies are consistent with the governance policy of the HeLTI Consortium (https://helti.org) and South African government legislation (POPIA). The recruitment and research team will obtain informed consent. TRIAL REGISTRATION: This trial is registered with the Pan African Clinical Trials Registry (https://pactr.samrc.ac.za) on 25 March 2019 (identifier: PACTR201903750173871). PROTOCOL VERSION: 20 March 2022 (version #4). Any protocol amendments will be communicated to investigators, Institutional Review Board (IRB)s, trial participants and trial registries.

Prenatal stress and epigenetics.

In utero exposure to environmental stress in both animals and humans could result in long-term epigenome alterations which further lead to consequences for adaptation and development in the offspring. Epigenetics, especially DNA methylation, is considered one of the most widely studied and well-characterized mechanisms involved in the long-lasting effects of in utero stress exposure. In this review, we outlined evidence from animal and human prenatal research supporting the view that prenatal stress could lead to lasting, broad and functionally organized signatures in DNA methylation which, in turn, could mediate exposure-phenotype associations. We also emphasized the advantage of using stressor from quasi-randomly assigned experiments. Furthermore, we discuss challenges that still need to be addressed in this field in the future.

Organ and gestational age effects of maternal nutrient restriction on global methylation in fetal baboons.

BACKGROUND: A sub-optimal intrauterine environment alters the trajectory of fetal development with profound effects on life-time health. Altered methylation, a proposed epigenetic mechanism responsible for these changes, has been studied in non-primate species but not nonhuman primates. We tested the hypotheses that global methylation in fetal baboon demonstrates organ specificity, gestational age specificity, and changes with maternal nutritional status. METHODS: We measured global DNA methylation in fetuses of control fed (CTR) and nutrient restricted mothers fed 70% of controls (MNR) for brain, kidney, liver and heart at 0.5 and 0.9 gestation (G). RESULTS: We observed organ and gestation specific changes that were modified by maternal diet. Methylation in CTR fetuses was highest in frontal cortex and lowest in liver. MNR decreased methylation in 0.5G kidney and increased methylation in 0.9G kidney and frontal cortex. CONCLUSION: These results demonstrate a potential epigenetic mechanism whereby reduced maternal nutrition has long-term programming effects on fetal organ development.

A DNA signal from the Thy-1 gene defines de novo methylation patterns in embryonic stem cells.

Although DNA can be extensively methylated de novo when introduced into pluripotent cells, the CpG island in the Thy-1 gene does not become methylated either in the mouse embryo or in embryonic stem cells. A 214-base-pair region near the promoter of the Thy-1 gene protects itself as well as heterologous DNA sequences from de novo methylation. We propose that this nucleotide sequence is representative of a class of important signals that limits de novo methylation in the embryo and establishes the pattern of hypomethylated CpG dinucleotides found in somatic tissues.

Concurrent replication and methylation at mammalian origins of replication.

Observations made with Escherichia coli have suggested that a lag between replication and methylation regulates initiation of replication. To address the question of whether a similar mechanism operates in mammalian cells, we have determined the temporal relationship between initiation of replication and methylation in mammalian cells both at a comprehensive level and at specific sites. First, newly synthesized DNA containing origins of replication was isolated from primate-transformed and primary cell lines (HeLa cells, primary human fibroblasts, African green monkey kidney fibroblasts [CV-1], and primary African green monkey kidney cells) by the nascent-strand extrusion method followed by sucrose gradient sedimentation. By a modified nearest-neighbor analysis, the levels of cytosine methylation residing in all four possible dinucleotide sequences of both nascent and genomic DNAs were determined. The levels of cytosine methylation observed in the nascent and genomic DNAs were equivalent, suggesting that DNA replication and methylation are concomitant events. Okazaki fragments were also demonstrated to be methylated, suggesting that the rapid kinetics of methylation is a feature of both the leading and the lagging strands of nascent DNA. However, in contrast to previous observations, neither nascent nor genomic DNA contained detectable levels of methylated cytosines at dinucleotide contexts other than CpG (i.e., CpA, CpC, and CpT are not methylated). The nearest-neighbor analysis also shows that cancer cell lines are hypermethylated in both nascent and genomic DNAs relative to the primary cell lines. The extent of methylation in nascent and genomic DNAs at specific sites was determined as well by bisulfite mapping of CpG sites at the lamin B2, c-myc, and beta-globin origins of replication. The methylation patterns of genomic and nascent clones are the same, confirming the hypothesis that methylation occurs concurrently with replication. Interestingly, the c-myc origin was found to be unmethylated in all clones tested. These results show that, like genes, different origins of replication exhibit different patterns of methylation. In summary, our results demonstrate tight coordination of DNA methylation and replication, which is consistent with recent observations showing that DNA methyltransferase is associated with proliferating cell nuclear antigen in the replication fork.

Associations among oxytocin receptor gene (OXTR) DNA methylation in adulthood, exposure to early life adversity, and childhood trajectories of anxiousness.

Recent models propose deoxyribonucleic acid methylation of key neuro-regulatory genes as a molecular mechanism underlying the increased risk of mental disorder associated with early life adversity (ELA). The goal of this study was to examine the association of ELA with oxytocin receptor gene (OXTR) methylation among young adults. Drawing from a 21-year longitudinal cohort, we compared adulthood OXTR methylation frequency of 46 adults (23 males and 23 females) selected for high or low ELA exposure based on childhood socioeconomic status and exposure to physical and sexual abuse during childhood and adolescence. Associations between OXTR methylation and teacher-rated childhood trajectories of anxiousness were also assessed. ELA exposure was associated with one significant CpG site in the first intron among females, but not among males. Similarly, childhood trajectories of anxiousness were related to one significant CpG site within the promoter region among females, but not among males. This study suggests that females might be more sensitive to the impact of ELA on OXTR methylation than males.

Regulation of the DNA methylation machinery and its role in cellular transformation.

DNA methylation, a covalent modification of the genome, is emerging as an important player in the regulation of gene expression. This review discusses the different components of the DNA methylation machinery responsible for replicating the DNA methylation pattern. Recent data have changed our basic understanding of the DNA methylation machinery. A number of DNA methyltransferases (DNMT) have been identified and a demethylase has recently been reported. Because the DNA methylation pattern is critical for gene expression programs, the cell possesses a number of mechanisms to coordinate DNA replication and methylation. DNMT1 levels are regulated with the cell cycle and are induced upon entry into the S phase of the cell cycle. DNMT1 also regulates expression of cell-cycle proteins by its other regulatory functions and not through its DNA methylation activity. Once the mechanisms that coordinate DNMT1 and the cell cycle are disrupted, DNMT1 exerts an oncogenic activity. Tumor suppressor genes are frequently methylated in cancer but the mechanisms responsible are unclear. Overexpression of DNMT1 is probably not responsible for the aberrant methylation of tumor suppressor genes. Unraveling how the different components of the DNA methylation machinery interact to replicate the DNA methylation pattern, and how they are disrupted in cancer, is critical for understanding the molecular mechanisms of cancer.

Ankyrin-3 as a molecular marker of early-life stress and vulnerability to psychiatric disorders.

Exposure to early-life stress (ELS) may heighten the risk for psychopathology at adulthood. Here, in order to identify common genes that may keep the memory of ELS through changes in their methylation status, we intersected methylome analyses performed in different tissues and time points in rats, non-human primates and humans, all characterized by ELS. We identified Ankyrin-3 (Ank3), a scaffolding protein with a strong genetic association for psychiatric disorders, as a gene persistently affected by stress exposure. In rats, Ank3 methylation and mRNA changes displayed a specific temporal profile during the postnatal development. Moreover, exposure to prenatal stress altered the interaction of ankyrin-G, the protein encoded by Ank3 enriched in the post-synaptic compartment, with PSD95. Notably, to model in humans a gene by early stress interplay on brain phenotypes during cognitive performance, we demonstrated an interaction between functional variation in Ank3 gene and obstetric complications on working memory in healthy adult subjects. Our data suggest that alterations of Ank3 expression and function may contribute to the effects of ELS on the development of psychiatric disorders.

DNA methylation properties: consequences for pharmacology.

DNA methylation plays an important role in controlling the profile of gene expression of mammalian cells. The hypothesis presented in this article by Moshe Szyf is that DNA methylation patterns are determined by an interplay between the level of DNA methyltransferase and demethylase activities and site-specific signals. The expression of the DNA methyltransferase gene is regulated with the proliferative state of the cell and it is upregulated by cellular oncogenic pathways, resulting in hypermethylation and repression of tumour-suppressing loci. DNA methyltransferase inhibitors would inhibit the excessive activity of DNA methyltransferase in cancer cells and induce the original cellular programme of tumour suppression. They can also be used to turn on alternative programmes of gene expression. Specific DNA methyltransferase antagonists might provide us with therapeutic agents directed at a nodal point of regulation of genetic information.

Towards a pharmacology of DNA methylation.

DNA methylation plays an important role in controlling gene-expression programs. Increasing evidence indicates that the enzyme responsible for replicating the DNA methylation pattern, DNA methyltransferase 1 (DNMT1), has a role in cancer. In this article, it is suggested that DNMT1 is a multifunctional protein that has regulatory activities in addition to DNA methylation activity. These functions are assembled into one protein to ensure the coordinate replication of DNA and its methylation pattern. The regulatory activities of DNMT1 are proposed to be involved in cellular transformation and should, therefore, serve as the targets for novel anti-cancer agents.

The DNA methylation machinery as a target for anticancer therapy.

DNA methylation is now recognized as an important mechanism regulating different functions of the genome; gene expression, replication, and cancer. Different factors control the formation and maintenance of DNA methylation patterns. The level of activity of DNA methyltransferase (MeTase) is one factor. Recent data suggest that some oncogenic pathways can induce DNA MeTase expression, that DNA MeTase activity is elevated in cancer, and that inhibition of DNA MeTase can reverse the transformed state. What are the pharmacological consequences of our current understanding of DNA methylation patterns formation? This review will discuss the possibility that DNA MeTase inhibitors can serve as important pharmacological and therapeutic tools in cancer and other genetic diseases.

Conditional transformation mediated via a pertussis toxin-sensitive receptor signalling pathway.

To determine whether a cloned receptor coupled to pertussis toxin (PTx)-sensitive G-proteins can induce cell proliferation and oncogenic transformation, as observed for receptors that elicit PTx-insensitive enhancement of phosphatidyl inositol (PI)-specific phospholipase-C (PLC) activity, nontransformed murine BALB/c-3T3 cells were transfected with the rat serotonin-1A (5-HT1A) receptor. The 5-HT1A receptor is coupled to PTx-sensitive G-proteins to induce a cell-specific activation of PLC. While 1 microM 5-HT induced no change in PI turnover or cytosolic free calcium levels ([Ca2+]i) in receptor-negative nontransfected 3T3 cells, 5-HT induced a 2-fold increase in inositol trisphosphate accumulation and a 2.5-fold increase in [Ca2+]i in the 3T3-ZD8 clone, which expressed 0.6 +/- 0.2 pmol/mg protein of specific 5-HT1A binding sites. The stimulatory actions of 5-HT on PI turnover and [Ca2+]i in 3T3ZD8 cells displayed the pharmacology of the 5-HT1A receptor and were abolished by pretreatment with PTx. Thus, BALB/c-3T3 fibroblast cells express the PLC-linked pathway of the 5-HT1A receptor. Overnight treatment with 5-HT (1 microM) enhanced incorporation of [3H]thymidine into DNA extracted from serum-starved 3T3ZD-8 cells, an action that was also blocked by pretreatment with pertussis toxin. Long term (1-2 weeks) exposure to 5-HT in the medium led to phenotypic transformation of the cells, including the formation of foci with 1 microM 5-HT. These actions of 5-HT were not observed in untransformed 3T3 cells. We conclude that the PTx-sensitive PLC-linked pathway of the 5-HT1A receptor expressed in nontransformed BALB/c-3T3 cells, in concert with other serum-derived factors, predisposes the cells to enhanced proliferation and transformation.

cis modification of the steroid 21-hydroxylase gene prevents its expression in the Y1 mouse adrenocortical tumor cell line.

The Y1 mouse adrenocortical tumor cell line retains the ability to synthesize and secrete steroids, but does not express steroid 21-hydroxylase (C21) and, therefore, does not produce 21-hydroxylated steroids. In this investigation the mechanisms underlying the loss of C21 activity in the Y1 cell line were explored. A 9-kilobase BglII fragment containing the C21 gene was cloned from the Y1 genome. This genomic clone directed the synthesis of C21 transcripts and 21-hydroxylated steroid products when transfected back into the Y1 cell line. As determined by restriction endonuclease digestions with MspI and HpaII, enzymes that distinguish between unmethylated and methylated CCGG sites, the endogenous C21 gene was extensively methylated in Y1 adrenal cells and in cells from other mouse tissues that do not normally express this gene. In contrast, the C21 gene was hypomethylated in primary cultures of mouse adrenal cells which normally synthesize large amounts of C21. The cloned C21 gene transfected into Y1 cells initially was unmethylated, but became extensively methylated with prolonged culture of the cells; prolonged culture of these transfectants also resulted in a loss of C21 expression. Loss of C21 expression in Y1 transfectants, however, temporally preceded the extensive methylation of the transfected C21 gene. Furthermore, treatment of Y1 cells with 5-azacytidine caused a demethylation of the endogenous C21 gene, but did not result in the recovery of C21 expression. These results indicate that Y1 cells contain a functional C21 gene that has been silenced by a reversible cis-modification event.(ABSTRACT TRUNCATED AT 250 WORDS)

Pregnant women's cognitive appraisal of a natural disaster affects DNA methylation in their children 13 years later: Project Ice Storm.

Prenatal maternal stress (PNMS) can impact a variety of outcomes in the offspring throughout childhood and persisting into adulthood as shown in human and animal studies. Many of the effects of PNMS on offspring outcomes likely reflect the effects of epigenetic changes, such as DNA methylation, to the fetal genome. However, no animal or human research can determine the extent to which the effects of PNMS on DNA methylation in human offspring is the result of the objective severity of the stressor to the pregnant mother, or her negative appraisal of the stressor or her resulting degree of negative stress. We examined the genome-wide DNA methylation profile in T cells from 34 adolescents whose mothers had rated the 1998 Québec ice storm's consequences as positive or negative (that is, cognitive appraisal). The methylation levels of 2872 CGs differed significantly between adolescents in the positive and negative maternal cognitive appraisal groups. These CGs are affiliated with 1564 different genes and with 408 different biological pathways, which are prominently featured in immune function. Importantly, there was a significant overlap in the differentially methylated CGs or genes and biological pathways that are associated with cognitive appraisal and those associated with objective PNMS as we reported previously. Our study suggests that pregnant women's cognitive appraisals of an independent stressor may have widespread effects on DNA methylation across the entire genome of their unborn children, detectable during adolescence. Therefore, cognitive appraisals could be an important predictor variable to explore in PNMS research.

Maternal depression is associated with DNA methylation changes in cord blood T lymphocytes and adult hippocampi.

Depression affects 10-15% of pregnant women and has been associated with preterm delivery and later developmental, behavioural and learning disabilities. We tested the hypothesis that maternal depression is associated with DNA methylation alterations in maternal T lymphocytes, neonatal cord blood T lymphocytes and adult offspring hippocampi. Genome-wide DNA methylation of CD3+ T lymphocytes isolated from 38 antepartum maternal and 44 neonatal cord blood samples were analyzed using Illumina Methylation 450 K microarrays. Previously obtained methylation data sets using methylated DNA immunoprecipitation and array-hybridization of 62 postmortem hippocampal samples of adult males were re-analyzed to test associations with history of maternal depression. We found 145 (false discovery rate (FDR) q<0.05) and 2520 (FDR q<0.1) differentially methylated CG-sites in cord blood T lymphocytes of neonates from the maternal depression group as compared with the control group. However, no significant DNA methylation differences were detected in the antepartum maternal T lymphocytes of our preliminary data set. We also detected 294 differentially methylated probes (FDR q<0.1) in hippocampal samples associated with history of maternal depression. We observed a significant overlap (P=0.002) of 33 genes with changes in DNA methylation in T lymphocytes of neonates and brains of adult offspring. Many of these genes are involved in immune system functions. Our results show that DNA methylation changes in offspring associated with maternal depression are detectable at birth in the immune system and persist to adulthood in the brain. This is consistent with the hypothesis that system-wide epigenetic changes are involved in life-long responses to maternal depression in the offspring.

A novel regulatory element in the dnmt1 gene that responds to co-activation by Rb and c-Jun.

Rb, c-Jun and dnmt1 play critical roles in the process of cellular differentiation. We demonstrate that a regulatory region of murine dnmt1 contains an element which is responsible for transactivation by Rb and c-Jun in P19 embryocarcinoma cells which is not observed in Y1 adrenocarcinoma cells. During differentiation of P19 cells, the induction of Rb and c-Jun coincides with an increase of dnmt1 mRNA. Using linker scanning mutagenesis we identify the element that is responsible for this activation to be a non-canonical AP-1 site. Our data is an example of how a proto-oncogene activates its downstream effectors by recruiting a tumor suppressor. This interaction of Rb and a proto-oncogene might play an important role in differentiation. The responsiveness of dnmt1 to this type of signal is consistent with an important role for regulated expression of dnmt1 during cellular differentiation.