Global ETD Search

311	A computational approach to discovering p53 binding sites in the human genome Lim, Ji-Hyun January 2013 (has links) The tumour suppressor p53 protein plays a central role in the DNA damage response/checkpoint pathways leading to DNA repair, cell cycle arrest, apoptosis and senescence. The activation of p53-mediated pathways is primarily facilitated by the binding of tetrameric p53 to two 'half-sites', each consisting of a decameric p53 response element (RE). Functional REs are directly adjacent or separated by a small number of 1-13 'spacer' base pairs (bp). The p53 RE is detected by exact or inexact matches to the palindromic sequence represented by the regular expression [AG][AG][AG]C[AT][TA]G[TC][TC][TC] or a position weight matrix (PWM). The use of matrix-based and regular expression pattern-matching techniques, however, leads to an overwhelming number of false positives. A more specific model, which combines multiple factors known to influence p53-dependent transcription, is required for accurate detection of the binding sites. In this thesis, we present a logistic regression based model which integrates sequence information and epigenetic information to predict human p53 binding sites. Sequence information includes the PWM score and the spacer length between the two half-sites of the observed binding site. To integrate epigenetic information, we analyzed the surrounding region of the binding site for the presence of mono- and trimethylation patterns of histone H3 lysine 4 (H3K4). Our model showed a high level of performance on both a high-resolution data set of functional p53 binding sites from the experimental literature (ChIP data) and the whole human genome. Comparing our model with a simpler sequence-only model, we demonstrated that the prediction accuracy of the sequence-only model could be improved by incorporating epigenetic information, such as the two histone modification marks H3K4me1 and H3K4me3. 610
312	Molecular mechanisms underlying heterochromatin formation in the mouse embryo / Mécanismes moléculaires responsables de la formation de l'hétérochromatine chez l'embryon des mammifères Jachowicz, Joanna Weronika 17 December 2015 (has links) Afin d'étudier la formation de l'hétérochromatine dans l’embryon préimplantatoire de souris, je me suis concentrée sur deux régions génétiques différentes - répétitions péricentriques et L1 éléments transposables - dans le but notamment de découvrir les mécanismes qui conduisent à la répression et le rôle distinct qu’ils peuvent jouer pendant le processus de développement et la division cellulaire. Mes expériences montrent que l’organisation spatiale spécifique des domaines péricentriques est essentielle pour leur répression ainsi que pour leur organisation correcte. De plus, mes résultats suggèrent que les défauts d’organisation de l’hétérochromatine conduisent à des défauts de division cellulaire et de prolifération. La seconde partie de ma thèse montre que la réglementation stricte de L1 éléments transposables est nécessaire pour le développement préimplantatoire d'embryons de souris. En outre, représente la première tentative pour élucider la biologie des éléments L1 dans l’embryon précoce de souris par l’utilisation de modificateurs de transcription ciblés spécifiquement. / To study the formation of heterochromatin in mouse preimplantation embryo, I focused on two different genetic regions – pericentric repeats and L1 transposable elements - in order to investigate the mechanisms that lead to their repression and the distinct role that these regions can play during the process of development and cell division. My experiments show that the specific spatial organization of pericentric domains is essential for their repression and for their correct organization. Moreover, my findings suggest that defects in organization of heterochromatin lead to improper cell division and proliferation. The second part of my thesis shows that the tight regulation of L1 transposable elements is required for the preimplantation development of mouse embryos. Additionally, it is the first attempt to elucidate the biology of L1 elements in the early mouse embryo through the use of targeted transcription modifiers. Heterochromatin Répétitions péricentriques L1 retrotransposon Epigenetics Pluripotence Embryon de souris Heterochromatin Pericentric repeats L1 retrotransposones Epigenetics Pluripotency Mouse preimplantation embryos 571.86 572.8
313	The role of KMT5C on EGFR inhibitor resistance in non-small cell lung cancer Alejandra Agredo Montealegre (16924932) 06 September 2023 (has links) <p dir="ltr">Lung cancer is the leading cause of cancer-related deaths, and although important therapy advancements have been achieved, ~1.6 million people die from lung cancer annually. Non-small cell lung cancer (NSCLC), which makes up ~85% of lung cancer cases, is mainly treated with radiotherapy, chemotherapies, and targeted agents. Targeted agents are selected based on the mutation spectrum of the tumor. In NSCLC the epidermal growth factor receptor (EGFR) is commonly mutated and, leads to increased proliferation and cell survival. The standard-of-care treatment for patients with activating mutations in EGFR is treatment with tyrosine kinase inhibitors (TKI), such as erlotinib. While tumors initially respond to TKIs, after 1-2 years most patients develop resistance. In ~60% of TKI resistant tumors, resistance is the result of a secondary mutation in EGFR, whereas in the remaining 20%, tumors turn on bypass track-signals to overcome inhibition of the EGFR pathway. However, 15-20% of the cases the mechanisms underlying resistance are unknown. Most studies focus on the gain of function of oncogenes as mediators of resistance; however, little is known about the role that tumor suppressors play in TKI resistance. Hence, we performed a genome-wide CRISPR Cas9 knock-out screen to identify genes that when knocked-out would drive erlotinib resistance, and KMT5C was identified as the top candidate. KMT5C is a histone methyltransferase that trimethylates H4K20 (H4K20me3), enabling the establishment of constitutive and facultative heterochromatin. Data from human samples suggests that the <i>KMT5C</i> transcript is globally downregulated in NSCLC and in tumor samples resistant to the third generation TKI osimertinib. Additionally, loss of the modification H4K20me3, influences prognosis of NSCLC, indicating that loss of KMT5C function is a crucial mechanism in carcinogenesis. Here we describe how loss of KMT5C leads to increased transcription of the oncogene MET, due to a loss in H4K20me3-mediated repression of a long non-coding RNA transcription (LINC01510) upstream of MET. This mechanism was found to be partially responsible in driving TKI resistance in EGFR mutant cells. Historically, KMT5C has been associated with generation of constitutive heterochromatin (cHC); however, recent reports, including our own, indicate that KMT5C also regulates transcription in regions outside of cHC. Our preliminary evidence suggests that deposition of H42K0me3 via KMT5C in regions outside of cHC, is less stable than in cHC regions. This novel finding led us to hypothesize that regulation of KMT5C and H42K0me3 at different regions of heterochromatin is a dynamic process.</p> Signal transduction H4K20me3 epigenetics and chromatin drug resistance lung cancer tyrosine kinase inhibitor KMT5C SUV420H2/H4K20me3
314	Alternative Transcription Of The SLIT2/Mir-218-1 Transcriptional Axis Mediates Pancreatic Cancer Invasion Rheinheimer, Brenna Ann January 2016 (has links) The development of several organ systems through modeling and shaping of the tissue structure occurs from signaling through axon guidance molecules. The Slit family of ligands has been shown to regulate branching morphogenesis in mammary gland duct development and loss of Slit gene expression during this time leads to the formation of hyperplastic, disorganized lesions suggesting a potential role for Slits in cancer formation. Characterization of human pancreatic ductal adenocarcinoma cell lines showed a loss of SLIT2 expression in cells that contain activated Kras. Loss of SLIT2 expression was associated with DNA methylation of CpG sites within the SLIT2 core promoter and chromatin enrichment of repressive histone modifications at the SLIT2 transcriptional start site. Additionally, treatment of pancreatic ductal adenocarcinoma cell lines with demethylating agent 5-aza-2'-deoxycytidine led to SLIT2 re-expression while treatment with histone deacetylase inhibitor Trichostatin A did not. Mir-218-1 is an intronic microRNA encoded within intron 15 of the SLIT2 gene. Expression of mir-218-1 does not correlate with SLIT2 mRNA expression suggesting that it is transcribed from a promoter independent of the SLIT2 gene promoter. Pancreatic ductal adenocarcinoma cell lines showed a peak of H3K4me3 chromatin enrichment localized to a 1kb region within intron 4 of the SLIT2 gene denoting a candidate alternative promoter for mir-218-1. A concordant peak of H4ac chromatin enrichment overlapped the peak of H3K4me3 enrichment and transcriptional activity was measured from the 1kb region in all pancreatic ductal adenocarcinoma cell lines. A NF-κB binding site was also predicted to exist within the 1kb region. Transfection with two independent siRNAs to NF-κB led to an increase in both pre-mir-218-1 and mature mir-218-1 while treatment with an inhibitor to IκB kinase led to an increase in pre-mir-218-1 expression. Additionally, the p65 subunit of NF-κB was found to bind to the candidate mir-218-1 alternative promoter in pancreatic ductal adenocarcinoma cell lines that do not contain DNA CpG methylation at the predicted NF-κB binding site. It was discovered that miR-218 is a modulator of ARF6 expression suggesting a role in the inhibition of pancreatic ductal adenocarcinoma cell invasion through modulation of the actin cytoskeleton. Overexpression with a miR-218 precursor showed that miR-218 is an inhibitor of pancreatic ductal adenocarcinoma cell invasion in two dimensions. Additionally, it was found that while miR-218 does not have an affect on the ability of pancreatic ductal adenocarcinoma cells to form functional invadopodia, miR-218 is an inhibitor of the extracellular matrix degradation properties of mature invadopodia. Interestingly, the effect of miR-218 on pancreatic ductal adenocarcinoma cell invasion or extracellular matrix degradation is not reliant on the cell's dependency on Kras signaling for growth and survival. Collectively, these observations indicate that understanding the transcriptional regulation of SLIT2 and mir-218-1 expression as well as their signaling properties may provide a step toward the development of diagnostic tests and therapeutic treatments for patients with invasive or metastatic pancreatic ductal adenocarcinoma. Epigenetics Invasion miRNA Pancreatic cancer Transcriptional regulation Cancer Biology Axon guidance molecules
315	Structural and functional studies of chromatin modifying enzymes Walport, Louise J. January 2013 (has links) Epigenetic regulation is a complex process involving the interplay of multiple different cellular factors. Work described in this thesis concerned the characterisation of proteins involved in the binding to, and demethylation of, histone 3 (H3) tails modified by N-methylation. Initial work focussed on the biophysical characterisation of the tandem plant homeodomains (PHD) of the chromatin remodeller CHD4. NMR spectroscopy was used to investigate the solution structure of the tandem PHDs. Studies on a more native-like construct including the C terminal tandem chromodomains are also presented. Binding studies of the PHDs with H3 peptides reveal that the individual PHD fingers can independently bind a histone peptide. The remainder of the work involved characterisation of JmjC histone demethylases (KDMs), enzymes that catalyse removal of Nε-methyl groups from histone lysyl-residues. Initially, two members of the KDM7 subfamily, PHF8 and KIAA1718, were studied; a high throughput screening assay for them was developed, which enabled identification of a selective inhibitor of the KDM2/7 subfamilies of KDMs, the plant growth regulator Daminozide. A disease relevant mutation in PHF8 was studied and shown to cause mis-localisation of the enzyme to the cytoplasm, providing a potential explanation for the clinically observed phenotype. Subsequent chapters describe unprecedented activities for the JmjC KDMs. 2OG oxygenases catalyse a wide range of oxidative reactions, predominantly mediated by initial substrate hydroxylation. The activity of PHF8 with lysine analogous was tested; the results demonstrated that PHF8, and other KDMs, can oxidatively remove Nε-alkyl groups other than methyl groups, such as ethyl and isopropyl groups. The substrate scope of the JmjC KDMs thus has the potential to be wider than previously thought. Observation of β-hydroxylation of the Nε-isopropyl group of a histone peptide including Nε methylisopropyllysine by JMJD2A/E supports the presumed mechanism of histone lysine demethylation as proceeding via initial hydroxylation. This work led to the discovery that JmjC KDMs can catalyse arginine demethylation. This novel arginine demethylase activity by JmjC KDMs was characterised and the work extended to encompass potential arginine demethylase activity in cells. Biochemical characterisation of UTY, a homologue of the H3 K27 demethylases JMJD3 and UTX, which is reported to be inactive, was carried out; UTY was shown to catalyse demethylation at H3 trimethylated at K27 on peptidic substrates, albeit it at substantially lower rates than the other family members. To investigate the reason for this reduced activity, two variants were made, S1142G and P1214I; the latter variant was shown to be considerably more active than wildtype UTY, likely due to an increased peptide-binding interaction. Preliminary experiments in cells did not conclusively demonstrate histone demethylation, but a luciferase assay suggested that UTY may have catalytic activity in cells. Overall the findings in the thesis suggest that the process of cellular epigenetic regulation is likely even more complex than previously thought, with the potential that JmjC KDMs carry out multiple, context dependent functions. 572.8
316	The role of DNA methylation in the regulation of depot-specific gene expression in human adipose tissue Denton, Nathan Frederick January 2013 (has links) Adipose tissue is not homogenous as individual fat depots display regional variation in their physiological properties. It follows that body fat distribution is increasingly being recognised as a major determinant of metabolic disease risk. At the cellular level, depot-specific properties are exhibited by adipocyte precursors during in vitro culture and persist for many generations, suggesting these cells retain an ‘intrinsic memory’ of their anatomical origin which is epigenetic in nature. A primary aim was to identify depot-specific genes whose expression may be regulated by DNA methylation in adipose precursors. Using two paired preadipocyte cell lines derived from human subcutaneous abdominal and gluteal adipose tissue - to represent upper and lower body fat with their opposing associations with cardiovascular disease and diabetes respectively - depot-specific gene expression and DNA methylation profiles were detected. Furthermore, the expression of certain genes in preadipocytes was found to change in response to treatment with the DNA demethylating agent 5-azacytidine, which suggests DNA methylation may regulate depot-specific gene expression. A secondary aim was to investigate whether glucocorticoids – which are important determinants of body fat distribution – exert their effects through DNA methylation. The synthetic glucocorticoid dexamethasone was found to modulate the expression of some of the differentially expressed genes in preadipocytes, with this effect possibly being mediated by DNA methylation. It has been postulated that depot-specific phenotypes in adipose tissue may arise from developmental differences. Several genes were found to be expressed in a depot-specific fashion during a differentiation time course, suggesting regional variation in adipogenesis may contribute to the generation of depot-specific phenotypes. Overall, the data presented suggests regional variation within subcutaneous white adipose tissue exists and supports the notion that DNA methylation patterns can, in part, determine adipose tissue heterogeneity. 572.8
317	Behavioural, genetic and epigenetic determinants of white matter pathology in a new mouse model of chronic cerebral hypoperfusion Tsenkina, Yanina January 2013 (has links) Recent clinical studies suggest that white matter pathology rather than grey matter abnormality is the major neurobiological substrate of age- related cognitive decline during “healthy” aging. According to this hypothesis, cerebrovascular (e.g. chronic cerebral hypoperfusion) and molecular (e.g. APOE, epigenetics) factors might contribute to age-related white matter pathology and cognitive decline. To test this, I used a new mouse model of chronic cerebral hypoperfusion and examined the following predictions: 1) hypoperfusion- induced white matter pathology might be associated with cognitive deficits, 2) APOE deficiency might be associated with white matter anomalies under normal physiological conditions and more severe hypoperfusion- induced white matter pathology, 3) chronic cerebral hypoperfusion might impact on hydroxymethylation (a newly discovered epigenetic marker) in white matter, via perturbations in associated epigenetic pathways, namely methylation and/ or TETs. I. Effects of chronic cerebral hypoperfusion on white matter integrity and cognitive abilities in mice To test the hypothesis suggesting that hypoperfusion- induced white matter pathology is associated with working memory and executive function impairment in mice, behavioural performance and neuropathology were systematically examined in two separate cohorts of sham and hypoperfused C57Bl6J mice. Spatial working memory, memory flexibility, learning capacity, short and long term memory recall were taxed using radial arm maze and water maze paradigms one month after surgery. At the completion of the behavioural testing white and grey matter integrity, inflammation were evaluated using standard immunohistochemistry with antibodies recognizing neuronal axons (APP), myelin sheath (MAG) and microglia (Iba1) as well as H&E histological staining to examine neuronal morphology and ischemic injury. In agreement with previous reports, the behavioral data indicated spatial working memory impairment in the absence of spatial memory flexibility, learning, short- and long- term memory recall deficits in hypoperfused mice However, in contrast to previous reports, a spectrum of white and grey matter abnormalities accompanied by an increased inflammation were observed in hypoperfused mice Although there was a significant association between hypoperfusion- induced inflammation in white matter and performance on a working memory radial arm maze task (p<0.05), the present pathological findings suggest that white matter abnormalities, neuronal ischemia and increased inflammation might be at the basis of hypoperfusioninduced cognitive impairment in mice. Further, chronic cerebral hypoperfusion might have affected alternative, non- examined brain processes (e.g. cerebral metabolism, neurotransmission) which might have contributed to the observed cognitive deficits in hypoperfused mice. II. Effects of APOE on white matter integrity under normal physiological and chronically hypoperfused conditions in mice To test the hypothesis suggesting that mouse APOE deficiency might be associated with white matter anomalies under normal physiological conditions and the development of more severe white matter pathology following chronic cerebral hypoperfusion, white and grey matter integrity, inflammation were examined in APOE deficient mice on a C57Bl6J background (APOEKO) and C57Bl6J wild- type (WT) counterparts one month after chronic cerebral hypoperfusion or sham surgery. A combined neuroimaging (MRI- DTI)/ immunochemical approach was attempted in these mice as an additional step towards translation of this research to human subjects. The ex vivo MRI- DTI findings demonstrated APOE genotype effects on the development of white matter abnormalities following chronic cerebral hypoperfusion in mice. Significant reductions in MRI metrics (FA and MTR) of white matter integrity were observed in examined white matter areas of APOEKO hypoperfused mice compared with WT hypoperfused counterparts (p<0.05). However, the neuroimaigng findings were not supported by the pathological analysis where no significant APOE differences were observed in hypoperfusion- induced axonal (APP), myelin (MAG, dMBP) pathology and inflammation (Iba1) (p>0.05). No significant differences in MRI parameters and pathological grades of white matter integrity were evidenced between APOEKO and WT sham mice (p>0.05). An absence of grey matter abnormalities was evidenced on T2- weighted scans and corresponding H&E stained brain sections in all experimental animals. However, significant reductions in MTR values and dMBP immunoreactivity (myelin pathology) (p<0.05) were observed in grey matter (the hippocampus) following chronic cerebral hypoperfusion in the absence of significant APOE genotype effect (p>0.05) suggesting the existence of both white and grey matter abnormalities in this animal model. Overall, the present neuroimaging data, but not pathological analysis, partially validated the main study hypothesis suggesting that APOE deficiency might be associated with the development of more severe white matter abnormalities in hypoperfused mice. III. Characterization of methylation and hydroxymethylation in white matter under normal physiological and chronically hypoperfused conditions in mice Lastly, I sought to test the hypothesis that chronic cerebral hypoperfusion might alter oxygen dependent DNA hydroxymethylation (5hmC) in white matter regions via perturbations in methylation (5mC) and/ or Ten- eleven translocation proteins (e.g. TET2) in mice. DNA methylation (5mC), hydroxymethylation (5hmC) and TET2 were immunochemically studied in white and grey matter of sham and chronically hypoperfused C57Bl6J mice a month after surgery. The immunochemical results demonstrated significant increases (p<0.05) in 5hmC in the hypoperfused corpus callosum (CC) in the absence of significant hypoperfusion- induced alterations in the distribution of 5mC and TET2 (p>0.05) in white matter. Significant hypoperfusion- induced increases were evident for TET2 in the cerebral cortex (Cx) (p<0.05). These data partially validated the main study hypothesis suggesting hypoperfusion- induced alterations in 5hmC in white matter. However, in contrast to the study hypothesis, the observed hypoperfusion- induced alterations in 5hmC occurred in the absence of changes in 5mC and TET2 in white matter. A subsequent correlation analysis between hydroxymethylation and 5mC, TET2 in the CC failed to show significant associations (p>0.05). In search of the cellular determinants of 5hmC in the CC, hydroxymethylation was examined in relation to some of the cell types in white matter- mature oligodendrocytes, oligodendrolial progenitors (OPC) and microglia both in vivo and in vitro. Specifically, a separate parametric correlation analysis between the proportion of 5hmC positive cells and the respective proportions of mature oligodendrocytes, OPC and microglia in the CC demonstrated that hydroxymethylation correlated significantly only with microglia in vivo (p<0.05). Following this, 5hmC immunochemical distribution was studied in vitro in oligodendroglia cells at different stages of maturation, and interferon γ/ lypopolisaccharide activated and nonactivated microglia. The in vitro analysis demonstrated that 5hmC is high in OPC, activated and nonactivated microglia, but it is low in mature oligodendrocytes. Taken together the in vivo and in vitro cellular analyses suggest that the processes of hydroxymethylation in white matter might be immunoregulated. However, it is possible that in vivo in addition to microglia, other cell types (e.g. astrocytes, OPC) contributed to the presently observed 5hmC upregulation in the hypoperfused CC. Conclusion The experimental work presented in this thesis further developed and characterized a new mouse model of chronic cerebral hypoperfusion by confirming previous behavioural findings (e.g. working memory deficits) and revealing previously undetected spectrum of white and grey matter pathology in this animal model. The thesis demonstrated for the first time by using a newly developed ex vivo MRI procedure that APOE might modulate hypoperfusion- induced white matter pathology in mice. Additional immunochemical analysis revealed important hypoperfusion- induced epigenetic alterations in white (5hmC) and grey (TET2) matter in this animal model. Future experiments on chronically hypoperfused mice would allow to get a better insight into the neurobiological determinants (e.g. white vs. grey matter) underlying the observed cognitive deficits in this animal model, the involved cellular and molecular pathways as well as the functional significance of genetic (APOE) and epigenetic (5hmC, TETs) alterations in the hypoperfused brain. Future experimental work on this animal model would potentially reveal new biological targets for the pre- clinical development of therapies for age- related cognitive decline. Further development and optimization of the newly developed ex vivo MRI procedure would allow its broader application in preclinical settings and would facilitate the translation of experimental findings to clinics. 616.8
318	Maintenance of genomic imprinting by G9a/GLP complex of histone methyltransferases in embryonic stem (ES) cells Zhang, Tuo January 2014 (has links) DNA methylation refers to an addition of a methyl group to the 5 position of the cytosine pyrimidine ring. As the best characterized epigenetic mark, DNA methylation plays an important role in a plethora of biological functions, including gene repression, genomic imprinting, silencing of retro-transposons and X chromosome inactivation. Genomic imprinting refers to the mono-allelic expression of certain genes according to their parent-of-origin. In mammals, the expression of imprinted genes is controlled by the cis-acting regulatory elements, termed imprinted control regions (ICRs). ICRs are marked by parent-of-origin-specific DNA methylation and loss of DNA methylation at ICRs also causes aberrant expression of imprinted genes. Therefore it is believed that the genomic imprinting is a DNA methylation-associated epigenetic phenomenon. As accurate expression of imprinted genes is essential for normal embryonic growth, energy homeostasis, development of the brain and behaviour and abnormal expression of imprinted genes leads to numerous clinical phenotype and human disorders, it is important to investigate how the imprinted DNA methylation is stably maintained in mammals. DNA methyltransferases (DNMTs) are the main enzymes that play a in the establishment and maintenance of imprinted DNA methylation. In primordial germ cells (PGCs), DNMT3A and DNMT3L are involved in the establishment of imprinted DNA methylation. Whereas once established, the imprinted DNA methylation is maintained by DNMT1, DNMT3A and DNMT3B, but mainly by DNMT1. In addition, some other enzymes and DNA binding proteins also play a role in this process. One of the best examples is ZFP57, which forms a complex with KAP1 and SETDB1. ZFP57 maintains imprinted DNA methylation by recognizing a methylated hexa-nucleotide and recruits DNMTs to the ICRs in mammalian embryonic stem (ES) cells. Interestingly, DNA methylation analysis combined with promoter microarrays carried out in our lab suggested that imprinted DNA methylation is absent from some of the maternal ICRs in ES cells genetically null for G9a, a histone H3 lysine 9 methylase. This indicates that G9a might also play a role in the maintenance of imprinted DNA methylation. In my work, I found that the repressive H3K9me2 and imprinted DNA methylation are absent from several analysed ICRs in embryonic stem (ES) cells genetically null for either G9a or its partner histone methyltransferase GLP. A knockdown of G9a in ES cells reproduced these observations suggesting that G9a/GLP complex is required for the maintenance of imprinted DNA methylation. I also found that neither wild type nor catalytically inactive G9a can restore the loss of imprinted DNA methylation in G9a-/- ES cells. Chromatin immunoprecipitation (ChIP) combined with bisulfite DNA sequencing showed that imprinted DNA methylation was present on the H3K9me2-marked allele indicating a direct role for G9a in maintenance of genomic imprinting. Using a pharmacological inhibitor of G9a and mutagenesis analyses, I found that G9a maintains the imprinted DNA methylation independently of its catalytic activity and recruits DNMTs to the ICRs via its ankyrin repeat domain. Dimerization of G9a with GLP is also essential for the maintenance of genomic imprinting in ES cells. In summary, in addition to establish H3K9me2, histone methyltransferases G9a and GLP also play an essential role in the maintenance of genomic methylation imprints in ES cells. 572.8
319	Epigenetic Regulation of Gene Transcription in Hematopoietic Tumors Tshuikina Wiklander, Marina January 2008 (has links) <p>Epigenetic modifications were shown to play an essential role in tumorigenesis. Epigenetic mechanisms can alter transcription in several ways, through DNA methylation and/or through histone modification. DNA methylation at the TSS (transcriptional start site) has been implicated in tumor development and gene silencing. However, several examples of atypical methylation were shown. In Paper I we present the ICSBP/IRF8 gene that belongs to the IRF family and has characteristics of a tumor suppressor gene. The ICSBP/IRF8 is fully methylated in the promoter and TSS regions in U-937 and despite high expression of the gene. Presence of positive histone marks suggests that methylated DNA can be overridden by histone modification.</p><p>In Paper II a panel of 13 MM (multiple myeloma) cell lines and 9 primary patient tumors were analysed for methylation status of the ICSBP/IRF8 gene. In most cell lines (8/13) the gene was partially or fully methylated and partial methylation was also observed in 1/9 primary tumors. In vitro methylation analysis and treatment with 5-aza-2’deoxycytidine (DAC) proved that the ICSBP/IRF8 gene is silenced by methylation and may be associated with the malignant phenotype.</p><p>In Paper III and IV the NFκB signalling pathway was analysed and the role of ATRA and TNFα induction. In Paper III the data shows that activation of the NFκB pathway is essential in ATRA-induced terminal differentiation in the U-937 cell line and IκBα (S32A/S36A) inhibits ATRA-induced differentiation and G1 cell cycle arrest. This was accompanied by delayed down-regulation of several cyclins (A and E) and up-regulation of p21<sup>WAF1/CIP1</sup> (CDKN1A) and p27<sup>KIP1</sup> (CDKN1B).</p><p>TNFα alone did not induce expression of RA-induced genes analysed in Paper IV. However, ATRA in combination with TNFα showed enhanced activation of RA-induced genes. TNFα triggers demethylation of H3K9me3/H3K9me2 and H3K4me3 at RAR/RXR target genes, which were not accompanied by changes in the level of H3K9-ac. This decrease in H3 methylation by TNFα may pave way for the later ATRA-induced gene transcription.</p> Medical sciences IRF family ICSBP/IRF8 epigenetics ATRA TNFα histone modifications methylation transcription MEDICIN OCH VÅRD
320	Differential Licking in Early Life Alters Stress Behaviour and Brain Gene Expression in Adult Female Rats Pan, Pauline 09 December 2013 (has links) We investigated licking and grooming (LG) levels received by each pup from their dams and the locomotor activity, anxiety-like behaviors, and stress reactivity in adult female offspring. We also investigated glucocorticoid receptor (GR) gene expression and its DNA methylation status in the hippocampus, comparing pups between and with-in litters. Rats that receive more LG than their siblings showed less anxiety-like behaviors and increased locomotor activity, regardless of their litter type. Higher licked pups also showed increased expression of the GR gene. Gene expression levels of the GR 17 splice variant were not significantly different as a function of dam LG or LG received, whereas DNA methylation levels at two CpG sites within GR17 promoter were significantly higher in high LG pups than low LG pups. Our results indicate that naturally occurring intra- and inter-litter differences in maternal LG have a lasting effect on the phenotypic outcomes of adult female offspring. Rats licking and grooming maternal care epigenetics corticosterone glucocorticoid receptor gene expression hippocampus 0317

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