Inhibition of p300 lysine acetyltransferase activity by luteolin reduces tumor growth in head and neck squamous cell carcinoma (HNSCC) xenograft mouse model

Chromatin acetylation is attributed with distinct functional relevance with respect to gene expression in normal and diseased conditions thereby leading to a topical interest in the concept of epigenetic modulators and therapy. We report here the identification and characterization of the acetylation inhibitory potential of an important dietary flavonoid, luteolin. Luteolin was found to inhibit p300 acetyltransferase with competitive binding to the acetyl CoA binding site. Luteolin treatment in a xenografted tumor model of head and neck squamous cell carcinoma (HNSCC), led to a dramatic reduction in tumor growth within 4 weeks corresponding to a decrease in histone acetylation. Cells treated with luteolin exhibit cell cycle arrest and decreased cell migration. Luteolin treatment led to an alteration in gene expression and miRNA profile including up-regulation of p53 induced miR-195/215, let7C; potentially translating into a tumor suppressor function. It also led to down regulation of oncomiRNAs such as miR-135a, thereby reflecting global changes in the microRNA network. Furthermore, a direct correlation between the inhibition of histone acetylation and gene expression was established using chromatin immunoprecipitation on promoters of differentially expressed genes. A network of dysregulated genes and miRNAs was mapped along with the gene ontology categories, and the effects of luteolin were observed to be potentially at multiple levels: at the level of gene expression, miRNA expression and miRNA processing.

New Oncogenic Drivers in Hepatocellular Carcinoma: Role of the RNA Binding Protein Hu antigen R

156 p. : graf.

Stress-induced visceral pain in rodents: neurochemical, hormonal, immune and epigenetic mechanisms

Visceral pain is a debilitating disorder which affects up to 25% of the population at any one time. It is a global term used to describe pain originating from the internal organs, which is distinct from somatic pain. Currently the treatment strategies are unsatisfactory, with development of novel therapeutics hindered by a lack of detailed knowledge of the underlying mechanisms. The work presented in this thesis aimed to redress this issue and look in more detail at the molecular mechanisms of visceral pain in preclinical models. Stress has long been implicated in the pathophysiology of visceral pain in both preclinical and clinical studies. Here a mouse model of early-life stress-induced visceral hypersensitivity was validated. Moreover, mouse strain differences were also apparent in visceral sensitivity suggesting a possible genetic component to the underlying pathophysiology. Furthermore, gender and sex hormones were also implicated in stress sensitivity and visceral pain. Using the rat model of maternal separation, some of the epigenetic mechanisms underpinning visceral hypersensitivity, specifically the contribution of histone acetylation were unravelled. Glutamate has been well established in somatic pain processing, however, its contribution to visceral pain has not been extensively characterised. It was found that glutamate uptake is impaired in viscerally hypersensitive animals, an effect which could be reversed by treatment with riluzole, a glutamate uptake activator. Moreover, negative modulation of the metabotropic glutamate (mGlu) receptor 7 was sufficient to reverse visceral hypersensitivity in a stress sensitive rat strain, the Wistar Kyoto rat. Furthermore, toll-like receptor 4 (TLR4) was implicated in chronic stress-induced visceral hypersensitivity. Taken together, these findings have furthered our knowledge of the pathophysiology of visceral pain. In addition, we have identified glutamate transporters, mGlu7 receptor, histone acetylation and TLR4 as novel targets, amenable to pharmacological manipulation for the specific treatment of visceral pain.

Wnt Protein Signaling Reduces Nuclear Acetyl-CoA Levels to Suppress Gene Expression during Osteoblast Differentiation.

Developmental signals in metazoans play critical roles in inducing cell differentiation from multipotent progenitors. The existing paradigm posits that the signals operate directly through their downstream transcription factors to activate expression of cell type-specific genes, which are the hallmark of cell identity. We have investigated the mechanism through which Wnt signaling induces osteoblast differentiation in an osteoblast-adipocyte bipotent progenitor cell line. Unexpectedly, Wnt3a acutely suppresses the expression of a large number of genes while inducing osteoblast differentiation. The suppressed genes include Pparg and Cebpa, which encode adipocyte-specifying transcription factors and suppression of which is sufficient to induce osteoblast differentiation. The large scale gene suppression induced by Wnt3a corresponds to a global decrease in histone acetylation, an epigenetic modification that is associated with gene activation. Mechanistically, Wnt3a does not alter histone acetyltransferase or deacetylase activities but, rather, decreases the level of acetyl-CoA in the nucleus. The Wnt-induced decrease in histone acetylation is independent of β-catenin signaling but, rather, correlates with suppression of glucose metabolism in the tricarboxylic acid cycle. Functionally, preventing histone deacetylation by increasing nucleocytoplasmic acetyl-CoA levels impairs Wnt3a-induced osteoblast differentiation. Thus, Wnt signaling induces osteoblast differentiation in part through histone deacetylation and epigenetic suppression of an alternative cell fate.

Hyperacetylation in prostate cancer induces cell cycle aberrations, chromatin reorganization and altered gene expression profiles.

Histone acetylation is a fundamental mechanism in the regulation of local chromatin conformation and gene expression. Research has focused on the impact of altered epigenetic environments on the expression of specific genes and their pathways. However, changes in histone acetylation also have a global impact on the cell. In this study we used digital texture analysis to assess global chromatin patterns following treatment with trichostatin A (TSA) and have observed significant alterations in the condensation and distribution of higher-order chromatin, which were associated with altered gene expression profiles in both immortalised normal PNT1A prostate cell line and androgen-dependent prostate cancer cell line LNCaP. Furthermore, the extent of TSA-induced disruption was both cell cycle and cell line dependent. This was illustrated by the identification of sub-populations of prostate cancer cells expressing high levels of H3K9 acetylation in the G2/M phase of the cell cycle that were absent in normal cell populations. In addition, the analysis of enriched populations of G1 cells showed a global decondensation of chromatin exclusively in normal cells.

Protein arginine-methyltransferase-dependent oncogenesis

Enzymes that mediate reversible epigenetic modifications have not only been recognized as key in regulating gene expression(1) and oncogenesis(2,3), but also provide potential targets for molecular therapy(4). Although the methylation of arginine 3 of histone 4 ( H4R3) by protein arginine methyltransferase 1 ( PRMT1) is a critical modification for active chromatin(5,6) and prevention of heterochromatin spread(7), there has been no direct evidence of any role of PRMTs in cancer. Here, we show that PRMT1 is an essential component of a novel Mixed Lineage Leukaemia ( MLL) oncogenic transcriptional complex with both histone acetylation and H4R3 methylation activities, which also correlate with the expression of critical MLL downstream targets. Direct fusion of MLL with PRMT1 or Sam68, a bridging molecule in the complex for PRMT1 interaction, could enhance self-renewal of primary haematopoietic cells. Conversely, specific knockdown of PRMT1 or Sam68 expression suppressed MLL-mediated transformation. This study not only functionally dissects the oncogenic transcriptional machinery associated with an MLL fusion complex, but also uncovers-for the first time-an essential function of PRMTs in oncogenesis and reveals their potential as novel therapeutic targets in human cancer.

Epigenetics in Vascular Disease - Therapeutic Potential of New Agents

Vascular diseases, including atherosclerosis, angioplasty-induced restenosis, vessel graft arteriosclerosis and hypertension-related stenosis, remain the most prevalent cause of death in the developed world. The aetiology of vascular diseases is multifactorial with both genetic and environmental factors. Recently, some of the most promising research identifies the epigenetic modification of the genome to play a major role in the disease development, linking the environmental insults with gene regulation. In this process, modification of DNA by methylation, and histone modification by acetylation, methylation, phosphorylation and/or SUMOylation are reported. Importantly, recent studies demonstrated that histone deacetylase (HDAC) enzymes are crucial in endothelial integrity, smooth muscle proliferation and in the formation of arteriosclerosis in animal models. The study of HDACs has shown remarkable specificity of HDAC family members in vascular cell growth/death that influences the disease process. Interestingly, the effects of HDACs on arteriosclerosis development in animal models have been observed after HDAC inhibition using specific inhibitors. This provides a new approach for the treatment of vascular disease using the agents that influence the epigenetic process in vascular cells. This review updates the rapid advances in epigenetics of vascular diseases focusing on the role of HDAC family in atherosclerosis. It will also discuss the underlying mechanisms of histone acetylation in vascular cells and highlight the therapeutic potential of such agents.

A phase I/II trial of vorinostat in combination with 5-fluorouracil in patients with metastatic colorectal cancer who previously failed 5-FU-based chemotherapy

PURPOSE: We conducted a phase I/II clinical trial to determine the safety and feasibility of combining vorinostat with 5-fluorouracil (5-FU) in patients with metastatic colorectal cancer (mCRC) and elevated intratumoral thymidylate synthase (TS).

METHODS: Patients with mCRC who had failed all standard therapeutic options were eligible. Intratumoral TS mRNA expression and peripheral blood mononuclear cell (PBMC) histone acetylation were measured before and after 6 consecutive days of vorinostat treatment at 400 mg PO daily. 5-FU/LV were given on days 6 and 7 and repeated every 2 weeks, along with continuous daily vorinostat. Dose escalation occurred in cohorts of three to six patients.

RESULTS: Ten patients were enrolled. Three dose levels were explored in the phase I portion of the study. Two dose-limiting toxicities (DLTs) were observed at the starting dose level, which resulted in dose de-escalation to levels -1 and -2. Given the occurrence of two DLTs at each of the dose levels, we were unable to establish a maximum tolerated dose (MTD). Two patients achieved significant disease stabilization for 4 and 6 months. Grade 3 and 4 toxicities included fatigue, thrombocytopenia and mucositis. Intratumoral TS downregulation > or = 50% was observed in one patient only. Acetylation of histone 3 was observed in PBMCs following vorinostat treatment.

CONCLUSIONS: The study failed to establish a MTD and was terminated. The presence of PBMC histone acetylation indicates biological activity of vorinostat, however, consistent reductions in intratumoral TS mRNA were not observed. Alternate vorinostat dose-scheduling may alleviate the toxicity and achieve optimal TS downregulation.

Mécanismes moléculaires impliqués dans la régulation de l’acide polysialique (PSA) dans le néocortex visuel des souris durant la maturation des synapses GABAergiques

Le fonctionnement du cortex cérébral nécessite l’action coordonnée de deux des sous-types majeurs de neurones, soient les neurones à projections glutamatergiques et les interneurones GABAergiques. Les interneurones GABAergiques ne constituent que 20 à 30% des cellules corticales par rapport au grand nombre de neurones glutamatergiques. Leur rôle est toutefois prépondérant puisqu’ils modulent fortement la dynamique et la plasticité des réseaux néocorticaux. Il n’est donc pas surprenant que les altérations de développement des circuits GABAergiques soient associées à plusieurs maladies du cerveau, incluant l’épilepsie, le syndrome de Rett et la schizophrénie. La compréhension des mécanismes moléculaires régissant le développement des circuits GABAergiques est une étape essentielle menant vers une meilleure compréhension de la façon dont les anormalités se produisent. Conséquemment, nous nous intéressons au rôle de l’acide polysialique (PSA) dans le développement des synapses GABAergiques. PSA est un homopolymère de chaînons polysialylés en α-2,8, et est exclusivement lié à la molécule d’adhésion aux cellules neuronales (NCAM) dans les cerveaux de mammifères. PSA est impliqué dans plusieurs processus développementaux, y compris la formation et la plasticité des synapses glutamatergiques, mais son rôle dans les réseaux GABAergiques reste à préciser. Les données générées dans le laboratoire du Dr. Di Cristo démontrent que PSA est fortement exprimé post- natalement dans le néocortex des rongeurs, que son abondance diminue au cours du développement, et, faits importants, que son expression dépend de l’activité visuelle i et est inversement corrélée à la maturation des synapses GABAergiques. La présente propose de caractériser les mécanismes moléculaires régulant l’expression de PSA dans le néocortex visuel de la souris. Les enzymes polysialyltransférases ST8SiaII (STX) et ST8SiaIV (PST) sont responsables de la formation de la chaîne de PSA sur NCAM. En contrôlant ainsi la quantité de PSA sur NCAM, ils influenceraient le développement des synapses GABAergiques. Mon projet consiste à déterminer comment l’expression des polysialyltransférases est régulée dans le néocortex visuel des souris durant la période post-natale; ces données sont à la fois inconnues, et cruciales. Nous utilisons un système de cultures organotypiques dont la maturation des synapses GABAergiques est comparable au modèle in vivo. L’analyse de l’expression génique par qPCR a démontré que l’expression des polysialyltransférases diminue au cours du développement; une baisse majeure corrélant avec l’ouverture des yeux chez la souris. Nous avons de plus illustré pour la première fois que l’expression de STX, et non celle de PST, est activité-dépendante, et que ce processus requiert l’activation du récepteur NMDA, une augmentation du niveau de calcium intracellulaire et la protéine kinase C (PKC). Ces données démontrent que STX est l’enzyme régulant préférentiellement le niveau de PSA sur NCAM au cours de la période post-natale dans le cortex visuel des souris. Des données préliminaires d’un second volet de notre investigation suggèrent que l’acétylation des histones et la méthylation de l’ADN pourraient également contribuer à la régulation de la transcription de cette enzyme durant le développement. Plus d’investigations seront toutefois nécessaires afin de confirmer cette hypothèse. En somme, la connaissance des mécanismes par lesquels l’expression des ii polysialyltransférases est modulée est essentielle à la compréhension du processus de maturation des synapses GABAergiques. Ceci permettrait de moduler pharmacologiquement l’expression de ces enzymes; la sur-expression de STX et/ou PST pourrait produire une plus grande quantité de PSA, déstabiliser les synapses GABAergiques, et conséquemment, ré-induire la plasticité cérébrale.

Rôle de l’acétylation/déacétylation des histones dans la régulation de l’expression des gènes de la COX-2, iNOS et mPGES-1 dans les tissus articulaires.

L’arthrose ou ostéoarthrose (OA) est l’affection rhumatologique la plus fréquente au monde. Elle est caractérisée principalement par une perte du cartilage articulaire et l’inflammation de la membrane synoviale. L’interleukine (IL)-1ß, une cytokine pro-inflammatoire, joue un rôle très important dans la pathogenèse de l’OA. Elle exerce son action en induisant l’expression des enzymes cyclo-oxygénase 2 (COX-2), prostaglandine E synthétase microsomale 1 (mPGES-1) et l’oxyde nitrique synthétase inductible (iNOS) ainsi que la production de la prostaglandine E2 (PGE2) et de l’oxyde nitrique (NO). Ces derniers (PGE2 et NO) contribuent à la synovite et la destruction du cartilage articulaire par leurs effets pro-inflammatoires, pro-cataboliques, anti-anaboliques, pro-angiogéniques et pro-apoptotiques. Les modifications épigénétiques, telles que la méthylation de l’ADN, et l’acétylation et la méthylation des histones, jouent un rôle crucial dans la régulation de l’expression des gènes. Parmi ces modifications, l’acétylation des histones est la plus documentée. Ce processus est contrôlé par deux types d’enzymes : les histones acétyltransférases (HAT) qui favorisent la transcription et les histones déacétylases (HDAC) qui l’inhibent. L’objectif de ce travail est d’examiner le rôle des enzymes HDAC dans la régulation de l’expression de la COX-2, mPGES-1 et iNOS. Nous avons montré qu’au niveau des chondrocytes, les inhibiteurs des HDAC (iHDAC), trichostatine A (TSA) et butyrate de sodium (NaBu), suppriment l’expression de la COX-2 et iNOS au niveau de l’ARNm et protéique, ainsi que la production de la PGE2 et du NO, induites par l’IL-1ß. L’effet inhibiteur à lieu sans affecter l’activité de liaison à l’ADN du facteur de transcription NF-κB (nuclear factor κ B). La TSA et le NaBu inhibent également la dégradation induite par l’IL-1ß des protéoglycanes au niveau du cartilage. Nous avons également montré, qu’au niveau des fibroblastes synoviaux, les iHDAC, TSA, NaBu et acide valproïque (VA), suppriment l’expression de la mPGES-1 ainsi que la production de la PGE2 induites par l’IL-1ß. En utilisant diverses approches expérimentales, nous avons montré que HDAC4 est impliquée dans l’induction de l’expression de la mPGES-1 par l’IL-1ß. HDAC4 exerce son action, via son activité déacétylase, en augmentant l’activité transcriptionnelle de Egr-1 (early growth factor 1), facteur de transcription principal de l’expression de la mPGES-1. L’ensemble de ces résultats suggère que les inhibiteurs des HDAC pourraient être utilisés dans le traitement de l’OA.

Homéostasie des histones en réponse au dommage à l’ADN et étude d’inhibiteurs de désacétylases d’importance clinique

La chromatine possède une plasticité complexe et essentielle pour répondre à différents mécanismes cellulaires fondamentaux tels la réplication, la transcription et la réparation de l’ADN. Les histones sont les constituants essentiels de la formation des nucléosomes qui assurent le bon fonctionnement cellulaire d’où l’intérêt de cette thèse d’y porter une attention particulière. Un dysfonctionnement de la chromatine est souvent associé à l’émergence du cancer. Le chapitre II de cette thèse focalise sur la répression transcriptionnelle des gènes d’histones par le complexe HIR (HIstone gene Repressor) en réponse au dommage à l'ADN chez Saccharomyces cerevisiae. Lors de dommage à l’ADN en début de phase S, les kinases du point de contrôle Mec1, Tel1 et Rad53 s’assurent de bloquer les origines tardives de réplication pour limiter le nombre de collisions potentiellement mutagéniques ou cytotoxiques entre les ADN polymérases et les lésions persistantes dans l'ADN. Lorsque la synthèse totale d’ADN est soudainement ralentie par le point de contrôle, l’accumulation d'un excès d'histones nouvellement synthétisées est néfaste pour les cellules car les histones libres se lient de manière non-spécifique aux acides nucléiques. L'un des mécanismes mis en place afin de minimiser la quantité d’histones libres consiste à réprimer la transcription des gènes d'histones lors d'une chute rapide de la synthèse d'ADN, mais les bases moléculaires de ce mécanisme étaient très mal connues. Notre étude sur la répression des gènes d’histones en réponse aux agents génotoxiques nous a permis d’identifier que les kinases du point de contrôle jouent un rôle dans la répression des gènes d’histones. Avant le début de mon projet, il était déjà connu que le complexe HIR est requis pour la répression des gènes d’histones en phase G1, G2/M et lors de dommage à l’ADN en phase S. Par contre, la régulation du complexe HIR en réponse au dommage à l'ADN n'était pas connue. Nous avons démontré par des essais de spectrométrie de masse (SM) que Rad53 régule le complexe HIR en phosphorylant directement une de ses sous-unités, Hpc2, à de multiples résidus in vivo et in vitro. La phosphorylation d’Hpc2 est essentielle pour le recrutement aux promoteurs de gènes d’histones du complexe RSC (Remodels the Structure of Chromatin) dont la présence sur les promoteurs des gènes d'histones corrèle avec leur répression. De plus, nous avons mis à jour un nouveau mécanisme de régulation du complexe HIR durant la progression normale à travers le cycle cellulaire ainsi qu'en réponse aux agents génotoxiques. En effet, durant le cycle cellulaire normal, la protéine Hpc2 est très instable durant la transition G1/S afin de permettre la transcription des gènes d’histones et la production d'un pool d'histones néo-synthétisées juste avant l'initiation de la réplication de l’ADN. Toutefois, Hpc2 n'est instable que pour une brève période de temps durant la phase S. Ces résultats suggèrent qu'Hpc2 est une protéine clef pour la régulation de l'activité du complexe HIR et la répression des gènes d’histones lors du cycle cellulaire normal ainsi qu'en réponse au dommage à l’ADN. Dans le but de poursuivre notre étude sur la régulation des histones, le chapitre III de ma thèse concerne l’analyse globale de l’acétylation des histones induite par les inhibiteurs d’histone désacétylases (HDACi) dans les cellules normales et cancéreuses. Les histones désacétylases (HDACs) sont les enzymes qui enlèvent l’acétylation sur les lysines des histones. Dans plusieurs types de cancers, les HDACs contribuent à l’oncogenèse par leur fusion aberrante avec des complexes protéiques oncogéniques. Les perturbations causées mènent souvent à un état silencieux anormal des suppresseurs de tumeurs. Les HDACs sont donc une cible de choix dans le traitement des cancers engendrés par ces protéines de fusion. Notre étude de l’effet sur l’acétylation des histones de deux inhibiteurs d'HDACs de relevance clinique, le vorinostat (SAHA) et l’entinostat (MS-275), a permis de démontrer une augmentation élevée de l’acétylation globale des histones H3 et H4, contrairement à H2A et H2B, et ce, autant chez les cellules normales que cancéreuses. Notre quantification en SM de l'acétylation des histones a révélé de façon inattendue que la stœchiométrie d'acétylation sur la lysine 56 de l’histone H3 (H3K56Ac) est de seulement 0,03% et, de manière surprenante, cette stœchiométrie n'augmente pas dans des cellules traitées avec différents HDACi. Plusieurs études de H3K56Ac chez l’humain présentes dans la littérature ont rapporté des résultats irréconciliables. Qui plus est, H3K56Ac était considéré comme un biomarqueur potentiel dans le diagnostic et pronostic de plusieurs types de cancers. C’est pourquoi nous avons porté notre attention sur la spécificité des anticorps utilisés et avons déterminé qu’une grande majorité d’anticorps utilisés dans la littérature reconnaissent d’autres sites d'acétylation de l’histone H3, notamment H3K9Ac dont la stœchiométrie d'acétylation in vivo est beaucoup plus élevée que celle d'H3K56Ac. De plus, le chapitre IV fait suite à notre étude sur l’acétylation des histones et consiste en un rapport spécial de recherche décrivant la fonction de H3K56Ac chez la levure et l’homme et comporte également une évaluation d’un anticorps supposément spécifique d'H3K56Ac en tant qu'outil diagnostic du cancer chez l’humain.

HDAC inhibitors attenuate the development of hypersensitivity in models of neuropathic pain

Histone deacetylase inhibitors (HDACIs) interfere with the epigenetic process of histone acetylation and are known to have analgesic properties in models of chronic inflammatory pain. The aim of this study was to determine whether these compounds could also affect neuropathic pain. Different class I HDACIs were delivered intrathecally into rat spinal cord in models of traumatic nerve injury and antiretroviral drug-induced peripheral neuropathy (stavudine, d4T). Mechanical and thermal hypersensitivity was attenuated by 40% to 50% as a result of HDACI treatment, but only if started before any insult. The drugs globally increased histone acetylation in the spinal cord, but appeared to have no measurable effects in relevant dorsal root ganglia in this treatment paradigm, suggesting that any potential mechanism should be sought in the central nervous system. Microarray analysis of dorsal cord RNA revealed the signature of the specific compound used (MS-275) and suggested that its main effect was mediated through HDAC1. Taken together, these data support a role for histone acetylation in the emergence of neuropathic pain.

Transcriptional regulation differs in affected facioscapulohumeral muscular dystrophy patients compared to asymptomatic related carriers

Facioscapulohumeral muscular dystrophy (FSHD) is a progressive muscle disorder that has been associated with a contraction of 3.3-kb repeats on chromosome 4q35. FSHD is characterized by a wide clinical inter- and intrafamilial variability, ranging from wheelchair-bound patients to asymptomatic carriers. Our study is unique in comparing the gene expression profiles from related affected, asymptomatic carrier, and control individuals. Our results suggest that the expression of genes on chromosome 4q is altered in affected and asymptomatic individuals. Remarkably, the changes seen in asymptomatic samples are largely in products of genes encoding several chemokines, whereas the changes seen in affected samples are largely in genes governing the synthesis of GPI-linked proteins and histone acetylation. Besides this, the affected patient and related asymptomatic carrier share the 4qA161 haplotype. Thus, these polymorphisms by themselves do not explain the pathogenicity of the contracted allele. Interestingly, our results also suggest that the miRNAs might mediate the regulatory network in FSHD. Together, our results support the previous evidence that FSHD may be caused by transcriptional dysregulation of multiple genes, in cis and in trans, and suggest some factors potentially important for FSHD pathogenesis. The study of the gene expression profiles from asymptomatic carriers and related affected patients is a unique approach to try to enhance our understanding of the missing link between the contraction in D4Z4 repeats and muscle disease, while minimizing the effects of differences resulting from genetic background.

Efeitos da tricostatina A sobre a acetilação de histonas, proliferação celular e diferenciação de células tronco embrionárias murinas

Background: Embryonic stem cells are cells derived from early-stage embryos that are characterized by pluripotency and self-renewal capacity. The in vitro cultured murine embryonic stem cells can indefinitely propagate in an undifferentiated state in the presence of leukemia inhibitory factor (LIF). However, when stimulated, these cells can differentiate into cell lines derived from all three embryonic germ layers. The trichostatin A (TSA) is an epigenetic modifier agent and several studies have used the TSA to stimulate cellular differentiation. However, most of these studies only assessed one TSA concentration. Therefore, this study aimed to evaluate the effects of different TSA concentrations on histone hyperacetylation during in vitro cell differentiation of murine pluripotent embryonic stem cells, cultured with or without LIF, in the quest of to standardize their application on early cultures of embryonic stem cells.Materials, Methods & Results: Undifferentiated murine embryonic stem cells were plated in the presence of different TSA concentrations (0 nM, 15 nm, 50 nM and 100 nM) in the presence or absence of LIF. Thus, the treatments were evaluated in undifferentiated embryonic stem cells cultured in the presence of LIF (Control group: 0 nM LIF(+); Group 15 nM LIF+; Group 50 nM LIF+ and Group 100 nM LIF+), and in embryonic stem cells cultured in the absence of LIF (Control group: 0 nM LIF; Group 15 nM LIF(-); Group 50 nM LIF(-) and Group 100 nM LIF-). Treatment with TSA was performed for 24 h. After that the medium was replaced with fresh medium without TSA. Samples were collected at 0, 12, 24, 36 and 48 h after the beginning of the experiment. Three replicates were performed in each experimental group. The relative amount of Histone H3 lysine 9 acetylation was analyzed in all groups, as well as the cell proliferation in the embryonic stem cells cultured in the presence of LIF. In the control group (0 nM), the absence of LIF resulted in higher levels (P < 0.05) of H3lys9ac compared to the cultures supplemented with LIF. In the embryonic stem cells cultured in the presence of LIF, the 50 nM and 100 nM treatments resulted in higher levels (P < 0.05) of H3lys9ac when compared with 0 nM and 15 nM treatments. Evaluating the Hoechst area in the 0 nM group, it was observed that the number of cells increased (P < 0.05) according to the time of culture. Treatment with 15 nM also reflected a similar distribution, but the Hoechst area in 15 nM group was lower (P < 0.05) at 24 and 48h when compared to the observed in the control group. In the 100 nM treatment, was observed that the area of Hoechst was lower (P < 0.05) to that obtained in the control group at 12, 24 and 48h. In addition, it was observed that treatment with TSA induces greater cellular differentiation when compared to control groups in stem cells cultured in the presence of LIF as well as in the absence of LIF.Discussion: In the present study it was observed that TSA treatment increased the levels of histone acetylation in murine embryonic stem cells at a 50 nM concentration, making it possible to reduce the concentration recommended in the literature (100 nM). In addtion, it was concluded that the lower TSA concentrations utilized (15 nm and 50 nM) was less harmful to cellular proliferation than the 100 nM TSA concentration.

HDAC inhibition decreases XIST expression on female IVP bovine blastocysts

During initial development, both X chromosomes are active in females, and one of them must be silenced at the appropriate time in order to dosage compensate their gene expression levels to male counterparts. Silencing involves epigenetic mechanisms, including histone deacetylation. Major X chromosome inactivation (XCI) in bovine occurs between hatching and implantation, although in vitro culture conditions might disrupt the silencing process, increasing or decreasing X-linked gene expression. In this study, we aimed to address the roles of histone deacetylase inhibition by trichostatin A (TSA) on female preimplantation development.We tested the hypothesis that by enhancing histone acetylation, TSA would increase the percentage of embryos achieving 16-cell stage, reducing percentage of embryos blocked at 8-cell stage, and interfere with XCI in IVF embryos. We noticed that after TSA treatment, acetylation levels in individual blastomeres of 8-16 cell embryos were increased twofold on treated embryos, and the samewas detected for blastocysts. Changes among blastomere levels within the same embryo were diminished on TSA group, as low-acetylated blastomeres were no longer detected. The percentage of embryos that reached the 5th cleavage cycle 118 h after IVF, analyzed by Hoechst staining, remained unaltered after TSA treatment. Then, we assessed XIST and G6PD expression in individual female bovine blastocysts by quantitative real-time PCR. Even though G6PD expression remained unaltered after TSA exposure, XIST expression was eightfold decreased, and we also detected a major decrease in the percentage of blastocysts expressing detectable XIST levels after TSA treatment. Based on these results, we conclude that HDAC is involved on XCI process in bovine embryos, and its inhibition might delay X chromosome silencing and attenuate aberrant XIST expression described for IVF embryos. © 2013 Society for Reproduction and Fertility.