IL3 Has a Detrimental Effect on Hematopoietic Stem Cell Self-Renewal in Transplantation Settings.

The ex vivo expansion and maintenance of long-term hematopoietic stem cells (LT-HSC) is crucial for stem cell-based gene therapy. A combination of stem cell factor (SCF), thrombopoietin (TPO), FLT3 ligand (FLT3) and interleukin 3 (IL3) cytokines has been commonly used in clinical settings for the expansion of CD34+ from different sources, prior to transplantation. To assess the effect of IL3 on repopulating capacity of cultured CD34+ cells, we employed the commonly used combination of STF, TPO and FILT3 with or without IL3. Expanded cells were transplanted into NSG mice, followed by secondary transplantation. Overall, this study shows that IL3 leads to lower human cell engraftment and repopulating capacity in NSG mice, suggesting a negative effect of IL3 on HSC self-renewal. We, therefore, recommend omitting IL3 from HSC-based gene therapy protocols.

Monocyte-derived tissue transglutaminase in multiple sclerosis patients: reflecting an anti-inflammatory status and function of the cells?

BACKGROUND: Leukocyte infiltration into the central nervous system is an important feature of multiple sclerosis (MS) pathology. Among the infiltrating cells, monocytes comprise the largest population and are considered to play a dual role in the course of the disease. The enzyme tissue transglutaminase (TG2), produced by monocytes, plays a central role in monocyte adhesion/migration in animal models of MS. In the present study, we questioned whether TG2 expression is altered in monocytes from MS patients compared to healthy control (HC) subjects. Moreover, we determined the inflammatory status of these TG2-expressing monocytes, what inflammatory factor regulates TG2 expression, and whether TG2 can functionally contribute to their adhesion/migration processes. METHODS: Primary human monocytes from MS patients and HC subjects were collected, RNA isolated and subjected to qPCR analysis. Human THP-1 monocytes were lentivirally transduced with TG2 siRNA or control and treated with various cytokines. Subsequently, mRNA levels of inflammatory factors, adhesion properties, and activity of RhoA were analyzed in interleukin (IL)-4-treated monocytes. RESULTS: TG2 mRNA levels are significantly increased in monocytes derived from MS patients compared to HC subjects. In addition, correlation analyses indicated that TG2-expressing cells display a more anti-inflammatory, migratory profile in MS patients. Using THP-1 monocytes, we observed that IL-4 is a major trigger of TG2 expression in these cells. Furthermore, knockdown of TG2 expression leads to a pro-inflammatory profile and reduced adhesion/migration properties of IL-4-treated monocytes. CONCLUSIONS: TG2-expressing monocytes in MS patients have a more anti-inflammatory profile. Furthermore, TG2 mediates IL-4-induced anti-inflammatory status in THP-1 monocytes, adhesion, and cytoskeletal rearrangement in vitro. We thus propose that IL-4 upregulates TG2 expression in monocytes of MS patients, driving them into an anti-inflammatory status.

T Cell factor 1 represses CD8+ effector T cell formation and function.

The Wnt-responsive transcription factor T cell factor 1 (Tcf1) is well known for its role in thymic T cell development and the formation of memory CD8(+) T cells. However, its role in the initial phases of CD8(+) T effector cell formation has remained unexplored. We report that high levels of Wnt signaling and Tcf1 are operational in naive and memory CD8(+) T cells, whereas Wnt signaling and Tcf1 were low in effector CD8(+) T cells. CD8(+) T cells deficient in Tcf1 produce IFN-γ more rapidly, coinciding with increased demethylation of the IFN-γ enhancer and higher expression of the transcription factors Tbet and Blimp1. Moreover, virus-specific Tcf1(-/-) CD8(+) T cells show accelerated expansion in acute infection, which is associated with increased IFN-γ and TNF production and lower viral load. Genetic complementation experiments with various Tcf1 isoforms indicate that Tcf1 dosage and protein stability are critical in suppressing IFN-γ production. Isoforms lacking the ß-catenin binding domain are equally effective in inhibiting CD8(+) effector T cell formation. Thus, Tcf1 functions as a repressor of CD8(+) effector T cell formation in a ß-catenin/Wnt-independent manner.

Chromatin status of apoptosis genes correlates with sensitivity to chemo-, immune- and radiation therapy in colorectal cancer cell lines.

The apoptosis pathway of programmed cell death is frequently deregulated in cancer. An intact apoptosis pathway is required for proper response to anti-cancer treatment. We investigated the chromatin status of key apoptosis genes in the apoptosis pathway in colorectal cancer cell lines in relation to apoptosis induced by chemo-, immune- or radiation therapy. Using chromatin immunoprecipitation (ChIP), we measured the presence of transcription-activating histone modifications H3Ac and H3K4me3 and silencing modifications H3K9me3 and H3K27me3 at the gene promoter regions of key apoptosis genes Bax, Bcl2, Caspase-9, Fas (CD95) and p53. Cell lines DLD1, SW620, Colo320, Caco2, Lovo and HT29 were treated with cisplatin, anti-Fas or radiation. The apoptotic response was measured by flow cytometry using propidium iodide and annexin V-FITC. The chromatin status of the apoptosis genes reflected the activation status of the intrinsic (Bax, Bcl2, Caspase-9 and p53) and extrinsic (Fas) pathways. An active intrinsic apoptotic pathway corresponded to sensitivity to cisplatin and radiation treatment of cell lines DLD1, SW620 and Colo320. An active Fas promoter corresponded to an active extrinsic apoptotic pathway in cell line DLD1. mRNA expression data correlated with the chromatin status of the apoptosis genes as measured by ChIP. In conclusion, the results presented in this study indicate that the balance between activating and silencing histone modifications, reflecting the chromatin status of apoptosis genes, can be used to predict the response of tumor cells to different anti-cancer therapies and could provide a novel target to sensitize tumors to obtain adequate treatment responses.

NLRC5 cooperates with the RFX transcription factor complex to induce MHC class I gene expression.

Tight regulation of MHC class I gene expression is critical for CD8 T cell activation and host adaptive-immune responses. The promoters of MHC class I genes contain a well-conserved core module, the W/S-X-Y motif, which assembles a nucleoprotein complex termed MHC enhanceosome. A member of the nucleotide-binding domain, leucine-rich repeat (NLR) protein family, NLRC5, is a newly identified transcriptional regulator of MHC class I genes. NLRC5 associates with and transactivates the proximal promoters of MHC class I genes, although the molecular mechanism of transactivation has not been understood. In this article, we show that NLRC5-mediated MHC class I gene induction requires the W/S and X1, X2 cis-regulatory elements. The transcription factors RFX5, RFXAP, and RFXANK/B, which compose the RFX protein complex and associate with the X1 box, cooperate with NLRC5 for MHC class I expression. Coimmunoprecipitation experiments revealed that NLRC5 specifically interacts with the RFX subunit RFXANK/B via its ankyrin repeats. In addition, we show that NLRC5 can cooperate with ATF1 and the transcriptional coactivators CBP/p300 and general control nonderepressible 5, which display histone acetyltransferase activity. Taken together, our data suggest that NLRC5 participates in an MHC class I-specific enhanceosome, which assembles on the conserved W/S-X-Y core module of the MHC class I proximal promoters, including the RFX factor components and CREB/ATF1 family transcription factors, to promote MHC class I gene expression.

Epigenetic control of CCR5 transcript levels in immune cells and modulation by small molecules inhibitors.

Previously, we have shown that CCR5 transcription is regulated by CREB-1. However, the ubiquitous pattern of CREB-1 expression suggests the involvement of an additional level of transcriptional control in the cell type-specific expression of CCR5. In this study, we show that epigenetic changes (i.e. DNA methylation and histone modifications) within the context of the CCR5 P1 promoter region correlate with transcript levels of CCR5 in healthy and in malignant CD4(+) T lymphocytes as well as in CD14(+) monocytes. In normal naïve T cells and CD14(+) monocytes the CCR5 P1 promoter resembles a bivalent chromatin state, with both repressive and permissive histone methylation and acetylation marks. The CCR5-expressing CD14(+) monocytes however show much higher levels of acetylated histone H3 (AcH3) compared to the non-CCR5-expressing naïve T cells. Combined with a highly methylated promoter in CD14(+) monocytes, this indicates a dominant role for AcH3 in CCR5 transcription. We also show that pharmacological interference in the epigenetic repressive mechanisms that account for the lack of CCR5 transcription in T leukaemic cell lines results in an increase in CREB-1 association with CCR5 P1 chromatin. Furthermore, RNA polymerase II was also recruited into CCR5 P1 chromatin resulting in CCR5 re-expression. Together, these data indicate that epigenetic modifications of DNA, and of histones, contribute to the control of CCR5 transcription in immune effector cells.

Epigenetic control in immune function.

This chapter describes recent advances in our understanding how epigenetic events control immune functions with emphasis on transcriptional regulation of major histocompatibility complex ClassI (MIC-I) and Class II (MHC-II) genes. MHC-I and MHC-II molecules play an essential role in the adaptive immune response by virtue of their ability to present peptides, respectively to CD8+ and CD4+ T cells. Central to the onset of an adequate immune response to pathogens is the presentation of pathogen-derived peptides in the context of MHC-II molecules by antigen presenting cells (APCs) to CD4+ T cells of the immune system. In particular dendritic cells are highly specialized APCs that are capable to activate naïve T cells. Given their central role in adaptive immunity, MHC-I and MHC-II genes are regulated in a tight fashion at the transcriptional level to meet with local requirements of an effective antigen-specific immune response. In these regulatory processes the MHC2TA encoded Class II transactivator (CIITA) plays a crucial role. CIITA is essential for transcriptional activation of all MHC-I genes, whereas it plays an ancillary function in the transcriptional control of MHC-I genes. The focus of this chapter therefore will be on the transcription factors that interact with conserved cis-acting promoter elements and epigenetic mechanisms that modulate cell type-specific regulation of MHC-I, MHC-I, and MHC2TA genes. Furthermore, we will also briefly discuss how genetic and epigenetic mechanisms contribute to T helper cell differentiation.

A Novel Branched DNA-Based Flowcytometric Method for Single-Cell Characterization of Gene Therapy Products and Expression of Therapeutic Genes.

Many preclinical and clinical studies of hematopoietic stem cell-based gene therapy (GT) are based on the use of lentiviruses as the vector of choice. Assessment of the vector titer and transduction efficiency of the cell product is critical for these studies. Efficacy and safety of the modified cell product are commonly determined by assessing the vector copy number (VCN) using qPCR. However, this optimized and well-established method in the GT field is based on bulk population averages, which can lead to misinterpretation of the actual VCN per transduced cell. Therefore, we introduce here a single cell-based method that allows to unmask cellular heterogeneity in the GT product, even when antibodies are not available. We use Invitrogen's flow cytometry-based PrimeFlow™ RNA Assay with customized probes to determine transduction efficiency of transgenes of interest, promoter strength, and the cellular heterogeneity of murine and human stem cells. The assay has good specificity and sensitivity to detect the transgenes, as shown by the high correlations between PrimeFlow™-positive cells and the VCN. Differences in promoter strengths can readily be detected by differences in percentages and fluorescence intensity. Hence, we show a customizable method that allows to determine the number of transduced cells and the actual VCN per transduced cell in a GT product. The assay is suitable for all therapeutic genes for which antibodies are not available or too cumbersome for routine flow cytometry. The method also allows co-staining of surface markers to analyze differential transduction efficiencies in subpopulations of target cells.

Transcriptional silencing of RFXAP in MHC class II-deficiency.

MHC-II deficiency is recognized by defects in components of the RFX complex or CIITA. In this study, we have characterized at the molecular level the putative defect in MHC-II regulatory factors of a recently identified MHC-II deficiency patient (FGK). We found that this patient lacked detectable levels of mRNA and protein of the RFX complex subunit RFXAP. It was subsequently established that the RFXAP gene in FGK differed from wild type RFXAP by a homozygous 75bp insertion in the 5'-UTR, which impaired the activity of the FGK RFXAP promoter. The transcriptional silent state of RFXAP correlated with reduced recruitment of RNA polymerase II to FGK RFXAP chromatin. Together, this insertion in the promoter region represents a novel type of MHC-II gene silencing in MHC-II deficiency patients.

Constitutive and IFNgamma-induced activation of MHC2TA promoter type III in human melanoma cell lines is governed by separate regulatory elements within the PIII upstream regulatory region.

Cell lines established from tumor tissue of cutaneous melanoma biopsies often display constitutive and IFNgamma-inducible expression of MHC class II molecules. The expression of MHC class II molecules in melanoma is associated with an overall poor prognosis and unfavorable clinical outcome. We have analyzed the DNA elements and interacting transcription factors that control the constitutive and IFNgamma-inducible expression of the class II transactivator (CIITA), a co-activator essential for transcription of all MHC class II genes. Our studies reveal the activation of multiple CIITA promoter regions (CIITA-PII, -PIII and -PIV) in melanoma cell lines for both the constitutive and IFNgamma-inducible expression of MHC class II molecules. Furthermore, we show that constitutive and IFNgamma-inducible expression of the CIITA-PIII isoform is governed by separate regulatory elements within the PIII upstream regulatory region (PURR). Similarly constitutive activation in melanoma of CIITA-PII, CIITA-PIII, and CIITA-PIV does not require components of the IFNgamma signaling pathway. However, these components are readily recruited to the PURR and CIITA-PIV after exposure of cells to IFNgamma and account for the IFNgamma-induced expression of CIITA. Together, our data reveal the contribution of distinct elements and factors in the constitutive and IFNgamma-inducible expression of CIITA in melanoma cell lines of the skin.

Epigenetic silencing of MHC2TA transcription in cancer.

Lack of expression of major histocompatibility complex (MHC) molecules of both classes is frequently noted on tumour cells . It is thought that in this way tumour cells escape immunosurveillance. The genes encoding both classes of MHC molecules are localized on the distal part of chromosome 6 (6p21.3). The class II transactivator (CIITA), encoded by the MHC2TA gene, is essential for transcriptional activation of all MHC-II genes, while it has a helper function in the transcriptional regulation of MHC-I genes (with the exception of human leukocyte antigen (HLA)-G) and of the gene encoding beta2-microglobulin (beta2m) . Here we discuss our current knowledge on the expression characteristics of MHC2TA and argue for an important role of epigenetic factors and mechanisms in the transcriptional silencing of MHC2TA in cancer cells.

Overexpression of LMO2 causes aberrant human T-Cell development in vivo by three potentially distinct cellular mechanisms.

Overexpression of LMO2 is known to be one of the causes of T-cell acute lymphoblastic leukemia (T-ALL) development; however, the mechanisms behind its oncogenic activity are incompletely understood. LMO2-overexpressing transgenic mouse models suggest an accumulation of immature T-cell progenitors in the thymus as the main preleukemic event. The effects of LMO2 overexpression on human T-cell development in vivo are unknown. Here, we report studies of a humanized mouse model transplanted with LMO2-transduced human hematopoietic stem/progenitor cells. The effects of LMO2 overexpression were confined to the T-cell lineage; however, initially, multipotent cells were transduced. Three effects of LMO2 on human T-cell development were observed: (1) a block at the double-negative/immature single-positive stage, (2) an accumulation of CD4(+)CD8(+) double-positive CD3(-) cells, and (3) an altered CD8/CD4 ratio with enhanced peripheral T lymphocytes. Microarray analysis of sorted double-positive cells overexpressing LMO2 led to the identification of an LMO2 gene set that clustered with human T-ALL patient samples of the described "proliferative" cluster. In this article, we demonstrate previously unrecognized mechanisms by which LMO2 alters human T-cell development in vivo; these mechanisms correlate with human T-ALL leukemogenesis.

Global histone H3 lysine 27 triple methylation levels are reduced in vessels with advanced atherosclerotic plaques.

AIMS: Alterations in epigenetic processes are frequently noted in human disease. These epigenetic processes involve methylation of DNA and post-translational modifications of histones. It is well established that in particular histone methylation plays a key role in gene transcription. In this study, we have investigated the relationship between triple methylation of lysine 27 in histone H3 (H3K27Me3) modifications and atherosclerotic plaque stage. MATERIALS AND METHODS: 28 peri-renal aortic tissue patches covering the entire spectrum of atherosclerotic plaque development were evaluated by immunohistochemistry for the levels of H3K27Me3, EZH2, JMJD3 and BMI1. KEY FINDINGS: The results of our studies are in support of a reduction in global levels of the H3K27Me3 modification in vessels with advanced atherosclerotic plaques. This reduction in H3K27Me3 levels is not accompanied by alterations in global levels of the corresponding histone methyltransferase EZH2, the catalytic subunit of the polycomb repressive complex 2 (PRC2). Likewise no alterations in global levels of BMI1, a component of the PRC1 complex, which binds to H3K27Me3-modified histones or the global expression levels of the histone demethylase JMJD3, which removes the methyl marks on H3K27, were observed. SIGNIFICANCE: Together, our data show that in atherosclerosis development alterations in global levels of H3K27Me3 occur. The reduction in the number of nuclei in the tunica media that display the repressive H3K27Me3 mark in vessels with advanced atherosclerosis plaques therefore could be a reflection of the dynamic pattern of smooth muscle cell differentiation and proliferation associated with atherosclerotic disease.

A role for KMT1c in monocyte to dendritic cell differentiation: Epigenetic regulation of monocyte differentiation.

Monocytes play a key role in immune system function. Chromatin remodeling is crucial for various differentiation and gene regulation processes and is rather well studied in T cells. However, for monocytes not much is known regarding how the epigenetic machinery influences the differentiation into various effector cell types. In the work presented here, we explore the epigenetic underpinnings of monocyte differentiation. By transcriptional profiling we show that transcription of lysine methyltransferases (KMTs) and in particular KMT1c is markedly up regulated after differentiation of monocytes into immature dendritic cells (iDCs). Specifically inhibiting KMT1c function, using the small-molecule inhibitor BIX-01294, changes the transcription levels of the DC marker DC-SIGN, but does not affect surface protein expression. Blocking global KMT activity, using DZNep, does influence monocyte differentiation into iDCs, indicated by a loss of DC-SIGN surface expression. When BIX-01294 and DZNep treatment was combined DC-SIGN expression was almost lost completely. This work shows that the activities of KMTs are required for successful differentiation of monocyte-derived dendritic cells. Furthermore it shows the importance of KMT inhibitors in the field of epigenetic immune therapy, which is still much focused around HDAC inhibitors.

Skewed expression of the genes encoding epigenetic modifiers in high-risk uveal melanoma.

PURPOSE: Monosomy 3 (M3) or the presence of a specific RNA expression profile, known as class 2, is strongly associated with death from uveal melanoma (UM). Given the important role of epigenetic processes in cancer development and progression, we compared the transcriptional profiles of a selection of epigenetic regulators between primary UM with a good and a bad prognosis. METHODS: Transcriptional levels of 59 epigenetic regulator genes were measured by quantitative PCR (qPCR) in 20 UM, 12 with monosomy of chromosome 3 (M3) and 8 with disomy of chromosome 3 (D3). Validation was performed in an independent cohort. Expression levels were compared to clinicopathological characteristics, including class type. Bisulfite sequencing was used to evaluate the role of DNA methylation in gene silencing. RESULTS: In the first set of tumors, general downregulation of transcription of the genes encoding epigenetic regulatory enzymes was seen in association with M3. The 10 genes with the highest differential expression between M3 and D3 were selected and were analyzed in a second set of tumors. In the validation set, significantly lower levels of KAT2B (P = 0.008), HDAC11 (P = 0.009), KMT1C (P = 0.05), KDM4B (P = 0.003), KDM6B (P = 0.04), and BMI-1 (P = 0.001) transcripts were found in tumors with M3/class 2. Methylation of C-phosphate-G (CpG) residues was not observed on the putative regulatory regions of KAT2B, KDM4B, or KDM6B. CONCLUSIONS: Expression levels of a number of histone-modifying genes and polycomb family members are significantly lower in uveal melanoma with monosomy 3/class 2, supporting a general dysregulation of epigenetic modifiers in UM with a bad prognosis.

Simvastatin reduces CCL2 expression in monocyte-derived cells by induction of a repressive CCL2 chromatin state.

Statins exert anti-inflammatory characteristics, besides their lipid lowering properties, and may display beneficial effects for the treatment of inflammatory diseases. One possible explanation is that statins interfere in the deregulated gene transcription patterns associated with immune-mediated diseases, although the precise mechanism is not fully understood. Besides gene regulatory proteins, epigenetic mechanisms play an important role in the orchestration of gene expression. Disturbances in the tightly controlled epigenetic mechanisms influence the cellular portrait of expressed genes resulting in the protein dysfunctions found in many inflammatory diseases. In this study, we found that simvastatin reduces secretion and gene expression of CCL2 in monocyte-derived immature dendritic cells and in type 1 macrophages, which is accompanied by increased levels of the 3meK27H3 and 3meK9H3 repressive histone marks and decreased levels of the permissive histone marks AcH3 and 3meK4H3 in CCL2 promoter chromatin. The repressive chromatin status of the CCL2 promoter region affected recruitment of the NF-κB p65 subunit, which controls CCL2 transcription. The down-regulation of CCL2 in these immune cells may therefore impact their chemotactic activity and reduce their recruitment to sites of tissue injury.

The epigenetics of multiple sclerosis and other related disorders.

Multiple Sclerosis (MS) is a demyelinating disease characterized by chronic inflammation of the central nervous system (CNS) gray and white matter. Although the cause of MS is unknown, it is widely appreciated that innate and adaptive immune processes contribute to its pathogenesis. These include microglia/macrophage activation, pro-inflammatory T-cell (Th1) responses and humoral responses. Additionally, there is evidence indicating that MS has a neurodegenerative component since neuronal and axonal loss occurs even in the absence of overt inflammation. These aspects also form the rationale for clinical management of the disease. However, the currently available therapies to control the disease are only partially effective at best indicating that more effective therapeutic solutions are urgently needed. It is appreciated that in the immune-driven and neurodegenerative processes MS-specific deregulation of gene expressions and resulting protein dysfunction are thought to play a central role. These deviations in gene expression patterns contribute to the inflammatory response in the CNS, and to neuronal or axonal loss. Epigenetic mechanisms control transcription of most, if not all genes, in nucleated cells including cells of the CNS and in haematopoietic cells. MS-specific alterations in epigenetic regulation of gene expression may therefore lie at the heart of the deregulation of gene expression in MS. As such, epigenetic mechanisms most likely play an important role in disease pathogenesis. In this review we discuss a role for MS-specific deregulation of epigenetic features that control gene expression in the CNS and in the periphery. Furthermore, we discuss the application of small molecule inhibitors that target the epigenetic machinery to ameliorate disease in experimental animal models, indicating that such approaches may be applicable to MS patients.

Heterogeneous clinical presentation in ICF syndrome: correlation with underlying gene defects.

Immunodeficiency with centromeric instability and facial anomalies (ICF) syndrome is a primary immunodeficiency, predominantly characterized by agammaglobulinemia or hypoimmunoglobulinemia, centromere instability and facial anomalies. Mutations in two genes have been discovered to cause ICF syndrome: DNMT3B and ZBTB24. To characterize the clinical features of this syndrome, as well as genotype-phenotype correlations, we compared clinical and genetic data of 44 ICF patients. Of them, 23 had mutations in DNMT3B (ICF1), 13 patients had mutations in ZBTB24 (ICF2), whereas for 8 patients, the gene defect has not yet been identified (ICFX). While at first sight these patients share the same immunological, morphological and epigenetic hallmarks of the disease, systematic evaluation of all reported informative cases shows that: (1) the humoral immunodeficiency is generally more pronounced in ICF1 patients, (2) B- and T-cell compartments are both involved in ICF1 and ICF2, (3) ICF2 patients have a significantly higher incidence of intellectual disability and (4) congenital malformations can be observed in some ICF1 and ICF2 cases. It is expected that these observations on prevalence and clinical presentation will facilitate mutation-screening strategies and help in diagnostic counseling.

Epigenetic regulation of CIITA expression in human T-cells.

In humans, T-cells accomplish expression of MHC-II molecules through induction of CIITA upon activation. Here we show that CIITA promoter accessibility in T-cells is epigenetically regulated. In unstimulated T-cells, CIITA-PIII chromatin displays relative high levels of repressive histone methylation marks (3Me-K27-H3 and 3Me-K20-H4) and low levels of acetylated histones H3 (Ac-H3) and H4 (Ac-H4). These repressive histone marks are replaced by histone methylation marks associated with transcriptional active genes (3Me-K4-H3) and high levels of Ac-H3 and Ac-H4 in activated T-cells. This is associated with concomitant recruitment of RNA polymerase II. In T-leukemia cells, devoid of CIITA expression, similar repressive histone methylation marks and low levels of acetylated histone H3 correlated with lack of CIITA expression. This in contrast to CIITA expressing T-lymphoma cells, which display high levels of Ac-H3 and 3Me-K4-H3, and relative low levels of the 3Me-K27-H3 and 3Me-K20-H4 marks. Of interest was the observation that the levels of histone acetylation and methylation modifications in histones H3 and H4 were also noted in chromatin of the downstream CIITA-PIV promoter as well as the upstream CIITA-PI and CIITA-PII promoters both in normal T-cells and in malignant T-cells. Together our data show that CIITA chromatin in T-cells expressing CIITA display similar histone acetylation and methylation characteristics associated with an open chromatin structure. The opposite is true for T-cells lacking CIITA expression, which display histone modifications characteristic of condensed chromatin.

Genetic and epigenetic control of the major histocompatibility complex class Ib gene HLA-G in trophoblast cell lines.

The transcriptional regulation of the major histocompatibility complex class (MHC) Ib gene HLA-G differs from the classical MHC class I genes. The cis-acting regulatory elements typical for classical MHC class I promoters are divergent in the promoter of HLA-G, rendering this gene unresponsive to NF-kappaB, IRF-1, and class II transactivator (CIITA)-mediated activation pathways. However, as we have previously shown, transactivation of HLA-G is regulated by CREB-1. Because CREB-1 is ubiquitously expressed, this observation does not explain the tissue-restricted expression of HLA-G in extravillous cytotrophoblasts. Using HLA-G-expressing JEG-3 cells and HLA-G-deficient JAR trophoblast-derived choriocarcinoma cells as a model, we have investigated the contribution of DNA methylation and histone acetylation in the transcriptional activation of HLA-G. Despite similar levels of DNA methylation both in JEG3 and JAR cells, we found the levels of histone acetylation in HLA-G promoter chromatin to be significantly enhanced in JEG3 cells coinciding with HLA-G expression.