Histone code of genes induced by co-treatment with a glucocorticoid hormone agonist and a p44/42 MAPK inhibitor in human small intestinal Caco-2 cells

Background

Inactivation of glucocorticoid hormones and p44/42 mitogen-activated protein kinase (MAPK) is thought to be important in small intestinal maturation and expression of genes related to intestinal differentiation and functions.

Methods

We investigated target genes induced by co-treatment for 48 h with a glucocorticoid hormone agonist, dexamethasone (Dex), and a p44/42 MAPK inhibitor, PD98059 (PD), in a small intestine-like cell line (Caco-2) using microarray analysis. We also investigated whether expression changes of the target genes induced by the co-treatment are associated with histone modifications around these genes.

Results

Co-treatment of Caco-2 cells with Dex and PD enhanced several genes related to intestinal differentiation and functions such as SCNN1A, FXYD3, LCT and LOX. Induction of the SCNN1A gene was associated with increased presence of acetylated histone H3 and H4 and di-methylated histone H3 at lysine (K) 4 around the transcribed region of the gene, and induction of the FXYD3 gene was associated with increased presence of acetylated histones H3 and H4 from the promoter/enhancer to the transcribed region of the gene. Induction of LCT and LOX genes was associated with increased presence of acetylated histone H4 on the promoter/enhancer region of the genes.

Conclusions

Histone acetylation and/or histone H3 K4 methylation around the promoter/enhancer or/and transcribed regions of target genes are associated with induction of the genes by co-treatment with Dex and PD in Caco-2 cells.

General significance

The histone code is specific to each gene with respect to induction by glucocorticoid hormone and inhibition of p44/42 MAPK in Caco-2 cells.     

Hunting for the 5th base: Techniques for analyzing DNA methylation

Background

In the recent past large progress has been made in the analysis of the epigenome, the entirety of epigenetic modifications, and its meaning for the implementation of the genetic code. Besides histone modifications and miRNA expression, DNA methylation is one of the key players in the field of epigenetics, involved in numerous regulatory processes.

Methods

In the present review we focus on methods for the analysis of DNA methylation patterns and present an overview about techniques and basic principles available for this purpose.

Results and general significance

We here discuss advantages and disadvantages of various methods and their feasibility for specific tasks of DNA methylation analysis.     

An atypical epigenetic mechanism affects uniparental expression of Pol IV-dependent siRNAs

Background

Small RNAs generated by RNA polymerase IV (Pol IV) are the most abundant class of small RNAs in flowering plants. In Arabidopsis thaliana Pol IV-dependent short interfering (p4-si)RNAs are imprinted and accumulate specifically from maternal chromosomes in the developing seeds. Imprinted expression of protein-coding genes is controlled by differential DNA or histone methylation placed in gametes. To identify epigenetic factors required for maternal-specific expression of p4-siRNAs we analyzed the effect of a series of candidate mutations, including those required for genomic imprinting of protein-coding genes, on uniparental expression of a representative p4-siRNA locus.

Results

Paternal alleles of imprinted genes are marked by DNA or histone methylation placed by DNA METHYLTRANSFERASE 1 or the Polycomb Repressive Complex 2. Here we demonstrate that repression of paternal p4-siRNA expression at locus 08002 is not controlled by either of these mechanisms. Similarly, loss of several chromatin modification enzymes, including a histone acetyltransferase, a histone methyltransferase, and two nucleosome remodeling proteins, does not affect maternal expression of locus 08002. Maternal alleles of imprinted genes are hypomethylated by DEMETER DNA glycosylase, yet expression of p4-siRNAs occurs irrespective of demethylation by DEMETER or related glycosylases.

Conclusions

Differential DNA methylation and other chromatin modifications associated with epigenetic silencing are not required for maternal-specific expression of p4-siRNAs at locus 08002. These data indicate that there is an as yet unknown epigenetic mechanism causing maternal-specific p4-siRNA expression that is distinct from the well-characterized mechanisms associated with DNA methylation or the Polycomb Repressive Complex 2.     

Histone H3 lysine 27 acetylation is altered in colon cancer

Background

Histone post-translational modifications (PTMs) play an important role in the regulation of the expression of genes, including those involved in cancer development and progression. However, our knowledge of PTM patterns in human tumours is limited.

Methods

MS-based analyses were used to quantify global alterations of histone PTMs in colorectal cancer (CRC) samples. Histones isolated from 12 CRCs and their corresponding normal mucosa by acidic extraction were separated by SDS-PAGE and analysed by liquid chromatography-mass spectrometry.

Results

Among 96 modified peptides, 41 distinct PTM sites were identified, of which 7, 13, 11, and 10 were located within the H2A, H2B, H3, and H4 sequences, respectively, and distributed among the amino-terminal tails and the globular domain of the four histones. Modification intensities were quantified for 33 sites, of which 4 showed significant (p-value ≤ 0.05) differences between CRC tissues and healthy mucosa samples. We identified histone H3 lysine 27 acetylation (H3K27Ac) as a modification upregulated in CRC, which had not been shown previously.

Conclusions

The present results indicate the usefulness of a bottom-up proteomic approach for the detection of histone modifications at a global scale. The differential abundance of H3K27Ac mark in CRC, a PTM associated with active enhancers, suggests its role in regulating genes whose expression changes in CRC.     

Knotting the NETs: Analyzing histone modifications in neutrophil extracellular traps

Neutrophil extracellular chromatin traps (NETs) are a recently described mechanism of innate immune responses to bacteria and fungi. Evidence indicates that NETs are induced by inflammation, that they contribute to diverse disease pathologies, and that they associate with bactericidal substances. Genomic DNA is released in NETs, leading to a cell death that has been labeled NETosis. Although NETosis clearly differs from apoptosis, the classical form of cell death, recent experiments indicate a connection between NETosis and autophagy. The regulated deployment of NETs may require covalent modification of histones, the basic DNA-binding proteins that organize chromatin in the cell''s nucleus and within NETs. Histone modification by peptidylarginine deiminase 4 (PAD4) is necessary for NET release. The functions of additional histone modifications, however, remain to be tested.Less than a decade since their discovery, neutrophil extracellular traps (NETs) remain in the headlines. Initially, interest focused on the structure of extracellular NET chromatin and its capacity to capture and damage bacteria. Soon, however, researchers began to see the implications of extracellular chromatin for the development of autoimmune diseases. One quintessential autoimmune disease, systemic lupus erythematosus (SLE), is known to arise together with autoantibodies to DNA and chromatin, although the immediate trigger for the production of these autoantibodies is unclear. A connection between NETs and autoimmunity was made by discovering that histones, a set of proteins that act as a structural harness for DNA in chromatin, are modified by peptidylarginine deiminase 4 (PAD4), an enzyme that converts arginines to citrullines. Researchers had long suspected that autoantigen modifications could provide the initial stimuli in autoimmunity because subtle alterations in a protein''s primary sequence can break tolerance. PAD4 is implicated in the development of rheumatoid arthritis (RA) because the most reliable clinical test for RA uses the detection of anti-citrulline antibodies in the sera of patients.In a sophisticated set of experiments reported in the previous issue of Arthritis Research & Therapy, Liu and colleagues [1] accomplished an extensive inventory of post-translational modifications in NET histones. The researchers induced NETs from human neutrophils, as well as two cell lines that assume neutrophil-like characteristics, and used a panel of 40 commercially available antisera to identify histone modifications that arise in parallel with NETs. Stimuli that were used to elicit NET release also induced histone H3 and H4 citrullination in human neutrophils and the EPRO cell line. However, other modifications such as histone H4 lysine 20 methylation and H4 lysine 16 acetylation showed inconsistent results in neutrophils versus the EPRO cells. To survey histone modifications, Liu and colleagues [1] confronted technical difficulties in that histone amino terminal tails contain the highest concentration of histone modifications yet are also highly susceptible to proteases secreted by activated neutrophils [2,3]. The histone tails act as flexible tethers that organize chromatin into higher-order structures. Interestingly, purified NETs failed to induce an immune response in mice, although a subset of SLE sera reacted strongly with citrullinated histone H3 [1]. Therefore, mechanisms that regulate histone modification deserve further attention.Neeli and colleagues [4] were the first to identify citrullinated histone H3 in NETs, a discovery that was confirmed by others [5]. Neeli and colleagues [4] provided a second important insight, namely that PAD4-citrullinated histone H3 is a reliable marker of inflammation. Thus, it became clear that the release of NETs is not an ''accident'' caused by a barrage of proteases and reactive oxygen species unleashed from neutrophils. Instead, production of NETs requires enzymatic activity and input from neutrophil surface receptors and the cytoskeleton [6]. By analyzing PAD4-deficient mice, Li and colleagues [7] demonstrated that PAD4 is essential for the production of NETs in response to bacterial infections. The regulation of PAD4 activity thus moved to the forefront of the research on NETs.It is now clear that NET release takes advantage of NADPH (nicotinamide adenine dinucleotide phosphate) oxidase and the main granule proteases to trigger and construct the extended chromatin network [3,8]. In addition, myeloperoxidase is found in NETs after their release from the cells, and this enzyme and its products are the main components in NETs that kill bacteria [9]. In a notable study from the labs of Banchereau and Pascual [10], it was reported that SLE neutrophils are poised to undergo NETosis upon stimulation with anti-ribonucleo-protein autoantibodies and that NETs released by these neutrophils contain LL37 and HMGB-1, well-known stimulators of immune responses. In subsequent analyses using sera from patients with connective tissue disease, anti-citrullinated histone antibodies were observed in Felty''s syndrome, a rare disorder that shares serologic features with RA and SLE, whereas such autoantibodies were infrequent in SLE and RA [11]. These findings indicate that the process of NETosis is highly relevant to the development of human autoimmune responses, although a direct cause and effect may not connect the release of NETs to the production of autoantibodies.The detailed characterization of NET histone modifications, as accomplished by Liu and colleagues [1], invites speculations about the possible functions of these modifications. Several questions deserve further study: Will NET histone modifications, such as methylation, acetylation, and citrullination, be found to participate in gene regulation that sets the stage for NET release? Will the primary function of histone modifications turn out to be the decondensation of nuclear chromatin that is required for NETs expand to their optimal size and internal structure? Alternatively, NET histone modifications may serve non-traditional purposes. For example, certain modifications may anchor other NET components such as elastase, LL37, or myeloperoxidase to the chromatin meshwork. Unique modifications in NETs may attract phagocytes and stimulate them to ingest the trapped microorganisms. Other histone modifications may activate or dampen the inflammatory response by acting on innate pattern recognition receptors. The answers to these questions will, no doubt, keep research on NETs in leading immunology and microbiology journals for years to come.     

Sepsis Induces Specific Changes in Histone Modification Patterns in Human Monocytes

Background

Sepsis is a global burden and the primary cause of death in intensive care units worldwide. The pathophysiological changes induced by the host’s systemic inflammatory response to infection are not yet fully understood. During sepsis, the immune system is confronted with a variety of factors, which are integrated within the individual cells and result in changes of their basal state of responsiveness. Epigenetic mechanisms like histone modifications are known to participate in the control of immune reactions, but so far the situation during sepsis is unknown.

Methods and Findings

In a pilot approach, we performed combined chromatin immunoprecipitation followed by high-throughput sequencing to assess the genome-wide distribution of the chromatin modifications histone 3 lysine 4 and 27 trimethylation and lysine 9 acetylation in monocytes isolated from healthy donors (n = 4) and patients with sepsis (n = 2). Despite different underlying causes for sepsis, a comparison over promoter regions shows a high correlation between the patients for all chromatin marks. These findings hold true also when comparing patients to healthy controls. Despite the global similarity, differential analysis reveals a set of distinct promoters with significant enrichment or depletion of histone marks. Further analysis of overrepresented GO terms show an enrichment of genes involved in immune function. To the most prominent ones belong different members of the HLA family located within the MHC cluster together with the gene coding for the major regulator of this locus—CIITA.

Conclusions

We are able to show for the first time that sepsis in humans induces selective and precise changes of chromatin modifications in distinct promoter regions of immunologically relevant genes, shedding light on basal regulatory mechanisms that might be contributing to the functional changes occurring in monocytes.