Project description:BACKGROUND: Glucocorticoid (GC) refractoriness is a common and unpredictable phenomenon in ulcerative colitis (UC). Although it has been demonstrated that NFkB is involved in its mechanism of action (MoA), there are no conclusive studies on the molecular functions involved. The current study describes in depth the MoA related to GC failure, by integrating transcriptomic data from UC patients, and updated molecular data on UC and GC. METHODS: miRNA and mRNA expression from rectal biopsies of active UC patients, obtained before and on the 3rd day of GC treatment, were evaluated by sequencing and microarrays, respectively. The differential results obtained were integrated into the mathematical models generated by Systems Biology. RESULTS: This computational approach identified 64 proteins, among which 18 stand out, either by being associated to the MoA or by providing a major capacity to classify the patients according to GC response. The biological functions of these proteins have been linked with inflammation, machinery GC-induced transcription and angiogenesis. All the selected proteins but one —Acidic leucine-rich Nuclear Phosphoprotein 32 family member E (ANP32E) — had previously been related to UC and/or GC-induced biological actions. ANP32E has been linked to the exchange of H2A to H2A.z histone, which promotes CG receptor complex-activated transcription. Western blot and immunofluorescence assays confirmed the predictive results obtained by Systems Biology. CONCLUSIONS: A comprehensive MoA of GC refractoriness has been described, highlighting the key role of GC-induced transcription in this phenomenon. Several proteins have been identified as putative predictors of GC refractoriness.

Project description:We report a genome wide enrichment, redistribution and accumulation of H2A.Z at specific chromatin control regions, in particular at enhancers and insulators, in mouse embryonic fibroblasts depleted for Anp32e (MEFs Anp32e-/-). H2A.Z ChIP-seq in MEFs WT (+/+) or KO (-/-) for Anp32e.

Project description:We report a genome wide enrichment, redistribution and accumulation of H2A.Z at specific chromatin control regions, in particular at enhancers and insulators, in mouse embryonic fibroblasts depleted for Anp32e (MEFs Anp32e-/-).

Project description:ANP32e, a chaperone of H2A.Z, is receiving increasing attention because of its link to cancer growth and progression. An unanswered question is whether ANP32e regulates H2A.Z dynamics during the cell cycle; if so, this could have clear implications for the proliferation of cancer cells. Using the human U2OS cancer cell line model system, we have confirmed that ANP32e regulates the growth of these cells. ANP32e preferentially interacts with H2A.Z during G1 phase of the cell cycle. Unexpectedly, however, ANP32e does not mediate the removal of H2A.Z from chromatin, is not a stable component of the p400 remodeling complex, and is not strongly associated with chromatin. Instead, most ANP32e is in the cytoplasm. Here, ANP32e preferentially interacts with H2A.Z in G1 phase in response to an increase in H2A.Z protein abundance and regulates its protein stability. This G1-specific interaction between ANP32e and H2A.Z is also observed in the nucleoplasm but is unrelated to any change in H2A.Z abundance. Collectively, these results challenge the idea that ANP32e is involved in regulating the abundance of H2A.Z in chromatin as part of a chromatin remodeling complex. Rather, we propose that ANP32e acts as a molecular chaperone that maintains the soluble pool of H2A.Z by regulating its protein stability and acting as a buffer in response to cell cycle-dependent changes in H2A.Z abundance.

Project description:Our group used rectal biopsies from patients with active ulcerative colitis (UC) and differential response to glucocorticoid treatment, to generate a predictive computational strategy based on systems biology. Contrasting mRNA and miRNAs intestinal expression profiles with updated molecular information related to UC and glucocorticoids, we were able to identify a mechanism of action (MoA) associated with corticosteroid failure in UC. ith the aim of transferring these results to clinical practice, the MoA-models created previously were implemented with plasmatic miRNAs profiles, to describe in silico non-invasive potential biomarkers of glucocorticoid refractoriness. Small RNA-seq analysis was perfomed using Illumina next generation sequencing and standard statistical criteria were applied to compare the miRNA profiles, incluidng paired samples before clucocorticoid treatment to the third day of the steroidal treatment. The selection these miRNA with predictive capacity was done using two complementary strategies: the first one using all the obtained miRNAs, and the second taking into account those miRNAs that are directly related to MoA, through various statistical restrictions (RELIEF, ENTROPY + CORRELATION, WILCOXON, ROC, and simple REGRESSION). These computational approaches from all miRNAs identified hsa-miR218-5p as the best to classify patients according their respond at basal time (Accuracy = 84.21%, Generalization Capability = 84.21%, Sensitivity = 100% and Specificity = 66.67%). In addition, the combination of this miRNA with hsa-miR6754-5p and hsa-miR4767, increases the diagnosis accuracy of the disease (Accuracy = 94.74%, Generalization Capability = 75.44%, Sensitivity = 70% and specificity = 81.48%). On the other hand, the combination of hsa-miR218-5p and the plasma levels of the Protein C Reactive increases the ability to classify patients towards their response to glucocorticoids up to 89%. Taking in account all this data, we can conclude that by means of a computer strategy based on Biology of Systems we have identified the plasmatic miR-218-5p as a potential biomarker to glucocorticoid response in UC before start the treatment.

Project description:Genome-wide chromatin state underlies gene expression potential and cellular function. Epigenetic features and nucleosome positioning contribute to the accessibility of DNA, but widespread regulators of chromatin state are largely unknown. Our study investigates how coordination of ANP32E and H2A.Z contributes to genome-wide chromatin state in mouse fibroblasts. We define H2A.Z as a universal chromatin accessibility factor, and demonstrate that ANP32E antagonizes H2A.Z accumulation to restrict chromatin accessibility genome-wide. In the absence of ANP32E, H2A.Z accumulates at promoters in a hierarchical manner. H2A.Z initially localizes downstream of the transcription start site, and if H2A.Z is already present downstream, additional H2A.Z accumulates upstream. This hierarchical H2A.Z accumulation coincides with improved nucleosome positioning, heightened transcription factor binding, and increased expression of neighboring genes. Thus, ANP32E dramatically influences genome-wide chromatin accessibility through subtle refinement of H2A.Z patterns, providing a means to reprogram chromatin state and to hone gene expression levels.

Project description:Genome-wide chromatin state underlies gene expression potential and cellular function. Epigenetic features and nucleosome positioning contribute to the accessibility of DNA, but widespread regulators of chromatin state are largely unknown. Our study investigates how coordination of ANP32E and H2A.Z contributes to genome-wide chromatin state in mouse fibroblasts. We define H2A.Z as a universal chromatin accessibility factor, and demonstrate that ANP32E antagonizes H2A.Z accumulation to restrict chromatin accessibility genome-wide. In the absence of ANP32E, H2A.Z accumulates at promoters in a hierarchical manner. H2A.Z initially localizes downstream of the transcription start site, and if H2A.Z is already present downstream, additional H2A.Z accumulates upstream. This hierarchical H2A.Z accumulation coincides with improved nucleosome positioning, heightened transcription factor binding, and increased expression of neighboring genes. Thus, ANP32E dramatically influences genome-wide chromatin accessibility through subtle refinement of H2A.Z patterns, providing a means to reprogram chromatin state and to hone gene expression levels.

Project description:A systems biology approach identifies ANP32E and other biomarkers of glucocorticoid refractoriness in ulcerative colitis

Project description:The mechanisms that regulate H2A.Z and its requirement for transcription in differentiated mammalian cells remains ambiguous. In this study, we identified the interaction between the C-terminus of ANP32e and N-terminus of H2A.Z in a yeast two-hybrid screen. Knockdown of ANP32e resulted in proteasomal degradation and nuclear depletion of H2A.Z or of a chimeric green florescence protein fused to its N-terminus. This effect was reversed by inhibition of protein phosphatase 2A (PP2A) and, conversely, reproduced by overexpression of its catalytic subunit. Accordingly, knockdown of ANP32e inhibited phosphorylation of H2A.Z, whereas a mutation of serine-9 proved its requirement for both the protein’s stability and nuclear localization, as did knockdown of the nuclear mitogen and stress-induced kinase 1. Moreover, ANP32e’s knockdown also revealed its differential requirement for cell signaling and gene expression, whereas, genome-wide binding analysis confirmed its co-localization with H2A.Z at transcription start sites, as well as, gene bodies of inducible genes. The data also suggest that H2A.Z restricts transcription, which is moderated by ANP32e after induction of transcriptional activity of inducible and housekeeping genes vs. constitutively-expressed tissue-specific genes during cellular growth. Thus, ANP32e, through inhibition of PP2A, is required for nucleosomal inclusion of H2A.Z and the regulation of gene expression.

Project description:Epigenetic regulation of chromatin states is crucial for proper gene expression programs and progression during development, but precise mechanisms by which epigenetic factors influence differentiation remain poorly understood. Here we find that the histone variant H2A.Z accumulates at Sox motif-containing promoters during zebrafish gastrulation while neighboring genes become transcriptionally active. These changes coincide with reduced expression of anp32e, the H2A.Z histone removal chaperone, suggesting that loss of Anp32e may lead to increases in H2A.Z binding during differentiation. Remarkably, genetic removal of Anp32e in embryos leads to H2A.Z accumulation prior to gastrulation and developmental genes become precociously active. Accordingly, H2A.Z accumulation occurs most extensively at Sox motif-associated genes, including many which are normally activated following gastrulation. Altogether, our results provide compelling evidence for a mechanism in which Anp32e preferentially restricts H2A.Z accumulation at Sox motifs to regulate the initial phases of developmental differentiation in zebrafish.