B cells provide humoral immunity by differentiating into antibody secreting plasma cells. Differentiation is dependent upon division and transcriptional changes, with commitment to B cell lineages associated with epigenetic changes. Analysis of early transcriptional and epigenetic events in B cell differentiation revealed that plasmablasts and plasma cells undergo dynamic changes in gene expression and a progressive DNA hypomethylation targeted to at least 10% of genes/loci. Of the differentially methylated loci, more than 99.7% were demethylated during differentiation and these clustered in cis-regulatory features such as enhancers and transcription factor binding sites. Changes in gene expression and DNA methylation coincided with each other at specific divisions during differentiation and inhibition of DNA methylation resulted in augmented plasma cell commitment in a division-dependent manner. These data identify a major epigenetic reprogramming event during early B cell differentiation coupled division and provide an approach to modulating humoral immune responses. Overall design: Splenic B cells (B220+ CD43-) from naïve C57/BL6J mice were labeled with CFSE or CTV and transferred into uMT mice and allowed to rest overnight prior to challenge with LPS. Three days post challenge adoptively transferred B cells representing distinct divisions were sorted out for molecular analysis. These divisions are labelled Div0, Div1, Div3, Div5, Div8- and Div8+. Division 8- refers to cells that divided at least 8 times but were CD138-, whereas Division 8+ refers to cells that divided at least 8 times but were CD138+. Cells were subjected to RNA-seq and Reduced Representation Bisulfite Sequencing.
Plasma cell differentiation is coupled to division-dependent DNA hypomethylation and gene regulation.
Sex, Age, Specimen part, Cell line, Subject
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Plasma cell differentiation is coupled to division-dependent DNA hypomethylation and gene regulation.
Sex, Age, Specimen part
View SamplesB cells provide humoral immunity by differentiating into antibody secreting plasma cells. Differentiation is dependent upon division and transcriptional changes, with commitment to B cell lineages associated with epigenetic changes. Analysis of early transcriptional and epigenetic events in B cell differentiation revealed that plasmablasts and plasma cells undergo dynamic changes in gene expression and a progressive DNA hypomethylation targeted to at least 10% of genes/loci. Of the differentially methylated loci, more than 99.7% were demethylated during differentiation and these clustered in cis-regulatory features such as enhancers and transcription factor binding sites. Changes in gene expression and DNA methylation coincided with each other at specific divisions during differentiation and inhibition of DNA methylation resulted in augmented plasma cell commitment in a division-dependent manner. These data identify a major epigenetic reprogramming event during early B cell differentiation coupled division and provide an approach to modulating humoral immune responses.
Plasma cell differentiation is coupled to division-dependent DNA hypomethylation and gene regulation.
Sex, Age, Specimen part
View SamplesTo understand the role of Ezh2 in B cell differentiation B cells were stimulated ex vivo with LPS, Il2, and Il5 in the presence of DMSO or the selective Ezh2 inhibitor GSK343. Following 3 days culture, activated B cells and Plasmablasts were FACS isolated and RNA-seq was performed to identify the molecular effects of Ezh2 inhibition on B cell subsets during differentiation. Overall design: RNAseq on ex vivo differentiated B cell subsets treated with GSK343 or DMSO
Plasma cell differentiation is controlled by multiple cell division-coupled epigenetic programs.
Sex, Specimen part, Cell line, Treatment, Subject
View SamplesTo understand the role of LSD1 in B cell differentiation, mice with B cell conditional deletion of LSD1 were intravenously inoculated with LPS. After 3 days, B220+GL7-CD138- naïve B cells and CD138+ plasmablasts were FACS-sorted from the spleens and RNA-seq was performed to identify LSD1-target regulated genes. Overall design: RNA-seq on control or LSD1-deficient murine naïve B cells or plasmablasts.
The Histone Demethylase LSD1 Regulates B Cell Proliferation and Plasmablast Differentiation.
Sex, Specimen part, Cell line, Subject
View SamplesB cells provide humoral immunity by differentiating into antibody-secreting plasma cells, a process that requires cell division and is linked to DNA hypomethylation and gene regulation. Conversely, accumulation of DNA methylation in B cell differentiation is less apparent. To determine the role of de novo DNA methylation in B cell differentiation, the de novo DNA methyltransferases, Dnmt3a and Dnmt3b, were deleted in B cells resulting in phenotypically normal B cell development in the bone marrow, spleen and lymph nodes. However, upon immunologic challenge, mice deficient for Dnmt3a and Dnmt3b (Dnmt3-deficient) accumulated more antigen-specific B cells and bone marrow chimeras showed this was cell-autonomous. Additionally, a five-fold increase in splenic and bone marrow plasma cells was observed. Molecular analysis revealed that Dnmt3-deficient bone marrow plasma cells failed to repress gene expression to the same level as their Dnmt3ab-sufficient counterparts. This was coupled with a failure of Dnmt3-deficient germinal center B cells and plasma cells to gain and/or maintain DNA methylation at several thousand loci that were clustered in enhancers of genes that function in B cell activation and homing. Analysis of chromatin accessibility showed Dnmt3-deficient plasma cells had increased accessibility at several genes involved in hematopoiesis and B cell differentiation. These data show that de novo DNA methylation limits B cell activation, proliferation and differentiation, and support a model whereby DNA methylation represses the aberrant transcription of genes silenced in B cell differentiation to maintain plasma cell homeostasis. Overall design: Naïve lymph node B cells (B220+ GL7- Fas-), Phycoerythrin-specific germinal center B cells (B220+ GL7+ Fas+ PE+), and bone marrow plasma cells (CD138+) were compared between Cd19cre/wtDnmt3afl/flDnmt3bfl/fl (Dnmt3-deficient) and littermate control Cd19wt/wtDnmt3afl/flDnmt3bfl/fl (Dnmt3-sufficient) mice using RRBS, RNA-seq, and ATAC-seq. Naïve lymph node B cells were taken from naïve mice, whereas PE-specific germinal center B cells and bone marrow plasma cells were isolated from mice that had been immunized with phycoerythrin 30 days prior. This Series includes the RNA-seq component of the study.
B cell activation and plasma cell differentiation are inhibited by de novo DNA methylation.
Sex, Specimen part, Subject
View SamplesTo understand the role of EZH2 in Plasmablast function EZH2 was inducibly deleted using tamoxifen and B cells stimulated to differentiate with LPS in vivo. After 3 days, CD138+ cells were enriched from the spleens and RNA-seq was performed to identify the genes targeted by EZH2 for repression. Overall design: RNAseq on control or EZH2-deficient murine plasmablasts.
EZH2 Represses the B Cell Transcriptional Program and Regulates Antibody-Secreting Cell Metabolism and Antibody Production.
Sex, Specimen part, Cell line, Treatment, Subject
View SamplesThis SuperSeries is composed of the SubSeries listed below.
A heterozygous IDH1R132H/WT mutation induces genome-wide alterations in DNA methylation.
Cell line
View SamplesThe cytosolic NADP+-dependent isocitrate dehydrogenase IDH1 is frequently mutated in human cancers. Recent studies have shown that IDH1 mutant primary glioblastomas (GBM) and acute myeloid leukemias (AML) display robust association with CpG island methylator phenotype (CIMP). Such observations bring into question whether IDH1 mutations directly contribute to the development of CIMP or if the hypermethylation phenotype precedes acquisition of IDH1 mutations. To reveal the effects of IDH1 mutations on DNA methylation and gene expression, we introduced the most frequently observed IDH1 mutation, R132H, into a human cancer cell line through gene targeting. We profiled changes in methylation at over 27,000 CpG dinucleotides spanning 14,475 unique gene regions and characterized genome-wide gene expression alterations resulting from IDH1R132H knockin. We observed consistent changes in both DNA methylation and gene expression when comparing two independent IDH1R132H knockin clones to their wild-type parent, and report hypermethylation of over 2,000 loci, the majority of which contained preexisting methylation in IDH1WT parental cells. These loci exhibit the same trend in primary TCGA glioblastoma tumors with mutant IDH1 as compared to those with wild-type IDH1 and have significant overlap with genes hypermethylated in glioma-CIMP+ tumors. Furthermore, we identify specific DNA methylation and gene expression alterations which correlate with IDH1 mutations in our cell-line model as well as primary glioblastomas, including hypermethylation and transcriptional silencing of RBP1. The presented data provide insight on epigenetic alterations induced by IDH1 mutations and support a contributory role for IDH1 mutants in regulation of DNA methylation and gene expression in human cancer cells.
A heterozygous IDH1R132H/WT mutation induces genome-wide alterations in DNA methylation.
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View SamplesSLE is characterized by the production of autoantibodies that arise from the B cell lineage. Therefore, we sought to assess the epigenetic and transcriptome profiles of distinct B cell subsets known to be expanded in SLE from healthy and SLE subjects. These data define the differentiation heirarchy of B cell subsets and the epigenetic and transcriptional consequences of SLE on human B cells. Overall design: Five distinct B cell subsets were FACS isolated from a cohort of SLE and HC subjects. For a subset of subjects, circulating Antibody Secreting Cells (ASC) were also isolated for comparisons. Cells were FACS sorted into lysis buffer and RNA purified and transcriptome profiles determined by RNA-seq.
Epigenetic programming underpins B cell dysfunction in human SLE.
Specimen part, Disease stage, Subject
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