Differentiation Stage-specific Manner Research Articles

GATA6 is predicted to regulate DNA methylation in an in vitro model of human hepatocyte differentiation

Hepatocytes are the dominant cell type in the human liver, with functions in metabolism, detoxification, and producing secreted proteins. Although gene regulation and master transcription factors involved in the hepatocyte differentiation have been extensively investigated, little is known about how the epigenome is regulated, particularly the dynamics of DNA methylation and the critical upstream factors. Here, by examining changes in the transcriptome and the methylome using an in vitro hepatocyte differentiation model, we show putative DNA methylation-regulating transcription factors, which are likely involved in DNA demethylation and maintenance of hypo-methylation in a differentiation stage-specific manner. Of these factors, we further reveal that GATA6 induces DNA demethylation together with chromatin activation in a binding-site-specific manner during endoderm differentiation. These results provide an insight into the spatiotemporal regulatory mechanisms exerted on the DNA methylation landscape by transcription factors and uncover an epigenetic role for transcription factors in early liver development.

Alternative Splicing Mediated by RNA-Binding Protein RBM24 Facilitates Cardiac Myofibrillogenesis in a Differentiation Stage-Specific Manner.

Mutations in genes encoding sarcomeric proteins lead to failures in sarcomere assembly, the building blocks of contracting muscles, resulting in cardiomyopathies that are a leading cause of morbidity and mortality worldwide. Splicing variants of sarcomeric proteins are crucial at different stages of myofibrillogenesis, accounting for sarcomeric structural integrity. RBM24 (RNA-binding motif protein 24) is known as a tissue-specific splicing regulator that plays an essential role in cardiogenesis. However, it had been unclear if the developmental stage-specific alternative splicing facilitated by RBM24 contributes to sarcomere assembly and cardiogenesis. Our aim is to study the molecular mechanism by which RBM24 regulates cardiogenesis and sarcomere assembly in a temporal-dependent manner. We ablated RBM24 from human embryonic stem cells (hESCs) using CRISPR/Cas9 techniques. Although RBM24-/- hESCs still differentiated into sarcomere-hosting cardiomyocytes, they exhibited disrupted sarcomeric structures with punctate Z-lines due to impaired myosin replacement during early myofibrillogenesis. Transcriptomics revealed >4000 genes regulated by RBM24. Among them, core myofibrillogenesis proteins (eg, ACTN2 [α-actinin 2], TTN [titin], and MYH10 [non-muscle myosin IIB]) were misspliced. Consequently, MYH6 (muscle myosin II) cannot replace nonmuscle myosin MYH10, leading to myofibrillogenesis arrest at the early premyofibril stage and causing disrupted sarcomeres. Intriguingly, we found that the ABD (actin-binding domain; encoded by exon 6) of the Z-line anchor protein ACTN2 is predominantly excluded from early cardiac differentiation, whereas it is consistently included in human adult heart. CRISPR/Cas9-mediated deletion of exon 6 from ACTN2 in hESCs, as well as forced expression of full-length ACTN2 in RBM24-/- hESCs, further corroborated that inclusion of exon 6 is critical for sarcomere assembly. Overall, we have demonstrated that RBM24-facilitated inclusion of exon 6 in ACTN2 at distinct stages of cardiac differentiation is evolutionarily conserved and crucial to sarcomere assembly and integrity. RBM24 acts as a master regulator to modulate the temporal dynamics of core myofibrillogenesis genes and thereby orchestrates sarcomere organization.

GPS2 promotes erythroid differentiation by control of the stability of EKLF protein

AbstractErythropoiesis is a complex multistage process that involves differentiation of early erythroid progenitors to enucleated mature red blood cells, in which lineage-specific transcription factors play essential roles. Erythroid Krüppel-like factor (EKLF/KLF1) is a pleiotropic erythroid transcription factor that is required for the proper maturation of the erythroid cells, whose expression and activation are tightly controlled in a temporal and differentiation stage-specific manner. Here, we uncover a novel role of G-protein pathway suppressor 2 (GPS2), a subunit of the nuclear receptor corepressor/silencing mediator of retinoic acid and thyroid hormone receptor corepressor complex, in erythrocyte differentiation. Our study demonstrates that knockdown of GPS2 significantly suppresses erythroid differentiation of human CD34+ cells cultured in vitro and xenotransplanted in nonobese diabetic/severe combined immunodeficiency/interleukin-2 receptor γ-chain null mice. Moreover, global deletion of GPS2 in mice causes impaired erythropoiesis in the fetal liver and leads to severe anemia. Flow cytometric analysis and Wright-Giemsa staining show a defective differentiation at late stages of erythropoiesis in Gps2−/− embryos. Mechanistically, GPS2 interacts with EKLF and prevents proteasome-mediated degradation of EKLF, thereby increasing EKLF stability and transcriptional activity. Moreover, we identify the amino acids 191-230 region in EKLF protein, responsible for GPS2 binding, that is highly conserved in mammals and essential for EKLF protein stability. Collectively, our study uncovers a previously unknown role of GPS2 as a posttranslational regulator that enhances the stability of EKLF protein and thereby promotes erythroid differentiation.

BMP4 and perivascular cells promote hematopoietic differentiation of human pluripotent stem cells in a differentiation stage-specific manner

The efficient and reproducible derivation and maturation of multipotent hematopoietic progenitors from human pluripotent stem cells (hPSCs) requires the recapitulation of appropriate developmental stages and the microenvironment. Here, using serum-, xeno-, and feeder-free stepwise hematopoietic induction protocols, we showed that short-term and high-concentration treatment of hPSCs with bone morphogenetic protein 4 (BMP4) strongly promoted early mesoderm induction followed by increased hematopoietic commitment. This method reduced variations in hematopoietic differentiation among hPSC lines maintained under chemically defined Essential 8 medium compared to those maintained under less-defined mTeSR medium. We also found that perivascular niche cells (PVCs) significantly augmented the production of hematopoietic cells via paracrine signaling mechanisms only when they were present during the hematopoietic commitment phase. A protein array revealed 86 differentially expressed (>1.5-fold) secretion factors in PVC-conditioned medium compared with serum-free control medium, of which the transforming growth factor-β inducible gene H3 significantly increased the number of hematopoietic colony-forming colonies. Our data suggest that BMP4 and PVCs promote the hematopoietic differentiation of hPSCs in a differentiation stage-specific manner. This will increase our understanding of hematopoietic development and expedite the development of hPSC-derived blood products for therapeutic use.

SF3B1 Gene Expression in Erythroid Cells Is Regulated By Intron Retention Via a Posttranscriptional Mechanism Involving Cryptic Exons Proposed to Function As Splicing Decoys

Proper expression of the MDS-disease gene, SF3B1, ensures appropriate pre-mRNA splicing in erythroid progenitors and during terminal erythropoiesis. We previously showed that the SF3B1 gene is post-transcriptionally regulated in a differentiation stage-specific manner by intron retention (IR), such that ~50% of its transcripts in mature erythroblasts retain intron 4. Based on new mechanistic studies, we propose a model in which mostly unannotated and noncoding exons within intron 4 function as splicing decoys; i.e., they promote retention of intron 4 by interacting with, and blocking splice sites of, the adjacent exons 4 and 5. A total of six putative decoy exons were revealed via RT-PCR and RNA-seq analysis of RNA from erythroblasts treated with inhibitors of nonsense-mediated decay. That decoy exons have IR-promoting activity is suggested by several criteria. First, the frequency of interaction between constitutive exons 4 and 5 and putative decoy exons within intron 4, measured by the abundance of splice junctions in RNA-seq read data, is temporally correlated with levels of intron 4 retention during terminal erythropoiesis. Both IR and decoy splice junctions were low in early stage erythroblasts and much higher in mature erythroblasts. Second, selected decoy exons exhibited IR-promoting activity in the context of minigene splicing reporters expressing the exon 3-6 region of SF3B1 in transfected K562 cells. The wild type minigene reproduced the intron-specific retention phenotype, since it was fully spliced at introns 3 and 5 but exhibited substantial retention of intron 4, whereas deletion of decoy exon 4e, or mutation of its splice sites, substantially decreased IR. Third, RBP (RNA binding protein) cross-linking data from K562 cells show that 3‘ splice site factors including U2AF1 and U2AF2 can bind specifically to 3‘ splice sites of intron 4's decoy exons. Finally, several experiments showed that IR-promoting activity of decoy exons is a more general phenomenon that likely governs IR in other erythroid genes. We observed not only that SF3B1 intron 4 decoy exons could promote IR in heterologous contexts, but also that predicted decoy exons from other erythroblast transcripts could promote IR in the SF3B1 minigene. Apart from this experimental data, comparative genomics revealed that the SF3B1 decoy exons are extremely conserved among vertebrate genomes, with two of the exons being essentially identical from fish to humans. Together this data supports the hypothesis that a subset of up-regulated IR events in late erythroblasts are controlled by decoy exons that block productive splicing at the flanking exons. We propose that regulated IR is an important post-transcriptional mechanism for adjusting cellular splicing capacity during terminal erythropoiesis by regulating expression of key splicing factors such as SF3B1. DisclosuresNo relevant conflicts of interest to declare.

RNA splicing during terminal erythropoiesis

Erythroid progenitors must accurately and efficiently splice thousands of pre-mRNAs as the cells undergo extensive changes in gene expression and cellular remodeling during terminal erythropoiesis. Alternative splicing choices are governed by interactions between RNA binding proteins and cis-regulatory binding motifs in the RNA. This review will focus on recent studies that define the genome-wide scope of splicing in erythroblasts and discuss what is known about its regulation. RNA-seq analysis of highly purified erythroblast populations has revealed an extensive program of alternative splicing of both exons and introns. During normal erythropoiesis, stage-specific splicing transitions alter the structure and abundance of protein isoforms required for optimized red cell production. Mutation or deficiency of splicing regulators underlies hematopoietic disease in myelopdysplasia syndrome patients via disrupting the splicing program. Erythroid progenitors execute an elaborate alternative splicing program that modulates gene expression posttranscriptionally, ultimately regulating the structure and function of the proteome in a differentiation stage-specific manner during terminal erythropoiesis. This program helps drive differentiation and ensure synthesis of the proper protein isoforms required to produce mechanically stable red cells. Mutation or deficiency of key splicing regulatory proteins disrupts the splicing program to cause disease.

The H3K27 demethylase, Utx, regulates adipogenesis in a differentiation stage-dependent manner.

Understanding the molecular mechanisms that drive adipogenesis is important in developing new treatments for obesity and diabetes. Epigenetic regulations determine the capacity of adipogenesis. In this study, we examined the role of a histone H3 lysine 27 demethylase, the ubiquitously transcribed tetratricopeptide repeat protein on the X chromosome (Utx), in the differentiation of mouse embryonic stem cells (mESCs) to adipocytes. Using gene trapping, we examined Utx-deficient male mESCs to determine whether loss of Utx would enhance or inhibit the differentiation of mESCs to adipocytes. Utx-deficient mESCs showed diminished potential to differentiate to adipocytes compared to that of controls. In contrast, Utx-deficient preadipocytes showed enhanced differentiation to adipocytes. Microarray analyses indicated that the β-catenin/c-Myc signaling pathway was differentially regulated in Utx-deficient cells during adipocyte differentiation. Therefore, our data suggest that Utx governs adipogenesis by regulating c-Myc in a differentiation stage-specific manner and that targeting the Utx signaling pathway could be beneficial for the treatment of obesity, diabetes, and congenital utx-deficiency disorders.

Intron Retention Mechanisms That Regulate SF3B1 and Mitoferrin Gene Expression during Late Erythropoiesis

Intron retention (IR) regulates hundreds of erythroid genes in a differentiation stage-specific manner during terminal erythropoiesis. Regulated genes include highly expressed RNA binding proteins (RBPs) such as SF3B1, as well as iron transporters (e.g., mitoferrins 1 and 2), and cytoskeletal proteins (e.g., alpha spectrin). Selected IR transcripts are relatively abundant; 25-50% of the above-mentioned transcripts can be polyadenylated, retained in the nucleus, and efficiently spliced at all but one or two introns, thus limiting the amount of translatable cytoplasmic mRNA. We are studying novel IR regulatory mechanisms involving both splice site strength and deeper intronic elements, using model introns that are differentially regulated in human erythroblasts. SF3B1, a key pre-RNA splicing factor implicated in MDS, exhibits dynamic regulation of intron 4, with low IR in proerythroblasts and high IR in mature orthochromatic erythroblasts. Intron 4 sequences include three ultraconserved elements that encode cryptic exons we term 4a, 4b, and 4c, two of which (4a and 4c) encode premature termination codons (PTCs) expected to induce nonsense-mediated decay (NMD) if spliced into SF3B1 transcripts. We hypothesize that these PTC exons can have an additional function as inefficiently spliced decoy(s), that is, their splice sites may interact with splice sites at the boundaries of intron 4 to form non-productive complexes that do not permit efficient splicing but instead prevent excision of the intron. This concept represents an extension of decoy models previously proposed by others to explain selected exon skipping events, and is supported by several recent findings: eCLIP (enhanced cross-linking and immunoprecipitation) data indicate strong binding of 3' splice site factors U2AF1 and U2AF2 at these exons; low levels of exon 4a and 4c splicing can be seen in NMD-inhibited cells; and deletion of exon 4c from minigene splicing reporters decreases IR. Besides SF3B1, we identified numerous other dynamically-regulated IR events encompassing cryptic PTC exons that bind 3' splice site factors. In contrast to the dynamic regulation of IR in SF3B1, IR in SLC25A37 (mitoferrin-1) and SLC25A28 (mitoferrin-2) is stably maintained at a high level throughout terminal erythropoiesis. Baseline IR levels for stably retained introns correlate with splice site strength, but are also influenced by deeper intronic elements. For example, SLC25A28 intron 2 contains intronic elements that appear to reduce IR, since blocking them with antisense morpholinos leads to substantially increased IR levels. These studies demonstrate that IR in major erythroid genes is regulated by sequences within the retained introns that can either increase or decrease retention, suggesting that multiple IR pathways are employed during terminal erythropoiesis to regulate gene expression. DisclosuresNo relevant conflicts of interest to declare.

Axl signaling induces development of natural killer cells in vitro and in vivo.

Natural killer (NK) cells have been well known to play a critical role in innate immunity, but they are also capable of regulating adaptive immunity through the induction of T cell-mediated memory response and B cell-mediated autoimmune response. NK cells are differentiated from hematopoietic stem cells (HSCs) in the bone marrow (BM), and a series of surface molecules are expressed on NK cells in a differentiation stage-specific manner. Axl receptor tyrosine kinase is originally identified as homeostatic regulators for antigen-presenting cells, and its ligand, growth-arrest-specific gene 6 (Gas6), has been reported to promote cell survival, proliferation, and migration, but their regulatory role in the development and effector function of NK cells is not yet fully understood. In this study, to investigate whether Axl is required for the regulation of NK cell development, the expression of mature NK (mNK) cell-specific receptors and NK cell-associated genes was analyzed in the differentiated HSCs-derived NK cells in vitro and the NK cells harvested from Axl-/- mice. We found that agonistic anti-Axlantibody or recombinant Gas6 specifically upregulated the expression of mNK cell-specific receptors, such as LY49A, Ly49G2, Ly49C/F/I, NKG2A/C/E (1.5- to 3.5-fold increase), and NK cell-associated genes, such as IL-2Rβ (2.3- or 2.4-fold increase), Perforin (4.1- or 2.1-fold increase), IL-15Rα (2.14- or 2.04-fold increase), and IFN-γ (3.3- or 2.8-fold increase) compared to each isotype control, whereas it was abrogated by treatment ofAxl-Ig. Anti-Axlantibody or rGas6 also induced a 2.5- or 1.9-fold increase in the proliferation of developing NK cells compared to each control, respectively. mNK cell populations expressing mNK cell-specific receptors were reduced about twofold in NK cells differentiated from HSCs of Axl-/- mice compared with those of wild-type mice. Furthermore, the triggering of Axl signaling by agonistic anti-Axlantibody promoted the cytolytic activity (1.5- to 1.9-fold increase) against target tumor cells. In B16F10 melanoma-bearing mice, the number of metastatic colonies was decreased by 83% by the administration of mNK cells treated with anti-Axlantibody compared to control Ig. These data suggest that Axl plays an essential role in the regulation of NK cell development as well as NK effector function.

Analysis on transglutaminase 1 and its substrates using specific substrate peptide in cultured keratinocytes

Transglutaminase (TGase) catalyzes protein cross-linking reactions essential for several biological processes. In differentiating keratinocytes, TG1 (keratinocyte-type) is crucial for the cross-linking of substrate proteins required for the complete formation of the cornified envelop, a proteinaceous supermolecule located in the outermost layer of the epidermis. TG1 expressions and its substrate were induced in cultured keratinocytes at differentiation-stage specific manner. In the cultured keratinocytes, we used the TG1-specific substrate peptide, which enables the specific detection of enzymatic activity to investigate its induction patterns. As a further application of the substrate peptide, several substrate candidates of TG1 that may be essential for cornified envelope formation were identified and characterized.

A dynamic alternative splicing program regulates gene expression during terminal erythropoiesis

Alternative pre-messenger RNA splicing remodels the human transcriptome in a spatiotemporal manner during normal development and differentiation. Here we explored the landscape of transcript diversity in the erythroid lineage by RNA-seq analysis of five highly purified populations of morphologically distinct human erythroblasts, representing the last four cell divisions before enucleation. In this unique differentiation system, we found evidence of an extensive and dynamic alternative splicing program encompassing genes with many diverse functions. Alternative splicing was particularly enriched in genes controlling cell cycle, organelle organization, chromatin function and RNA processing. Many alternative exons exhibited differentiation-associated switches in splicing efficiency, mostly in late-stage polychromatophilic and orthochromatophilic erythroblasts, in concert with extensive cellular remodeling that precedes enucleation. A subset of alternative splicing switches introduces premature translation termination codons into selected transcripts in a differentiation stage-specific manner, supporting the hypothesis that alternative splicing-coupled nonsense-mediated decay contributes to regulation of erythroid-expressed genes as a novel part of the overall differentiation program. We conclude that a highly dynamic alternative splicing program in terminally differentiating erythroblasts plays a major role in regulating gene expression to ensure synthesis of appropriate proteome at each stage as the cells remodel in preparation for production of mature red cells.

A Dynamic Alternative Splicing Program Regulates Gene Expression In A Differentiation Stage-Specific Manner During Terminal Erythropoiesis

Spatio-temporal regulation of switches in alternative pre-mRNA splicing modulate exon usage, critically remodeling the transcriptome during development and differentiation of many tissues, while aberrant regulation of alternative splicing disrupts these processes and plays a role in numerous human diseases. Recently, the discovery of splicing factor mutations in myelodysplasia has increased interest in splicing regulation in hematology. Previously, a functionally critical erythroid splicing switch in protein 4.1 pre-mRNA has been reported, in which activation of alternative exon 16 splicing in late erythroblasts is required for assembly of a mechanically stable red cell membrane. To explore globally the landscape of important alternative splicing events in the erythroid lineage, we applied RNA-seq analysis to five highly FACS-purified populations of human erythroblasts, cultured from CD34+ cord blood progenitors, representing proerythroblasts, early and late basophilic erythroblasts, polychromatophilic erythroblasts, and orthochromatophilic erythroblasts. Alternative splicing events predicted by computational analysis were filtered to remove low expression genes and low frequency splicing events, to derive a list of >3000 ‘major' alternative splicing events of potential importance in erythroid biology. Many of these were validated by inspection of RNA-seq reads mapped on the human genome, and/or by RT-PCR analysis. In this unique differentiation system we found an extensive and dynamic alternative splicing program enriched in genes that function in cell cycle regulation, organelle organization, chromatin structure and function, and RNA processing. For example, we identified alternative splicing events in ∼25 genes encoding chromatin modifying enzymes that methylate, demethylate, or acetylate specific lysine or arginine residues in histones; in transcription modulators such as ATRX and BCL11A that regulate normal globin gene expression; and in ∼50 RNA binding proteins with various roles in post-transcriptional gene regulation. Comparison of PSI (percent spliced in) values across the differentiation series revealed that dozens of alternative exons exhibit substantial switches in splicing efficiency during terminal erythropoiesis. The majority of splicing switches occur in late-stage polychromatophilic and orthochromatophilic erythroblasts, temporally correlated with changes in transcript abundance for many splicing factors and with substantial cell remodeling prior to enucleation. One of the biggest switches in late erythroblasts involves inclusion of a 35nt exon in the NDEL1 (nuclear distribution factor E-homolog-like1) gene, which alters C-terminal structure of a protein that functions in nuclear migration and nucleokinesis in nonerythroid cells and may have a role in erythroblast enucleation. Most of the regulated splicing events insert or delete sequences predicted to modulate protein structure and function in late erythroblasts. However, a subset of altered splicing events have a different effect on gene expression by introducing premature translation termination codons (PTCs), leading us to hypothesize that alternative splicing-coupled nonsense-mediated-decay (AS-NMD) contributes to stage-specific down-regulation of numerous erythroid transcripts. Consistent with such a model, most genes that up-regulate PTC exons in late erythroblasts exhibit reduction in overall expression levels, and inhibition of NMD increases the apparent expression of PTC isoforms. In contrast, genes that up-regulate coding exons are not preferentially down-regulated in late erythroblasts. We conclude that a dynamically regulated alternative splicing program in terminally differentiating erythroblasts plays a major post-transcriptional role in shaping gene expression as the cells transition from proliferation to differentiation, ensuring synthesis of the appropriate constellation of proteins as the cells prepare for enucleation and production of mature red cells. Disclosures:No relevant conflicts of interest to declare.

EKLF/KLF1, a tissue-restricted integrator of transcriptional control, chromatin remodeling, and lineage determination.

Erythroid Krüppel-like factor (EKLF or KLF1) is a transcriptional regulator that plays a critical role in lineage-restricted control of gene expression. KLF1 expression and activity are tightly controlled in a temporal and differentiation stage-specific manner. The mechanisms by which KLF1 is regulated encompass a range of biological processes, including control of KLF1 RNA transcription, protein stability, localization, and posttranslational modifications. Intact KLF1 regulation is essential to correctly regulate erythroid function by gene transcription and to maintain hematopoietic lineage homeostasis by ensuring a proper balance of erythroid/megakaryocytic differentiation. In turn, KLF1 regulates erythroid biology by a wide variety of mechanisms, including gene activation and repression by regulation of chromatin configuration, transcriptional initiation and elongation, and localization of gene loci to transcription factories in the nucleus. An extensive series of biochemical, molecular, and genetic analyses has uncovered some of the secrets of its success, and recent studies are highlighted here. These reveal a multilayered set of control mechanisms that enable efficient and specific integration of transcriptional and epigenetic controls and that pave the way for proper lineage commitment and differentiation.

Regulation of GATA Factor Expression Is Distinct between Erythroid and Mast Cell Lineages

The zinc finger transcription factors GATA1 and GATA2 participate in mast cell development. Although the expression of these factors is regulated in a cell lineage-specific and differentiation stage-specific manner, their regulation during mast cell development has not been clarified. Here, we show that the GATA2 mRNA level was significantly increased while GATA1 was maintained at low levels during the differentiation of mast cells derived from mouse bone marrow (BMMCs). Unlike in erythroid cells, forced expression or small interfering RNA (siRNA)-mediated knockdown of GATA1 rarely affected GATA2 expression, and vice versa, in mast cells, indicating the absence of cross-regulation between Gata1 and Gata2 genes. Chromatin immunoprecipitation assays revealed that both GATA factors bound to most of the conserved GATA sites of Gata1 and Gata2 loci in BMMCs. However, the GATA1 hematopoietic enhancer (G1HE) of the Gata1 gene, which is essential for GATA1 expression in erythroid and megakaryocytic lineages, was bound only weakly by both GATA factors in BMMCs. Furthermore, transgenic-mouse reporter assays revealed that the G1HE is not essential for reporter expression in BMMCs and peritoneal mast cells. Collectively, these results demonstrate that the expression of GATA factors in mast cells is regulated in a manner quite distinct from that in erythroid cells.

Aid-Initiated DNA Lesions Are Differentially Processed in Distinct B Cell Differentiation Stages in a Locus-Dependent Manner.

Abstract 2376Activation induced deaminase (AID) initiates U:G mismatches that are subsequently converted into point mutations or DNA double-stranded breaks. AID-mediated DNA alterations in switch (S) regions at the Igh locus frequently occur in both antigen-stimulated germinal center (GC) B cells and cytokine-activated B cells. To investigate whether AID-initiated U:G lesions are differentially processed in a differentiation stage-specific manner at non-Ig loci to maintain genome stability, we established a knock-in model by inserting an Sg2b region into the first intron of proto-oncogene c-myc. We found that the inserted Sg2b region mutated at an extremely low level and did not enhance genomic instability of c-myc locus in antigen-stimulated GC B cells. In contrast, the inserted Sg2b region mutated more frequently and increased c-myc locus abnormalities in cytokine-activated B cells. Furthermore, uracil glycosylase deficiency led to increased mutation frequency at the c-myc locus. These results reveal that AID-initiated lesions are differentially processed via error-free or error-prone repair in a differentiation stage-specific and locus-dependent manner. Our data might provide mechanistic explanation for differential frequency of AID-mediated genetic alterations in distinct subtypes of common B cell lymphomas. Disclosures:No relevant conflicts of interest to declare.

Early chromatin unfolding by RUNX1: a molecular explanation for differential requirements during specification versus maintenance of the hematopoietic gene expression program

AbstractAt the cellular level, development progresses through successive regulatory states, each characterized by their specific gene expression profile. However, the molecular mechanisms regulating first the priming and then maintenance of gene expression within one developmental pathway are essentially unknown. The hematopoietic system represents a powerful experimental model to address these questions and here we have focused on a regulatory circuit playing a central role in myelopoiesis: the transcription factor PU.1, its target gene colony-stimulating-factor 1 receptor (Csf1r), and key upstream regulators such as RUNX1. We find that during ontogeny, chromatin unfolding precedes the establishment of active histone marks and the formation of stable transcription factor complexes at the Pu.1 locus and we show that chromatin remodeling is mediated by the transient binding of RUNX1 to Pu.1 cis-elements. By contrast, chromatin reorganization of Csf1r requires prior expression of PU.1 together with RUNX1 binding. Once the full hematopoietic program is established, stable transcription factor complexes and active chromatin can be maintained without RUNX1. Our experiments therefore demonstrate how individual transcription factors function in a differentiation stage–specific manner to differentially affect the initiation versus maintenance of a developmental program.

Differential Contribution of the Gata1 Gene Hematopoietic Enhancer to Erythroid Differentiation

GATA1 is a key regulator of erythroid cell differentiation. To examine how Gata1 gene expression is regulated in a stage-specific manner, transgenic mouse lines expressing green fluorescent protein (GFP) reporter from the Gata1 locus in a bacterial artificial chromosome (G1BAC-GFP) were prepared. We found that the GFP reporter expression faithfully recapitulated Gata1 gene expression. Using GFP fluorescence in combination with hematopoietic surface markers, we established a purification protocol for two erythroid progenitor fractions, referred to as burst-forming units-erythroid cell-related erythroid progenitor (BREP) and CFU-erythroid cell-related erythroid progenitor (CREP) fractions. We examined the functions of the Gata1 gene hematopoietic enhancer (G1HE) and the highly conserved GATA box in the enhancer core. Both deletion of the G1HE and substitution mutation of the GATA box caused almost complete loss of GFP expression in the BREP fraction, but the CREP stage expression was suppressed only partially, indicating the critical contribution of the GATA box to the BREP stage expression of Gata1. Consistently, targeted deletion of G1HE from the chromosomal Gata1 locus provoked suppressed expression of the Gata1 gene in the BREP fraction, which led to aberrant accumulation of BREP stage hematopoietic progenitor cells. These results demonstrate the physiological significance of the dynamic regulation of Gata1 gene expression in a differentiation stage-specific manner.

Imatinib Mesylate Has a Stage-Specific Inhibitory Role in Generation of CD26highCD8+ Central Memory T Cells in Vitro and in Vivo.

CD26 is a transmembrane glycoprotein with intrinsic dipeptidyl peptidase IV (DPPIV) activity as well as costimulatory activity of mitotic signals triggered by the CD3/TCR complex. Based on the expression level of CD26, CD4+ and CD8+ T cells can be divided into 3 (high/intermediate/low or negative) subsets. The significance of CD26 has been studied mainly on CD4+ T cells, and CD26highCD4+ T cells are considered to represent effector memory T cells of a typical Th1 phenotype producing IL2 and IFNg. Furthermore, we reported a significant decrease of this subset in CML patients under imatinib therapy in comparison to those under IFNa therapy and normal volunteers. In contrast, the role of each subset of CD8+ T cells has not yet been clarified.Multi-parameter flow cytometry analysis was performed to characterize CD8+ T cells differentially expressing CD26 in combination with intracellular detection of effector molecules such as perforin (P) and granzyme B (Gr). The capacity to secrete effector cytokines such as IFNg following short-term stimulation was also assessed. As a result, according to the expression level of CD26, we could clearly categorize CD8+ T cells as follows: CD26highCD8+ T cells are defined as central memory T cells which has a phenotype of CD45RO+CD28+CD27+ IFNg+Gr−P+/−, CD26intCD8+ T cells as naïve T cells of CD45ROCD28+ CD27+ IFNg−Gr−P−, and CD26lowCD8+ T cells as effector memory/effector T cells of CD45RO−/+ CD28−CD27−IFNg++Gr++P++, respectively. We next investigated the effects of imatinib on 3 distinct subsets during CD8+ T cell differentiation program. Peripheral blood mononuclear cells were primed with anti-CD3/CD28 MAb and subjected to the grading doses of imatinib for short term culture, followed by flow cytometory. CFSE labeling was used for monitoring cell proliferation. Intriguingly, we found that imatinib dose-dependently inhibits activation, cytokine production and proliferation of CD26highCD8+ central memory T cell subsets in a differentiation stage-specific manner. Finally, we compared the absolute number of peripheral blood CD26highCD8+ T cell subsets between 20 patients with CML in imatinib-induced CCR and 20 normal volunteers, clearly indicating a significant decrease of this subset in CML patients (22.30/ml vs 45.60/ml, p<0.01).The present study offers another evidence for immunomodulatory effects of imatinib or the critical role of Abl (-related) kinase in T cell development, and draws special attention to susceptibility to viral infection of CML patients under long-term imatinib therapy. [Display omitted]

Rho/Rho-associated Kinase Signal Regulates Myogenic Differentiation via Myocardin-related Transcription Factor-A/Smad-dependent Transcription of the Id3 Gene

RhoA is known to be involved in myogenic differentiation, but whether it acts as a positive or negative regulator is controversial. To resolve this issue, we investigated the differentiation stage-specific roles of RhoA and its effector, Rho-associated kinase, using C2C12 myoblasts. We found that proliferating myoblasts show high levels of RhoA and serum-response factor activities and strong expression of the downstream target of RhoA, myocardin-related transcription factor-A (MRTF-A or MAL); these activities and expression are markedly lower in differentiating myocytes. We further demonstrated that, in proliferating myoblasts, an increase in MRTF-A, which forms a complex with Smad1/4, strikingly activates the expression level of the Id3 gene; the Id3 gene product is a potent inhibitor of myogenic differentiation. Finally, we found that during differentiation, one of the forkhead transcription factors translocates into the nucleus and suppresses Id3 expression by preventing the association of the MRTF-A-Smad complex with the Id3 promoter, which leads to the enhancement of myogenic differentiation. We conclude that RhoA/Rho-associated kinase signaling plays positive and negative roles in myogenic differentiation, mediated by MRTF-A/Smad-dependent transcription of the Id3 gene in a differentiation stage-specific manner.

LIF Inhibits Osteoblast Differentiation at Least in Part by Regulation of HAS2 and Its Product Hyaluronan

LIF arrests osteogenesis in fetal rat calvaria cells in a differentiation stage-specific manner. Differential display identified HAS2 as a LIF-induced gene and its product, HA, modulated osteoblast differentiation similarly to LIF. Our data suggest that LIF arrests osteoblast differentiation by altering HA content of the extracellular matrix. Leukemia inhibitory factor (LIF) elicits both anabolic and catabolic effects on bone. We previously showed in the fetal rat calvaria (RC) cell system that LIF inhibits osteoblast differentiation at the late osteoprogenitor/early osteoblast stage. To uncover potential molecular mediators of this inhibitory activity, we used a positive-negative genome-wide differential display screen to identify LIF-induced changes in the developing osteoblast transcriptome. Although LIF signaling is active throughout the RC cell proliferation-differentiation sequence, only a relatively small number of genes, in several different functional clusters, are modulated by LIF specifically during the LIF-sensitive inhibitory time window. Based on their known and predicted functions, most of the LIF-regulated genes identified are plausible candidates to be involved in the LIF-induced arrest of osteoprogenitor differentiation. To test this hypothesis, we further analyzed the function of one of the genes identified, hyaluronan synthase 2 (HAS2), in the LIF-induced inhibition. Synthesis of hyaluronan (HA), the product of HAS enzymatic activity, was stimulated by LIF and mimicked the HAS2 expression profile, with highest expression in early/proliferative and late/maturing cultures and lowest levels in intermediate/late osteoprogenitor-early osteoblast cultures. Exogenously added high molecular weight HA, the product of HAS2, dose-dependently inhibited osteoblast differentiation, with pulse-treatment effective in the same differentiation stage-specific inhibitory window as seen with LIF. In addition, however, pulse treatment with HA in early cultures slightly increased bone nodule formation. Treatment with hyaluronidase, on the other hand, stimulated bone nodule formation in early cultures but caused a small dose-dependent inhibition of osteoblast differentiation in the LIF- and HA-sensitive late time window. Together the data suggest that osteoblast differentiation is acutely sensitive to HA levels and that LIF inhibits osteoblast development at least in part by stimulating high molecular weight HA synthesis through HAS2.