A multistep mechanism for the activation of rearrangement in the immune system

MicroRNA-376b-3p targets RGS1 mRNA to inhibit proliferation, metastasis, and apoptosis in osteosarcoma

Background

To investigate the role of microRNA-376b-3p (miR-376b-3p) and regulator of G protein signaling 1 (RGS1) in the proliferation, metastasis, and apoptosis of osteosarcoma.

Methods

Differentially expressed genes (DEGs) between tumor and normal tissues from GSE14359 and GSE33382 in the cancer genome atlas (TCGA) dataset were analyzed with GEO2R online. Similarly, differentially expressed miRNAs from GSE70367 were also analyzed with GEO2R. The interaction between the differentially expressed miRNAs and the shared distal metastasis-related DEGs from the two datasets were analyzed using miRWalk and Cytoscape. RGS1 and miR-376-3p were chosen to verify the prediction. RGS1 stably expressing and silencing cells were established based on the MG63 and U2OS cell lines. The targeting of RGS1 with miR-376b-3p was confirmed with Starbase prediction and luciferase reporter assay. Cell proliferation, metastasis, and apoptosis were characterized in vitro and in xenograft mice.

Results

A total of 10 up-regulated and 8 down-regulated DEGs were characterized as shared metastasis-related DEGs for GSE14359 and GSE33382. Among these DEGs, RGS1 was targeted with miR-376b-3p, a predicted down-regulated miRNA in GSE70367. High expression of RGS1 predicted proliferation, invasion, metastases, and poor prognosis in osteosarcoma. Overexpression of RGS1 promoted proliferation, invasion, mobility, and stemness in MG63 and U2OS cells, while silencing of RGS1 had the opposite effect in both cell lines. High expression of RGS1 promoted tumor growth in xenograft nude mice. RGS1 was targeted with miR-376b-3p; the addition of miR-376b-3p down-regulated RGS1, and suppressed cell proliferation, invasion, and metastasis. Meanwhile, sponging of miR-376b-3p had the opposite effect. The suppressive effects of miR-376b-3p could be abolished with RGS1, as cell proliferation, stemness, metastasis, and invasion were all promoted with RGS1 co-transfection in both cell lines.

Conclusions

Our study indicated that RGS1 is a tumor-promoting gene in osteosarcoma, which could be inhibited with miR-376b-3p.

Asynchronous Replication Timing: A Mechanism for Monoallelic Choice During Development

Developmental programming is carried out by a sequence of molecular choices that epigenetically mark the genome to generate the stable cell types which make up the total organism. A number of important processes, such as genomic imprinting, selection of immune or olfactory receptors, and X-chromosome inactivation in females are dependent on the ability to stably choose one single allele in each cell. In this perspective, we propose that asynchronous replication timing (ASRT) serves as the basis for a sophisticated universal mechanism for mediating and maintaining these decisions.

RAG enhances BCR-ABL1-positive leukemic cell growth through its endonuclease activity in vitro and in vivo

BCR-ABL1 gene fusion associated with additional DNA lesions involves the pathogenesis of chronic myelogenous leukemia (CML) from a chronic phase (CP) to a blast crisis of B lymphoid (CML-LBC) lineage and BCR-ABL1+ acute lymphoblastic leukemia (BCR-ABL1+ ALL). The recombination-activating gene RAG1 and RAG2 (collectively, RAG) proteins that assemble a diverse set of antigen receptor genes during lymphocyte development are abnormally expressed in CML-LBC and BCR-ABL1+ ALL. However, the direct involvement of dysregulated RAG in disease progression remains unclear. Here, we generate human wild-type (WT) RAG and catalytically inactive RAG-expressing BCR-ABL1+ and BCR-ABL1- cell lines, respectively, and demonstrate that BCR-ABL1 specifically collaborates with RAG recombinase to promote cell survival in vitro and in xenograft mice models. WT RAG-expressing BCR-ABL1+ cell lines and primary CD34+ bone marrow cells from CML-LBC samples maintain more double-strand breaks (DSB) compared to catalytically inactive RAG-expressing BCR-ABL1+ cell lines and RAG-deficient CML-CP samples, which are measured by γ-H2AX. WT RAG-expressing BCR-ABL1+ cells are biased to repair RAG-mediated DSB by the alternative non-homologous end joining pathway (a-NHEJ), which could contribute genomic instability through increasing the expression of a-NHEJ-related MRE11 and RAD50 proteins. As a result, RAG-expressing BCR-ABL1+ cells decrease sensitivity to tyrosine kinase inhibitors (TKI) by activating BCR-ABL1 signaling but independent of the levels of BCR-ABL1 expression and mutations in the BCR-ABL1 tyrosine kinase domain. These findings identify a surprising and novel role of RAG in the functional specialization of disease progression in BCR-ABL1+ leukemia through its endonuclease activity.

Epigenetic regulation of monoallelic rearrangement (allelic exclusion) of antigen receptor genes

While most genes in the mammalian genome are transcribed from both parental chromosomes in cells where they are expressed, approximately 10% of genes are expressed monoallelically, so that any given cell will express either the paternal or maternal allele, but not both. The antigen receptor genes in B and T cells are well-studied examples of a gene family, which is expressed in a monoallelic manner, in a process coined "allelic exclusion." During lymphocyte development, only one allele of each antigen receptor undergoes V(D)J rearrangement at a time, and once productive rearrangement is sensed, rearrangement of the second allele is prevented. In this mini review, we discuss the epigenetic processes, including asynchronous replication, nuclear localization, chromatin condensation, histone modifications, and DNA methylation, which appear to regulate the primary rearrangement of a single allele, while blocking the rearrangement of the second allele.

Histones: annotating chromatin

Chromatin is a highly regulated nucleoprotein complex through which genetic material is structured and maneuvered to elicit cellular processes, including transcription, cell division, differentiation, and DNA repair. In eukaryotes, the core of this structure is composed of nucleosomes, or repetitive histone octamer units typically enfolded by 147 base pairs of DNA. DNA is arranged and indexed through these nucleosomal structures to adjust local chromatin compaction and accessibility. Histones are subject to multiple covalent posttranslational modifications, some of which alter intrinsic chromatin properties, others of which present or hinder binding modules for non-histone, chromatin-modifying complexes. Although certain histone marks correlate with different biological outputs, we have yet to fully appreciate their effects on transcription and other cellular processes. Tremendous advancements over the past years have uncovered intriguing histone-related matters and raised important related questions. This review revisits past breakthroughs and discusses novel developments that pertain to histone posttranslational modifications and the affects they have on transcription and DNA packaging.

Immunoglobulin kappa enhancers are differentially regulated at the level of chromatin structure

The kappa intronic and the kappa 3' enhancers synergize to regulate recombination and transcription of the Ig kappa locus. Although these enhancers have overlapping functions, the kappa i enhancer appears to predominate during receptor editing, while the kappa 3' enhancer may be more important for initiating Ig kappa germline transcription to target locus recombination and, later in development, somatic hypermutation. Changes in chromatin structure appear to regulate both enhancers, and previous reports suggest that both enhancers are packaged into an accessible chromatin structure only in B lineage cells. Why these enhancers cannot activate the demethylated, accessible, protein-associated Ig kappa allele in pro-B cells is not known. Furthermore, how the enhancers function to reactivate the locus for receptor editing or to quantitatively promote hypermutation in B cells is vague. Quantitative analysis of Ig enhancer chromatin structure in murine pro-, pre-and splenic B cells demonstrated that the kappa i enhancer maintains a highly accessible chromatin structure under a variety of conditions. This stable chromatin structure mirrored the highly accessible structure characterizing the Ig mu intronic enhancer, despite the fact that Ig mu is activated prior to Ig kappa during B cell development. Surprisingly, parallel analysis of the kappa 3' enhancer demonstrated its accessible chromatin structure is markedly unstable, as characterized by sensitivity to changes in environmental conditions. These data unexpectedly suggest that kappa locus regulation is compartmentalized along the gene in B lineage cells. Furthermore, these findings raise the possibility that environmentally dependent regulation of kappa 3' enhancer structure underlies changes in kappa activation during B cell development.

IFN regulatory factor 4 and 8 promote Ig light chain kappa locus activation in pre-B cell development

Previous studies have shown that B cell development is blocked at the pre-B cell stage in IFN regulatory factor (IRF)4 (pip) and IRF8 (IFN consensus sequence binding protein) double mutant mice (IRF4,8(-/-)). In this study, the molecular mechanism by which IRF4,8 regulate pre-B cell development was further investigated. We show that IRF4,8 function in a B cell intrinsic manner to control pre-B cell development. IRF4,8(-/-) mice expressing a Bcl-2 transgene fail to rescue pre-B cell development, suggesting that the defect in B cell development in IRF4,8(-/-) mice is not due to a lack of survival signal. IRF4,8(-/-) pre-B cells display a high proliferation index that may indirectly inhibit the L chain rearrangement. However, forced cell cycle exit induced by IL-7 withdrawal fails to rescue the development of IRF4,8(-/-) pre-B cells, suggesting that cell cycle exit by itself is not sufficient to rescue the development of IRF4,8(-/-) pre-B cells and that IRF4,8 may directly regulate the activation of L chain loci. Using retroviral mediated gene transduction, we show that IRF4 and IRF8 function redundantly to promote pre-B cell maturation and the generation of IgM(+) B cells. Molecular analysis indicates that IRF4, when expressed in IRF4,8(-/-) pre-B cells, induces kappa germline transcription, enhances V(D)J rearrangement activity at the kappa locus, and promotes L chain rearrangement and transcription. Chromatin immunoprecipitation assay further reveals that IRF4 expression leads to histone modifications and enhanced chromatin accessibility at the kappa locus. Thus, IRF4,8 control pre-B cell development, at least in part, by promoting the activation of the kappa locus.

Fine tuning of globin gene expression by DNA methylation

Expression patterns in the globin gene cluster are subject to developmental regulation in vivo. While the γ^A and γ^G genes are expressed in fetal liver, both are silenced in adult erythrocytes. In order to decipher the role of DNA methylation in this process, we generated a YAC transgenic mouse system that allowed us to control γ^A methylation during development. DNA methylation causes a 20-fold repression of γ^A both in non-erythroid and adult erythroid cells. In erythroid cells this modification works as a dominant mechanism to repress γ gene expression, probably through changes in histone acetylation that prevent the binding of erythroid transcription factors to the promoter. These studies demonstrate that DNA methylation serves as an elegant in vivo fine-tuning device for selecting appropriate genes in the globin locus. In addition, our findings provide a mechanism for understanding the high levels of γ-globin transcription seen in patients with Hereditary Persistence of Fetal Hemoglobin, and help explain why 5azaC and butyrate compounds stimulate γ-globin expression in patients with β-hemoglobinopathies.

Activation of V(D)J recombination at the IgH chain JH locus occurs within a 6-kilobase chromatin domain and is associated with nucleosomal remodeling

IgH genes are assembled during early B cell development by a series of regulated DNA recombination reactions in which DH and JH segments are first joined followed by V(H) to DJH rearrangement. Recent studies have highlighted the role of chromatin structure in the control of V(D)J recombination. In this study, we show that, in murine pro-B cell precursors, the JH segments are located within a 6-kb DNase I-sensitive chromatin domain containing acetylated histones H3 and H4, which is delimited 5' by the DQ52 promoter element and 3' by the intronic enhancer. Within this domain, the JH segments are covered by phased nucleosomes. High-resolution mapping of nucleosomes reveals that, in pro-B cells, unlike recombination refractory nonlymphoid cells, the recombination signal sequences flanking the four JH segments are located in regions of enhanced micrococcal nuclease and restriction enzyme accessibility, corresponding to either nucleosome-free regions or DNA rendered accessible within a nucleosome. These results support the idea that nucleosome remodeling provides an additional level of control in the regulation of Ig locus accessibility to recombination factors in B cell precursors.

Changes in immunoglobulin–nucleoprotein complex structure mapped by chromatin immunoprecipitation

Transcription factor-mediated immunoglobulin (Ig) enhancer activation has been analyzed extensively outside the physiological constraints of chromatin. Towards understanding the role sequence-specific DNA binding proteins identified by these methods play in activating Ig genes during B cell development, we have investigated in vivo interaction between the Ig enhancer activator PU.1 and two target elements, the Igmu and kappa3' enhancers, by chromatin immunoprecipitation (ChIP). By using two antibodies recognizing different PU.1 epitopes in murine B cells, these analyses demonstrate that ChIP results may depend on the availability of the epitope(s) targeted by the immunoprecipitating antibody. Specifically, PU.1 epitope availability at the mu and kappa3' enhancers does not accurately quantitate total PU.1 association. This result suggests the nucleoprotein complexes formed at these various active enhancers is cell type-specific. Interestingly, RAG1-/- but not RAG2-/- pro-B cells lack PU.1/kappa3' association, probably due to limited accessibility of the kappa locus in the former. The more robust association of PU.1 with the kappa3' versus mu enhancer in all but RAG1-/- B lineage cells is not explained by differences in PCR primer efficiency, but likely reflects the different structures formed by the complexes at mu versus kappa3' enhancers. Finally, PU.1 is not associated with an inaccessible mu or kappa3' enhancer chromatin structure in macrophages, again emphasizing the importance cellular protein context plays in PU.1/Ig enhancer association. The demonstration that changes in epitope availability, hence nucleoprotein structure, can be monitored by ChIP suggests using this technique to monitor biologically important changes in nucleoprotein complex structure/composition in situ.

G9a-mediated irreversible epigenetic inactivation of Oct-3/4 during early embryogenesis

Oct-3/4 is a POU domain homeobox gene that is expressed during gametogenesis and in early embryonic cells, where it has been shown to be important for maintaining pluripotency. Following implantation, this gene undergoes a novel multi-step programme of inactivation. Transcriptional repression is followed by a pronounced increase in histone H3 methylation on Lys 9 that is mediated by the SET-containing protein, G9a. This step sets the stage for local heterochromatinization via the binding of HP1 and is required for subsequent de novo methylation at the promoter by the enzymes Dnmt3a/3b. Genetic studies show that these epigenetic changes actually have an important role in the inhibition of Oct-3/4 re-expression, thereby preventing reprogramming.

Allele-Specific Regulation of TCRβ Variable Gene Segment Chromatin Structure

Allelic exclusion of the murine Tcrb locus is imposed at the level of recombination and restricts each cell to produce one functional VDJbeta rearrangement. Allelic exclusion is achieved through asynchronous Vbeta to DJbeta recombination as well as feedback inhibition that terminates recombination once a functional rearrangement has occurred. Because the accessibility of Vbeta gene segment chromatin is diminished as thymocytes undergo allelic exclusion at the CD4(-)CD8(-) (double-negative) to CD4(+)CD8(+) (double-positive) transition, chromatin regulation was thought to be an important component of the feedback inhibition process. However, previous studies of chromatin regulation addressed the status of Tcrb alleles using genetic models in which both alleles remained in a germline configuration. Under physiological conditions, developing thymocytes would undergo Vbeta to DJbeta recombination on one or both alleles before the enforcement of feedback. On rearranged alleles, Vbeta gene segments that in germline configuration are regulated independently of the Tcrb enhancer are now brought into its proximity. We show in this study that in contrast to Vbeta segments on a nonrearranged allele, those situated upstream of a functionally rearranged Vbeta segment are contained in active chromatin as judged by histone H3 acetylation, histone H3 lysine 4 (K4) methylation, and germline transcription. Nevertheless, these Vbeta gene segments remain refractory to recombination in double-positive thymocytes. These results suggest that a unique feedback mechanism may operate independent of chromatin structure to inhibit Vbeta to DJbeta recombination after the double-negative stage of thymocyte development.

Silence of the genes--mechanisms of long-term repression

A large fraction of genes in the mammalian genome is repressed in every cell throughout development. Here, we propose that this long-term silencing is carried out by distinct molecular mechanisms that operate in a global manner and, once established, can be maintained autonomously through DNA replication. Both individually and in combination these mechanisms bring about repression, mainly by lowering gene accessibility through closed chromatin structures.

The key to development: interpreting the histone code?

Developmental stages in multicellular organisms proceed according to a temporally and spatially precise pattern of gene expression. It has become evident that changes within the chromatin structure brought about by covalent modifications of histones are of crucial importance in determining many biological processes, including development. Numerous studies have provided evidence that the enzymes responsible for the modifications of histones function in a coordinated pattern to control gene expression in the short term and, through the transferral of these modifications by inheritance to their progeny, in the long term.

The Ig kappa 3' enhancer is activated by gradients of chromatin accessibility and protein association

The Igkappa locus is recombined following initiation of a signaling cascade during the early pre-B stage of B cell development. The Ig kappa3' enhancer plays an important role in normal B cell development by regulating kappa locus activation. Quantitative analyses of kappa3' enhancer chromatin structure by restriction endonuclease accessibility and protein association by chromatin immunoprecipitation in a developmental series of primary murine B cells and murine B cell lines demonstrate that the enhancer is activated progressively through multiple steps as cells mature. Moderate kappa3' chromatin accessibility and low levels of protein association in pro-B cells are increased substantially as the cells progress from pro- to pre-B, then eventually mature B cell stages. Chromatin immunoprecipitation assays suggest transcriptional regulators of the kappa3' enhancer, specifically PU.1 and IFN regulatory factor-4, exploit enhanced accessibility by increasing association as cells mature. Characterization of histone acetylation patterns at the kappa3' enhancer and experimental inhibition of histone deacetylation suggest changes therein may determine changes in enzyme and transcription factor accessibility. This analysis demonstrates kappa activation is a multistep process initiated in early B cell precursors before Igmu recombination and finalized only after the pre-B cell stage.

Immunoglobulin locus silencing and allelic exclusion

Lymphocytes are characterised by monoclonal expression of antigen receptors. This is achieved by silencing of one of two homologous antigen receptor alleles, a process known as allelic exclusion. This process is regulated both before and after V(D)J recombination, by a variety of mechanisms. These include nuclear localisation, changes in chromatin structure and histone modifications, non-coding sense and antisense RNA transcription, epigenetic alterations at the DNA level, feedback signalling from expressed alleles, locus contraction and decontraction, recruitment to heterochromatin. This review will focus on recent advances in the immunoglobulin heavy and kappa light chain loci. The current picture is of a complex, temporally ordered sequence of events, in which these loci share many contributory mechanisms, but clear and intriguing differences are emerging.

Regulation of T cell receptor beta allelic exclusion at a level beyond accessibility

Allelic exclusion of V(beta)-to-DJ(beta) recombination depends on asynchronous rearrangement of alleles of the gene encoding T cell receptor beta in double-negative thymocytes and feedback inhibition that is maintained in double-positive thymocytes. Feedback is thought to be enforced through downregulation of V(beta) accessibility. In an attempt to override this negative regulation, we introduced the enhancer of the gene encoding T cell receptor alpha into the V(beta) gene cluster downstream of V(beta)12. In double-negative thymocytes, the introduced enhancer had no measurable effect on accessibility, but V(beta)12 rearrangement was stimulated and V(beta)12 allelic exclusion was partially subverted. In contrast, double-positive thymocytes showed increased V(beta) transcription and accessibility, but feedback inhibition of V(beta)-to-DJ(beta) recombination remained intact. Our results indicate additional regulatory constraints on V(beta)-to-DJ(beta) recombination that operate beyond the accessibility barrier.

Epigenetic ontogeny of the Igk locus during B cell development

To become accessible for rearrangement, the immunoglobulin kappa locus must undergo a series of epigenetic changes. This begins in pro-B cells with the relocation of both immunoglobulin kappa alleles from the periphery to the center of the nucleus. In pre-B cells, one allele became preferentially packaged into an active chromatin structure characterized by histone acetylation and methylation of histone H3 lysine 4, while the other allele was recruited to heterochromatin, where it was associated with heterochromatin protein-gamma and Ikaros. These events in cis made only one allele accessible to trans-acting factors, such as RelB, which mediated DNA demethylation, to facilitate rearrangement. These results suggest that early B lymphoid epigenetic changes generate differential structures that serve as the basis for allelic exclusion.

A stepwise epigenetic process controls immunoglobulin allelic exclusion

During the differentiation of T and B cells, immune-receptor loci in the genome must be made sterically accessible so that they can undergo rearrangement. Here, we discuss how this is carried out by the stepwise removal of epigenetic repression mechanisms - such as later-replication timing, heterochromatization, histone hypo-acetylation and DNA methylation - in a manner that initially favours one allele in each cell. We propose that this mechanism of allelic exclusion might also be the basis for the generation of gene diversity in other systems.

B cell-specific loss of histone 3 lysine 9 methylation in the V(H) locus depends on Pax5

Immunoglobulin heavy chain rearrangement (V(H)-to-DJ(H)) occurs only in B cells, suggesting it is inhibited in other lineages. Here we found that in the mouse V(H) locus, methylation of lysine 9 on histone H3 (H3-K9), a mark of inactive chromatin, was present in non-B lineage cells but was absent in B cells. As others have shown that H3-K9 methylation can inhibit V(D)J recombination on engineered substrates, our data support the idea that H3-K9 methylation inhibits endogenous V(H)-to-DJ(H) recombination. We also show that Pax5, a transcription factor required for B cell commitment, is necessary and sufficient for the removal of H3-K9 methylation in the V(H) locus and provide evidence that one function of Pax5 is to remove this inhibitory modification by a mechanism of histone exchange, thus allowing B cell-specific V(H)-to-DJ(H) recombination.

DNA methylation and cancer therapy

Vertebrate DNA is modified by methyl moieties at the 5'-position of cytosine rings residing in the di-nucleotide sequence CpG. Approximately 80% of CpG dinucleotide sequences are methylated. The pattern of distribution of methylated CGs is cell-type specific and correlates with gene expression programming and chromatin structure. Three kinds of seemingly contradictory aberrations in DNA methylation are observed in cancer, global hypomethylation, and regional hypermethylation and deregulated level of expression of DNA methyltransferases. It was previously proposed that the DNA methylation machinery is a candidate target for anticancer therapy. Inhibition of hypermethylation was the first therapeutic target. However, recent data suggests that inhibition of DNA methylation might have untoward effects such as induction of genes involved in metastasis. This review discusses the relative role of the three levels of alteration in the DNA methylation in cancer, proposes a unified hypothesis on the relative roles of increased DNA methyltransferase as well as the coexistence of hypo -and hyper- methylation in cancer and its possible implications on anticancer therapy.