Yukiko Nambu

The Balance Between Pax5 and Id2 Activities Is the Key to AID Gene Expression

Pax5 activity is enhanced in activated B cells and is essential for class switch recombination (CSR). We show that inhibitor of differentiation (Id)2 suppresses CSR by repressing the gene expression of activation-induced cytidine deaminase (AID), which has been shown to be indispensable for CSR. Furthermore, a putative regulatory region of AID contains E2A- and Pax5-binding sites, and the latter site is indispensable for AID gene expression. Moreover, the DNA-binding activity of Pax5 is decreased in Id2-overexpressing B cells and enhanced in Id2−/− B cells. The kinetics of Pax5, but not E2A, occupancy to AID locus is the same as AID expression in primary B cells. Finally, enforced expression of Pax5 induces AID transcription in pro–B cell lines. Our results provide evidence that the balance between Pax5 and Id2 activities has a key role in AID gene expression.

Requirement for Runx Proteins in IgA Class Switching Acting Downstream of TGF-β1 and Retinoic Acid Signaling

IgA is a specific isotype required for mucosal immunity and is the most abundant Ab produced in vivo. Recently, several inductive signals for IgA class switch recombination have been identified; however, the molecular details of the action of these signals and the specific factors acting in B cells remain elusive. In this study, we show that combination of retinoic acid (RA) and TGF-β1 with other factors induced a much higher frequency of IgA-switched cells than reported previously. In addition, IgA production is severely impaired in Runx2-Runx3 double-deficient mice. In Runx2-Runx3–deficient B cells, both RA- and TGF-β1–dependent inductions of α germline transcription are completely blocked. These data suggest that Runx proteins play an essential role in IgA class switching acting downstream of RA and TGF-β1 signaling.

Role of Id proteins in B lymphocyte activation: new insights from knockout mouse studies

Id (inhibitor of differentiation) proteins play important roles in cell differentiation, cell cycle control, and apoptosis. They act as negative regulators of basic helix-loop-helix-type transcription factors, which positively regulate differentiation of various cell types. Id proteins work to block B lymphocyte (B cell) maturation at an early differentiation step, as demonstrated by gain-of-function studies. In recent years a series of gene-targeted mice lacking different Ids have been generated. Analyses of these gene-targeted mice provide information useful for understanding the physiological roles of Ids in B cell biology. Id3 is required for proper B cell functions and acts by controlling the cell cycle. Upon B cell activation, Id2 acts as a negative regulator to prevent potentially harmful effects brought about by excessive immunological reactions; one of its special roles is to maintain low serum concentrations of immunoglobulin E (IgE). The Id2 protein does this by antagonizing E2A and Pax5 activities, both of which are required for proper B cell activation. This review presents several new insights into B cell differentiation and activation programs and the physiological role of Id proteins in B cell activation.

Mitochondrial function provides instructive signals for activation-induced B-cell fates

During immune reactions, functionally distinct B-cell subsets are generated by stochastic processes, including class-switch recombination (CSR) and plasma cell differentiation (PCD). In this study, we show a strong association between individual B-cell fates and mitochondrial functions. CSR occurs specifically in activated B cells with increased mitochondrial mass and membrane potential, which augment mitochondrial reactive oxygen species (mROS), whereas PCD occurs in cells with decreased mitochondrial mass and potential. These events are consequences of initial slight changes in mROS in mitochondriahigh B-cell populations. In CSR-committed cells, mROS attenuates haeme synthesis by inhibiting ferrous ion addition to protoporphyrin IX, thereby maintaining Bach2 function. Reduced mROS then promotes PCD by increasing haeme synthesis. In PCD-committed cells, Blimp1 reduces mitochondrial mass, thereby reducing mROS levels. Identifying mROS as a haeme synthesis regulator increases the understanding of mechanisms regulating haeme homeostasis and cell fate determination after B-cell activation.

Runx3 Is Required for Full Activation of Regulatory T Cells To Prevent Colitis-Associated Tumor Formation

Inflammation is increasingly recognized as an essential component of tumorigenesis, which is promoted and suppressed by various T cell subsets acting in different ways. It was shown previously in Runx3-deficient mice that differentiation of CD8 T and NK cells is perturbed. In this study, we show that Runx3 is also required for proper differentiation and function of regulatory T cells. In Runx3-deficient mice, T cells were unable to inhibit inflammation and to suppress tumor development. As expected, recombination activating gene 2-deficient mice bearing Runx3-deficient lymphocytes spontaneously developed colon tumors. However, tumor formation was completely blocked by transfer of either regulatory T cells or CD8 T cells derived from wild-type mice to mutant mice or by housing mutant mice in a specific pathogen-free condition. These results indicate that Runx3-deficient lymphocytes and microorganisms act together to induce inflammation and consequently induce the development of colon tumors.

In situ differentiation of CD8αα Τ cells from CD4 T cells in peripheral lymphoid tissues

Mutually exclusive cell fate determination of CD4 helper or CD8 killer T cells occurs in the thymus. These T-cell subsets are not believed to redirect other lineages. Here we showed that retinoic acid and transforming growth factor-β1 promoted the differentiation of CD8αα T cells from CD4 T cells in a Runx3-dependent manner. These cells were inferred to belong to immunoregulatory populations because subpopulations of CD8αα+TCRαβ T cells are known to suppress activated T cells, and mice with Runx3−/− T cells showed defects during recovery from experimental allergic encephalomyelitis. Our results demonstrate that CD4 T cells play fundamental roles in controlling immune reactions through promotion and attenuation. We accordingly anticipate that clarifying the mechanisms underlying this process will provide insights leading to autoimmune and immunodeficiency disease therapies.

Accessibility Control of Recombination at Immunoglobulin Locus

During B cell development, two somatic DNA recombination events occur at the immunoglobulin heavy chain loci: VDJ recombination and class switch recombination (CSR). VDJ recombination assembles antigen receptor genes from a pool of gene segments. CSR exchanges the μ constant region of the immunoglobulin heavy chain gene for the other isotypes (γ1, γ2a, γ2b, γ3, α or ε). In both cases, the target specificity of recombination reactions seems to be regulated by structural changes of the target chromatin. In fact, many studies support this notion, called the “accessibility model”. In recent years, covalent modifications of histones have gained prominence as epigenetic markers that alter the properties of the associated DNA and contribute to structural changes of the target chromatin. This review focuses on the control of CSR by modulation of accessibility, and the role of histone modifications and germline transcription in CSR.

Functions of Runx in IgA class switch recombination

Runt‐related (Runx) transcriptional regulators play essential roles in various cell fate determination processes, and dysfunction of these regulators causes many human diseases. Considerable insight into the functions of Runx proteins was provided mainly by studies of hematopoietic and skeletal disorders. Recently, extensive investigations have revealed new functions of these transcription factors in immune cell differentiation and functioning. In the present review, we discuss the mechanisms of selective IgA production in the intestine and report the involvement of Runx proteins in this process. J. Cell. Biochem. 112: 409–414, 2011.