Mitochondrial function provides instructive signals for activation-induced B cell　fates / ミトコンドリアによる活性化B細胞運命決定機構の解析

Jang, Kyoung-Jin

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第18899号 / 医博第4010号 / 新制||医||1009(附属図書館) / 31850 / 京都大学大学院医学研究科医学専攻 / (主査)教授 生田 宏一, 教授 三森 経世, 教授 岩井 一宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Mitochondria

B cell differentiation

Class Switch Recombination (CSR)

Plasma Cell Differentiation (PCD)

Reactive Oxygen Species (ROS)

Heme synthesis

490

Regulation of B cell development by antigen receptors

Hauser, Jannek

January 2011

The developmental processes of lymphopoiesis generate mature B lymphocytes from hematopoietic stem cells through increasingly restricted intermediates. Networks of transcription factors regulate these cell fate choices and are composed of both ubiquitously expressed and B lineage-specific factors. E-protein transcription factors are encoded by the three genes E2A, E2-2 (SEF2-1), and HEB. The E2A gene is required for B cell development and encodes the alternatively spliced proteins E12 and E47. During B lymphocyte development, the cells have to pass several checkpoints verifying the functionality of their antigen receptors. Early in the development, the expression of a pre-B cell receptor (pre-BCR) with membrane-bound immunoglobulin (Ig) heavy chain protein associated with surrogate light chain (SLC) proteins is a critical checkpoint that monitors for functional Ig heavy chain rearrangement. Signaling from the pre-BCR induces survival and a limited clonal expansion. Here it is shown that pre-BCR signaling rapidly down-regulates the SLCs l5 and VpreB and also the co-receptor CD19. Ca2+ signaling and E2A were shown to be essential for this regulation. E2A mutated in its binding site for the Ca2+ sensor protein calmodulin (CaM), and thus with CaM-resistant DNA binding, makes l5, VpreB and CD19 expression resistant to the inhibition following pre-BCR stimulation. Thus, Ca2+ down-regulates SLC and CD19 gene expression upon pre-BCR stimulation through inhibition of E2A by Ca2+/CaM. A general negative feedback regulation of the pre-BCR proteins as well as many co-receptors and proteins in signal pathways from the receptor was also shown. After the ordered recombination of Ig heavy chain gene segments, also Ig light chain gene segments are recombined together to create antibody diversity. The recombinations are orchestrated by the recombination activating gene (RAG) enzymes, other enzymes that cleave/mutate/assemble DNA of the Ig loci, and the transcription factor Pax5. A key feature of the immune system is the concept that one lymphocyte has only one antigen specificity that can be selected for or against. This requires that only one of the alleles of genes for Ig chains is made functional. The mechanism of this allelic exclusion has however been an enigma. Here pre-BCR signaling was shown to down-regulate several components of the recombination machinery including RAG1 and RAG2 through CaM inhibition of E2A. Furthermore, E2A, Pax5 and the RAGs were shown to be in a complex bound to key sequences on the IgH gene before pre-BCR stimulation and instead bound to CaM after this stimulation. Thus, the recombination complex is directly released through CaM inhibition of E2A. Upon encountering antigens, B cells must adapt to produce a highly specific and potent antibody response. Somatic hypermutation (SH), which introduces point mutations in the variable regions of Ig genes, can increase the affinity for antigen, and antibody effector functions can be altered by class switch recombination (CSR), which changes the expressed constant region exons. Activation-induced cytidine deaminase (AID) is the mutagenic antibody diversification enzyme that is essential for both SH and CSR. The AID enzyme has to be tightly controlled as it is a powerful mutagen. BCR signaling, which signals that good antibody affinity has been reached, was shown to inhibit AID gene expression through CaM inhibition of E2A.  SH increases the antigen binding strength by many orders of magnitude. Each round of SH leads to one or a few mutations, followed by selection for increased affinity. Thus, BCR signaling has to enable selection for successive improvements in antibodies (Ab) over an extremely broad range of affinities. Here the BCR is shown to be subject to general negative feedback regulation of the receptor proteins as well as many co-receptors and proteins in signal pathways from the receptor. Thus, the BCR can down-regulate itself to enable sensitive detection of successive improvements in antigen affinity. Furthermore, the feedback inhibition of the BCR signalosome and most of its protein, and most other gene regulations by BCR stimulation, is through inhibition of E2A by Ca2+/CaM. Differentiation to Ab-secreting plasmablasts and plasma cells is antigen-driven. The interaction of antigen with the membrane-bound Ab of the BCR is critical in determining which clones enter the plasma cell response. Genome-wide analysis showed that differentiation of B cells to Ab-secreting cell is induced by BCR stimulation through very fast regulatory events, and induction of IRF-4 and down-regulation of Pax5, Bcl-6, MITF, Ets-1, Fli-1 and Spi-B gene expressions were identified as immediate early events. Ca2+ signaling through CaM inhibition of E2A was essential for these rapid down-regulations of immediate early genes after BCR stimulation in initiation of plasma cell differentiation.

calcium

calmodulin

e-proteins

E2A

B cell development

antigen receptor signaling

surrogate light chains

RAG

allelic exclusion

V(D)J recombination

AID

negative feedback regulation

plasma cell differentiation

Quelle contribution du centre germinatif et de ses composants moléculaires et cellulaires dans la physiopathologie du lupus ? / What contribution for molecular and cellular germinal center components during lupus development?

Le Coz, Carole

19 September 2014

Le lupus érythémateux disséminé est une maladie auto-immune systémique très invalidante dont les atteintes sont multiples, les plus fréquentes étant cutanées, articulaires et rénales. Dans ce type de maladie, le système immunitaire, hyperactif, ne se limite pas à lutter contre des agents extérieurs mais s'attaque à ses propres cellules, entre autres par le biais d'auto-anticorps. Ces anticorps délétères sont produits par des plasmocytes, cellules issus de la différenciation des lymphocytes B. Ce processus se déroule principalement au sein des centres germinatifs (GC) dans les organes lymphoïdes secondaires, et fait intervenir de nombreux acteurs moléculaires et cellulaires. Mon projet de thèse a porté sur l'étude de la contribution du GC et de ses constituants, tels que les cellules auxiliaires folliculaires (Tfh) et l'IL-21, au cours du lupus. Au cours de ce travail, nous avons mis en évidence une altération à la fois quantitative et qualitative des cellules Tfh chez des patients lupiques et dans un modèle murin, altération entre autres responsable de taux anormalement élevés d'IL-21. Nous avons également observé une sensibilité accrue des cellules B de souris lupiques à cette cytokine, dont la cause est une surexpression de molécules clés telles que STAT3, et dont la conséquence est un surcroit de différenciation plasmocytaire. Tous les éléments sont donc présents pour favoriser l'interaction "Tfh-B" et la réaction du GC, et amplifier la réponse autoimmune. Enfin, la découverte de l'existence de GC ectopiques fonctionnels dans les reins de souris lupiques permet d'envisager l'existence de réponses locales au sein même des organes cibles. Les données obtenues, fondamentales, sont prometteuses et laissent entrevoir de nouvelles perspectives de biothérapies, plus ciblées, pour le traitement de la maladie lupique. / Systemic lupus erythematosus is a disabling chronic autoimmune disease characterized by B cell hyperactivity leading to the production of autoantibodies, some of which exerting pathogenic effects. Autoantibodies are produced by plasma cells, which originate from the differentiation of B cells through a process that mainly takes place in germinal centers (GC) in secondary lymphoïd organs and involves many molecular and cellular parameters. The aim of my PhD project was to analyze the individual contribution of GC components, such as follicular helper T cells (Tfh) and IL-21, to lupus development. During this work, we have shown both a quantitative and qualitative impairment of Tfh cells in lupus patients and in a mouse model, leading, among other things, to high IL-21 levels. We also observed that B cells from lupus mice display a specific intrinsic sensitivity to this cytokine, due to over-expression of key molecules such as STAT3, which results in increased plasma cell differentiation. Thus, all elements are gathered that favor "Tfh-B" cell interactions and the GC reaction, and therefore the autoimmune response. Finally, the discovery of functional ectopic GC in the kidneys of lupus mice allows envisaging that local responses occur within the target organs and likely participate to kidney injury. The fundamental data we obtained are promising and anticipate new and better targeted biotherapies for lupus treatment.

Lupus

Centre germinatif

Différenciation plasmocytaire

Cellules Tfh

IL-21

Organes lymphoïdes tertiaires

Lupus

Germinal center

Plasma cell differentiation

Tfh cells

IL-21

Tertiary lymphoïd organs

571.96