PRDM1/Blimp-1 is expressed in human B-lymphocytes committed to the plasma cell lineage.

PRDM1/Blimp-1 (in human and mouse, respectively) has a central role in determining and shaping the secretory arm of mature B-cell differentiation. In this study, a mouse monoclonal antibody that recognizes PRDM1 was used to detail its distribution in normal human lymphoid tissue and in lymphoid neoplasms that correspond to different stages of B-cell differentiation. PRDM1 was expressed in germinal centre blasts that co-express Pax5, CD19, CD20, and CD10, but not BCL6 or MTA-3. Pax5 was downregulated and full plasma cell morphology and phenotype were acquired by PRDM1+, nuclear cREL-, pre-plasma cells upon exit from the germinal centre. Activated extrafollicular B-cells (CD30+, Pax5+) were largely PRDM1-. PRDM1 was also absent in tissue histiocytes and the majority of resting T-cells and S-100+ antigen-presenting cells. PRDM1 and CD138 were expressed simultaneously in human lymphomas with plasma cell differentiation, but not in marginal zone lymphomas or chronic lymphocytic leukaemias. A minority of diffuse large B-cell lymphomas expressed PRDM1 and Hodgkin lymphomas were largely PRDM1-. Infiltrating T-cells in PRDM1- B-cell lymphomas expressed PRDM1. In conclusion, PRDM1 staining is a reliable and informative assay to define plasma cell commitment and differentiation in human normal and neoplastic B-cell lineages.

Thyroid hormone T3 acting through the thyroid hormone alpha receptor is necessary for implementation of erythropoiesis in the neonatal spleen environment in the mouse.

Thyroid hormones (THs) mediate many physiological and developmental functions in vertebrates. All these functions are mediated by binding of the active form of the TH T3 to the specific nuclear receptors TRalpha and TRbeta, which are transcription factors. Using mutant mice lacking TRs or deficient for TH production, we show that T3 influences neonatal erythropoiesis through TRalpha. The effect of T3 and TRalpha is restricted to this developmental window and is specific for the spleen but not for other erythropoietic organs. We show that T3 via TRalpha affects late steps of erythrocytic development, promoting the proliferation of late basophilic erythroblasts. In vitro, this effect is exerted directly on erythrocytic cells. In vivo, the action of T3 is also intrinsic to spleen erythrocytic progenitors, as shown by grafting experiments of splenocytes derived from wildtype and TRalpha knockout (TRalpha(0/0)) mice into wild-type and TRalpha(0/0) irradiated recipients. Our results indicate that defective spleen erythropoiesis in hypothyroid and TRalpha(0/0) mice results from impaired recognition of the spleen environment by the mutant erythrocytic progenitors. The data presented support a model in which T3 signaling through TRalpha is essential for the implementation of the transient spleen erythropoiesis at birth.

Direct repression of prdm1 by Bcl-6 inhibits plasmacytic differentiation.

We have identified two intronic regions of mouse prdm1, the gene encoding B lymphocyte-induced maturation protein-1 (Blimp-1), which confer transcriptional repression in response to Bcl-6. The Bcl-6 response element in intron 5, which is conserved between mice and humans, was studied in detail. It binds Bcl-6 in vitro and was shown by chromatin immunoprecipitation to be occupied by Bcl-6 in vivo. Neither Bcl-6 response element functions as a STAT3-response element, showing that STAT3 does not compete with Bcl-6 at these sites. Bcl-6(-/-) mice confirm the biological importance of Bcl-6-dependent repression of prdm1. These mice have elevated Ab response, increased Ig-secreting cells, and increased Blimp-1(+) cells in spleen following immunization and their splenic B cells show accelerated plasmacytic development in vitro.

Changes in histone acetylation are associated with differences in accessibility of V(H) gene segments to V-DJ recombination during B-cell ontogeny and development.

Although V(D)J recombination is thought to be regulated by changes in the accessibility of chromatin to the recombinase machinery, the mechanisms responsible for establishing "open" chromatin are poorly understood. We performed a detailed study of the acetylation status of histones associated with 11 V(H) gene segments, their flanking regions, and various intergenic elements during B-cell development and ontogeny, when V(D)J recombination is highly regulated. Histone H4 shows higher and more-regulated acetylation than does histone H3 in the V(H) locus. In adult pro-B cells, V(H) gene segments are acetylated prior to V(D)J rearrangement, with higher acetylation associated with J(H)-distal V(H) gene segments. While large regions of the V(H) locus have similar patterns of histone acetylation, acetylation is narrowly confined to the gene segments, their flanking promoters, and recombinase signal sequence elements. Thus, histone acetylation in the V(H) locus is both locally and globally regulated. Increased histone acetylation accompanies preferential recombination of J(H)-proximal V(H) gene segments in early B-cell ontogeny, and decreased histone acetylation accompanies inhibition of V-DJ recombination in a transgenic model of immunoglobulin heavy-chain allelic exclusion. Thus, changes in histone acetylation appear to be important for both promotion and inhibition of V-DJ rearrangement during B-cell ontogeny and development.

Blimp-1-dependent repression of Pax-5 is required for differentiation of B cells to immunoglobulin M-secreting plasma cells.

B-cell lineage-specific activator protein (BSAP), encoded by the Pax-5 gene, is critical for B-cell lineage commitment and B-cell development but is not expressed in terminally differentiated B cells. We demonstrate a direct connection between BSAP and B-lymphocyte-induced maturation protein 1 (Blimp-1), a transcriptional repressor that is sufficient to drive plasmacytic differentiation. Blimp-1 binds a site on the Pax-5 promoter in vitro and in vivo and represses the Pax-5 promoter in a binding-site-dependent manner. By ectopically expressing Blimp-1 or a competitive inhibitor of Blimp-1, we show that Blimp-1 is both necessary and sufficient to repress Pax-5 during plasmacytic differentiation of primary splenic B cells. Blimp-1-dependent repression of Pax-5 is sufficient to regulate BSAP targets CD19 and J chain and is necessary but not sufficient to induce XBP-1. We further show that repression of Pax-5 is required for Blimp-1 to drive differentiation of splenocytes to immunoglobulin M-secreting cells. Thus, repression of Pax-5 plays a critical role in the Blimp-1-dependent program of plasmacytic differentiation.

An interfering form of Blimp-1 increases IgM secreting plasma cells and blocks maturation of peripheral B cells.

B lymphocyte-induced maturation protein-1 (Blimp-1) can drive plasmacytic differentiation in cultured cell models. To determine the role of Blimp-1 in B cell development in vivo, we have generated transgenic mice expressing an interfering truncated form of Blimp-1 (TBlimp) under the control of an immunoglobulin heavy chain promoter and intronic (E) enhancer. TBlimp-transgenic mice have elevated serum IgM and a prolonged IgM response. This effect is due to an increased number of short-lived, IgM-secreting plasma cells resulting from increased proliferation and prolonged survival. In addition, TBlimp-transgenic mice have a developmental defect in the generation of mature B cells in the spleen. These results show that in vivo Blimp-1 plays a fundamental role in the control of the life span and exit from the cell cycle of IgM secreting plasma cells.