Nonetheless, the absence of HAX1 did not lead to a complete block

Nonetheless, the absence of HAX1 did not lead to a complete block of B-cell development, as mature B cells were present. However, HAX1 was not required for splenic B-cell proliferation under the stimulation conditions used in vitro and immunoglobulin levels of naïve Hax1−/− mice resembled those Afatinib from WT littermates. These

experimental facts, from our point of view, indicate that the developmental impairment of HAX1-deficient B lymphocytes can most probably be explained by migration defects. Importantly, the observed phenotypes were also not restricted to 10-wk-old Hax−/− mice, which is near their end of life. FACS analysis of B-cell maturation in the bone marrow and spleen of 6-wk-old mice showed a comparable lymphocyte loss (Supporting Information Fig. 1). Thus, B lymphopoiesis is also affected selleck products early in life and the decline is not due to systemic poor health. A characteristic feature of B-cell development in the bone marrow is the migration of developing precursors from early stages nearest the endosteum layer to latter stages progressively closer to the central arteriole, the site of exiting 32. This migration is likely due to differential expression of specific adhesion molecules and chemokine receptors. A critical chemokine in this process is SDF1 (CXCL12), found on bone marrow stromal cells, and its receptor CXCR4 22, expressed by hematopoietic

precursors and B-cell progenitors. Deletion of either the receptor or ligand leads to impairments in B-cell development probably because of failure to retain precursors in the bone marrow 33, 34. Therefore, we analysed Hax1−/− and WT splenic B cells for CXCR4 expression by a real time PCR. Interestingly, compared to Cyclooxygenase (COX) WT B cells, CXCR4 expression was reduced by approximately 70%. However, this fact had no effect on the formation of follicular structures or distributions of B or T cells within these follicles. Nevertheless, migration defects of Hax−/− B cells could

partially be responsible for the observed defects in B-cell development. In parallel, we also tried to analyse the expression of CXCL12 in B- and T-cell-depleted bone marrow cells (data not shown). However, CXCL12 expression even in WT mice was too low to significantly evaluate the amplification products. Alternatively, we speculated about a possible function of the receptor for B-cell-activating factor (BAFFR) because signals through the BAFFR have a significant role in promoting B-cell survival and homeostatic proliferation 23. Signalling through the BCR provides a cell intrinsic measure of B-cell fitness, whereas BAFFR-mediated survival is linked to the cell-extrinsic parameter of primary B-cell population size, i.e. the amount of available BAFF (also known as BlyS) is a measure of unfilled “space” in the B-cell compartment 35, 36.

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