Eosinophils are required for the maintenance of plasma cells in the bone marrow.

Plasma cells are of crucial importance for long-term immune protection. It is thought that long-lived plasma cells survive in specialized niches in the bone marrow. Here we demonstrate that bone marrow eosinophils localized together with plasma cells and were the key providers of plasma cell survival factors. In vitro, eosinophils supported the survival of plasma cells by secreting the proliferation-inducing ligand APRIL and interleukin-6 (IL-6). In eosinophil-deficient mice, plasma cell numbers were much lower in the bone marrow both at steady state and after immunization. Reconstitution experiments showed that eosinophils were crucial for the retention of plasma cells in the bone marrow. Moreover, depletion of eosinophils induced apoptosis in long-lived bone marrow plasma cells. Our findings demonstrate that the long-term maintenance of plasma cells in the bone marrow requires eosinophils.

In silico subtraction approach reveals a close lineage relationship between follicular dendritic cells and BP3(hi) stromal cells isolated from SCID mice.

Organization of the stromal compartments in secondary lymphoid tissue is a prerequisite for an efficient immune reaction. In particular, follicular dendritic cells (FDC) are pivotal for the activation and differentiation of B cells. To investigate the development of FDC, FDC together with tightly associated B cells (FDC networks) were micro-dissected from frozen tissue sections and follicular B cells were sorted by FACS. Using an in silico subtraction approach, gene expression of FDC was determined and compared with that of follicular stromal cells micro-dissected from the spleen of SCID mice. Nearly 90% of the FDC genes were expressed in follicular stromal cells of the SCID mouse, providing further evidence that FDC develop from the residual network of reticular cells. Thus, it suggests that rather minor modifications in the gene expression profile are sufficient for differentiation into mature FDC. The analysis of different immune-deficient mouse strains shows that a complex pattern of gene regulation controls the development of residual stromal cells into mature FDC. The in silico subtraction approach provides a molecular framework within which to determine the diverse roles of FDC in support of B cells and to investigate the differentiation of FDC from their mesenchymal precursor cells.

Systemic activation of the immune system induces aberrant BAFF and APRIL expression in B cells in patients with systemic lupus erythematosus.

OBJECTIVE: Elevated levels of BAFF and APRIL are characteristic of patients with systemic lupus erythematosus (SLE). The reasons for enhanced cytokine production are not well understood. This study was undertaken to identify the cells responsible for the overproduction of these cytokines. METHODS: BAFF expression was analyzed on peripheral blood mononuclear cells by multiparameter flow cytometry and in tissue samples by immunofluorescence staining. The levels of BAFF and APRIL mRNA were quantified in sorted B cells. In vitro cultures were used to analyze whether B cell survival and differentiation was supported by autocrine BAFF and/or APRIL. RESULTS: Aberrant activation of B cells in patients with SLE was associated with a significant up-regulation of BAFF expression in naive, memory, and plasma cells. Furthermore, strong expression of BAFF and APRIL was found in plasma cells from the lymph node, bone marrow, and kidney. The levels of BAFF and APRIL mRNA in CD19+ B cells correlated both with the titer of anti-double stranded DNA antibodies and with the SLE Disease Activity Index. In vitro experiments demonstrated that B cells released functional BAFF/APRIL upon activation. CONCLUSION: Our data show that B cells contribute to the enhanced levels of circulating BAFF and APRIL. The aberrant up-regulation of these cytokines may initiate a vicious circle in which enhanced levels of BAFF and APRIL act in an autocrine manner to reinforce the systemic activation of the humoral immune system.

Diversification of Ig heavy chain genes in human preterm neonates prematurely exposed to environmental antigens.

Preterm neonates are exposed to extrauterine environmental Ags during the time period that corresponds to the last trimester of normal intrauterine development. To study whether this precocious exposure to Ags accelerates the Ig repertoire diversification, we compared IgH chain genes of preterm neonates (gestational age, 25-29 wk) during their first postnatal months with those of term neonates. Preterm infants approaching their expected date of delivery after 8-13 wk of extrauterine life used a similar V(H), D(H), and J(H) gene segment repertoire as term neonates born after intrauterine development. Furthermore, the length increase of the NDN region between V(H) and J(H) by 0.25 nt per gestational week (r = 0.556, p < 0.0001) was not accelerated. Thus, the generation of the V(H) region gene repertoire is developmentally controlled and independent of environmental influences. However, exposure to extrauterine Ags induced class switch and somatic mutations in IgH chain genes within 2 wk after premature birth and IgG transcript diversity and mutational frequency increased with the duration of extrauterine life. Three-month-old preterm infants expressed a heterogeneous IgG repertoire at their expected date of delivery with V(H) region genes carrying significant numbers of somatic mutations with evidence for Ag selection. Term neonates, however, had no such IgG repertoire. We conclude that restrictions in the neonatal Ig V(H) region gene repertoire persist until term despite exposure to environmental Ags. Yet, many weeks before term the immune system of the preterm neonate can already support germinal center reactions in response to environmental Ags.