Human thymus regeneration and T cell reconstitution

The thymus supports the development of T cells throughout life from hematopoietic progenitor cells migrating from the bone marrow. During the early years after birth thymic activity is highest, but progressively declines resulting in diminished naïve T cell output. Underlying causes of thymic involution may be degeneration of the stromal thymic network, providing survival and differentiation factors for developing T cells, or insufficiency of the progenitor cells to home and/or develop in the aged thymus. In young people the reduced thymic output is insignificant, since the peripheral T cell compartment is under compensatory homeostatic control. However, in more or less immunocompromised individuals, including aged people and patients depleted of T cells due to conditioning regimens before bone marrow transplantation or HIV infection, the thymus is necessary to replenish the peripheral T cell compartment. This may require rejuvenation of the thymus. Alternatively, approaches to generate mature T cells independent of the thymus have gained considerable interes

Delta-like1-induced Notch1 signaling regulates the human plasmacytoid dendritic cell versus T-cell lineage decision through control of GATA-3 and Spi-B

Human early thymic precursors have the potential to differentiate into multiple cell lineages, including T cells and plasmacytoid dendritic cells (pDCs). This decision is guided by the induction or silencing of lineage-specific transcription factors. The ETS family member Spi-B is a key regulator of pDC development, whereas T-cell development is critically dependent on GATA-3. Here we show that triggering of the Notch1 signaling pathway by Delta-like1 controls the T/pDC lineage decision by regulating the balance between these factors. CD34+ CD1a- thymic progenitor cells express Notch1, but down-regulate this receptor when differentiating into pDCs. On coculture with stromal cell lines expressing either human Delta-like1 (DL1) or Jagged1 (Jag1) Notch ligands, thymic precursors express GATA-3 and develop into CD4+ CD8+ TCRalphabeta+ T cells. On the other hand, DL1, but not Jag1, down-regulates Spi-B expression, resulting in impaired development of pDCs. The Notch1-induced block in pDC development can be relieved through the ectopic expression of Spi-B. These data indicate that DL1-induced activation of the Notch1 pathway controls the lineage commitment of early thymic precursors by altering the levels between Spi-B and GATA-

Synergy between IL-15 and Id2 Promotes the Expansion of Human NK Progenitor Cells, Which Can Be Counteracted by the E Protein HEB Required To Drive T Cell Development

The cytokine IL-15 and the inhibitor of DNA binding (Id) 2, which negatively regulates the activity of basic helix-loop-helix transcription factors, have been shown to play key roles in NK cell development. Consistent with this, exogenous IL-15 added to human thymic progenitor cells stimulated their development into NK cells at the expense of T cells both in fetal thymic organ culture and in coculture with stromal cells expressing the Notch ligand Delta-like 1. Overexpression of Id2 in thymic progenitor cells stimulated NK cell development and blocked T cell development. This, in part, is attributed to inhibition of the transcriptional activity of the E protein HEB, which we show in this study is the only E protein that enhanced T cell development. Notably, Id2 increased a pool of lineage CD1a(-)CD5(+) progenitor cells that in synergy with IL-15 furthered expansion and differentiation into NK cells. Taken together, our findings point to a dualistic function of Id2 in controlling T/NK cell lineage decisions; T cell development is impaired by Id2, most likely by sequestering HEB, whereas NK cell development is promoted by increasing a pool of CD1a(-)CD5(+) NK cell progenitors, which together with IL-15 differentiate into mature NK cells. The Journal of Immunology, 2010, 184: 6670-667

Stimulated plasmacytoid dendritic cells impair human T-cell development

Thymic plasmacytoid dendritic cells (pDCs) are located predominantly in the medulla and at the corticomedullary junction, the entry site of bone marrow–derived multipotential precursor cells into the thymus, allowing for interactions between thymic pDCs and precursor cells. We demonstrate that in vitro–generated pDCs stimulated with CpG or virus impaired the development of human autologous CD34+CD1a– thymic progenitor cells into the T-cell lineage. Rescue by addition of neutralizing type I interferon (IFN) antibodies strongly implies that endogenously produced IFN-α/β is responsible for this inhibitory effect. Consistent with this notion, we show that exogenously added IFN-α had a similar impact on IL-7– and Notch ligand–induced development of thymic CD34+CD1a– progenitor cells into T cells, because induction of CD1a, CD4, CD8, and TCR/CD3 surface expression and rearrangements of TCRβ V-DJ gene segments were severely impaired. In addition, IL-7–induced proliferation but not survival of the developing thymic progenitor cells was strongly inhibited by IFN-α. It is evident from our data that IFN-α inhibits the IL-7R signal transduction pathway, although this could not be attributed to interference with either IL-7R proximal (STAT5, Akt/PKB, Erk1/2) or distal (p27kip1, pRb) events

IL-7 Enhances Thymic Human T Cell Development in "Human Immune System" Rag2-/-IL-2R{gamma}c-/- Mice without Affecting Peripheral T Cell Homeostasis

IL-7 is a central cytokine in the development of hematopoietic cells, although interspecies discrepancies have been reported. By coculturing human postnatal thymus hematopoietic progenitors and OP9-huDL1 stromal cells, we found that murine IL-7 is approximately 100-fold less potent than human IL-7 for supporting human T cell development in vitro. We investigated the role of human IL-7 in newborn BALB/c Rag2(-/-)gamma(c)(-/-) mice transplanted with human hematopoietic stem cells (HSC) as an in vivo model of human hematopoiesis using three approaches to improve IL-7 signaling: administration of human IL-7, ectopic expression of human IL-7 by the transplanted human HSC, or enforced expression of a murine/human chimeric IL-7 receptor binding murine IL-7. We show that premature IL-7 signaling at the HSC stage, before entrance in the thymus, impeded T cell development, whereas increased intrathymic IL-7 signaling significantly enhanced the maintenance of immature thymocytes. Increased thymopoiesis was also observed when we transplanted BCL-2- or BCL-x(L)-transduced human HSC. Homeostasis of peripheral mature T cells in this humanized mouse model was not improved by any of these strategies. Overall, our results provide evidence for an important role of IL-7 in human T cell development in vivo and highlight the notion that IL-7 availability is but one of many signals that condition peripheral T cell homeostasi

Frequency of food allergy in school-aged children in eight European countries-The EuroPrevall-iFAAM birth cohort

To access publisher's full text version of this article, please click on the hyperlink in Additional Links field or click on the hyperlink at the top of the page marked DownloadBackground: The prevalence of food allergy (FA) among European school children is poorly defined. Estimates have commonly been based on parent-reported symptoms. We aimed to estimate the frequency of FA and sensitization against food allergens in primary school children in eight European countries. Methods: A follow-up assessment at age 6-10 years of a multicentre European birth cohort based was undertaken using an online parental questionnaire, clinical visits including structured interviews and skin prick tests (SPT). Children with suspected FA were scheduled for double-blind, placebo-controlled oral food challenges (DBPCFC). Results: A total of 6105 children participated in this school-age follow-up (57.8% of 10 563 recruited at birth). For 982 of 6069 children (16.2%), parents reported adverse reactions after food consumption in the online questionnaire. Of 2288 children with parental face-to-face interviews and/or skin prick testing, 238 (10.4%) were eligible for a DBPCFC. Sixty-three foods were challenge-tested in 46 children. Twenty food challenges were positive in 17 children, including seven to hazelnut and three to peanut. Another seventy-one children were estimated to suffer FA among those who were eligible but refused DBPCFC. This yielded prevalence estimates for FA in school age between 1.4% (88 related to all 6105 participants of this follow-up) and 3.8% (88 related to 2289 with completed eligibility assessment). Interpretation: In primary school children in eight European countries, the prevalence of FA was lower than expected even though parents of this cohort have become especially aware of allergic reactions to food. There was moderate variation between centres hampering valid regional comparisons. Keywords: IgE; birth cohort study; epidemiology; food allergy; prevalence.European Commission Joint Research Centr

Spi-B inhibits human plasma cell differentiation by repressing BLIMP1 and XBP-1 expression

The terminal differentiation of B cells into antibody-secreting plasma cells is tightly regulated by a complex network of transcription factors. Here we evaluated the role of the Ets factor Spi-B during terminal differentiation of human B cells. All mature tonsil and peripheral blood B-cell subsets expressed Spi-B, with the exception of plasma cells. Overexpression of Spi-B in CD19+ B cells inhibited, similar to the known inhibitor BCL-6, the expression of plasma cell–associated surface markers and transcription factors as well as immunoglobulin production, ie, in vitro plasma cell differentiation. The arrest in B-cell differentiation enforced by Spi-B was independent of the transactivation domain, but dependent on the Ets-domain. By chromatin immunoprecipitation and assays using an inducible Spi-B construct BLIMP1 and XBP-1 were identified as direct target genes of Spi-B mediated repression. We propose a novel role for Spi-B in maintenance of germinal center and memory B cells by direct repression of major plasma cell factors and thereby plasma cell differentiation