We have shown that high IL-7 transgene (Tg) over-expression (39-fold at day 1 in thymic tissue) under the T cell specific, proximal lck promoter had a dose effect on TCRαβ that was accompanied by active B cell development in the thymus. To further characterize these affects in the thymus of IL-7 transgenic mice, we analyzed thymi from day 18 embryos and newborn Tg mice, as well as fetal thymic organ culture (FTOC) derived from using day 16 embryos. We show that arrested T-cell and increased B-cell thymic development is initiated during fetal development. Using mixed bone marrow chimeras and anti-IL-7 monoclonal antibody injection, we further demonstrate that abnormalities in thymic T and B cell development are non-cell autonomous and are due to IL-7 over-expression. Recently, it was shown that only the early thymocyte progenitor (ETP, c-kit+IL-7R−/lo) fraction within the DN1 subpopulation had a T-cell proliferative potential in contrast to the c-kit−IL-7R+ DN1 subset. Here we show that in Tg mice the ETPs were decreased, while the c-kit−IL-7R+ cells are increased in both percentage and absolute count when compared to normal controls. In order to explore the T vs. B ETP potential, we seeded re-aggregate thymic organ cultures with sorted lin−CD44+CD25−c-kit+IL-7R+ cells. While ETPs derived from normal controls were able to proliferate and produce 83% of DP thymocytes, ETPs sorted from Tg mice developed poorly (10-fold less) into DP cells (30%) and produced 14% of B220+ cells vs. 6% in controls. Moreover, sorted Pro/Pre B derived thymic B cells from Tg mice, but not BM-derived Pro/Pre B cells had the TCRβD-J rearrangement, suggesting a T-specific origin. Since the B-cell differentiation pathway in normal mice is selectively inhibited by thymic presentation of Notch ligands, we hypothesized that IL-7 down-regulates Notch signaling. To test this hypothesis, we analyzed thymocyte progenitors (DN1-DN4) in normal and Tg mice for the intra-cytoplasmic part of Notch, that is cleaved upon Notch/Notch-ligand activation. Notch staining was decreased in the lin−CD44+CD25inter representing the only DN2 population present in these Tg mice. These data favour a decrease of Notch signalling in mice with high IL-7 Tg over-expression, inducing a block in TCRαβ development, and skewing of thymic B cell development by T vs. B lineage subversion. These conclusions may have implications for IL-7 in the clinical setting.
IL-7 is a non-redundant cytokine in T cell development. We studied the role of IL-7 in early T-cell development using a model of transgenic (Tg) mice with the murine IL-7 gene under control of the lck proximal promoter. At high IL-7 over-expression (x39 fold increase at day 1 in total thymic tissue), we observed a disruption of TCRαβ development along with increased B cell development in the thymus (7- to 13-fold increase) (El Kassar, Blood, 2004). In order to further explore abnormal T and B cell thymic development in these mice, we first confirmed that they both arise in parallel and were non-cell autonomous, by in vivo injection of neutralizing anti-IL-7 MAb and mixed bone marrow chimera experiments. Using a six color flow cytometry analysis, we found a dramatic decrease of the early thymocyte progenitors (ETPs, lin−CD44+CD25−c-kithiIL-7R−/lo) in the adult Tg mice (x4.7 fold decrease). Lin−CD44+CD25−c-kit+ thymocytes were sorted and cultured on OP9 and OP9 delta-like1 (OP9-DL1) stromal cells (kindly provided by Pr Zuniga Pflucker). At day 14, we observed an important decrease of T cell development (54% vs. 1% of DP cells) and an increase of NK cells (x5 fold increase) in the Tg-derived DN1 cell culture. DN2 (Lin−CD44+CD25−c-kit+) Tg thymocytes showed the same, but less dramatic abnormalities. While DN1 progenitors developed effectively into B220+CD19+ cells on OP9 stromal cells, no B cell development was observed on OP-DL stromal cells from DN1-Tg derived progenitors or by addition of increasingly high doses of IL-7 (x10, x40, x160) to normal B6-derived DN1 progenitors. Instead, a block of T-cell development was observed with increased IL-7. We hypothesized a down regulation of Notch signaling by IL-7 over-expression and analyzed by FACS Notch expression in the DN thymocytes. By staining the intra-cellular part of Notch cleaved after Notch 1/Notch ligand activation, Tg-derived DN2 cells showed decreased Notch signaling. More importantly, HES expression was decreased in the DN2, DN3 and DN4 fractions by semi-quantitative PCR. Sorted Pro/Pre B cells from Tg thymi showed TCR Dβ1-Jβ1 rearrangement indicating their T specific origin, in opposition to Pro/Pre B cells sorted from the bone marrow of the same mice. We suggest that more than one immature progenitor seeds the thymus from the bone marrow. While ETPs had T and NK proliferative capacity, another thymic progenitor with B potential may be responsible for thymic B cell development in normal and IL-7 Tg mice. Finally, IL-7 over-expression may induce a decreased Notch signaling in thymic progenitors, inducing a switch of T vs. B lineage development.
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