Mice deficient for fibroblast growth factor (Fgf)R2-IIIb show a block in thymic growth after embryonic day 12.5, a stage that just precedes its detection in thymic epithelial cells. Fgf7 and Fgf10, the main ligands for FgfR2-IIIb, are expressed in the mesenchyme surrounding the thymic epithelial primordium, and Fgf10-deficient mice also exhibit impaired thymic growth. Hence, Fgf signaling is essential for thymic epithelial proliferation. In addition to the proliferative block, most thymic epithelial cells fail to progress from an immature cytokeratin 5-positive to a cytokeratin 5-negative phenotype. Nevertheless, sufficient epithelial cell differentiation occurs in the severely hypoplastic thymus to allow the development of CD4/CD8-double-positive thymocytes and a very small number of single-positive thymocytes expressing TCRs.
We show that the mesenchymal cells that surround the 12-d mouse embryo thymus are necessary for T cell differentiation. Thus, epithelial lobes with attached mesenchyme generate all T cell populations in vitro, whereas lobes from which mesenchyme has been removed show poor lymphopoiesis with few cells progressing beyond the CD4−CD8− stage of development. Interestingly, thymic mesenchyme is derived from neural crest cells, and extirpation of the region of the neural crest involved results in impaired thymic development and craniofacial abnormalities similar to the group of clinical defects found in the DiGeorge syndrome.Previous studies have suggested an inductive effect of mesenchyme on thymic epithelial morphogenesis. However, we have found that mesenchyme-derived fibroblasts are still required for early T cell development in the presence of mature epithelial cells, and hence mesenchyme might have a direct role in lymphopoiesis. We provide an anatomical basis for the role of mesenchyme by showing that mesenchymal cells migrate into the epithelial thymus to establish a network of fibroblasts and associated extracellular matrix. We propose that the latter might be important for T cell development through integrin and/or cytokine interactions with immature thymocytes.
Stem cells first enter the thymus around the 11 th to 12 th days of gestation in BALB/c mouse embryos. The phenotype of these stem cells has been difficult to determine because their entry occurs when the thymic primordium is very small and involves too few stem cells to allow studies by flow cytometry. We have been able to microdissect the thymus from embryos during this stage and immunophenotype cells in sections using a sensitive tyra-mide amplification system. Our results show that migrant stem cells express CD45, c-kit, CD44, CD34 and § 4 integrin, but other markers such as CD62L, CD25, Thy-1.2, CD3 4 , § 5 integrin and RAG-1 expression are detected only after stem cell entry. These results should help to improve the isolation and characterization of migrant thymic stem cells.
Stem cells first enter the thymus around the 11th to 12th days of gestation in BALB/c mouse embryos. The phenotype of these stem cells has been difficult to determine because their entry occurs when the thymic primordium is very small and involves too few stem cells to allow studies by flow cytometry. We have been able to microdissect the thymus from embryos during this stage and immunophenotype cells in sections using a sensitive tyramide amplification system. Our results show that migrant stem cells express CD45, c-kit, CD44, CD34 and alpha4 integrin, but other markers such as CD62L, CD25, Thy-1.2, CD3epsilon, alpha5 integrin and RAG-1 expression are detected only after stem cell entry. These results should help to improve the isolation and characterization of migrant thymic stem cells.
The thymus contains an extensive extracellular matrix. Although thymocytes express integrins capable of binding to matrix molecules, the functional significance of the matrix for T cell development is uncertain. We have shown that the matrix is associated with thymic fibroblasts which are required for the CD44 + CD25 + stage of double negative (CD4 -8 -) thymocyte development. The survival of cells at this stage is dependent on IL-7 and we propose that the role of fibroblasts is to present, via the matrix, IL-7 to developing T cells.
We provide evidence that thymocytes receive signals from the thymic microenvironment which regulate the protein kinase C (PKC) signaling pathway. Thus, phorbol 12-myristate 13-acetate (PMA) causes a PKC-dependent down-regulation of CD4 expression and induces apoptosis in isolated thymocytes but has little effect on thymocytes maintained within intact thymic lobes or in reaggregate lobes containing purified thymocytes with either thymic or non-thymic stromal cells. Moreover, compact pellets of thymocytes alone are protected from the effects of PMA. This protection is maintained when the compacted thymocytes are rigorously depleted of MHC class II-expressing cells. We conclude that signals arising from thymocyte-thymocyte contact control the utilization of the PKC cascade. These observations have implications for thymocyte signaling in general as well as for the interpretation of studies carried out on thymocyte suspensions.
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