Characterization of TCR gene rearrangements during adult murine T cell development

Development of the alphabeta and gammadelta T cell lineages is dependent upon the rearrangement and expression of the TCRalpha and beta or gamma and delta genes, respectively. Although the timing and sequence of rearrangements of the TCRalpha and TCRbeta loci in adult murine thymic precursors has been characterized, no similar information is available for the TCRgamma and TCRdelta loci. In this report, we show that approximately half of the total TCRdelta alleles initiate rearrangements at the CD44highCD25+ stage, whereas the TCRbeta locus is mainly in germline configuration. In the subsequent CD44lowCD25+ stage, most TCRdelta alleles are fully recombined, whereas TCRbeta rearrangements are only complete on 10-30% of alleles. These results indicate that rearrangement at the TCRdelta locus can precede that of TCRbeta locus recombination by one developmental stage. In addition, we find a bias toward productive rearrangements of both TCRdelta and TCRgamma genes among CD44highCD25+ thymocytes, suggesting that functional gammadelta TCR complexes can be formed before the rearrangement of TCRbeta. These data support a model of lineage commitment in which sequential TCR gene rearrangements may influence alphabeta/gammadelta lineage decisions. Further, because TCR gene rearrangements are generally limited to T lineage cells, these analyses provide molecular evidence that irreversible commitment to the T lineage can occur as early as the CD44highCD25+ stage of development.     

Notch1 and IL-7 receptor interplay maintains proliferation of human thymic progenitors while suppressing non-T cell fates

Notch signaling is critical for T cell development of multipotent hemopoietic progenitors. Yet, how Notch regulates T cell fate specification during early thymopoiesis remains unclear. In this study, we have identified an early subset of CD34high c-kit+ flt3+ IL-7Ralpha+ cells in the human postnatal thymus, which includes primitive progenitors with combined lymphomyeloid potential. To assess the impact of Notch signaling in early T cell development, we expressed constitutively active Notch1 in such thymic lymphomyeloid precursors (TLMPs), or triggered their endogenous Notch pathway in the OP9-Delta-like1 stroma coculture. Our results show that proliferation vs differentiation is a critical decision influenced by Notch at the TLMP stage. We found that Notch signaling plays a prominent role in inhibiting non-T cell differentiation (i.e., macrophages, dendritic cells, and NK cells) of TLMPs, while sustaining the proliferation of undifferentiated thymocytes with T cell potential in response to unique IL-7 signals. However, Notch activation is not sufficient for inducing T-lineage progression of proliferating progenitors. Rather, stroma-derived signals are concurrently required. Moreover, while ectopic IL-7R expression cannot replace Notch for the maintenance and expansion of undifferentiated thymocytes, Notch signals sustain IL-7R expression in proliferating thymocytes and induce IL-7R up-regulation in a T cell line. Thus, IL-7R and Notch pathways cooperate to synchronize cell proliferation and suppression of non-T lineage choices in primitive intrathymic progenitors, which will be allowed to progress along the T cell pathway only upon interaction with an inductive stromal microenvironment. These data provide insight into a mechanism of Notch-regulated amplification of the intrathymic pool of early human T cell progenitors.     

Human alpha beta and gamma delta thymocyte development: TCR gene rearrangements, intracellular TCR beta expression, and gamma delta developmental potential--differences between men and mice

To evaluate the role of the TCR in the alphabeta/gammadelta lineage choice during human thymocyte development, molecular analyses of the TCRbeta locus in gammadelta cells and the TCRgamma and delta loci in alphabeta cells were undertaken. TCRbeta variable gene segments remained largely in germline configuration in gammadelta cells, indicating that commitment to the gammadelta lineage occurred before complete TCRbeta rearrangements in most cases. The few TCRbeta rearrangements detected were primarily out-of-frame, suggesting that productive TCRbeta rearrangements diverted cells away from the gammadelta lineage. In contrast, in alphabeta cells, the TCRgamma locus was almost completely rearranged with a random productivity profile; the TCRdelta locus contained primarily nonproductive rearrangements. Productive gamma rearrangements were, however, depleted compared with preselected cells. Productive TCRgamma and delta rearrangements rarely occurred in the same cell, suggesting that alphabeta cells developed from cells unable to produce a functional gammadelta TCR. Intracellular TCRbeta expression correlated with the up-regulation of CD4 and concomitant down-regulation of CD34, and plateaued at the early double positive stage. Surprisingly, however, some early double positive thymocytes retained gammadelta potential in culture. We present a model for human thymopoiesis which includes gammadelta development as a default pathway, an instructional role for the TCR in the alphabeta/gammadelta lineage choice, and a prolonged developmental window for beta selection and gammadelta lineage commitment. Aspects that differ from the mouse are the status of TCR gene rearrangements at the nonexpressed loci, the timing of beta selection, and maintenance of gammadelta potential through the early double positive stage of development.     

Distinct requirements for IL-7 in development of TCR gamma delta cells during fetal and adult life

TCRgammadelta-transgenic IL-7(-/-) mice were generated to determine whether T cells containing productively rearranged TCRgammadelta genes have additional requirements for IL-7 within the thymus or peripheral lymphoid tissues. Differences in developmental requirements for IL-7 by TCRgammadelta cells were noted and were linked to derivation from fetal- vs adult-type precursors in the thymus. Although TCRgammadelta cells are absent from IL-7(-/-) mice, TCRgammadelta cells were restored to the thymus and periphery by expression of TCRgammadelta transgenes. Endogenous TCRgamma chains were expressed by IL-7(+/-) but not IL-7(-/-) TCRgammadelta-transgenic mice, providing direct support for findings that IL-7 is necessary for rearrangement and expression of TCRgamma genes. The number of TCRgammadelta thymocytes was 10-fold reduced in TCRgammadelta-transgenic IL-7(-/-) embryos; however, adult TCRgammadelta-transgenic IL-7(-/-) or IL-7(+/-) mice had similar numbers of fetal thymus-derived TCRgammadelta cells in their skin. Thus, fetal TCRgammadelta cells required IL-7 for TCR rearrangement, but not for proliferation or survival in the periphery. In contrast, the numbers of TCRgammadelta cells in other tissues of TCRgammadelta-transgenic IL-7(-/-) mice were not completely restored. Moreover, coincident with the transition from the first to second wave of T cell precursors maturing in neonatal thymus, thymus cellularity of TCRgammadelta-transgenic IL-7(-/-) mice dropped significantly. These data indicated that in addition to TCRVgamma gene rearrangement, TCRgammadelta cells differentiating from late fetal liver or adult bone marrow precursors have additional requirements for IL-7. BrdU incorporation studies indicated that although IL-7 was not required for TCRgammadelta cell proliferation, it was required to prolong the life span of mature TCRgammadelta cells.     

Elevated interleukin-9 receptor expression and response to interleukins-9 and -7 in thymocytes during radiation-induced T-cell lymphomagenesis in B6C3F1 mice

Dysregulation of cytokine receptor expression and responsiveness to cytokines is hypothesized to play an important role in the development and expansion of preneoplastic cells or progression of neoplastic cells during the early and late stages of leukemogenesis. To determine the crucial changes in initiated cells that confer significant growth during the early stage of radiation-induced lymphomagenesis, we examined both the expression of receptors for thymus-derived cytokines and thymocyte response to cytokines before the onset of T cell lymphomas in B6C3F1 mice after split-dose irradiation. After irradiation, thymic T cell subsets underwent delayed regeneration consisting of two phases as determined by receptor expression. The first phase occurred within 1 week post-irradiation and was accompanied by transient expansion of T cell subsets strongly expressing receptor genes for IL-1, IL-2, IL-6, IL-7, IL-15, and TNF alpha. The second phase occurred 12 weeks after irradiation and was characterized by increased expression of IL-9R alpha. Thymocytes from non-irradiated control mice were unresponsive to IL-9. However, IL-9 acted synergistically with IL-7 and PHA to stimulate the proliferation of irradiated cells during the second post-irradiation phase. Moreover, these cells showed hyper-responsiveness to IL-7 or PHA alone compared to age-matched non-irradiated control thymocytes. These results suggest that the unusual expression of IL-9 receptors and/or increased responsiveness of thymocytes to cytokines are key processes in the development of radiation-induced T cell lymphomas.     

Cytokine production by mature and immature thymocytes.

We have studied the ability of subpopulations of activated thymocytes to produce four cytokines (IL-2, IL-4, IFN-gamma and TNF-alpha) which are believed to play roles in T cell development. Supernatants from various thymocyte subsets activated with calcium ionophore and PMA were tested for these cytokines. All CD3hi thymocyte subsets (CD4+8-, CD4-8- and CD4-8+) produced high titers of these four cytokines except CD3+4-8+ thymocytes, which did not produce IL-4. In contrast, CD4+8+ thymocytes did not produce any detectable cytokines. CD3-4-8- thymocytes produced IL-2, IFN-gamma, and TNF-alpha (but not IL-4) when activated by calcium ionophore + PMA and IL-1. We then separated CD3-4-8- thymocytes into IL-2R+ and IL-2R-. CD3-4-8-IL-2R+ thymocytes only produced small amounts of IL-2 when activated with calcium ionophore + PMA + IL-1, whereas CD3-4-8-IL-2R- thymocytes did not require IL-1 to produce IL-2, IFN-gamma, and TNF-alpha. Finally, CD4-8+3- thymocytes (an immature population believed to be an intermediate between CD3-4-8- and CD4+8+ thymocytes) only produced marginally detectable levels of IL-2 upon stimulation with calcium ionophore, PMA, and the addition of IL-1 did not result in increased levels of cytokine production. These observations indicate discrete patterns of cytokine production by the subsets studied and suggest specific controls of cytokine gene expression during T cell development.     

The interleukin-7 receptor alpha chain transmits distinct signals for proliferation and differentiation during B lymphopoiesis.

The interleukin 7 receptor (IL7R), which contains a unique alpha chain and a gamma chain shared by other cytokine receptors, is indispensable for normal lymphocyte development. The basis for this role is poorly understood. Here we show that the IL7R alpha chain not only causes progenitors to proliferate, but also has a distinct activity in inducing differentiation. First, we identify a single cytoplasmic tyrosine residue in the IL7R alpha chain that is essential for cell cycle entry and proliferation dependent on phosphatidylinositol 3-kinase. We use a mutant alpha chain in which this residue has been altered to reconstitute B lymphopoiesis by retrovirus-mediated gene transfer in cultures of bone marrow from mice deficient in IL7R alpha chain. The mutation abrogates the proliferation of B-lymphocyte progenitors, but reveals a novel function of the alpha chain in promoting immunoglobulin heavy chain gene rearrangement leading to B-cell differentiation. This function is lost (but proliferation sustained) when the cytoplasmic domain of IL7R alpha is replaced by corresponding sequences from the IL2R, despite the similarity on their signalling mechanisms. Thus, the signals which mediate a differentiative function of the IL7R in B lymphopoiesis are specific and distinct from those causing proliferation.     

Early expression of a functional TCRbeta chain inhibits TCRgamma gene rearrangements without altering the frequency of TCRgammadelta lineage cells

To investigate the consequences of the simultaneous expression in progenitor cells of a TCRgammadelta and a pre-TCR on alphabeta/gammadelta lineage commitment, we have forced expression of functionally rearranged TCRbeta, TCRgamma, and TCRdelta chains by means of transgenes. Mice transgenic for the three TCR chains contain numbers of gammadelta thymocytes comparable to those of mice transgenic for both TCRgamma and TCRdelta chains, and numbers of alphabeta thymocytes similar to those found in mice solely transgenic for a rearranged TCRbeta chain gene. gammadelta T cells from the triple transgenic mice express the transgenic TCRbeta chain, but do not express a TCRalpha chain, and, by a number of phenotypic and molecular parameters, appear to be bona fide gammadelta thymocytes. Our results reveal a remarkable degree of independence in the generation of alphabeta and gammadelta lineage cells from progenitor cells that, in theory, could simultaneously express a TCRgammadelta and a pre-TCR.     

An essential role for the IL-7 receptor during intrathymic expansion of the positively selected neonatal T cell repertoire

Intrathymic T cell development is a multistage process involving discrete phases of proliferation as well as differentiation. From studies on IL-7 or IL-7Ralpha-deficient mice, it is clear that the IL-7 receptor (IL-7R) plays a critical role during the initial stages of intrathymic CD4-8- precursor development. In contrast, the role of IL-7R in later stages of thymocyte development are unclear. Here, we have used various approaches to investigate directly the role of the IL-7R in thymocyte positive selection and the recently described phase of postselection proliferation. First, we show that positive selection involves selective up-regulation of IL-7Ralpha- and IL-7Rgamma-chains, with the majority of CD4+ and CD8+ cells being IL-7R+. Second, MHC class II+ thymic epithelium-which drives postselection proliferation-expresses IL-7 mRNA. Finally, analysis of positive selection and postselection proliferation in thymocytes from IL-7Ralpha-/- neonates shows that positive selection occurs normally, whereas postselection expansion is drastically reduced. Thus, our data provide the first evidence that, as well as playing a role during early phases of thymic development, IL-7R mediates intrathymic expansion of positively selected thymocytes, which may aid in establishment of the neonatal peripheral T cell pool.     

A profound deficiency in thymic progenitor cells in mice lacking Jak3

Humans and mice with genetic deficiencies that lead to loss of signaling through common gamma-chain (gammac)-containing cytokine receptors have severe defects in B and T lymphocytes. In humans, these deficiencies lead to a complete absence of T cells, whereas in mice, small thymuses give rise to normal numbers of peripheral T cells. We have examined the first wave of developing T cells in Jak3-/-, IL-7-/-, and IL-7Ralpha-/- fetal mice, and have found a near absence of thymic progenitor cells. This deficiency is highlighted by the complete inability of Jak3-/- progenitor cells to reconstitute T cell development in the presence of competing wild-type cells. These data clearly demonstrate a strong common basis for the T cell deficiencies in mice and humans lacking gammac/Jak3 signaling pathways.     

In vitro induction of CD8 expression on thymic pre-T cells. I. Transforming growth factor-beta and tumor necrosis factor-alpha induce CD8 expression on CD8- thymic subsets including the CD25+CD3-CD4-CD8- pre-T cell subset.

We previously reported that IL-7 maintains the viability and differentiation potential of CD25 (IL-2R p55) positive CD3-CD4-CD8- thymic pre-T cells in vitro. This culture system is suitable for studying signals that regulate differentiation of T cell precursors in the thymus. In this study, we screened cytokines for their capacity to induce CD4 or CD8 in murine thymic pre-T cells cultured with IL-7. Of 15 cytokines tested, only transforming growth factor (TGF-beta) and TNF-alpha induced CD8 (Lyt-2), while no cytokine was able to induce CD4 on CD25+CD3-CD4-CD8- thymocytes. The combination of TGF-beta and TNF-alpha was synergistic, and the majority of cells recovered after 2 to 3 days in culture expressed CD8 (but not CD3 or CD4). A similar effect of TGF-beta and TNF-alpha was observed using day-15 fetal thymocytes, CD3+CD4-CD8- or CD3+CD4+CD8- adult thymocytes, although the combination of these cytokines resulted in an additive rather than a synergistic effect in these subsets. In contrast, neither TGF-beta nor TNF-alpha induced CD8 expression on splenic CD4+CD8- T cells. These observations suggest a role for these cytokines in the induction of CD8 expression in CD8- thymocyte subsets including CD3-CD4-CD8- thymic pre-T cells.