Interleukin-7 supports survival of T-cell receptor-ß-expressing CD4(-) CD8(-) double-negative thymocytes.

Among the milestones that occur during T-cell development in the thymus is the expression of T-cell receptor-ß (TCR-ß) and the formation of the pre-TCR complex. Signals emanating from the pre-TCR trigger survival, proliferation and differentiation of T-cell precursors. Although the pre-TCR is essential for these cell outcomes, other receptors, such as Notch and CXCR4, also contribute. Whether interleukin-7 (IL-7) participates in promoting the survival or proliferation of pre-TCR-expressing cells is controversial. We used in vitro and in vivo models of T-cell development to examine the function of IL-7 in TCR-ß-expressing thymocytes. Culturing TCR-ß-expressing CD4(-) CD8(-) double-negative thymocytes in an in vitro model of T-cell development revealed that IL-7 reduced the frequency of CD4(+) CD8(+) double-positive thymocytes at the time of harvest. The mechanism for this change in the percentage of double-positive cells was that IL-7 promoted the survival of thymocytes that had not yet differentiated. By preserving the double-negative population, IL-7 reduced the frequency of double-positive thymocytes. Interleukin-7 was not required for proliferation in the in vitro system. To follow this observation, we examined mice lacking CD127 (IL-7Rα). In addition to the known effect of CD127 deficiency on T-cell development before TCR-ß expression, CD127 deficiency also impaired the development of TCR-ß-expressing double-negative thymocytes. Specifically, we found that Bcl-2 expression and cell cycle progression were reduced in TCR-ß-expressing double-negative thymocytes in mice lacking CD127. We conclude that IL-7 continues to function after TCR-ß is expressed by promoting the survival of TCR-ß-expressing double-negative thymocytes.

Gads-deficient thymocytes are blocked at the transitional single positive CD4+ stage.

Positive selection of T-cell precursors is the process by which a diverse T-cell repertoire is established. Positive selection begins at the CD4(+)CD8(+) double positive (DP) stage of development and involves at least two steps. First, DP thymocytes down-regulate CD8 to become transitional single positive (TSP) CD4(+) thymocytes. Then, cells are selected to become either mature single positive CD4(+) or mature single positive CD8(+) thymocytes. We sought to define the function of Gads during the two steps of positive selection by analyzing a Gads-deficient mouse line. In Gads(+/+) mice, most TSP CD4(+) thymocytes are TCR(hi)Bcl-2(hi)CD69(+), suggesting that essential steps in positive selection occurred in the DP stage. Despite that Gads(-/-) mice could readily generate TSP CD4(+) thymocytes, many Gads(-/-) TSP CD4(+) cells were TCR(lo)Bcl-2(lo)CD69(-), suggesting that Gads(-/-) cells proceeded to the TSP CD4(+) stage prior to being positively selected. These data suggest that positive selection is not a prerequisite for the differentiation of DP thymocytes into TSP CD4(+) thymocytes. We propose a model in which positive selection and differentiation into the TSP CD4(+) stage are separable events and Gads is only required for positive selection.

Proliferating CD4+ T cells undergo immediate growth arrest upon cessation of TCR signaling in vivo.

To investigate the role of TCR signaling in the exit of CD4+ T cells from cell cycle, we took advantage of a low frequency TEa T cell adoptive transfer technique as well as the Y-Ae mAb to interrupt Ag/MHC recognition before the completion of clonal expansion. Termination of TCR signaling after 36 h of Ag exposure caused an immediate reduction in cell size and deceleration of G1->SG2M phase cell cycle progression. As a consequence, clonal expansion in the absence of durable TCR signaling decreased by two-thirds. Thus, CD4+ T cells scan for the presence Ag throughout their clonal expansion response, and continuously adjust their rate of cell growth and G1->S phase transition to match their intensity of TCR signaling.

Gads-/- mice reveal functionally distinct subsets of TCRbeta+ CD4-CD8- double-negative thymocytes.

TCRbeta expression in CD4(-)CD8(-) double-negative (DN) thymocytes induces signaling pathways that promote survival and proliferation, as well as differentiation into CD4(+)CD8(+) double-positive thymocytes. The signaling pathways that regulate survival, proliferation, and differentiation remain unclear. We used Gads-deficient mice to investigate the signaling pathways that regulate these cell fates. During this investigation, we focused on TCRbeta(+) DN thymocytes and found that there are at least three functionally distinct subsets of TCRbeta(+) DN thymocytes: TCRbeta(+) DN3E, TCRbeta(+) DN3L, and TCRbeta(+) DN4. Survival and proliferation of TCRbeta(+) DN3E were independent of Gads, but survival and proliferation of TCRbeta(+) DN3L cells were Gads dependent. Likewise, expression of Bcl-2 in TCRbeta(+) DN3E cells was Gads independent, but Gads was necessary for Bcl-2 expression in TCRbeta(+) DN3L cells. Bcl-2 expression was not dependent on Gads in TCRbeta(+) DN4 cells, but proliferation of TCRbeta(+) DN4 cells was Gads dependent. Gads was not required for the differentiation of DN thymocytes into DP thymocytes. In fact, Gads(-/-) DN3E cells differentiated into DP thymocytes more readily than wild-type cells. We conclude that signaling pathways required to initiate TCRbeta-induced survival and proliferation are distinct from the pathways that maintain survival and proliferation. Furthermore, signaling pathways that promote survival and proliferation may slow differentiation.

Gene expression profiling in murine obliterative airway disease.

Lung and heart-lung transplantation are effective treatments for many diseases unresponsive to other therapy. However, long-term survival of recipients is limited by the development of obliterative bronchiolitis (OB). In this study, microarray analysis of a heterotopic mouse model of obliterative airway disease (OAD) was used to test the hypothesis that the expression and patterns of genes will correlate with specific changes in tracheal tissue developing a response to allotransplantation and the infiltrating cells manifesting these changes. Expression profiles observed were in accordance with the current paradigm of a predictable sequence of events, beginning with airway injury; an innate immune response followed by an adaptive immune response, including both cell-mediated and humoral components; and eventual loss of airway epithelial cells. These observations confirm and expand the list of genes and molecular processes that can be studied as potential surrogate markers or targets for intervention of OB.

Sharing of class I MHC molecules between donor and host promotes the infiltration of allografts by mHAg-reactive CD8 T cells.

Indirect recognition of minor histocompatibility antigens (mHAg) and/or MHC-encoded allopeptides is an important barrier to long-term allograft acceptance following solid organ transplantation. Efficient priming of CD8+ T cells can occur after allotransplantation as a consequence of cross-presentation of donor-derived proteins by the graft recipient's APC. Consistent with this, draining lymph node clonal expansion of OVA-reactive OT-I CD8+ T cells following placement of OVA-transgenic skin grafts did not depend on graft expression of K(b). However, OT-I T cells did accumulate in OVA-transgenic skin grafts most efficiently only when both the donor and host expressed K(b). OT-I infiltration of (B6-OVA x BALB/c)F1 grafts in B6 recipients was not suppressed by graft expression of H-2d. Furthermore, B6 animals transplanted with both B6-OVA and BALB/c-OVA skin had more OT-I T cells infiltrating their B6-OVA MHC-matched graft. Therefore, class I MHC matching between donor and host may not always favor an avoidance of alloreactivity within the graft tissue.

Indirect minor histocompatibility antigen presentation by allograft recipient cells in the draining lymph node leads to the activation and clonal expansion of CD4+ T cells that cause obliterative airways disease.

Ag recognition by OVA-reactive OT-II (I-Ab restricted) and DO11.10 (I-Ad restricted) TCR-Tg CD4+ T cells after heterotopic transplantation of OVA transgene-expressing tracheal grafts was examined as a model of minor histocompatibility Ag (mHAg)-induced chronic allograft rejection. In response to airway allotransplantation with grafts expressing the OVA transgene, these TCR-Tg CD4+ T cells expressed the activation markers CD69 and CD44, demonstrated evidence of blastogenesis, underwent multiple rounds of cell division leading to their clonal expansion in the draining lymph node, and proceeded to differentiate to a effector/memory T cell phenotype based on a reduction in the expression of CD45RB. These mHAg-specific TCR-Tg CD4+ T cells responded equally well to fully MHC-mismatched tracheas and to class II-deficient allografts, demonstrating that donor mHAg recognition by recipient CD4+ T cells does not rely on Ag presentation by donor-derived APC. The activation of mHAg-specific TCR-Tg CD4+ T cells after their adoptive transfer into recipient mice given MHC-matched, but mHAg-disparate, airway allografts was associated with their movement into the allograft and the near uniform destruction of the transplanted airway tissue secondary to the development of obliterative airways disease. These results demonstrate that an activation of mHAg-reactive CD4+ T cells in the draining lymph node by recipient APC that indirectly express graft mHAg-derived peptide/class II MHC complexes precedes responder T cell proliferation and differentiation, and leads to the eventual migration of these alloreactive T cells to the transplanted airway tissue and the promotion of chronic graft rejection.

Trachea allograft class I molecules directly activate and retain CD8+ T cells that cause obliterative airways disease.

Human T cells responding against transplanted allogeneic lung tissue have been implicated in late graft failure secondary to obliterative bronchiolitis. This obliterative airways disease (OAD) also develops in heterotopic murine tracheal allografts in association with graft infiltration by both CD8(+) and CD4(+) T cells. To date, there has been little evidence to suggest that directly alloreactive CD8(+) T cells either promote chronic rejection or lead to the development of OAD following airway allotransplantation. Using L(d)-specific TCR-Tg 2C CD8(+) T cells adoptively transferred into wild-type B6 (H-2(b)) mice and the transplantation of BALB/c (H-2(d)) tracheal allografts, we now show that the direct recognition of donor-specific class I MHC molecules by host CD8(+) T cells leads to their activation, clonal expansion within the graft, and differentiation to an effector phenotype with the capacity to induce airway fibrosis. In addition, these experiments demonstrate that ongoing direct alloantigen recognition within the transplanted airway tissue is necessary for the recruitment and retention of these directly alloreactive CD8(+) T cells. Thus, these experiments are the first to definitively show a role for directly alloreactive CD8(+) T cells in the chronic rejection that leads to OAD.