Scheduled kinetics of cell proliferation and phenotypic changes during immature thymocyte generation.

Precursor CD4-CD8- (DN) thymocytes rearrange their TCR-beta genes, and only those which succeed in beta-selection subsequently expand and differentiate into immature CD4+CD8+ (DP) thymocytes. The cell subsets corresponding to the successive steps of this transition can be defined in terms of CD44 and CD25 expression. We partially synchronized the differentiation process by eliminating cycling cells with the anti-mitotic agent demecolcine. Using in vivo pulse labeling with bromodeoxyuridine, we determined the order of entry into DNA synthesis of the different DN and transitory (CD4-/lo CD8+) cell subsets. Two independent proliferation phases were identified. The first cells to enter the cell cycle were CD44-CD25lo, and CD4/CD8/TCR-/BrdU four-color staining showed that they all expressed a low density of the TCR-beta chain, an element of the pre-TCR (the TCR-alpha locus is still in germ-line configuration at this stage). Cycling of CD44+CD25+ cells was detected later, and no starting point was observed at the CD44-CD25hi stage. CD8 expression was immediately detectable in cycling cells, but they took 24 h to reach the DP stage. The study of TCR-Calpha-deficient mice showed that beta gene rearrangement occurred once proliferation had ceased at the DP stage, and that it had no influence on the DN-DP transition. These data show that precursor thymocytes undergo two independent waves of expansion, and that the second wave is restricted to cells capable of pre-TCR expression.

Naive CD4(+) lymphocytes convert to anergic or memory-like cells in T cell-deprived recipients.

Recent demonstrations that naive T cells proliferate after transfer to lymphopenic hosts have led to the theory that active homeostatic mechanisms fill the peripheral pool of naive T cells. To extend these data, we injected naive CD4(+) T cells from AND TCR transgenic mice (H-2(b/b) or H-2(k/k)) into CD3 epsilon-deficient mice, and studied the absolute number, phenotype and functional capacities of the transferred lymphocytes, from the first days to a few months after transfer. Proliferation of naive CD4(+) T cells did not fill the peripheral naive T cell pool. Injected naive T cells acquired a memory-like phenotype that was stable with time, despite the absence of foreign antigenic stimulation. Their functional capacities were modified, enhanced or abolished depending on the MHC haplotype. Thus, "homeostatic" proliferation of naive CD4(+) T cells in T cell-deprived recipients does not regenerate the naive CD4(+) T cell pool.

Regulation and kinetics of premigrant thymocyte expansion.

Normal mature thymocytes proliferate before emigrating to the periphery, and continuous bromodeoxyuridine labeling showed that more than 30 % of fully mature thymic emigrants have replicated DNA in the 24 h before exit. The percentage of DNA-synthetizing single-positive (SP) thymocytes is transiently augmented during the postnatal period, with peaks on days 2 and 4 for CD4 and CD8 cells, respectively. Similar kinetics were observed in mouse chimeras made by transfer of normal bone marrow cells into RAG-2-deficient mice. These data show that proliferation of mature thymocytes is developmentally regulated. The proliferation peaks (on days 16 and 18 post transfer) observed in simple bone marrow chimeras were abolished when lymph node T cells were mixed with the bone marrow cell inoculum, suggesting that the peripheral pool controls the late thymic expansion. The phenotype of cycling SP thymocytes is atypical: they do not regulate activation and adhesion surface molecules like peripheral activated T cells.

Distribution of cycling T lymphocytes in blood and lymphoid organs during immune responses.

Proliferation of murine T lymphocytes in blood, lymph nodes, and spleen was studied in four in vivo stimulation systems, using BrdU pulse-labeling of DNA-synthesizing cells. The T cell response to the superantigen Staphylococcus enterotoxin B (SEB) was studied in detail. Vbeta8+ T cells showed a peak of DNA synthesis 16-24 h after SEB injection, and the percentage of BrdU+ CD4 and CD8 T cells was higher in blood than in lymph nodes and spleen. DNA synthesis was preceded by massive migration of Vbeta8+ cells from blood to lymphoid organs, in which the early activation marker CD69 was first up-regulated. SEB-nonspecific Vbeta6+ cells showed minimal stimulation but, when cycling, also expressed a high level of CD69. The other systems studied were injection of the IFN-gamma inducer polyinosinic:polycytidylic acid, infection by the BM5 variants of murine leukemia virus (the causative agent of murine AIDS), and T cell expansion after transfer of normal bone marrow and lymph node cells into recombinase-activating gene-2-deficient mice. In each case, a peak of T cell proliferation was observed in blood. These data demonstrate the extensive redistribution of cycling T cells in the first few hours after activation. Kinetic studies of blood lymphocyte status appear crucial for understanding primary immune responses because cycling and redistributing T lymphocytes are enriched in the circulating compartment.

Timing and casting for actors of thymic negative selection.

We have recently proposed a new model for the differentiation pathway of alphabeta TCR thymocytes, with the CD4 and CD8 coreceptors undergoing an unexpectedly complex series of expression changes. Taking into account this new insight, we reinvestigated the timing of thymic negative selection. We found that, although endogenous superantigen-driven thymic negative selection could occur at different steps during double-positive/single-positive cell transition, this event was never observed among CD4lowCD8low TCRint CD69+ thymocytes, i.e., within the first subset to be generated upon TCR-mediated activation of immature double-positive cells. We confirm a role for CD40/CD40L interaction, and the absence of involvement of CD28 costimulation, in thymic deletion in vivo. Surprisingly, we found that thymic negative selection was impaired in the absence of Fas, but not FasL, molecule expression. Finally, we show involvement in opposing directions for p59fyn and SHP-1 molecules in signaling for thymic negative selection.