Using transgenic mice that express a constitutively active version of STAT5b, we demonstrate that STAT5 plays a key role in governing B cell development and T cell homeostasis. STAT5 activation leads to a 10-fold increase in pro-B, but not pro-T, cells. Conversely, STAT5 signaling promotes the expansion of mature αβ T cells (6-fold increase) and γδ and NK T cells (3- to 4-fold increase), but not of mature B cells. In addition, STAT5 activation has dramatically divergent effects on CD8+ vs CD4+ T cells, leading to the selective expansion of CD8+ memory-like T cells and CD4+CD25+ regulatory T cells. These results establish that activation of STAT5 is the primary mechanism underlying both IL-7/IL-15-dependent homeostatic proliferation of naive and memory CD8+ T cells and IL-2-dependent development of CD4+CD25+ regulatory T cells.
Signals initiated by the IL7R are required for B cell development. However, the roles that distinct IL7R-induced signaling pathways play in this process remains unclear. To identify the function of the Raf and STAT5 pathways in IL7R-dependent B cell development, we used transgenic mice that express constitutively active forms of Raf (Raf-CAAX) or STAT5 (STAT5b-CA) throughout lymphocyte development. Both Raf-CAAX and STAT5b-CA mice exhibit large increases in pro-B cells. However, crossing the Raf-CAAX transgene onto the IL7R−/− background fails to rescue B cell development. In contrast, STAT5 activation selectively restores B cell expansion in IL7R−/− mice. Notably, the expansion of pro-B cells in STAT5b-CA mice correlated with an increase in cyclin D2, pim-1, and bcl-xL expression, suggesting that STAT5 directly affects pro-B cell proliferation and survival. In addition, STAT5 activation also restored B cell differentiation in IL7R−/− mice as determined by 1) the restoration of VH Ig gene rearrangement and 2) the appearance of immature and mature B cell subsets. These findings establish STAT5 as the key player entraining B cell development downstream of the IL7R.
The molecular mechanisms regulating lymphocyte lineage commitment remain poorly characterized. To explore the role of the IL7R in this process, we generated transgenic mice that express a constitutively active form of STAT5 (STAT5b-CA), a key downstream IL7R effector, throughout lymphocyte development. STAT5b-CA mice exhibit a 40-fold increase in pro-B cells in the thymus. As documented by BrdU labeling studies, this increase is not due to enhanced B cell proliferation. Thymic pro-B cells in STAT5b-CA mice show a modest increase in cell survival (∼4-fold), which correlates with bcl-xL expression. However, bcl-xL transgenic mice do not show increases in thymic B cell numbers. Thus, STAT5-dependent bcl-xL up-regulation and enhanced B cell survival are not sufficient to drive the thymic B cell development observed in STAT5b-CA mice. Importantly, thymic pro-B cells in STAT5b-CA mice are derived from early T cell progenitors (ETPs), suggesting that STAT5 acts by altering ETP lineage commitment. Supporting this hypothesis, STAT5 binds to the pax5 promoter in ETPs from STAT5b-CA mice and induces pax5, a master regulator of B cell development. Conversely, STAT5b-CA mice exhibit a decrease in the DN1b subset of ETPs, demonstrating that STAT5 activation inhibits early T cell differentiation or lineage commitment. On the basis of these findings, we propose that the observed expression of the IL-7R on common lymphoid progenitors, but not ETPs, results in differential STAT5 signaling within these distinct progenitor populations and thus helps ensure appropriate development of B cells and T cells in the bone marrow and thymic environments, respectively.
Activation of the serine/threonine kinase c-Raf-1 requires membrane localization, phosphorylation, and oligomerization. To study these mechanisms of Raf activation more precisely, we have used a membrane-localized fusion protein, myr-Raf-GyrB, which can be activated by coumermycin-induced oligomerization in NIH3T3 transfectants. By introducing a series of point mutations into the myr-Raf-GyrB kinase domain (S338A, S338A/Y341F, Y340F/Y341F, and T491A/S494A) we can separately study the role that membrane localization, phosphorylation, and oligomerization play in the process of Raf activation. We find that phosphorylation of Ser-338 plays a critical role in Raf activation and that this requires membrane localization but not oligomerization of Raf. Mutation of Tyr-341 had a limited effect, whereas mutation of both Ser-338 and Tyr-341 resulted in a synergistic loss of Raf activation following coumermycin-induced dimerization. Importantly, we found that membrane localization and phosphorylation of Ser-338 were not sufficient to activate Raf in the absence of oligomerization. Thus, our studies suggest that three key steps are required for optimal Raf activation: recruitment to the plasma membrane by GTP-bound Ras, phosphorylation via membrane-resident kinases, and oligomerization.The Ras/Raf/MEK 1 /MAPK signaling pathway plays a key role in regulating cell proliferation and differentiation in a variety of organisms (1). In the absence of stimulation, Ras is found in its inactive GDP-bound state. Recruitment of guanine nucleotide exchange factors to the plasma membrane by activated cytokine or growth factor receptors promotes the exchange of GDP for GTP; this converts Ras to its active GTP-bound state. Ras-GTP activates a number of effector molecules including the serine/ threonine kinase Raf-1. Subsequently, activated Raf-1 phosphorylates MEK, which in turn phosphorylates MAPK. Ultimately, this leads to activation of transcription factors in the nucleus that regulate downstream cellular processes.The mechanisms responsible for Ras, MEK, and MAPK activation are well characterized. In contrast, our understanding of Raf activation remains incomplete. Previous results show that artificial farnesylation of Raf results in its activation (2, 3). This has led to the suggestion that membrane localization is sufficient for Raf-1 activation. Another proposed mechanism for Raf activation involves phosphorylation by membrane resident kinases (4). For example, previous studies (5, 6) have demonstrated that phosphorylation on both serine and tyrosine residues in the Raf kinase domain cooperate to activate Raf-1. Specifically, mutation of Tyr-341 or Ser-338 compromises Raf activation. These residues have been shown to be phosphorylated by membrane resident kinases such as Src/Lck (Tyr-341) or Pak1 and/or Pak3 (Ser-338) (4,7,8). A more recent finding by Chong et al. (9) suggests that two additional sites, Thr-491 and Ser-494, are also important residues in the kinase domain of Raf that contribute to its activation.Although considerabl...
Allelic exclusion prevents pre-B cells from generating more than one functional H chain, thereby ensuring the formation of a unique pre-BCR. The signaling processes underlying allelic exclusion are not clearly understood. IL-7R-dependent signals have been clearly shown to regulate the accessibility of the Ig H chain locus. More recent work has suggested that pre-BCR-dependent attenuation of IL-7R signaling returns the H chain loci to an inaccessible state; this process has been proposed to underlie allelic exclusion. Importantly, this model predicts that preventing pre-BCR-dependent down-regulation of IL-7R signaling should interfere with allelic exclusion. To test this hypothesis, we made use of transgenic mice that express a constitutively active form of STAT5b (STAT5b-CA). STAT5b-CA expression restores V(D)J recombination in IL-7R−/− B cells, demonstrating that IL-7 regulates H chain locus accessibility and V(D)J recombination via STAT5 activation. To examine the effects of constitutively active STAT5b on allelic exclusion, we crossed STAT5b-CA mice (which express the IgMb allotype) to IgMa allotype congenic mice. We found no difference in the percentage of IgMa/IgMb-coexpressing B cells in STAT5b-CA vs littermate control mice; identical results were observed when crossing STAT5b-CA mice with hen egg lysozyme (HEL) H chain transgenic mice. The HEL transgene enforces allelic exclusion, preventing rearrangement of endogenous H chain genes; importantly, rearrangement of endogenous H chain genes was suppressed to a similar degree in STAT5b-CA vs HEL mice. Thus, attenuation of IL-7R/STAT5 signaling is not required for allelic exclusion.
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