B-1 cells and B-1 cell precursors prompt different responses to Wnt signaling.

Recently several studies demonstrated a role for the Wnt pathway in lymphocyte development and self-renewal of hematopoietic stem cells (HSCs). B-1 cells constitute a separate lineage of B lymphocytes, originating during fetal hematopoiesis, expressing lymphoid and myeloid markers and possessing self-renewal ability, similar to early hematopoietic progenitors and HSCs. A plethora of studies have shown an important role for the evolutionary conserved Wnt pathway in the biology of HSCs and T lymphocyte development. Our previous data demonstrated abundant expression of Wnt pathway components by B-1 cells, including Wnt ligands and receptors. Here we report that the canonical Wnt pathway is activated in B-1 cell precursors, but not in mature B-1 cells. However, both B-1 precursors and B-1 cells are able to respond to Wnt ligands in vitro. Canonical Wnt activity promotes proliferation of B-1 cells, while non-canonical Wnt signals induce the expansion of B-1 precursors. Interestingly, using a co-culture system with OP9 cells, Wnt3a stimulus supported the generation of B-1a cells. Taking together, these results indicate that B-1 cells and their progenitors are differentially responsive to Wnt ligands, and that the balance of activation of canonical and non-canonical Wnt signaling may regulate the maintenance and differentiation of different B-1 cell subsets.

Human CD4(+) effector T lymphocytes generated upon TCR engagement with self-peptides respond defectively to IL-7 in their transition to memory cells.

The peripheral repertoire of CD4(+) T lymphocytes contains autoreactive cells that remain tolerant through several mechanisms. However, nonspecific CD4(+) T cells can be activated in physiological conditions as in the course of an ongoing immune response, and their outcome is not yet fully understood. Here, we investigate the fate of human naive CD4(+) lymphocytes activated by dendritic cells (DCs) presenting endogenous self-peptides in comparison with lymphocytes involved in alloresponses. We generated memory cells (Tmem) from primary effectors activated with mature autologous DCs plus interleukin (IL)-2 (Tmauto), simulating the circumstances of an active immune response, or allogeneic DCs (Tmallo). Tmem were generated from effector cells that were rested in the absence of antigenic stimuli, with or without IL-7. Tmem were less activated than effectors (demonstrated by CD25 downregulation) particularly with IL-7, suggesting that this cytokine may favour the transition to quiescence. Tmauto and Tmallo showed an effector memory phenotype, and responded similarly to polyclonal and antigen-specific stimuli. Biochemically, IL-7-treated Tmallo were closely related to conventional memory lymphocytes based on Erk-1/2 activation, whereas Tmauto were more similar to effectors. Autologous effectors exhibited lower responses to IL-7 than allogeneic cells, which were reflected in their reduced proliferation and higher cell death. This was not related to IL-7 receptor expression but rather to signalling deficiencies, according to STAT5 activation These results suggest that ineffective responses to IL-7 could impair the transition to memory cells of naive CD4(+) T lymphocytes recognizing self-peptides in the setting of strong costimulation.

Enhanced Th17 phenotype in individuals with generalized anxiety disorder.

The generalized anxiety disorder (GAD) is often a debilitating chronic condition, characterized by long-lasting anxiety that is not focused on any object or situation. Besides being clearly linked to increased susceptibility to infectious diseases, anxiety is also known to contribute to the pathogenesis of many inflammatory/autoimmune disorders. The present work aimed to explore the T cell profile following in vitro activation in cultures obtained from a group of individuals with GAD, comparing them with healthy control individuals. Our results demonstrated that cell cultures from GAD group proliferated less following T cell activation as compared with the control group. The analysis of the cytokine profile revealed Th1 and Th2 cytokine deficiencies in the anxious group, as compared with the control subjects. On the other hand, this cellular and humoral immune damage was followed by enhanced production of Th17-derived cytokines. In particular, the levels of TNF-α and IL-17 were significantly higher in cell cultures containing activated T cells from GAD individuals. Therefore, besides a deficiency on Th1 phenotype, an elevated proinflammatory status of these individuals might be related to both glucocorticoid immune resistance and lower IL-10 levels produced by activated T cells. In conclusion, our results demonstrated a T cell functional dysregulation in individuals with GAD, and can help to explain the mechanisms of immune impairment in these subjects and their relationship with increased susceptibility to infections and autoimmune diseases.

Selective blockade of lymphopoiesis induced by kalanchosine dimalate: inhibition of IL-7-dependent proliferation.

Lymphopoiesis and myelopoiesis continuously generate mature cells from hematopoietic cell progenitors during the lifetime of the organism. The identification of new endogenous or exogenous substances that can act specifically on the differentiation of distinct cell lineages is of relevance and has potential therapeutical use. Kalanchoe brasiliensis (Kb) is a medicinal plant from the Crassulaceae family, used in folk medicine to treat inflammatory and infectious diseases. Here, we show that short-term treatment of naïve mice with Kb led to a strong and selective inhibition of lymphopoiesis, affecting B and T cell lineages without reduction of the myeloid lineage development. Similar effects were observed after treatment with the highly purified compound kalanchosine dimalate (KMC), obtained from Kb. Numbers of mature lymphocytes in secondary lymphoid organs were preserved in Kb(KMC)-treated mice. The effect of Kb(KMC) was not a result of secondary augmentation of plasma levels of endogenous corticoids; neither involves TNF-alpha, type-I IFN, or TLR2/TLR4 ligands, which have all been described as selective inhibitors of lymphopoiesis. Flow cytometry analysis of the phenotypes of T and B cell precursors indicate a blockade of maturation on IL-7-dependent, proliferative stages. In vitro, Kb(KMC) inhibited the IL-7-dependent proliferation of pre-B cells and does not induce massive apoptosis of B and T cell precursors. These results suggest that Kb(KMC) is selectively blocking lymphopoiesis through a mechanism that does not involve the previously characterized substances, possibly acting on the IL-7 signaling pathway, opening new perspectives for a potential therapeutic use of Kb-derived drugs.

Modulation of CD44 in acute lymphoblastic leukemia identifies functional and phenotypic differences of human B cell precursors.

CD44 expression and other B cell markers were analyzed in 38 samples of B cell precursors (BCP) from patients with acute lymphoblastic leukemia (ALL). According to the expression of CD10 and CD44, we established the following five stages of BCP-ALL phenotypes that may represent different forms of interaction between BCP-ALL and bone marrow-adherent cells: stage 1, CD19+, CD44bright, CD10-; stage 2, CD19+, CD44bright, CD10dim/bright; stage 3, CD19+, CD44dim, CD10bright, CD20-/+; stage 4, CD19+, CD44dim, CD10dim, CD20+; and stage 5, CD19+, CD44bright, CD10-, CD20+. Next, we analyzed the modulation of CD44 according to the expression of the different BCP-ALL phenotypes by incubating the samples under different culture conditions, including addition of stromal cells and interleukin (IL)-7. In culture, the samples in stages 1 and 2 maintained high expression of CD44 and re-expressed this molecule when cultured after trypsin treatment, indicating ongoing synthesis of CD44. Similarly, the stage 3 samples cultured in the presence of stromal cells, IL-7, or both also upregulated CD44 expression in culture. In contrast, the low expression of CD44 on the presumably more mature stage 4 samples was not modified by the addition of stromal cells or IL-7 or when cultured after trypsin treatment, suggesting that those cells had arrested CD44 synthesis. We concluded that down-modulation of CD44 occurred in association with differentiation to phenotype stages 3 and 4 and we hypothesized that this down-modulation might be associated with the exit of BCP-ALL from the bone marrow.

Localization of the human gene for Src-related protein tyrosine kinase LYN to chromosome 8q11-12: a lymphoid signaling cluster?

A member of the Src family of protein tyrosine kinases, Lyn is involved in the signaling pathways for cytokine or immunoglobulin-stimulated blood cells. Lyn is especially prominent in B-cell function. We have fine mapped LYN to chromosome 8q11-12 by fluorescence in situ hybridization. Of note, the gene for the pre-B cell growth factor, interleukin 7 (IL-7), has been mapped to 8q12-13. We show that IL-7 increases the protein tyrosine kinase activity of Lyn in the Daudi B-cell line. A third gene, HYRC, whose product may be involved in immunoglobulin rearrangement, has recently been localized to 8q11. We postulate that a lymphoid signaling region exists at 8q11-13.

Use of a modified Transwell culture to quantitate the contribution of non-IL-7 substances to growth of an IL-7-dependent pre-B cell clone.

Clone 3 is a mouse pre-B cell line that cannot grow in standard tissue culture media but is immortalized by coculture with a bone marrow-derived feeder layer. In addition, clone 3 cells can be passaged indefinitely in recombinant interleukin-7 (IL-7) in the absence of a feeder layer if maintained at high cell density. Using monoclonal antibody to IL-7 and Transwells ligated to dialysis membranes, we have examined the relative contributions of IL-7, both endogenous and exogenous, and of "non-IL-7" feeder layer factors to growth promotion of clone 3 cells. There is synergy between feeder layers and exogenous IL-7 that is most marked when the latter is present in suboptimal concentrations. The synergizing activity is not neutralized by antibody to IL-7 and appears to be freely dialyzable. This "non-IL-7" effect is common to two different feeder layers, the one derived from bone marrow (3E) being an IL-7 producer, and the other, 3T3 fibroblasts, making no detectable IL-7. These experiments reveal a substantial contribution of the dialyzable moiety to the total feeder layer effect, and are the first to demonstrate cytokine-dependent low-molecular-weight synergy in a coculture. This demonstration is possible because the synergizing cofactor(s) can cross a semipermeable membrane whereas the cytokine and its neutralizing antibody cannot.