Diminished pheromone-induced sexual behavior in neurokinin-1 receptor deficient (TACR1(-/-)) mice.

Studies in mice with targeted deletions of tachykinin genes suggest that tachykinins and their receptors influence emotional behaviors such as aggression, depression and anxiety. Here, we investigated whether TAC1- and TAC4-encoded peptides (substance P and hemokinin-1, respectively) and the neurokinin-1 receptor (NK-1R) are involved in the modulation of sexual behaviors. Male mice deficient for the NK-1R (TACR1 (-/-)) exhibited decreased exploration of female urine in contrast to C57BL/6 control mice and mice deficient for NK-1R ligands such as TAC1 (-/-), TAC4 (-/-) and the newly generated TAC1 (-/-) /TAC4 (-/-) mice. In comparison to C57BL/6 mice, mounting frequency and duration were decreased in male TACR1 (-/-) mice, while mounting latency was increased. Decreased preference for sexual pheromones was also seen in female TACR1 (-/-) mice. Furthermore, administration of the NK-1R-antagonist L-703,606 decreased investigation of female urine by male C57BL/6 mice, suggesting an involvement of NK-1R in urine sniffing behavior. Our results provide evidence for the NK-1R in facilitating sexual approach behavior, as male TACR1 (-/-) mice exhibited blunted approach behavior toward females following the initial interaction compared with C57BL/6 mice. NK-1R signaling may therefore play an important role in pheromone-induced sexual behavior.

Stromal cells attract B-cell progenitors to promote B-cell-B-cell contact and maturation.

The in vitro differentiation of B-lineage progenitors into Ig-secreting mature B cells has classically required a co-culture system containing lipopolysaccharide (LPS) and stromal cells. We have previously showed that B-lineage progenitors cultured in round-bottomed wells can mature and secrete immunoglobulin M (IgM) on par with cultures containing stromal cells. This clearly demonstrates that any factors essential for progenitor cell maturation can be found in cultures containing media, serum, LPS and B-cell progenitors. However, stromal cells are important for the maturation observed when cells are cultured in flat-bottomed wells. We hypothesized that stromal cells may attract B-cell progenitors and promote contacts between responsive cells, a phenomenon that is mimicked by the cultures in round-bottomed wells. In this study, we explore how stromal cells accomplish these functions. We show that stromal cells attract B-cell progenitors in a pertussis toxin-sensitive manner. The stromal cell line S17 produces the chemokine CXCL12, which is able to induce the chemotaxis of B-lineage progenitors. Chemotaxis can be blocked by a small peptide inhibitor (T134) of CXCR4, the CXCL12 receptor. Further, disrupting chemotaxis can reduce the supportive role played by S17 when B-lineage progenitors are cultured in flat-bottomed wells.

Pre-B cell receptor signaling mediates selective response to IL-7 at the pro-B to pre-B cell transition via an ERK/MAP kinase-dependent pathway.

B lymphocyte development is regulated at multiple checkpoints, mediated by signals originating both inside and outside the cell. Two signaling pathways known to be essential in this process are interleukin-7 (IL-7) and the pre-B cell receptor (pBCR). We have shown previously that these signaling pathways intersect functionally. Specifically, response to low concentrations of IL-7 requires pBCR expression. In this report, we identify the ERK/MAP kinase pathway as a key regulatory component of this response. We propose a molecular mechanism for the selective expansion of pBCR(+) precursors and for the culling of inappropriately rearranged pro-B cells.

The role of homotypic interactions in the differentiation of B cell precursors.

Numerous studies have demonstrated that B lymphopoiesis is dependent upon a stromal cell microenvironment. Many of the stromal cell-derived factors and cell surface interactions that regulate B cell development have been identified; however, little consideration has been paid to the intimate interactions known to occur among B cell precursors themselves in both the fetal liver and marrow microenvironments. In this study we show that homotypic interactions between B cell precursors play an important role in promoting the development of mature B cells. We used an in vitro assay system to demonstrate that the function of stromal cells can be replaced by culturing B cell precursors in proximity. B cell precursors isolated from bcl-2 transgenic mice were used to rule out the possibility that improved survival, hypothesized to result from culturing precursors in proximity, solely accounted for the observed increase in B cell maturation. The putative maturation signal(s) were shown to be dependent upon direct contact between precursors rather than the release of soluble factors from nearby cells. Upon examination of the potential role of several known cell surface proteins, we found that blocking mu heavy chains with monovalent Fab antibody fragments dramatically inhibited maturation, in a stage-specific manner. Together these results suggest that a major function of stromal cells in vivo may be to act as a docking site to promote critical preB-preB homotypic interactions and ensuing signals. Further, the antibody blocking experiments raise the interesting possibility that interactions between B cell precursors themselves may promote and/or regulate preB cell receptor-driven signals.

The role of the preBCR, the interleukin-7 receptor, and homotypic interactions during B-cell development.

Considerable progress has been made in defining intermediate stages in the process leading from stem cells to mature B cells. Cell-bound and secreted molecules direct the progression through these stages and regulate the selection of clones from which the immune repertoire emerges. In fact, a myriad of signals derived from B-cell progenitors themselves and the microenvironment in which they develop direct the differentiation process. These signals are provided by B-cell antigen receptors (BCR) and their surrogates, and by adhesion and cytokine receptors. The co-operation of these receptors to control survival, expansion, and differentiation of early B-cell progenitors is the topic of this review. Specifically, we will summarize recent findings from our laboratory demonstrating that preBCR expression lowers the threshold for interleukin (IL)-7 responsiveness. How signals initiated by these receptors may intersect at this critical point of B-cell selection will be discussed. At the stage following IL-7 responsiveness we have shown that interactions between B-cell progenitors themselves promote their differentiation to immunoglobulin-secreting B cells. We propose that one function of stromal cells, known to be central to B lymphopoiesis, is to promote critical preB-preB homotypic interactions and ensuing signals.

Hemokinin is a hematopoietic-specific tachykinin that regulates B lymphopoiesis.

We report here the molecular cloning of a newly identified preprotachykinin gene, Pptc, which specifies the sequence for a new preprotachykinin protein and bioactive peptide designated hemokinin 1 (HK-1). PPT-C mRNA was detected primarily in hematopoietic cells in contrast to the previously described Ppta and Pptb genes, which are predominantly expressed in neuronal tissues. HK-1 has several biological activities that are similar to the most studied tachykinin, substance P, such as induction of plasma extravasation and mast cell degranulation. However, HK-1 also has properties that are indicative of a critical role in mouse B cell development. HK-1 stimulated the proliferation of interleukin 7-expanded B cell precursors, whereas substance P had no effect. HK-1, but not substance P, promoted the survival of freshly isolated bone marrow B lineage cells or cultured, lipopolysaccharide-stimulated pre-B cells. N-acetyl-L-trytophan-3,5-bistrifluromethyl benzyl ester, a tachykinin receptor antagonist, increased apoptosis of these cells and in vivo administration of this antagonist led to specific reductions of the B220lowCD43 population (the pre-B cell compartment) in the bone marrow and the IgMhighIgDlow population (the newly generated B cells) in the spleen. Thus, HK-1 may be an autocrine factor that is important for the survival of B cell precursors at a critical phase of development.

B cell development in the spleen takes place in discrete steps and is determined by the quality of B cell receptor-derived signals.

Only mature B lymphocytes can enter the lymphoid follicles of spleen and lymph nodes and thus efficiently participate in the immune response. Mature, long-lived B lymphocytes derive from short-lived precursors generated in the bone marrow. We show that selection into the mature pool is an active process and takes place in the spleen. Two populations of splenic B cells were identified as precursors for mature B cells. Transitional B cells of type 1 (T1) are recent immigrants from the bone marrow. They develop into the transitional B cells of type 2 (T2), which are cycling and found exclusively in the primary follicles of the spleen. Mature B cells can be generated from T1 or T2 B cells. Mice with genetic deletions of elements participating in the B cell receptor signaling cascade display developmental arrest at the T1 or T2 stage. The analysis of these defects showed that the development of T2 and mature B cells from T1 precursors requires defined qualitative and quantitative signals derived from the B cell receptor and that the induction of longevity and maturation requires different signals.

TRAF6 deficiency results in osteopetrosis and defective interleukin-1, CD40, and LPS signaling.

Bone resorption and remodeling is an intricately controlled, physiological process that requires the function of osteoclasts. The processes governing both the differentiation and activation of osteoclasts involve signals induced by osteoprotegerin ligand (OPGL), a member of tumor necrosis factor (TNF) superfamily, and its cognate receptor RANK. The molecular mechanisms of the intracellular signal transduction remain to be elucidated. Here we report that mice deficient in TNF receptor-associated factor 6 (TRAF6) are osteopetrotic with defects in bone remodeling and tooth eruption due to impaired osteoclast function. Using in vitro assays, we demonstrate that TRAF6 is crucial not only in IL-1 and CD40 signaling but also, surprisingly, in LPS signaling. Furthermore, like TRAF2 and TRAF3, TRAF6 is essential for perinatal and postnatal survival. These findings establish unexpectedly diverse and critical roles for TRAF6 in perinatal and postnatal survival, bone metabolism, LPS, and cytokine signaling.

Extensive junctional diversity in Ig light chain genes from early B cell progenitors of mu MT mice.

Nontemplated (N) nucleotide additions contribute significantly to the junctional diversity of all Ag receptor chains in adult mice except Ig light (L) chains, primarily because terminal deoxynucleotidyl transferase (TdT) expression is turned off at the time of their rearrangement in pre-B cells. However, because some Ig L chain gene rearrangements are detectable earlier during B cell ontogeny when TdT expression is thought to be maximal, we have examined the junctional processing of kappa- and lambda-chain genes of CD45(B220)+CD43+ pro-B cells from mu MT mice. We found that both kappa and lambda coding junctions formed in these B cell precursors were extensively diversified with N-region additions. Together, these findings demonstrate that Ig L chain genes are equally accessible to TdT in pro-B cells as Ig heavy chain genes. Surprisingly, however, the two L chain isotypes differed in the pattern of N addition, which was more prevalent at the lambda-chain locus. We observed the same diversity pattern in pre-B cells from TdT-transgenic mice. These results suggest that some aspects of TdT processing could be influenced by factors intrinsic to the sequence of Ig genes and/or the process of V(D)J recombination itself.

Modulation of the IL-7 dose-response threshold during pro-B cell differentiation is dependent on pre-B cell receptor expression.

The IL-7R and the pre-B cell receptor (pre-BCR) each provide critical signals during differentiation of B cell precursors. In this study we examine the interplay between signals dependent upon these receptors. We demonstrate that pre-BCR-deficient pro-B cells differ significantly from controls in their ability to use the IL-7R. We show that this difference, characterized by a failure to proliferate in response to IL-7, is narrowly restricted to IL-7 concentrations in the picogram per milliliter range and can be overcome with increasing amounts of IL-7. Restoration of Ig heavy chain to recombinase-activating gene-2-deficient pro-B cells leads to a restored response to picogram per milliliter levels of IL-7, providing strong evidence that modulation of the IL-7 dose-response threshold is dependent on pre-BCR. Culture of normal pro-B cells under low IL-7 conditions leads to selective outgrowth of cells expressing mu heavy chain, suggesting that modulation of IL-7 dose-response thresholds can allow for selective expansion of pre-BCR+ cells under conditions where IL-7 is limiting. We also provide evidence that expression of pre-BCR on pro-B cells limits the duration of IL-7 responsiveness by causing differentiation to an IL-7-unresponsive pre-B cell stage. Thus, the pre-BCR-dependent modulation of IL-7 responsiveness affects both the dose-response threshold and the duration of IL-7-induced clonal expansion. Our results suggest that positive selection of pre-BCR+ pro-B cells may be achieved through the fine tuning of IL-7 responses.

Terminal deoxynucleotidyl transferase expression during neonatal life alters D(H) reading frame usage and Ig-receptor-dependent selection of V regions.

During neonatal life, Ig diversity is limited in many respects. The absence of terminal deoxynucleotidyl transferase (TdT) expression with the consequent lack of nontemplated addition during the neonatal period, coupled with the predominant usage of a single D(H) reading frame (RF), leads to severe limitations of diversity in the CDR3 region of Ig heavy (H) chains. The neonatal Ig H chain repertoire is also characterized by restricted V(H) usage, with predominant expression of certain V(H) segments, such as V(H)81x, that are rarely evident during adult life. In this report, we examine the effect of enforced TdT expression on the neonatal repertoire of V(H)81xDJ(H) rearrangements. We find that TdT synthesis abrogates D(H) RF bias during the fetal/neonatal period through a Ig-receptor-independent mechanism. These findings suggest that D(H) RF bias during neonatal life is determined largely by homology-directed joining. We also find that TdT synthesis alters the selection of productively rearranged V(H)81xDJ(H) alleles in the neonatal spleen through a Ig-receptor-dependent mechanism. Analysis of predicted CDR3 amino acid sequences indicates that positive selection of V(H)81x-encoded H chains is correlated with the presence of a consensus sequence immediately adjacent to the V(H) segment. These data support the hypothesis that the CDR3 region is critical in determining the ability of V(H)81x-encoded H chains to form functional receptors that support positive selection of B lymphocytes. Together, our results demonstrate that TdT can indirectly influence the Ig repertoire by influencing both receptor-dependent and receptor-independent selection processes.

Stromal cell-independent maturation of IL-7-responsive pro-B cells.

The proliferation, survival, and differentiation of B cell progenitors in primary hematopoietic tissues depends on extracellular signals produced by stromal cells within the microenvironment. IL-7 is a stromal-derived growth factor that plays a crucial role in B lineage development. We have shown that in the presence of IL-7, pro-B cells proliferate and differentiate to a stage in which they are responsive to stromal cells and LPS, leading to terminally differentiated IgM-secreting plasma cells. In this report, we examine in detail the role of stromal cells in the transition from the IL-7-responsive pro-B cell stage to the mature LPS-responsive B cell stage. We demonstrate that this transition fails to occur, even in the presence of stromal cells and LPS, if constant exposure to IL-7 is maintained. The transition from the large pro-B cell stage to the small cmu+ pre-B cell stage occurs independent of stromal cells. Moreover, the "stromal cell-dependent" maturation that occurs subsequent to the expression of surface IgM leading to responsiveness to B cell mitogens can also be accomplished in the absence of stromal cells if pre-B cells are cultured in proximity to each other or at high cell concentrations. Together these results suggest that stromal cells mediate B cell differentiation by providing the necessary growth requirements (i.e., IL-7) to sustain the development of pre-B cells. The progeny of these pre-B cells can then differentiate through as yet unidentified homotypic interactions, leading to the production of LPS-responsive B cells.

Analysis of murine CD22 during B cell development: CD22 is expressed on B cell progenitors prior to IgM.

CD22 is a B cell-restricted glycoprotein involved in cell adhesion and signaling. Since CD22 is likely to play an important role in interactions between B cells and other cells, and in regulating signaling thresholds, we characterized the expression of murine CD22 during different stages of B cell development. In contrast to previous reports, we show that CD22 is expressed on B cell progenitors prior to expression of IgM. IL-7-responsive B cell precursors from the fetal liver and early B lineage cells (B220+IgM-) from the bone marrow both express a low density of surface CD22. The majority of the earliest B cell progenitors (B220+IgM-CD43+) in the bone marrow, however, do not express CD22. As B cells mature, the density of CD22 molecules on the cell surface increases. B220brightIgM+ bone marrow cells express high levels of CD22, as do splenic B cells. The correlation of CD22 levels with B cell maturation is replicated in an in vitro culture system, which distinguishes stages of B cell development based on function. Following activation of mature resting splenic B cells with anti-mu mAb or lipopolysaccharide (LPS), levels of CD22 decrease. Finally, we show that the addition of anti-CD22 mAb augments the proliferative response of both anti-mu- and LPS-stimulated B cells, suggesting a role for CD22 in diverse signaling pathways.

CD44 regulates hematopoietic progenitor distribution, granuloma formation, and tumorigenicity.

CD44 is expressed in various isoforms on numerous cell types and tissues during embryogenesis and in the mature organism. CD44 may also be involved in tumor growth. To study the multiple roles of CD44, we abolished expression of all known isoforms of CD44 in mice by targeting exons encoding the invariant N-terminus region of the molecule. Surprisingly, mice were born in Mendelian ratio without any obvious developmental or neurological deficits. Hematological impairment was evidenced by altered tissue distribution of myeloid progenitors with increased levels of colony-forming unit-granulocyte-macrophage (CFU-GM) in bone marrow and reduced numbers of CFU-GM in spleen. Fetal liver colony-forming unit-spleen and granulocyte colony-stimulating factor mobilization assays, together with reduced CFU-GM in peripheral blood, suggested that progenitor egress from bone marrow was defective. In what was either a compensatory response to CD44 deficiency or an immunoregulatory defect, mice also developed exaggerated granuloma responses to Cryotosporidium parvum infection. Finally, tumor studies showed that SV40-transformed CD44-deficient fibroblasts were highly tumorigenic in nude mice, whereas reintroduction of CD44s expression into these fibroblasts resulted in a dramatic inhibition of tumor growth.

The motheaten mutation rescues B cell signaling and development in CD45-deficient mice.

The cytosolic SHP-1 and transmembrane CD45 protein tyrosine phosphatases (PTP) play critical roles in regulating signal transduction via the B cell antigen receptor (BCR). These PTPs differ, however, in their effects on BCR function. For example, BCR-mediated mitogenesis is essentially ablated in mice lacking CD45 (CD45(-)), but is enhanced in SHP-1-deficient motheaten (me) and viable motheaten (mev) mice. To determine whether these PTPs act independently or coordinately in modulating the physiologic outcome of BCR engagement, we assessed B cell development and signaling in CD45-deficient mev (CD45-/SHP-1-) mice. Here we report that the CD45-/SHP-1-) cells undergo appropriate induction of protein kinase activity, mitogen-activated protein kinase activation, and proliferative responses after BCR aggregation. However, BCR-elicited increases in the tyrosine phosphorylation of several SHP-1-associated phosphoproteins, including CD19, were substantially enhanced in CD45-/SHP-1-, compared to wild-type and CD45- cells. In addition, we observed that the patterns of cell surface expression of mu, delta, and CD5, which distinguish the PTP-deficient from normal mice, are largely restored to normal levels in the double mutant animals. These findings indicate a critical role for the balance of SHP-1 and CD45 activities in determining the outcome of BCR stimulation and suggest that these PTPs act in a coordinate fashion to couple antigen receptor engagement to B cell activation and maturation.

Identification of a novel developmental stage marking lineage commitment of progenitor thymocytes.

Bipotent progenitors for T and natural killer (NK) lymphocytes are thought to exist among early precursor thymocytes. The identification and functional properties of such a progenitor population remain undefined. We report the identification of a novel developmental stage during fetal thymic ontogeny that delineates a population of T/NK-committed progenitors (NK1. 1(+)/CD117(+)/CD44(+)/CD25(-)). Thymocytes at this stage in development are phenotypically and functionally distinguishable from the pool of multipotent lymphoid-restricted (B, T, and NK) precursor thymocytes. Exposure of multipotent precursor thymocytes or fetal liver- derived hematopoietic progenitors to thymic stroma induces differentiation to the bipotent developmental stage. Continued exposure to a thymic microenvironment results in predominant commitment to the T cell lineage, whereas coculture with a bone marrow-derived stromal cell line results in the generation of mature NK cells. Thus, the restriction point to T and NK lymphocyte destinies from a multipotent progenitor stage is marked by a thymus-induced differentiation step.

V(H) repertoire maturation during B cell development in vitro: differential selection of Ig heavy chains by fetal and adult B cell progenitors.

B cell development is characterized by marked changes in Ig repertoire, which include shifts in the pattern of V(H) segment usage. B cell precursors characteristically utilize a restricted set of V(H) segments, while mature B cell populations use a wide range of V(H) segments. V(H)81x is an example of a V(H) segment that is highly utilized in B cell precursors, but is rarely utilized in mature B cells. To dissect the molecular and cellular requirements for Ig repertoire maturation, we have examined V(H)81x usage in an in vitro model of B cell development. We find that primary fetal or adult B cell progenitors differentiating in vitro mimic progenitors differentiating in vivo with respect to V(H)81x overusage and subsequent decline in V(H)81x usage, showing that neither of these events is dependent on the intact architecture of the primary lymphoid organ or contact with stromal cells. The relative decline in V(H)81x usage in cultures initiated with adult progenitors was associated with a decrease in the ratio of productive/nonproductive V(H)81x-DJ(H) rearrangements; however, an increase in this ratio was observed in identical cultures initiated with fetal progenitors. This result indicates a difference in selection of V(H)81x-encoded heavy chains that is intrinsic to fetal and adult B cell progenitors. Thus, while the relative decline in V(H)81x usage during adult development can be at least partially explained by selection against cells bearing V(H)81x-encoded heavy chains, other mechanisms must be postulated to explain the decline in V(H)81x usage during fetal development.

Rheumatoid arthritis synovial fibroblast and U937 macrophage/monocyte cell line interaction in cartilage degradation.

OBJECTIVE: To examine the interaction between synovial fibroblasts and macrophages in the context of cartilage degradation. METHODS: An in vitro model of human cartilage degradation was used, in which purified populations of fibroblasts and macrophages were added to a radiolabeled cartilage disc. Cartilage destruction was measured by the percentage of radiolabel release. RESULTS: Fibroblasts, obtained from either rheumatoid arthritis (RA) or osteoarthritis synovial tissue, could mediate cartilage degradation if cocultured with the U937 macrophage cell line. Skin and RA bone marrow fibroblasts had no degradative effect on cartilage. Fibroblast-macrophage contact was not required for cartilage degradation. Cartilage degradation by synovial fibroblasts was inhibited by antibodies to tumor necrosis factor alpha (TNF alpha), interleukin-1 beta (IL-1 beta), and IL-6. Cartilage degradation was almost completely abrogated by a combination of antibodies to TNF alpha and IL-1 beta. Contact between fibroblasts and cartilage was shown to be essential. Antibodies to CD44, but not to intercellular adhesion molecule 1, markedly inhibited cartilage degradation. CONCLUSION: TNF alpha, IL-1 beta, and IL-6 were involved in the activation of synovial fibroblasts to cause cartilage degradation. Cartilage degradation occurred only when fibroblasts were in contact with cartilage. CD44 was demonstrated to be involved in the fibroblast-cartilage interaction.

Targeted disruption of the PU.1 gene results in multiple hematopoietic abnormalities.

PU.1 is a member of the ets family of transcription factors and is expressed exclusively in cells of the hematopoietic lineage. Mice homozygous for a disruption in the PU.1 DNA binding domain are born alive but die of severe septicemia within 48 h. The analysis of these neonates revealed a lack of mature macrophages, neutrophils, B cells and T cells, although erythrocytes and megakaryocytes were present. The absence of lymphoid commitment and development in null mice was not absolute, since mice maintained on antibiotics began to develop normal appearing T cells 3-5 days after birth. In contrast, mature B cells remained undetectable in these older mice. Within the myeloid lineage, despite a lack of macrophages in the older antibiotic-treated animals, a few cells with the characteristics of neutrophils began to appear by day 3. While the PU.1 protein appears not to be essential for myeloid and lymphoid lineage commitment, it is absolutely required for the normal differentiation of B cells and macrophages.