The genetics of gene expression in complex mouse crosses as a tool to study the molecular underpinnings of behavior traits

Complex Mus musculus crosses provide increased resolution to examine the relationships between gene expression and behavior. While the advantages are clear, there are numerous analytical and technological concerns that arise from the increased genetic complexity that must be considered. Each of these issues is discussed, providing an initial framework for complex cross study design and planning.     

Calcitonin gene-related peptide inhibits interleukin 2 production by murine T lymphocytes.

Evidence from the literature suggests that the nervous and the immune systems closely interact via neuromediators, which affect the immune system, and cytokines, which control nerve cell growth and activity. Calcitonin gene-related peptide (CGRP) is a neuropeptide that has been identified in numerous tissues including immune organs and inhibits the proliferation of spleen cells. We investigated whether CGRP altered the function of T lymphocytes. We present evidence that CGRP induces a dose-dependent cAMP accumulation in interleukin 2-producing TH1 cells and inhibits their production of interleukin 2. These effects are prevented by CGRP8-37, a CGRP antagonist that is missing the first 7 amino acids. This CGRP-mediated inhibition of interleukin 2 production is accompanied by a decrease in interleukin 2 mRNA accumulation. CGRP also inhibits the accumulation of mRNA coding for tumor necrosis factor-alpha and -beta and interferon-gamma. Thus, we have identified one mechanism by which CGRP inhibits the proliferation of spleen cells.     

3H-uridine incorporation by small lymphocytes of tolerant rats: relationship to T and B lymphocytes.

Tissue tolerance was induced in neonatal rats by the intravenous injection of bone marrow cells from adult allogeneic rat donors. After 6 to 8 weeks, lymphoid cells from rats in which tolerance had been induced were tested for mixed lymphocyte reactivity (MLR), 3H-uridine uptake, and the relationship of uridine incorporation to B and T lymphocytes. Lymph node (LN) and spleen (SPL) cells from the adult inoculated rats showed no reactivity in the MLR or normal lymphocyte transfer reaction (NLTRx), indicating that the animals were tolerant. After in vitro exposure to 3H-uridine, an abundance of small lymphocytes (SL) from these same tolerant rats were heavily labeled, in contrast to nontolerant controls, where relatively few SL were heavily labeled. In order to determine whether the heavily uridine-labeled cells were T cells or B cells, lymphoid cells from the LN and SPL of tolerant animals were exposed to either rabbit anti-AKR brain serum or rabbit anti-rat Ig conjugated with ferritin. The results showed that the heavily uridine-labeled SL of the tolerant rats were mainly Ig-positive cells.     

Granulocyte-macrophage colony stimulating factor produced by cloned L3T4a+, class II-restricted T cells induces HT-2 cells to proliferate

Cloned L3T4a+ antigen-specific, class II-restricted T cells can be subdivided by function and by cytokine production. All cloned T cell lines produce T cell growth factors that can be distinguished by the ability of monoclonal antibodies to inhibit the proliferation of cytokine-dependent T cell lines induced by these T cell growth factors. From these types of analyses, it has been shown that all cloned T cells that help hapten-specific B cells secrete immunoglobulin, produce interleukin 4 (IL 4). Those cloned T cells that fail to help for anti-hapten responses produce neither IL 4 nor interleukin 2 (IL 2), yet release an activity that induces the proliferation of the cytokine-dependent T cell line, HT-2. Additional analysis of the HT-2 stimulating activity has shown that it is indistinguishable from granulocyte macrophage-colony stimulating factor (GM-CSF)--this activity being produced by all cloned T cells tested. Thus GM-CSF is a product of all cloned L3T4a+ T cell lines tested thus far, and can serve as a T cell growth factor for HT-2, as well as a co-factor for in vivo derived T cells.     

T cell-dependent hapten-specific and polyclonal B cell responses require release of interleukin 5

CD4+ T cells in the mouse have recently been subdivided into two major subpopulations which differ in their functional activities and in the lymphokines they produce. Although cloned T cells lines representative of both sets will activate B cells in polyclonal responses, only the subset producing interleukin 4 (IL-4) will activate antigen-specific B cells in linked recognition assays. This suggested that IL-4 was essential for such responses. In the present experiments, the requirements were compared for B cell activation in specific as opposed to polyclonal antibody responses by T cell clones of the helper (IL-4 producing) subset. It was found that specific responses involve primarily small B cells, whereas polyclonal responses activate exclusively the large B cells. Second, polyclonal B cell responses can proceed in the absence of T:B contact, whereas specific responses require physical interaction of the two cells. Third, it was found that interleukin 5 (IL-5, formerly known as T cell replacing factor/B cell growth factor II) is essential for these polyclonal responses by inhibition of such responses with monoclonal anti-IL-5 antibody. Anti-IL-5 also inhibits specific antibody responses involving direct T:B interaction. Thus, IL-5 is clearly a critical mediator of differentiation to immunoglobulin secretion of activated B cells, whether such B cells are obtained as large B cells from freshly isolated spleen cells or are initially activated in an IL-4-dependent fashion by cognate interaction by a helper T cell clone.     

IL-4 promotes airway eosinophilia by suppressing IFN-gamma production: defining a novel role for IFN-gamma in the regulation of allergic airway inflammation

Airway eosinophilia in asthma is dependent on cytokines secreted by Th2 cells, including IL-5 and IL-4. In these studies we investigated why the absence of IL-4 led to a reduction in airway, but not lung tissue, eosinophils. Using adoptively transferred, in vitro-generated TCR-transgenic Th2 cells deficient in IL-4, we show that this effect is independent of IL-5 and Th2 cell generation. Airway eosinophilia was no longer inhibited when IL-4(-/-) Th2 cells were transferred into IFN-gammaR(-/-) mice, indicating that IFN-gamma was responsible for reducing airway eosinophils in the absence of IL-4. Intranasal administration of IFN-gamma to mice after IL-4(+/+) Th2 cell transfer also caused a reduction in airway, but not lung parenchymal, eosinophils. These studies show that IL-4 indirectly promotes airway eosinophilia by suppressing the production of IFN-gamma. IFN-gamma reduces airway eosinophils by engaging its receptor on hemopoietic cells, possibly the eosinophil itself. These studies capitalize on the complex counterregulatory effects of Th1 and Th2 cytokines in vivo and clarify how IL-4 influences lung eosinophilia. We define a new regulatory role for IFN-gamma, demonstrating that eosinophilic inflammation is differentially regulated at distinct sites within the respiratory tract.     

A new mechanism for inhalational priming: IL-4 bypasses innate immune signals

Signaling via innate immune mechanisms is considered pivotal for T cell-mediated responses to inhaled Ags. Furthermore, Th2 cells specific for one inhaled Ag can facilitate priming of naive T cells to unrelated new inhaled Ags, a process we call "Th2 collateral priming". Interestingly, our previous studies showed that collateral priming is independent of signals via the innate immune system but depends on IL-4 secretion by CD4(+) T cells. We thus hypothesized that IL-4 can bypass the need for signals via the innate immune system, considered essential for pulmonary priming. Indeed, we were able to show that IL-4 bypasses the requirement for TLR4- and MyD88-mediated signaling for responses to new allergens. Furthermore, we characterized the mechanisms by which IL-4 primes for new inhaled allergens: "IL-4-dependent pulmonary priming" relies on IL-4 receptor expression on hematopoietic cells and structural cells. Transfer experiments indicate that within the hematopoietic compartment both T cells and dendritic cells need to express the IL-4 receptor. Finally, we were able to show that IL-4 induces recruitment and maturation of myeloid dendritic cells in vivo and increases T cell recruitment to the draining lymph nodes. Our findings bring new mechanistic knowledge to the phenomenon of polysensitization and primary sensitization in asthma.