Identification of mushroom body miniature, a zinc-finger protein implicated in brain development of Drosophila.

The mushroom bodies are bilaterally arranged structures in the protocerebrum of Drosophila and most other insect species. Mutants with altered mushroom body structure have been instrumental not only in establishing their role in distinct behavioral functions but also in identifying the molecular pathways that control mushroom body development. The mushroom body miniature(1) (mbm(1)) mutation results in grossly reduced mushroom bodies and odor learning deficits in females. With a survey of genomic rescue constructs, we have pinpointed mbm(1) to a single transcription unit and identified a single nucleotide exchange in the 5' untranslated region of the corresponding transcript resulting in a reduced expression of the protein. The most obvious feature of the Mbm protein is a pair of C(2)HC zinc fingers, implicating a function of the protein in binding nucleic acids. Immunohistochemical analysis shows that expression of the Mbm protein is not restricted to the mushroom bodies. BrdUrd labeling experiments indicate a function of Mbm in neuronal precursor cell proliferation.

Mice deficient in nuclear factor of activated T-cell transcription factor c2 mount increased Th2 responses after infection with Nippostrongylus brasiliensis and decreased Th1 responses after mycobacterial infection.

Infection of nuclear factor of activated T-cell transcription factor c2 (NFATc2)-deficient mice with the helminth Nippostrongylus brasiliensis led to a distinct increase in interleukin-4 (IL-4) and IL-5 protein synthesis by lymph node and spleen cells and to elevated serum immunoglobulin E (IgE) levels in comparison to those seen with infected control mice. While IL-4, IL-5, and IL-13 mRNA expression was also enhanced in lymph node cells from the lungs of infected NFATc2(-/-) mice, the number of T cells secreting Th2-type lymphokines remained the same in mice infected with N. brasiliensis. In contrast, lymphocytes from NFATc2-deficient mice infected with Mycobacterium bovis BCG secreted less gamma interferon than lymphocytes from infected control mice. These findings indicate that NFATc2 is an activator of Th1 responses and a suppressor of Th2 responses in vivo.

Loss of p53 in craf-induced transgenic lung adenoma leads to tumor acceleration and phenotypic switch.

One of the most frequent malignancies in humans is lung adenocarcinoma.To develop novel diagnostic and therapeutic approaches for the management of this disease, animal models are required. We have used transgenic mice with lung-targeted expression of the CRaf kinase to evaluate genes altered frequently in human lung adenocarcinoma for their effect on tumor progression. Here we report that loss of p53 dramatically accelerates tumor development and induces a phenotypic switch in the target cell from cuboid to a nonciliated columnar morphology. Coexpression of lung epithelial cell markers surfactant protein C and Clara cell antigen suggests that tumor cell dedifferentiation could be involved in this process. The effect of p53 is specific, because loss of one of its target genes, p21(CIP1/WAF1), did not have this effect on cell phenotype although tumor latency was also reduced significantly. Neither loss of p53 nor p21 stimulated acquisition of the metastasis program beyond the stage of bronchiolar extension. This mouse model for pulmonary adenoma and adenocarcinoma should be very helpful for a better understanding of pathogenesis and treatment of this most deadly human cancer.

Induction of NFATc2 expression by interleukin 6 promotes T helper type 2 differentiation.

Interleukin (IL)-6 is produced by professional antigen-presenting cells (APCs) such as B cells, macrophages, and dendritic cells. It has been previously shown that APC-derived IL-6 promotes the differentiation of naive CD4+ T cells into effector T helper type 2 (Th2) cells. Here, we have studied the molecular mechanism for IL-6-mediated Th2 differentiation. During the activation of CD4+ T cells, IL-6 induces the production of IL-4, which promotes the differentiation of these cells into effector Th2 cells. Regulation of IL-4 gene expression by IL-6 is mediated by nuclear factor of activated T cells (NFAT), as inhibition of NFAT prevents IL-6-driven IL-4 production and Th2 differentiation. IL-6 upregulates NFAT transcriptional activity by increasing the levels of NFATc2. The ability of IL-6 to promote Th2 differentiation is impaired in CD4+ T cells that lack NFATc2, demonstrating that NFATc2 is required for regulation of IL-4 gene expression by IL-6. Regulation of NFATc2 expression and NFAT transcriptional activity represents a novel pathway by which IL-6 can modulate gene expression.