Defective p53 engagement after the induction of DNA damage in cells deficient in topoisomerase 3beta.

The type IA topoisomerases have been implicated in the repair of dsDNA breaks by homologous recombination and in the resolution of stalled or damaged DNA replication forks; thus, these proteins play important roles in the maintenance of genomic stability. We studied the functions of one of the two mammalian type IA enzymes, Top3beta, using murine embryonic fibroblasts (MEFs) derived from top3beta(-/-) embryos. top3beta(-/-) MEFs proliferated more slowly than TOP3beta(+/+) control MEFs, demonstrated increased sensitivity to DNA-damaging agents such as ionizing and UV radiation, and had increased DNA double-strand breaks as manifested by increased gamma-H2-AX phosphorylation. However, incomplete enforcement of the G(1)-S cell cycle checkpoint was observed in top3beta(-/-) MEFs. Notably, ataxia-telangiectasia, mutated (ATM)/ATM and Rad3-related (ATR)-dependent substrate phosphorylation after UV-B and ionizing radiation was impaired in top3beta(-/-) versus TOP3beta(+/+) control MEFs, and impaired up-regulation of total and Ser-18-phosphorylated p53 was observed in top3beta(-/-) cells. Taken together, these results suggest an unanticipated role for Top3beta beyond DNA repair in the activation of cellular responses to DNA damage.

Anti-HLA-DR-triggered monocytes mediate in vitro T cell anergy.

Monomorphic MHC class II determinants are attractive targets for immunomodulation. HLA-DR ligation on antigen-presenting cells (APCs) can dramatically alter their function or induce cell death. In monocytes, HLA-DR triggering diminishes their capacity to stimulate T cell proliferation. To further investigate this monocyte-dependent T cell inhibition, we activated human T cells +/- HLA-DR triggering on APCs and tested whether this can induce T cell anergy. Only anti-HLA-DR, but not anti-proliferative control agent anti-CD45, could modulate monocytes in primary cultures with stimulated T cells, so that T cells were hyporesponsive during re-stimulation. Cell separation studies demonstrated that HLA-DR ligation on monocytes is sufficient for mediating T cell anergy. Secretion of monokines was severely reduced after primary culture. Monocytes anergized independently of soluble factors. Extracellular signal-regulated kinase (ERK) phosphorylation occurred early with anti-HLA-DR, but late with anti-CD45 antibody. However, ERK inhibition did not reverse the T cell-anergizing potential of HLA-DR-ligated monocytes implicating other signaling pathways involved in tolerance induction. When analyzing the anergized T cells, they were refractory to exogenous IL-2 and characterized by defective secretion of various cytokines. Expression of CD25, CD28, intracellular CD3zeta and CTLA-4 was reduced. The hyporesponsive T cells up-regulated cell-cycle inhibitors p27(kip1) and p21(cip1) in correlation with human T cell anergy. In contrast, caspase-3 and -8, known to contribute to T cell proliferation, were equally decreased in anti-HLA-DR- and anti-CD45-inhibited cultures. In summary, anti-HLA-DR treatment can generate tolerogenic monocytes transmitting T cell anergy that may be exploited for future immunomodulatory strategies to treat immune-mediated disease states.

Defective signal transduction in B lymphocytes lacking presenilin proteins.

The mammalian presenilin (PS) proteins mediate the posttranslational cleavage of several protein substrates, including amyloid precursor protein, Notch family members, and CD44, but they have also been suggested to function in diverse cellular processes, including calcium-dependent signaling and apoptosis. We carried out an integrative computational study of multiple genomic datasets, including RNA expression, protein interaction, and pathway analyses, which implicated PS proteins in Toll-like receptor signaling. To test these computational predictions, we analyzed mice carrying a conditional allele of PS1 and a germ line-inactivating allele of PS2, together with Cre site-specific recombinase expression under the influence of CD19 control sequences. Notably, B cells deficient in both PS1 and PS2 function have an unexpected and substantial deficit in both lipopolysaccharide and B cell antigen receptor-induced proliferation and signal transduction events, including a defect in anti-IgM-mediated calcium flux. Taken together, these results demonstrate a fundamental and unanticipated role for PS proteins in B cell function and emphasize the potency of (systems level) integrative analysis of whole-genome datasets in identifying novel biologic signal transduction relationships. Our findings also suggest that pharmacologic inhibition of PS for the treatment of conditions such as Alzheimer's disease may have potential consequences for immune system function.

CD8 alpha- and Langerin-negative dendritic cells, but not Langerhans cells, act as principal antigen-presenting cells in leishmaniasis.

In the early phase of leishmaniasis three types of potential antigen-presenting cells, including epidermal Langerhans cells (LC), dermal dendritic cells (DC) and inflammatory DC, are localized at the site of infection. Therefore, it has been a central question which cell type is responsible for the initiation of a protective immune response. In the early stage of an anti-Leishmania immune response, detectable Leishmania major antigen was localized in the paracortex of the draining lymph nodes (LN). Characterization of antigen-positive cells showed that L. major co-localized with DC of a CD11c(+) CD8 alpha(-) Langerin(-) phenotype. To determine the area of antigen uptake, dermis or epidermis, and to further define the type of antigen-transporting cells, L. major was inoculated subcutaneously and concurrently LC were mobilized with fluorescein isothiocyanate (FITC). After 3 days, DC carrying L. major antigen were always FITC(-), indicating a dermal and not an epidermal origin. Moreover, addition of L. major antigen to ex vivo isolated CD8 alpha(-) and CD8 alpha(+) DC from the draining LN of L. major-infected C57BL/6 mice demonstrated that both DC subpopulations were able to stimulate antigen-specific T cell proliferation in vitro. Without addition of exogenous antigen only the CD8 alpha(-) Langerin(-) DC were capable of stimulating antigen-specific T cell proliferation. Thus, we demonstrate that CD8 alpha(-) Langerin(-) DC and not LC are the basis of the protective immune response to intracellular L. major parasites in vivo.

Membrane lymphotoxin contributes to anti-leishmanial immunity by controlling structural integrity of lymphoid organs.

Lymphotoxin (LT)alpha in combination with LTbeta forms membrane-bound heterotrimeric complexes with a crucial function in lymph node (LN) organogenesis and correct morphogenesis of secondary lymphoid tissue. To study the role of membrane LT (mLT) in lymphoid tissue organogenesis we generated an LTbeta-deficient mouse strain on a pure genetic C57BL/6 background (B6.LTbeta-/-) and compared it to a unique series of LTalpha-, TNF- and TNF/LTalpha-gene-targeted mice on an identical genetic background (B6.LTalpha-/-, B6.TNF-/- and B6 TNF/LTalpha-/-). B6.LTbeta-/- mice lacked peripheral LN with the exception of mesenteric LN, and displayed a disturbed micro-architecture of the spleen, although less profoundly than LTalpha- or TNF/LTalpha-deficient mice. Radiation bone marrow chimeras (B6.WT-->B6.LTbeta-/- developed Peyer's patch (PP)-like lymphoid aggregates in the intestinal wall indicating a possible role for soluble LTalpha(3) in the formation of the PP anlage. After infection with Leishmania major, B6.LTbeta-/- mice developed a fatal disseminating leishmaniasis resulting in death after 8 to 14 weeks, despite the natural resistance of the C57BL/6 genetic background (B6.WT) mice to the parasite. Both, the cellular and the humoral anti-L. major immune responses were delayed and ineffective. However, the expression pattern of the key cytokines IFN-gamma and IL-12 were comparable in B6.WT and B6.LTbeta-/- mice. Infection of radiation bone marrow chimeras showed that it is the LTbeta-dependent presence of lymphoid tissue and not the expression of mLT itself that renders mice resistant to leishmaniasis.