Triggering CD40 on endothelial cells contributes to tumor growth.

Inflammatory cells can either promote or inhibit tumor growth. Here we studied whether CD40, a key molecule for adaptive immune response, has any role in mammary carcinogenesis of BALB/NeuT transgenic tumor-prone mice. We transferred the HER2/neu oncogene into CD40-null background to obtain the CD40-KO/NeuT strain. CD40-KO/NeuT mice showed delayed tumor onset and reduced tumor multiplicity. BM (BM) transplantation experiments excluded a role of BM-derived cells in the reduced tumorigenicity associated with CD40 deficiency. Rather, CD40 expressed by endothelial cells (ECs) takes part to the angiogenic process. Accordingly, large vessels, well organized around the tumor lobular structures, characterize BALB/NeuT tumors, whereas tiny numerous vessels with scarce extracellular matrix are dispersed in the parenchyma of poorly organized CD40-KO/NeuT tumors. Activated platelets, which may interact with and activate ECs, are a possible source of CD40L. Their localization within tumor vessels prompted the idea of treating BALB/NeuT and CD40-KO/NeuT mice chronically with the anti-platelet drug clopidogrel, known to inhibit platelet CD40L expression. Treatment of BALB/NeuT mice reduced tumor growth to a level similar to CD40-deficient mice, whereas CD40-KO/NeuT mice treated or not showed the same attenuated tumor outgrowth, indicating that activated platelets are the likely source of CD40L in this model. Collectively, these data point to a participation of CD40/CD40L in the angiogenic processes associated with mammary carcinogenesis of BALB/NeuT mice.

Interleukin-12 production by leukemia-derived dendritic cells counteracts the inhibitory effect of leukemic microenvironment on T cells.

OBJECTIVE: Acute myeloid leukemia (AML) cells are poorly immunogenic and inhibit T-cell function. AML-derived dendritic cells (AML-DCs) have better antigen-presentation capacity than undifferentiated leukemic blasts, but may not be fully competent to stimulate T cells previously inhibited by leukemic cells. MATERIALS AND METHODS: AML-DCs were generated from AML cells and used to stimulate proliferation and cytokine production by T cells previously inhibited by AML cells. AML-DCs were also transfected with interleukin (IL)-12 gene by the nonviral method, nucleofection. RESULTS: Mature AML-DCs stimulated naive and, to a lesser extent, leukemic cell (LC)-cultured T cells more efficiently than their immature counterparts and their activity was mediated by IL-12. AML-DCs generated from CD14(-) AML samples (which represent 80% of total AML patients) were defective in IL-12 production and T-cell activation. Addition of exogenous IL-12 to LC-cultured T cells stimulated by CD14(-)-derived AML-DCs restored optimal interferon-gamma (IFN-gamma) production and Th1 skewing. IL-12 gene-nucleofected AML-DCs derived from CD14(-) cells produced significant amounts of IL-12, maintained leukemia-specific karyotype, DC-like phenotype, and function. When stimulated by IL-12-gene transduced CD14(-)-derived AML-DCs, LC-cultured T cells produced higher concentrations of IFN-gamma, thus maintaining a Th1 cytokine profile. CONCLUSION: IL-12 produced by AML-DCs plays a critical role in counteracting the inhibitory activity of LCs on T-cell function. IL-12 gene can be successfully expressed into AML-DCs defective in endogenous IL-12 production by using a novel nonviral method that does not modify their phenotypical, cytogenetic, and functional features. Genetically modified AML-DCs restore a near normal T-cell function.