ß1Integrin/FAK/cortactin signaling is essential for human head and neck cancer resistance to radiotherapy.

Integrin signaling critically contributes to the progression, growth, and therapy resistance of malignant tumors. Here, we show that targeting of ß1 integrins with inhibitory antibodies enhances the sensitivity to ionizing radiation and delays the growth of human head and neck squamous cell carcinoma cell lines in 3D cell culture and in xenografted mice. Mechanistically, dephosphorylation of focal adhesion kinase (FAK) upon inhibition of ß1 integrin resulted in dissociation of a FAK/cortactin protein complex. This, in turn, downregulated JNK signaling and induced cell rounding, leading to radiosensitization. Thus, these findings suggest that robust and selective pharmacological targeting of ß1 integrins may provide therapeutic benefit to overcome tumor cell resistance to radiotherapy.

Diverse effects of combined radiotherapy and EGFR inhibition with antibodies or TK inhibitors on local tumour control and correlation with EGFR gene expression.

PURPOSE: To compare functional effects of combined irradiation and EGFR inhibition in different HNSCC tumour models in vivo with the results of molecular evaluations, aiming to set a basis for the development of potential biomarkers for local tumour control. MATERIAL AND METHODS: In five HNSCC tumour models, all wild-type for EGFR and KRAS, the effect of radiotherapy alone (30 fractions/6 weeks) and with simultaneous cetuximab or erlotinib treatment on local tumour control were evaluated and compared with molecular data on western blot, immunohistochemistry and fluorescence-in situ-hybridisation (FISH). RESULTS: Erlotinib and cetuximab alone significantly prolonged tumour growth time in 4/5 tumour models. Combined irradiation and cetuximab treatment significantly improved local tumour control in 3/5 tumour models, whereas erlotinib did not alter local tumour control in any of the tumour models. The amount of the cetuximab-effect on local tumour control significantly correlated with the EGFR/CEP-7 ratios obtained by FISH. CONCLUSION: Both drugs prolonged growth time in most tumour models, but only application of cetuximab during irradiation significantly improved local tumour control in 3/5 tumour models. The significant correlation of this curative effect with the genetic EGFR expression measured by FISH will be further validated in preclinical and clinical studies.

Heterogeneity of tumour response to combined radiotherapy and EGFR inhibitors: differences between antibodies and TK inhibitors.

PURPOSE: Clinical and preclinical data show a wide variability of tumour response to combined inhibition of the Epidermal Growth Factor Receptor (EGFR) and radiotherapy or chemotherapy. Differences are obvious not only between different tumour entities, but also between different combination schedules and different classes of drugs. The underlying reasons are currently not well understood. CONCLUSIONS: In light of the disappointing results of some phase III trials on combined EGFR tyrosine kinase (TK) inhibition and chemotherapy in non-small-cell lung cancer, but also of some early clinical trials on the triple combination of EGFR inhibitors and radio-chemotherapy, negative interactions between the components of the treatment cannot be ruled out. Also, there is increasing evidence for a differential activity of anti-EGFR antibodies and EGFR-TK inhibitors. Potential reasons are an immunogenic component of the cytotoxic effect of chimeric antibodies, alternative signal transduction pathways leading to acquired resistance against the drugs, different effects on tumour micromilieu or nutritional supply, differences in pharmacokinetics and intratumoural distribution or different effects on cancer stem cells. Clarifying these potential mechanisms will require further preclinical and clinical research effort but could in future enable us to individually tailor the use of molecular targeted drugs in order to fully utilise their high potential in cancer therapy.

Integrin-linked kinase: dispensable for radiation survival of three-dimensionally cultured fibroblasts.

PURPOSE: Cancer treatment by conventional radiotherapy is limited by normal tissue side-effects. Fibroblasts as "non-target" stromal cell type are considered as strong promoter of tumor growth and for developing a therapy resistant phenotype. Regarding application of novel molecular therapeutics combined with radiotherapy, evaluation of a specific targeted molecule in both tumor and normal cells is mandatory for efficacy and tolerability assessment. Previous work showed integrin-linked kinase (ILK), a mediator of beta-integrin signals and putative phosphorylator of AKT, as potent anti-survival regulator in human cancer cell lines. MATERIALS AND METHODS: To evaluate the role of ILK in normal fibroblast survival, ILK-wild-type (ILK(fl/fl)), ILK(-/-) and ILK(N-terminal) and ILK(C-terminal) domain expressing fibroblasts were irradiated with X-rays on different substrata or in three-dimensional laminin-rich extracellular matrix (lrECM). RESULTS: On control substrata, ILK-deficient and ILK-mutant fibroblasts showed significant increase in radiation survival relative to ILK-wild-type cells. This effect was compensated by growth on ECM proteins and in 3D lrECM. ILK regulated AKT activity in a phosphatidylinositol-3 kinase (PI3K)-dependent manner. Upon PI3K inhibition, only ILK-wild-type fibroblasts showed significant radiosensitization. CONCLUSIONS: These findings obtained in 3D cell cultures suggest ILK to be dispensable for the radiation survival response of normal fibroblasts. However, targeting the PI3K/AKT signaling axis pharmacologically might be critical for survival of normal fibroblasts exposed to ionizing radiation.

Tumoricidal potential of native blood dendritic cells: direct tumor cell killing and activation of NK cell-mediated cytotoxicity.

Dendritic cells (DCs) are characterized by their unique capacity for primary T cell activation, providing the opportunity for DC-based cancer vaccination protocols. Novel findings reveal that besides their role as potent inducers of tumor-specific T cells, human DCs display additional antitumor effects. Most of these data were obtained with monocyte-derived DCs, whereas studies investigating native blood DCs are limited. In the present study, we analyze the tumoricidal capacity of M-DC8(+) DCs, which represent a major subpopulation of human blood DCs. We demonstrate that IFN-gamma-stimulated M-DC8(+) DCs lyse different tumor cell lines but not normal cells. In addition, we show that tumor cells markedly enhance the production of TNF-alpha by M-DC8(+) DCs via cell-to-cell contact and that this molecule essentially contributes to the killing activity of M-DC8(+) DCs. Furthermore, we illustrate the ability of M-DC8(+) DCs to promote proliferation, IFN-gamma production, and tumor-directed cytotoxicity of NK cells. The M-DC8(+) DC-mediated enhancement of the tumoricidal potential of NK cells is mainly dependent on cell-to-cell contact. These results reveal that, in addition to their crucial role in activating tumor-specific T cells, blood DCs exhibit direct tumor cell killing and enhance the tumoricidal activity of NK cells. These findings point to the pivotal role of DCs in triggering innate and adaptive immune responses against tumors.