Availability of tumor and non-tumor patient-derived models would promote the development of more effective therapeutics for non-small cell lung cancer (NSCLC). Recently, conditionally reprogrammed cells (CRC) methodology demonstrated exceptional potential for the expansion of epithelial cells from patient tissues. However, the possibility to expand patient-derived lung cancer cells using CRC protocols is controversial. Here, we used CRC approach to expand cells from non-tumoral and tumor biopsies of patients with primary or metastatic NSCLC as well as pulmonary metastases of colorectal or breast cancers. CRC cultures were obtained from both tumor and non-malignant tissues with extraordinary high efficiency. Tumor cells were tracked in vitro through tumorigenicity assay, monitoring of tumor-specific genetic alterations and marker expression. Cultures were composed of EpCAM+ lung epithelial cells lacking tumorigenic potential. NSCLC biopsies-derived cultures rapidly lost patient-specific genetic mutations or tumor antigens. Similarly, pulmonary metastases of colon or breast cancer generated CRC cultures of lung epithelial cells. All CRC cultures examined displayed epithelial lung stem cell phenotype and function. In contrast, brain metastatic lung cancer biopsies failed to generate CRC cultures. In conclusion, patient-derived primary and metastatic lung cancer cells were negatively selected under CRC conditions, limiting the expansion to non-malignant lung epithelial stem cells from either tumor or non-tumor tissue sources. Thus, CRC approach cannot be applied for direct therapeutic testing of patient lung tumor cells, as the tumor-derived CRC cultures are composed of (non-tumoral) airway basal cells.
Background: The probability of local tumor control after radiotherapy (RT) remains still miserably poor in pediatric rhabdomyosarcoma (RMS). Thus, understanding the molecular mechanisms responsible of tumor relapse is essential to identify personalized RT-based strategies. Contrary to what has been done so far, a correct characterization of cellular radioresistance should be performed comparing radioresistant and radiosensitive cells with the same isogenic background. Methods: Clinically relevant radioresistant (RR) embryonal (RD) and alveolar (RH30) RMS cell lines have been developed by irradiating them with clinical-like hypo-fractionated schedule. RMS-RR cells were compared to parental isogenic counterpart (RMS-PR) and studied following the radiobiological concept of the "6Rs", which stand for repair, redistribution, repopulation, reoxygenation, intrinsic radioresistance and radio-immuno-biology. Results: RMS-RR cell lines, characterized by a more aggressive and in vitro pro-metastatic phenotype, showed a higher ability to i) detoxify from reactive oxygen species; ii) repair DNA damage by differently activating nonhomologous end joining and homologous recombination pathways; iii) counteract RT-induced G2/M cell cycle arrest by restarting growth and repopulating after irradiation; iv) express cancer stem-like profile. Bioinformatic analyses, performed to assess the role of 41 cytokines after RT exposure and their network interactions, suggested TGF-β, MIF, CCL2, CXCL5, CXCL8 and CXCL12 as master regulators of cancer immune escape in RMS tumors.
Background: Human Dachshund homologue 1 (DACH1) is involved in carcinogenesis with opposite roles reported in different tumor types. Four alternatively spliced transcripts encoding different DACH1 isoforms were described but their specific role in human cancers is still unknown. Prostate cancer (PCa) is a heterogeneous disease with a very wide variability, so there is yet a relevant need to find new diagnostic and therapeutic biomarkers to make a safe clinical evaluation. It is well known that the differential expression of protein isoforms can induce distinct transcriptional programs with opposing effects on tumor progression and therapy. Thus, in this study we aimed to correlate the functional role of DACH1 with its splicing variants expression in PCa.Methods: The expression and functional role of DACH1 splicing variants in PCa were investigated using tumor (PC3) and normal (RWPE-1) cell lines, patient biopsies and TCGA dataset. Flow-cytometry, western blots and RT-qPCR were used for in vitro molecular characterization; invasion, adhesion, clonogenic assays and cell cycle analysis for functional characterization. Immunohystochemistry and western blot were performed on human PCa biopsies.Results: RT-qPCR and Western Blot revealed that DACH1-positive PC3 cells predominantly expressed DACH1 variant 4 (DACH1-v4), whereas RWPE-1 cells mostly expressed DACH1 variant 3. Stable DACH1-v4 overexpression enhanced the transformed phenotype of PC3 cells by inducing proliferation, colony formation, invasion ability, epithelial to mesenchymal transition. Given its intrinsic radioresistance, PCa frequently recurs after radiotherapy. Of note, DACH1-v4-overexpressing PC3 cells displayed higher radioresistant behavior. Overexpression of DACH1-v4 also transformed RWPE-1 cells to oncogenic phenotype, suggesting a pro-oncogenic role for this specific isoform. PCa biopsies analysis showed DACH1 nuclear staining enhanced throughout the increase of the tumor grade. Remarkably, tumor glands were found to express a long DACH1 variant, while normal prostate tissue expressed the short DACH1 isoform, in line with data from TCGA-PRAD analysis and our data in RWPE-1 cells. Conclusions: Our findings highlight the oncogenic role of DACH1-v4 in PCa and suggest that the longer DACH1 variants could be associated to pro-tumor function, while the shortest DACH1 variant would perform tumor suppression. The expression of specific DACH1 isoforms could represent a novel diagnostic/prognostic marker in PCa.
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