Project description:This SuperSeries is composed of the following subset Series: GSE15350: Resistance of primary ovarian cancer cells to oncolytic adenoviruses part1 of 2 GSE15351: Resistance of primary ovarian cancer cells to oncolytic adenoviruses part2 of 2 Refer to individual Series

Project description:The mechanisms of primary ovarian cancer cells for resistance to viral oncolysis were investigated using Ad5/35.IR.E1A/TRAIL on clonal cultures derived from ovc316m cells. Part 2 of 2, 26 clonal ovc316m cultures additionally to Resistance of primary ovarian cancer cells to oncolytic adenoviruses part1 of 2

Project description:Resistance of primary ovarian cancer cells to oncolytic adenoviruses part2 of 2

Project description:Resistance of primary ovarian cancer cells to oncolytic adenoviruses part1 of 2

Project description:The microtubule-stabilising drug paclitaxel has activity in relapsed ovarian cancer. However, resistance frequently develops. Oncolytic adenoviruses are a novel cancer therapy, and replicate selectively within and lyse malignant cells, leading to productive infection of neighbouring cells. We found increased efficacy of adenoviruses of multiple subtypes in paclitaxel-resistant ovarian cancer cells. There was increased expression of a key adenovirus receptor, CAR (coxsackie adenovirus receptor), due to increased transcription that resulted from histone modification. Moreover, CAR transcription increased in intraperitoneal xenografts with acquired paclitaxel resistance and in tumours from patients with paclitaxel-resistant ovarian cancer. Finally, we identified dysregulated cell cycle control as a second mechanism of increased adenovirus efficacy in paclitaxel-resistant ovarian cancer and that inhibition of CDK4/6 using PD-0332991 was able both to reverse paclitaxel resistance and reduce adenovirus efficacy. Thus, paclitaxel resistance increases oncolytic adenovirus efficacy via at least two separate mechanisms. Parental SKOV3 and paclitaxel-resistant SKOV3-TR cells were analysed in duplicate

Project description:The mechanisms of primary ovarian cancer cells for resistance to viral oncolysis were investigated using Ad5/35.IR.E1A/TRAIL on clonal cultures derived from ovc316m cells. Part 2 of 2, 26 clonal ovc316m cultures additionally to Resistance of primary ovarian cancer cells to oncolytic adenoviruses part1 of 2 Cells were infected for 8 days and cell survival determined by MTT assay. Uninfected control cells of each clonal culture were utilized for DNA expression arrays. SKOV3-ip1 cells were used for reference RNA in all samples. The reference RNA from SKOV3-ip1 cells for part 2 of 2 had to be re-amplified.

Project description:The microtubule-stabilising drug paclitaxel has activity in relapsed ovarian cancer. However, resistance frequently develops. Oncolytic adenoviruses are a novel cancer therapy, and replicate selectively within and lyse malignant cells, leading to productive infection of neighbouring cells. We found increased efficacy of adenoviruses of multiple subtypes in paclitaxel-resistant ovarian cancer cells. There was increased expression of a key adenovirus receptor, CAR (coxsackie adenovirus receptor), due to increased transcription that resulted from histone modification. Moreover, CAR transcription increased in intraperitoneal xenografts with acquired paclitaxel resistance and in tumours from patients with paclitaxel-resistant ovarian cancer. Finally, we identified dysregulated cell cycle control as a second mechanism of increased adenovirus efficacy in paclitaxel-resistant ovarian cancer and that inhibition of CDK4/6 using PD-0332991 was able both to reverse paclitaxel resistance and reduce adenovirus efficacy. Thus, paclitaxel resistance increases oncolytic adenovirus efficacy via at least two separate mechanisms.

Project description:Autophagy-overactivated composite microbe engineered from oncolytic adenoviruses for the cascade enhancement of cancer immunotherapy

Project description:Although oncolytic adenoviruses have been widely studied for their direct oncolytic activity and immunomodulatory role in cancer immunotherapy, the immunosuppressive feedback loop induced by oncolytic adenoviruses remains poorly studied. Here, we showed that type V adenovirus (ADV) induces the polarization of tumor-associated macrophages (TAMs) to the M2 phenotype and increases the infiltration of regulatory T cells (Tregs) in the tumor microenvironment (TME). By selectively compensating for these deficiencies, Tα1 reprogrammed “M2-like” TAMs toward an antitumoral phenotype, thereby reprogramming the TME into a state more beneficial for antitumor immunity. Moreover, ADVTα1 was constructed by harnessing the merits of all the components for the aforementioned combinatorial therapy. Both in vitro and in vivo data showed that both exogenously supplied and adenovirus-produced Tα1 orchestrate TAM reprogramming and enhance the antitumor efficacy of ADV via CD8+ T cells, showing promising prospects for clinical translation. Our findings provide inspiration for improving oncolytic adenovirus combination therapy and designing new oncolytic engineered adenoviruses.

Project description:Although oncolytic adenoviruses have been widely studied for their direct oncolytic activity and immunomodulatory role in cancer immunotherapy, the immunosuppressive feedback loop induced by oncolytic adenoviruses remains poorly studied. Here, we showed that type V adenovirus (ADV) induces the polarization of tumor-associated macrophages (TAMs) to the M2 phenotype and increases the infiltration of regulatory T cells (Tregs) in the tumor microenvironment (TME). By selectively compensating for these deficiencies, Tα1 reprogrammed “M2-like” TAMs toward an antitumoral phenotype, thereby reprogramming the TME into a state more beneficial for antitumor immunity. Moreover, ADVTα1 was constructed by harnessing the merits of all the components for the aforementioned combinatorial therapy. Both in vitro and in vivo data showed that both exogenously supplied and adenovirus-produced Tα1 orchestrate TAM reprogramming and enhance the antitumor efficacy of ADV via CD8+ T cells, showing promising prospects for clinical translation. Our findings provide inspiration for improving oncolytic adenovirus combination therapy and designing new oncolytic engineered adenoviruses.