Preclinical Evaluation of Differentially Targeting Dual Virotherapy for Human Solid Cancer

Sakai, Ryo; Kagawa, Shunsuke; Yamasaki, Yasumoto; Kojima, Toru; Uno, Futoshi; Hashimoto, Yuichi; Watanabe, Yuichi; Urata, Yasuo; Tanaka, Noriaki; Fujiwara, Toshiyoshi

doi:10.1158/1535-7163.mct-10-0205

Cited by 20 publications

(5 citation statements)

References 28 publications

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“…We recently reported that combination therapy with OBP-301 and Adp53 resulted in a more profound antitumor effect than monotherapy with either OBP-301 or Ad-p53 (25). Moreover, we generated armed OBP-301 expressing the wildtype p53 tumor suppressor gene (OBP-702) and showed that OBP-702 suppressed the viability of various types of epithelial malignant cells more efficiently than did OBP-301 (26).…”

Section: Introductionmentioning

confidence: 99%

Dual Programmed Cell Death Pathways Induced by p53 Transactivation Overcome Resistance to Oncolytic Adenovirus in Human Osteosarcoma Cells

Hasei

Sasaki

Tazawa

et al. 2013

Molecular Cancer Therapeutics

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Tumor suppressor p53 is a multifunctional transcription factor that regulates diverse cell fates, including apoptosis and autophagy in tumor biology. p53 overexpression enhances the antitumor activity of oncolytic adenoviruses; however, the molecular mechanism of this occurrence remains unclear. We previously developed a tumor-specific replication-competent oncolytic adenovirus, OBP-301, that kills human osteosarcoma cells, but some human osteosarcoma cells were OBP-301-resistant. In this study, we investigated the antitumor activity of a p53-expressing oncolytic adenovirus, OBP-702, and the molecular mechanism of the p53-mediated cell death pathway in OBP-301-resistant human osteosarcoma cells. The cytopathic activity of OBP-702 was examined in OBP-301-sensitive (U2OS and HOS) and OBP-301-resistant (SaOS-2 and MNNG/ HOS) human osteosarcoma cells. The molecular mechanism in the OBP-702-mediated induction of two cell death pathways, apoptosis and autophagy, was investigated in OBP-301-resistant osteosarcoma cells. The antitumor effect of OBP-702 was further assessed using an orthotopic OBP-301-resistant MNNG/HOS osteosarcoma xenograft tumor model. OBP-702 suppressed the viability of OBP-301-sensitive and -resistant osteosarcoma cells more efficiently than OBP-301 or a replication-deficient p53-expressing adenovirus (Adp53). OBP-702 induced more profound apoptosis and autophagy when compared with OBP-301 or Ad-p53. E1A-mediated miR-93/106b upregulation induced p21 suppression, leading to p53-mediated apoptosis and autophagy in OBP-702-infected cells. p53 overexpression enhanced adenovirus-mediated autophagy through activation of damage-regulated autophagy modulator (DRAM). Moreover, OBP-702 suppressed tumor growth in an orthotopic OBP-301-resistant MNNG/HOS xenograft tumor model. These results suggest that OBP-702-mediated p53 transactivation is a promising antitumor strategy to induce dual apoptotic and autophagic cell death pathways via regulation of miRNA and DRAM in human osteosarcoma cells.

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Section: Introductionmentioning

confidence: 99%

Dual Programmed Cell Death Pathways Induced by p53 Transactivation Overcome Resistance to Oncolytic Adenovirus in Human Osteosarcoma Cells

Hasei

Sasaki

Tazawa

et al. 2013

Molecular Cancer Therapeutics

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“…Upon infection, E1A and E1B are expressed and induce viral replication and cellular lysis in TERT promoter active tumor cells, while sparing TERT promoter inactive benign cells [ 160 ]. In vitro , the oncolytic virus OBP-301 (telomelysin) has been shown to selectively lyse lung cancer cells [ 161 ], kill CD133+ human gastric cancer stem-like cells [ 162 ], and inhibit lung tumor xenografts treated with direct intratumoral injection [ 163 ]. In phase I testing, OBP-301 was well tolerated at three different dose levels with no serious adverse events [ 136 ].…”

Section: Telomere and Telomerase Therapeuticsmentioning

confidence: 99%

Telomere and Telomerase Therapeutics in Cancer

Goldkorn

2016

Genes

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Telomerase is a reverse transcriptase capable of utilizing an integrated RNA component as a template to add protective tandem telomeric single strand DNA repeats, TTAGGG, to the ends of chromosomes. Telomere dysfunction and telomerase reactivation are observed in approximately 90% of human cancers; hence, telomerase activation plays a unique role as a nearly universal step on the path to malignancy. In the past two decades, multiple telomerase targeting therapeutic strategies have been pursued, including direct telomerase inhibition, telomerase interference, hTERT or hTERC promoter driven therapy, telomere-based approaches, and telomerase vaccines. Many of these strategies have entered clinical development, and some have now advanced to phase III clinical trials. In the coming years, one or more of these new telomerase-targeting drugs may be expected to enter the pharmacopeia of standard care. Here, we briefly review the molecular functions of telomerase in cancer and provide an update about the preclinical and clinical development of telomerase targeting therapeutics.

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“…For example, AD5CMV-p53 is an adenoviral vector encoding p53 that was shown to replenish p53 in p53 deficient tumor cells. This approach inhibited lung cancer cell growth both in vitro and in vivo [141]. Clinical phase I and II trials have subsequently demonstrated that this agent is both safe and effective against esophageal squamous cell carcinoma [142, 143].…”

Section: Fak Inhibitorsmentioning

confidence: 99%

Evolving Therapies and FAK Inhibitors for the Treatment of Cancer

Dunn

Heffler²,

Golubovskaya³

2010

ACAMC

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Despite advances in medical and surgical therapy, cancer kills more than half a million people in the United States annually, and the majority of these patients succumb to metastatic disease. The traditional approach to treating systemic disease has been the use of cytotoxic chemotherapy. However, chemotherapy is rarely curative and toxicity is often dose limiting. In addition, the effects of chemotherapy are nonspecific, targeting both malignant and normal tissues. As a result, recent efforts increasingly have focused on developing agents that target specific molecules in tumor cells in order to both improve efficacy and limit toxicity. This review summarizes the history and current use of targeted molecular therapy for cancer, with a special emphasis on recently developed inhibitors of Focal Adhesion Kinase (FAK).

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Preclinical Evaluation of Differentially Targeting Dual Virotherapy for Human Solid Cancer

Cited by 20 publications

References 28 publications

Dual Programmed Cell Death Pathways Induced by p53 Transactivation Overcome Resistance to Oncolytic Adenovirus in Human Osteosarcoma Cells

Dual Programmed Cell Death Pathways Induced by p53 Transactivation Overcome Resistance to Oncolytic Adenovirus in Human Osteosarcoma Cells

Telomere and Telomerase Therapeutics in Cancer

Evolving Therapies and FAK Inhibitors for the Treatment of Cancer

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