Jiahu Wang1, Rozanne Arulanandam1, Richard Wassenaar2, Theresa Falls1, Julia Petryk2, Judith Paget1, Kenneth Garson1, Catia Cemeus1, Barbara C Vanderhyden1,3, R Glenn Wells2, John C Bell1,4, Fabrice Le Boeuf5. 1. Centre for Innovative Cancer Research, Ottawa Hospital Research Institute, Ottawa, Ontario, Canada. 2. Cardiac PET Research, University of Ottawa Heart Institute, Ottawa, Ontario, Canada. 3. Department of Cellular and Molecular Medicine, University of Ottawa, Ottawa, Ontario, Canada; and. 4. Department of Biochemistry, Microbiology and Immunology, University of Ottawa, Ottawa, Ontario, Canada. 5. Centre for Innovative Cancer Research, Ottawa Hospital Research Institute, Ottawa, Ontario, Canada fleboeuf@ohri.ca.
Abstract
Oncolytic virus (OV) therapy has emerged as a novel tool in our therapeutic arsenals for fighting cancer. As a live biologic agent, OV has the ability to target and selectively amplify at the tumor sites. We have reported that a vaccinia-based OV (Pexa-Vec) has shown good efficacy in preclinical models and in clinical trials. To give an additional tool to clinicians to allow both treatment of the tumor and improved visualization of tumor margins, we developed new viral-based platforms with 2 specific gene reporters. METHODS: We incorporated the human sodium iodide symporter (hNIS) and the human somatostatin receptor 2 (hSSR2) in the vaccinia-based OV and tested viral constructs for their abilities to track and treat tumor development in vivo. RESULTS: Early and high-level expression of hNIS is detrimental to the recombinant virus, leading to the aggregation of hNIS protein and early cell death. Putting hNIS under a late synthetic promoter allowed a higher functional expression of the protein and much stronger 123I or 99Tc uptake. In vivo, the hNIS-containing virus infected and amplified in the tumor site, showing a better efficacy than the parental virus. The hNIS expression at the tumor site allowed for the imaging of viral infection and tumor regression. Similarly, hSSR2-containing OV vaccinia infected and lysed cancer cells. CONCLUSION: When tumor-bearing mice were given hNIS- and hSSR2-containing OV, 99Tc and 111In signals coalesced at the tumor, highlighting the power of using these viruses for tumor diagnosis and treatment.
Oncolytic virus (OV) therapy has emerged as a novel tool in our therapeutic arsenals for fighting cancer. As a live biologic agent, OV has the ability to target and selectively amplify at the tumor sites. We have reported that a vaccinia-based OV (Pexa-Vec) has shown good efficacy in preclinical models and in clinical trials. To give an additional tool to clinicians to allow both treatment of the tumor and improved visualization of tumor margins, we developed new viral-based platforms with 2 specific gene reporters. METHODS: We incorporated the humansodium iodide symporter (hNIS) and the humansomatostatin receptor 2 (hSSR2) in the vaccinia-based OV and tested viral constructs for their abilities to track and treat tumor development in vivo. RESULTS: Early and high-level expression of hNIS is detrimental to the recombinant virus, leading to the aggregation of hNIS protein and early cell death. Putting hNIS under a late synthetic promoter allowed a higher functional expression of the protein and much stronger 123I or 99Tc uptake. In vivo, the hNIS-containing virus infected and amplified in the tumor site, showing a better efficacy than the parental virus. The hNIS expression at the tumor site allowed for the imaging of viral infection and tumor regression. Similarly, hSSR2-containing OV vaccinia infected and lysed cancer cells. CONCLUSION: When tumor-bearing mice were given hNIS- and hSSR2-containing OV, 99Tc and 111In signals coalesced at the tumor, highlighting the power of using these viruses for tumor diagnosis and treatment.
Authors: Raquel Yokoda; Bolni M Nagalo; Brent Vernon; Rahmi Oklu; Hassan Albadawi; Thomas T DeLeon; Yumei Zhou; Jan B Egan; Dan G Duda; Mitesh J Borad Journal: Oncolytic Virother Date: 2017-11-08
Authors: Cristina Barca; Christoph M Griessinger; Andreas Faust; Dominic Depke; Markus Essler; Albert D Windhorst; Nick Devoogdt; Kevin M Brindle; Michael Schäfers; Bastian Zinnhardt; Andreas H Jacobs Journal: Pharmaceuticals (Basel) Date: 2021-12-22