Intravenous delivery of oncolytic reovirus to brain tumor patients immunologically primes for subsequent checkpoint blockade.
Adel SamsonKaren J ScottDavid TaggartEmma J WestErica B WilsonGerard J NuovoSimon ThomsonRobert CornsRyan Koshy MathewMartin J FullerTimothy J KottkeJill M ThompsonElizabeth J IlettJulia V CocklePhilip van HilleGnanamurthy SivakumarEuan S PolsonSamantha J TurnbullElizabeth S AppletonGemma MignecoAilsa S RoseMatthew C CoffeyDeborah A BeirneFiona J CollinsonChristy RalphAlan AnthonyChristopher J TwelvesAndrew J FurnessSergio A QuezadaHeiko WurdakFiona Errington-MaisHardev PandhaKevin J HarringtonPeter John SelbyRichard G VileStephen D GriffinLucy F SteadSusan C ShortAlan A MelcherPublished in: Science translational medicine (2019)
Immune checkpoint inhibitors, including those targeting programmed cell death protein 1 (PD-1), are reshaping cancer therapeutic strategies. Evidence suggests, however, that tumor response and patient survival are determined by tumor programmed death ligand 1 (PD-L1) expression. We hypothesized that preconditioning of the tumor immune microenvironment using targeted, virus-mediated interferon (IFN) stimulation would up-regulate tumor PD-L1 protein expression and increase cytotoxic T cell infiltration, improving the efficacy of subsequent checkpoint blockade. Oncolytic viruses (OVs) represent a promising form of cancer immunotherapy. For brain tumors, almost all studies to date have used direct intralesional injection of OV, because of the largely untested belief that intravenous administration will not deliver virus to this site. We show, in a window-of-opportunity clinical study, that intravenous infusion of oncolytic human Orthoreovirus (referred to herein as reovirus) leads to infection of tumor cells subsequently resected as part of standard clinical care, both in high-grade glioma and in brain metastases, and increases cytotoxic T cell tumor infiltration relative to patients not treated with virus. We further show that reovirus up-regulates IFN-regulated gene expression, as well as the PD-1/PD-L1 axis in tumors, via an IFN-mediated mechanism. Finally, we show that addition of PD-1 blockade to reovirus enhances systemic therapy in a preclinical glioma model. These results support the development of combined systemic immunovirotherapy strategies for the treatment of both primary and secondary tumors in the brain.
Keyphrases
- gene expression
- end stage renal disease
- newly diagnosed
- high grade
- ejection fraction
- prognostic factors
- immune response
- dendritic cells
- healthcare
- small cell lung cancer
- chronic kidney disease
- dna damage
- brain metastases
- stem cells
- squamous cell carcinoma
- cancer therapy
- dna methylation
- low dose
- peritoneal dialysis
- clinical trial
- transcription factor
- lymph node
- mesenchymal stem cells
- small molecule
- cell cycle
- cell therapy
- young adults
- quality improvement
- cell proliferation
- free survival
- subarachnoid hemorrhage
- patient reported
- combination therapy
- drug delivery
- multiple sclerosis
- binding protein
- protein protein
- lymph node metastasis