The present invention relates to oncolytic virus comprising: (i) a GM-CSF-encoding gene; and (ii) an immune co-stimulatory pathway activating molecule or an immune co-stimulatory pathway activating molecule-encoding gene.

Described herein are pseudotyped oncolytic viruses comprising nucleic acids encoding an engager molecule. In some embodiments, the pseudotyped oncolytic viruses comprises nucleic acids encoding an engager molecule and one or more therapeutic molecules. Pharmaceutical compositions containing the pseudotyped oncolytic virus and methods of treating cancer using the pseudotyped oncolytic viruses are further provided herein.

The present invention relates to an oncolytic virus which is, or is derived from, a clinical isolate which has been selected by comparing the abilities of a panel of three or more clinical isolates of the same viral species to kill tumor cells of two or more tumor cell lines in vitro and selecting a clinical isolate which is capable of killing cells of two or more tumor cell lines more rapidly and/or at a lower dose in vitro than one or more of the other clinical isolates in the panel.

The present invention relates to oncolytic virus comprising: (i) a GM-CSF-encoding gene; and (ii) an immune co-stimulatory pathway activating molecule or an immune co-stimulatory pathway activating molecule-encoding gene.

The present invention provides a method of treating cancer, which comprises administering a therapeutically effective amount of an oncolytic virus, an inhibitor of the indoleamine 2,3-dioxygenase (IDO) pathway and a further antagonist of an immune co-inhibitory pathway or an agonist of an immune co-stimulatory pathway to a patient in need thereof.

The present invention relates to an oncolytic virus comprising: (i) a fusogenic protein-encoding gene; and (ii) an immune stimulatory molecule-encoding gene.

The present invention relates to an oncolytic virus which is, or is derived from, a clinical isolate which has been selected by comparing the abilities of a panel of three or more clinical isolates of the same viral species to kill tumor cells of two or more tumor cell lines in vitro and selecting a clinical isolate which is capable of killing cells of two or more tumor cell lines more rapidly and/or at a lower dose in vitro than one or more of the other clinical isolates in the panel.

The present invention relates to a recombinant adenovirus with increased in-vivo safety, tissue specificity, and anticancer activities, and a use thereof. Specifically, the recombinant adenovirus comprising: a promoter of the liver tissue-specific phosphoenolpyruvate carboxykinase (PEPCK) gene; a trans-splicing ribozyme which is operably linked to the promoter and acts on a cancer-specific gene; a therapeutic gene or a reporter gene which is linked to the 3 exon of the ribozyme; and a serotype 35 fiber knob and a serotype 5 shaft, in which the orf4 gene is deleted from adenovirus E1, E3 and E4 orf1, shows remarkable in-vivo safety, high specificity for a target tissue, and remarkable anticancer effects, and thus can be useful for an anticancer drug or a cancer diagnostic agent as a gene delivery vector.

The present disclosure provides, in general, a method for selecting a therapy for treating cancer in a human subject and subsequently treating cancer in a subject, which includes isolating a cancer cell from a human subject having cancer, determining the functional activity of STING or cGAS in the cell; and selecting a therapy for the cancer based on the functional activity of the STING or cGAS in the cell. Also provided, if the functional activity of STING and/or cGAS is determined to be defective in the cell, the therapy selected is one that is effective at killing STING-deficient and/or cGAS-deficient cancer cells, e.g., therapy including administering to the subject an oncolytic virus.

Compositions and methods are provided comprising soluble TRAIL polypeptide agents and cells engineered to express such agents for the treatment of multifocal brain metastases.