Provided is an M2-LVP-K1 virus including a colorectal cancer cell-specific mutant sialic acid binding domain and a composition for treating colorectal cancer including the same. The mutant sialic acid binding domain is constructed using directed evolution technology, and is a recombinant Newcastle disease virus constructed by substituting a normal sialic acid binding domain for a HN protein, a cell-binding receptor, to improve the specific infectivity to HCT116 cells. It was identified that M2-LVP-K1 recombinant Newcastle disease virus with improved colorectal cancer cell-specific infectivity has improved HCT116 cell death effect compared to the conventional normal recombinant Newcastle disease virus, and produces an excellent effect in inhibiting cancer tissue growth through in vivo experiments. The mutant recombinant Newcastle disease virus presented in this study relates to a therapeutic viral agent capable of inducing clinical symptom reduction, partial remission, or complete remission through colorectal cancer cell death or colorectal cancer tissue shrinkage.

The present application discloses a recombinant Newcastle disease virus genome, a recombinant Newcastle disease virus rNDV-VEGF-Trap containing the genome and a preparation method therefor, a DNA molecule encoding the recombinant Newcastle disease virus genome, and a use of the genome and the recombinant Newcastle disease virus in the preparation of a drug for treating cancer. The recombinant Newcastle disease virus provided by the present application relates to inserting a coding gene of VEGF-Trap into the genome of the recombinant Newcastle disease virus, such that the recombinant Newcastle disease virus obtained therefrom is replicated with a strong replication capability, thereby killing host cancer cells; moreover, the recombinant Newcastle disease virus has reliable safety for non-cancer cells, and shows improved anti-tumor effect and oncolytic efficiency.

Disclosed are means of treatment of cancer by enhancing efficacy of oncolytic virus ability to eradicate tumors through the destruction/inactivation of cancer endothelial cells through immunological means. In one embodiment of the invention, administration of placental endothelial cells generated antitumor endothelial immune responses are used to sensitize tumors to oncolytic viral entry. In another embodiment, oncolytic viruses are utilized to enhance generation of cancer endothelial specific responses by causing localized inflammation in the tumor endothelium, which enhances efficacy of the tumor endothelial targeting vaccine. In another embodiment, the invention teaches the use of replication deficient oncolytic viruses to deliver proteins to tumor cells in an immunogenic manner such that proteins encoded by the oncolytic viruses induce immunity to tumor endothelial cell antigens.

A recombinant fusion protein is disclosed. The fusion protein comprises: (a) a CD55 peptide sequence, (b) a linker sequence C-terminal to the CD55 sequence, (c) a transmembrane domain C-terminal to the linker sequence, and (d) an intracellular domain C-terminal to the transmembrane domain. The fusion protein does not contain a GPI anchor. The fusion protein can be expressed with an N-terminal secretory signal peptide, which is cleaved to yield the mature protein on the surface of a cell line or an enveloped virus. An oncolytic virus expressing the fusion protein is resistant to complement inactivation and can be used to treat cancer.

Described herein are chimeric Newcastle disease viruses engineered to express an agonist of a co-stimulatory signal of an immune cell and compositions comprising such viruses. Also described herein are chimeric Newcastle disease viruses engineered to express an antagonist of an inhibitory signal of an immune cell and compositions comprising such viruses. The chimeric Newcastle disease viruses and compositions are useful in the treatment of cancer. In addition, described herein are methods for treating cancer comprising administering Newcastle disease viruses in combination with an agonist of a co-stimulatory signal of an immune and/or an antagonist of an inhibitory signal of an immune cell.

Described herein are chimeric Newcastle disease viruses comprising a packaged genome comprising a transgene encoding interleukin-12. The chimeric Newcastle disease viruses and compositions thereof are useful in combination with an antagonist of programmed cell death protein 1 (PD-1) or a ligand thereof in the treatment of cancer. In particular, described herein are methods for treating cancer comprising administering the chimeric Newcastle disease viruses in combination with an antagonist of PD-1 or a ligand thereof, wherein the chimeric Newcastle disease virus comprises a packaged genome comprising a transgene encoding interleukin-12.

A recombinant Newcastle disease virus and a preparation method therefor, a recombinant plasmid, and use of the recombinant Newcastle disease virus or the recombinant plasmid. The recombinant Newcastle disease virus is obtained by replacing an F protein of a Newcastle disease virus lasota with an F protein encoded by a DNA as set forth in SEQ ID NO: 1 at positions 7274-8935 from a 5-terminus. The recombinant Newcastle disease virus is safe and capable of effectively inhibiting tumour cells and promoting tumour cell apoptosis.

Described herein are chimeric Newcastle disease viruses engineered to express an agonist of a co-stimulatory signal of an immune cell and compositions comprising such viruses. Also described herein are chimeric Newcastle disease viruses engineered to express an antagonist of an inhibitory signal of an immune cell and compositions comprising such viruses. The chimeric Newcastle disease viruses and compositions are useful in the treatment of cancer. In addition, described herein are methods for treating cancer comprising administering Newcastle disease viruses in combination with an agonist of a co-stimulatory signal of an immune and/or an antagonist of an inhibitory signal of an immune cell.

Provided are an oncolytic heterologous recombinant Newcastle disease virus (NDV), preparation method and application thereof. The heterologous recombinant NDV can express alpha (1,3) galactosyltransferase (1,3GT). The 1,3GT is the protein represented by the flowing B1) and B2): B1) the protein has an amino acid sequence of SEQ ID No.1; and B2) the protein is derived from B1) and has a function of 1,3GT obtained by substituting and/or deleting and/or adding one or more amino acid residue(s) in the amino acid sequence represented by SEQ ID No.1. The recombination NDV can be used for tumor treatment.

Described herein are chimeric Newcastle disease viruses engineered to express an agonist of a co-stimulatory signal of an immune cell and compositions comprising such viruses. Also described herein are chimeric Newcastle disease viruses engineered to express an antagonist of an inhibitory signal of an immune cell and compositions comprising such viruses. The chimeric Newcastle disease viruses and compositions are useful in the treatment of cancer. In addition, described herein are methods for treating cancer comprising administering Newcastle disease viruses in combination with an agonist of a co-stimulatory signal of an immune and/or an antagonist of an inhibitory signal of an immune cell.