The instant invention provides materials and methods for producing immunologically active antigens derived from members of the Picornaviridae virus family. The picornavirus antigens of the invention may be in a form for use as a vaccine administered to a subject in a therapeutic treatment or for the prevention of a picornavirus infection. The picornavirus antigens of the invention may be in the form of an immunogenic composition for use in vaccines which are administered for the prevention of an Enterovirus infection. The instant invention further encompasses immunogenic compositions comprising Human enterovirus A, Human enterovirus B, Human enterovirus C, Human enterovirus D antigens and their use in vaccines for the prevention of an Enterovirus infection.

The present disclosure relates to methods of producing Enterovirus A, e.g., for vaccine production, that include culturing cells in a fixed bed bioreactor. Further provided herein is an Enterovirus A produced by the methods of production disclosed herein, as well as compositions, immunogenic compositions, and vaccines related thereto.

The instant invention provides materials and methods for producing immunologically active antigens derived from members of the Picornaviridae virus family. The picornavirus antigens of the invention may be in a form for use as a vaccine administered to a subject in a therapeutic treatment or for the prevention of a picornavirus infection. The picornavirus antigens of the invention may be in the form of an immunogenic composition for use in vaccines which are administered for the prevention of an Enterovirus infection. The instant invention further encompasses immunogenic compositions comprising Human enterovirus A, Human Enterovirus B, Human enterovirus C, Human Enterovirus D antigens and their use in vaccines for the prevention of an enterovirus infection.

Methods and compositions for detection of enterovirus D in a sample, particularly detection of enterovirus D68, are provided. The methods include contacting a sample with at least one primer (such as a forward primer and/or a reverse primer) capable of specifically amplifying an EV-D68 viral protein 1 (VP1) nucleic acid or a portion thereof and/or a detectably labeled probe capable of specifically hybridizing to an EV-D68 VP1 nucleic acid, under conditions sufficient for specific amplification of the EV-D68 VP1 nucleic acid by the at least one primer and/or under conditions sufficient for specific hybridization of the probe to the EV-D68 nucleic acid. The amplification of the EV-D68 VP1 nucleic acid and/or the hybridization of the probe to the EV-D68 VP1 nucleic acid is detected, thereby identifying presence of EV-D68 in the sample.

Methods and compositions for detection of enterovirus D in a sample, particularly detection of enterovirus D68, are provided. The methods include contacting a sample with at least one primer (such as a forward primer and/or a reverse primer) capable of specifically amplifying an EV-D68 viral protein 1 (VP1) nucleic acid or a portion thereof and/or a detectably labeled probe capable of specifically hybridizing to an EV-D68 VP1 nucleic acid, under conditions sufficient for specific amplification of the EV-D68 VP1 nucleic acid by the at least one primer and/or under conditions sufficient for specific hybridization of the probe to the EV-D68 nucleic acid. The amplification of the EV-D68 VP1 nucleic acid and/or the hybridization of the probe to the EV-D68 VP1 nucleic acid is detected, thereby identifying presence of EV-D68 in the sample.

Methods of inhibiting or reducing tumor growth are disclosed. A composition containing at least one selected oncolytic virus is administered within a tumor of a patient. The virus kills cancerous cells and induces a systemic and lasting anti-tumor immunity that is also compatible with other cancer treatments. Also disclosed are methods of creating synthetic viruses for targeting cancerous tumors.

Provided is a Coxsackievirus A6 (CVA6) strain CVA6-KM-J33 and use thereof, and belongs to the technical field of biomedicine. The present invention provides a CVA6 strain CVA6-KM-J33, which belongs to a CVA6 virus. In the present invention, the strain CVA6-KM-J33 is susceptible to KMB17 cells and can achieve a relatively high titer. The strain has strong virulence, high pathogenicity and lethality to suckling mice, and desirable immunogenicity, and is a highly effective virus strain for CVA6 vaccine development. This strain can be used for immunogenicity evaluation or protective evaluation of CVA6 vaccine to improve the accuracy and reproducibility of vaccine immunogenicity evaluation. This strain can also be used to prepare animal models of Coxsackievirus (CV) infection, and exhibits desirable application prospects.

Provided herein are engineered cell lines. In some embodiments, cells of an engineered cell line have altered expression of a gene and/or altered expression of an miRNA, wherein the altered expression results in increased or decreased production of a virus. The virus is a picomavirus, such as a poliovirus or Enterovirus 71. Also provided herein are methods for using the engineered cells to produce virus, and methods for treating a subject having or at risk of having a viral infection.

The present invention relates to a recombinant adenoviral vector for generating immunity against enterovirus infection. In one embodiment, the recombinant adenoviral vector of the invention comprises an expression cassette encoding a PI protein and a 3 CD protease of an enterovirus. In another embodiment, the recombinant adenoviral vector of the invention comprises an expression cassette encoding a 3C protease or a 3CD protease of an enterovirus. The present invention also relates to a vaccine composition comprising the recombinant adenoviral vector as described. A method of inducing an immune response in a subject against enterovirus infection using the recombinant adenoviral vector and the vaccine composition is provided. Further provided is a method for producing virus like particles of an enterovirus by expressing the adenoviral vector as described herein in mammalian cells.

Methods of inhibiting or reducing tumor growth are disclosed. A composition containing at least one selected oncolytic virus is administered within a tumor of a patient. The virus kills cancerous cells and induces a systemic and lasting anti-tumor immunity that is also compatible with other cancer treatments. Also disclosed are methods of creating synthetic viruses for targeting cancerous tumors.