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 a cell membrane penetrating peptide and an intracellular delivery carrier including the same. The intracellular delivery carrier of the present invention has an advantage of efficiently transferring substances into cells even at a low concentration thereof compared with the existing cell membrane penetrating peptide derived from the virus.

The present invention provides a kit of vectors comprising a first and second viral vector, wherein the first viral vector comprises a transgene of interest (TOI), and presence of the second viral vector in a host cell is required for integration of the first viral vector TOI into the host cell genome.

The present invention describes the development of a modified envelope glycoproteins to pseudo-type viruses of the retroviridae family. These are derived from Murine leukaemia virus amphotropic, Gibbon Ape leukaemia virus and feline endogenous virus envelopes.

The improved envelope glycoproteins contain, among other modifications, newly introduced alternative cleavable sequences.

The viral vectors pseudo-typed with these modified envelopes may be suitably employed for cargo delivery such as in gene and cell therapy applications, for the ex vivo and in vivo delivery of gene(s), protein(s), or molecule(s) of interest to a variety of target cells.

There is provided a plasmid system for transfection into a cell to create a producer cell, the system comprising: a. a helper plasmid comprising a first nucleotide sequence encoding Murine leukemia virus (MLV)-derived Gag and Pol poly-proteins; b. an envelope plasmid comprising a second nucleotide sequence encoding an Env protein; c. a genome plasmid comprising a third nucleotide sequence encoding a retroviral genome, wherein the first nucleotide sequence is codon-shuffled to remove any significant regions of homology with the third nucleotide sequence; and wherein the second nucleotide sequence is codon-optimised for expression in the producer cell.

The present disclosure provides compositions and methods useful for preventing and/or treating coronavirus infection. As described herein, the compositions and methods are based on development of immunogenic compositions that include virus-like particles (VLPs) which comprise one or more Moloney Murine leukemia virus (MMLV) core proteins and include one or more coronavirus epitopes, such as, for example, from SARS-Cov-2 spike protein.

The present invention provides an effective vaccine for Marek's disease, which may be prepared using a recombinant Marek's Disease Virus (MDV), strain CVI988, having been transformed with a foreign DNA construct that includes a long terminal repeat sequence of a reticuloendotheliosis virus. This safe viral agent elicits a highly protective immune response in a chicken against virulent MDV challenge without causing a significant degree of pathogenicity. Suitable formulations of the vaccine for use in chickens include an effective immunization dosage of this novel viral agent, along with a pharmaceutically acceptable carrier or diluent.

The subject matter disclosed herein is generally directed to inhibition of XPR1 :KIDINS220-mediated phosphate export to treat cancer, in particular, ovarian and uterine cancers. The subject matter disclosed herein is also generally directed to determining cancer dependency on phosphate export by detecting the expression of SLC34A2. Compositions for inhibiting XPR1 :KIDINS220-mediated phosphate export are also described.

Described herein are compositions for delivering a therapeutic or vaccine. Also described herein are methods for using the compositions described herein for delivering a therapeutic or a vaccine.

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.