The present invention relates to polypeptide for engineering integrase chimeric proteins and their use in gene therapy. In particular, the present invention relates to a polypeptide which comprises the amino acid sequence ranging from the amino acid residue at position 617 to the amino acid residue at position 622 in SEQ ID NO: 1 or a function conservative thereof.

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 treating Zika virus 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 Zika epitopes, such as, for example, from Zika envelope glycoprotein E and the Zika structural protein NS1 including variants thereof.

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.

Provided herein are delivery particle systems (XDP) useful for the delivery of payloads of any type. In some embodiments, a XDP particle system with tropism for target cells of interest is used to deliver CRISPR/Cas polypeptides (e.g., CasX proteins) and guide nucleic acids (gNA), for the modification of nucleic acids in target cells. Also provided are methods of making and using such XDP to modify the nucleic acids in such cells.

The present invention relates to methods and kits for diagnosis of cancer in a subject by detecting human endogenous retrovirus env (HERV-WL) polypeptides.

Covalently-linked DNA polymerases are provided.

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.

Described herein are virus-like particles (VLPs) and minimal human-derived virus-like particles (mhVLPs), comprising a membrane comprising a phospholipid bilayer with one or more human-derived envelope glycoproteins (env) on the external side. Optionally, a biomolecule cargo is disposed in the core of the VLP or mhVLP on the inside of the membrane. Preferably, the mhVLPs do not comprise any exogenous virally derived proteins, e.g., proteins from viral gag, pro, or pol, or other viral proteins that reside inside of enveloped particles (unless the cargo comprises the viral protein(s)). In some embodiments, the mhVLPs do not comprise any human endogenous retroviral (HERV) proteins other than the env (hENV), e.g., do not comprise gag, pol, or pro that was exogenously introduced into producer cells. In some embodiments, the VLPs include a targeting domain, either fused at the N or C terminus or internally into the hENV, or as a separate membrane-anchored targeting domain. Also described are methods of use of the VLPs or mhVLPs for delivery of the biomolecule cargo to cells.

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.