The present invention describes a unique method of treating cancer with the administration of an improved DAGRS™ construct which functions as a humanized agent specifically targeting cancer cells in vivo. A specific DAGRS™ is described constructed of a humanized drug delivery biologic, carboxyl to an Apoptin fragment consisting of Apoptin's proline-rich SH3-binding fragment, a spacer, and a MAP kinase (MAPK) phosphorylation site, in replacement of the SH3-binding domain at HIV-1 TAT's amino terminus. Apoptin is a viral protein with incumbent immunogenicity and toxicity in humans. Improved DAGRS™ constructs are described that replace the viral VP3 peptide with human AKT peptide or derivative, all equivalently spaced 11 amino acids from the initial proline to the beginning of the MAPK phosphorylation site, through which technology the DAGRS™ is fully humanized. DAGRS™ provide for improved bioavailability, enhanced specific activity, and low toxicity for in vivo treatment of cancer. DAGRS™ are a superior method for targeting any oncogene with an inhibitory peptide. An algorithm for “humanization” is described through which human functional equivalent(s) to viral product(s) are identified by alignment of peptides anchored at each end by matching functional motifs that are spaced equivalently distant in the two aligned peptides. The algorithm totally disregards the primary amino acid composition of the spacer, and as such separates from current computer algorithms that prioritize primary amino acid alignments. Accounting for spacing dictates that functional domains be oriented correctly in three dimensions. The invention taught here can be developed into computer algorithms for rapidly identifying these anchored alignments, and thereafter developing safe humanized drugs from disruptive viral activities. Computers once taught the basic rules for anchoring equivalents, can improve on the basic algorithm through artificial intelligence to expand drug development.

Disclosed herein are methods and systems for manufacturing viral vectors (e.g., lentiviral vectors) using a static light scattering device in-line with a manufacturing process.

Described herein is a method for high-efficiency virus enrichment and purification using an asymmetric nanopore membrane (ANM) filtration technology. The ANM design prevents viral particle deformation, lysing, and fusion due to the strong external force and thus significant increases the yield while preserving other advantages of size-based ultrafiltration. It also offers a unique feature of being able to flush the contaminating proteins from the viral particles. It offers higher throughput, yield, sample purity, concentration factor, and more precise size fractionation than current approaches.

We have modified a commercially-available adherent cell culture bioreactor in several ways to increase productivity of cultured cells, while decreasing contamination risk. We found that modifying a commercially-available adherent cell culture bioreactor to provide for slower cell culture medium flow unexpectedly and dramatically increases the productivity of the cultured adherent cells. We also developed a new sampling manifold configuration and new way of taking samples, to reduce contamination risk.

The present invention is directed to recombinant lentiviral particles that array the SARS-CoV-2 spike (S) protein on their surface (“SARS-CoV-2 S Protein Lentiviral Particles”), and that optionally comprise an additional copy of a polynucleotide encoding the SARS-CoV-2 spike (S) protein in their viral genome, and to methods for the production of such lentiviral particles. The invention particularly pertains to such SARS-CoV-2 S Protein Lentiviral Particles that have been engineered to be incapable of mediating the integration of their lentiviral genome into the chromosomes of infected cells and/or to be incapable of mediating the reverse transcription of their lentiviral genome. The present invention is also directed to “SARS-CoV-2 S Protein Lentiviral Vaccine” pharmaceutical compositions that comprise such SARS-CoV-2 S Protein Lentiviral Particles. The present invention is additionally directed to the use of such SARS-CoV-2 S Protein Lentiviral Vaccine pharmaceutical compositions for providing immunity to COVID-19 infection to humans and other mammals, either directly or as an inactivated form.

Materials and methods useful for generating highly mannosylated pseudotyped lentiviral vector particles comprising a Vpx protein are provided.

Methods for preparing highly purified rLV vector formulations at the scale needed to meet anticipated demand for human gene therapy are provided.

The invention relates to methods of purifying viral vectors from cell culture. In particular, the invention relates to a method of purifying a supernatant containing viral vectors from a cell culture by removing cells by filtering the cell culture using diatomaceous earth.

Provided is a method for large-scale preparation of a purified preparation of a recombinant lentiviral vector at the GMP grade. The method comprises: (a) providing raw material feed liquid to be purified that comprises recombinant viral vectors; (b) carrying out a microfiltration treatment on the feed liquid to obtain a microfiltered filtrate comprising the recombinant viral vectors; (c) optionally concentrating the filtrate to obtain a concentrated filtrate; (d) purifying the filtrate obtained in the previous step by means of chromatography to obtain a crude pure product comprising the recombinant viral vectors; and (e) subjecting the crude pure product obtained in the previous step to liquid exchange and elaborate purification to obtain the purified recombinant viral vectors.

Provided is a method for large-scale production of lentivirus by using GMP-level serum-free suspension cells. Said method comprises the following steps: (a) providing a seed solution of packaged cells; (b) inoculating the seed solution in a first culture solution; (c) carrying out subculture of the packaged cells; (d) starting a liquid change operation when a liquid change trigger condition is met; (e) repeating steps (c) and (d) 1, 2 or 3 times; (f) starting a transfection operation when a transfection trigger condition is met; (g) optionally performing liquid change after transfection; (h) cultivating the transfected packaged cells; (i) starting harvesting and liquid change operations when a liquid change trigger condition is met; (j) repeating steps (h) and (i) 1, 2 or 3 times; (k) combining each of the recovered liquids; and (1) performing a purifying treatment. The culture solution used in each step is a serum-free cell culture solution.