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.

Polyclonal Antibodies produced using HIV-1 Trimeric Envelope Glycoprotein Subunits (TEGS) are provided. TEGS are comprised of non-infectious complexes comprising a trimeric envelope glycoprotein subunit comprising gp120 bound to membrane-anchored trimeric native gp41. The gp120 and gp41 present in the TEGS are not chemically fixed or cross-linked. Immunization with the TEGS elicits polyclonal antibodies that neutralize diverse viruses in HIV infection assay using peripheral blood mononuclear cells (PBMCs). The present invention relates to a method for reducing the occurrence and/or severity of HIV infections.

The present invention provides methods of making engineered viral proteins and protein complexes that are useful as vaccine immunogens, engineered viral proteins and protein complexes made using such methods, and pharmaceutical compositions comprising such engineered viral proteins and protein complexes. Such engineered viral proteins and protein complexes may comprise one or more cross-links that stabilize the conformation of an antibody epitope, such as a quaternary neutralizing antibody, and may exhibit an enhanced ability to elicit a protective immune response when administered to a subject as a component of a vaccine.

A method for preparing an infectious, recombinant virus vector comprises the steps of: (a) infecting host cells with a first virus comprising an encapsidation defective adenovirus (edAd), the edAd comprising a first defective virus genome; (b) incubating the infected host cells in a culture medium for a period of time sufficient for producing infectious virus particles; and (c) recovering infectious virus particles secreted into a culture supernatant, wherein the edAd or the host cells comprise a second defective virus genome engineered to express a target gene of interest, wherein the edAd or the host cells comprise nucleic acid sequences sufficient for expressing adenovirus (Ad) helper genes necessary for replication of the defective virus DNA; and wherein the edAd or the host cells comprise nucleic acid sequences sufficient from expressing helper functions necessary for producing infectious, replication defective virus particles corresponding to the second virus.

This invention relates to novel anti-HIV antibodies that can be used in the treatment and detection of human immunodeficiency virus (HIV). These antibodies exhibit a high degree of sensitivity and can provide a broad range of specificity.

The present invention relates to a retro viral system for the transfer of non-viral RNA into target cells and more particularly a retroviral particle capable of delivering multiple RNAs. More particularly, it relates to retroviral particles comprising a protein derived from the Gag polyprotein, an envelope protein, optionally an integrase and at least two encapsidated non-viral RNAs, the encapsidated non-viral RNAs each comprising an RNA sequence of interest linked to an encapsidation sequence, each encapsidation sequence being recognised by a binding domain introduced into the protein derived from the Gag polyprotein and/or into the integrase.

The present invention relates to a retroviral system for the transfer of non-viral RNA into target cells and more particularly a retroviral particle capable of delivering multiple RNAs. More particularly, it relates to retroviral particles comprising a protein derived from the Gag polyprotein an envelope protein, optionally an integrase and at least two encapsidated non-viral RNAs, the encapsidated non-viral RNAs each comprising an RNA sequence of interest linked to an encapsidation sequence, each encapsidation sequence being recognised by a binding domain introduced into the protein derived from the Gag polyprotein and/or into the integrase.

The invention relates to methods of improving titer in transfection-based bioreactor culture production or transfection-based production systems using eukaryotic cells.

In one aspect of the present disclosure is a method of harvesting viral titer about every 40 hours to about every 56 hours following induction of stable producer cell line cells, wherein the viral titer is at least partially harvested in a serum-free medium. In another aspect of the present disclosure is a method of harvesting vector supernatant comprising: generating stable producer cell line cells; inducing viral vector production from the generated stable producer cell line cells; and repeatedly harvesting the viral vectors from the induced generated stable producer cell line cells in serum-free media every about 40 to about 56 hours following an initial harvesting of the viral vectors.

The present disclosure provides methods for manufacturing a recombinant lentiviral vectors in an adherent bioreactor, for example, by calcium-phosphate transfection of cells grown in adherent mode on low-compaction macrocarriers in an iCELLis® bioreactor system.