The present invention provides novel scaffolded HIV-1 vaccine immunogens. Some of the scaffolded immunogens contain a soluble gp140 trimer linked to the N-terminus of the nanoparticle subunit and a T-helper epitope that is fused via a short peptide spacer to the C-terminus of the nanoparticle subunit. Some other immunogens of the invention contain a soluble gp140 trimer protein that is linked to a stable nanoparticle via a short peptide spacer that is a T-helper epitope. Some of the scaffolded immunogens contain a gp140 trimer immunogen presented on a nanoparticle platform formed with I3-01 protein, E2p, or variants of protein 1VLW. Also provided in the invention are nucleic acids that encode the various vaccine immunogens described herein, and expression vectors and host cells harboring the nucleic acids. The invention further provides methods of using the scaffolded HIV-1 vaccine immunogens for preventing or treating HIV infections.

Provided are methods for identifying whether a compound inhibits entry of a virus into a cell. The method may include obtaining nucleic acid encoding a viral envelope protein from a patient infected by the virus and co-transfecting it into a first cell along with a viral expression vector which lacks a nucleic acid encoding the envelope protein. The method may further include contacting the viral particles produced by the first cell with a second cell to which the virus binds in the absence and presence of the compound and measuring the amount of signal produced by the second cell.

The present application relates to a lipopeptide for potently inhibiting HIV, a derivative thereof, or a pharmaceutical composition thereof, and use thereof. The lipopeptide is the following a) or b): a) a lipopeptide formed by linking a polypeptide having an antiviral activity to a lipophilic compound linked to the carboxyl-terminus of the polypeptide; or b) a lipopeptide formed by linking a polypeptide having an antiviral activity to a terminal protecting group and a lipophilic compound linked to the carboxyl-terminus of the polypeptide, wherein the terminal protecting group is an amino-terminal protecting group and/or a carboxyl-terminal protecting group, the polypeptide has a sequence of 28 amino acid residues, corresponding to amino acids at positions of 127-154 of the sequence of gp41 from HIV-1 strain HXB2. The anti-HIV activity of the lipopeptide of the present invention is higher than that of T-20 by several thousands of times or even tens of thousands of times, and is also significantly higher than that of the anti-HIV lipopeptides such as C34-Chol, LP-19 and the like.

The present invention provides methods for producing HIV-1 nanoparticle vaccines with enhanced immunogenicity. The methods entail (1) enzymatic digestion of glycan chain on the surface of a self-assembling nanoparticle vaccine displaying an HIV-1 Env derived trimer immunogen, or (2) expression of an HIV-1 nanoparticle construct in an expression system lacking normal glycosylation function for human proteins. Also provided in the invention are HIV-1 nanoparticle vaccines produced with the described methods. The invention further provides methods of using the HIV-1 nanoparticle vaccine compositions described herein in various therapeutic applications, e.g., for preventing or treating viral infections.

HIV-1 envelope proteins and fragments that possess naturally occurring and novel engineered epitopes that can be used to elicit (and are recognized by) broadly neutralizing antibodies.

The present invention relates to a method for detecting and/or quantifying human immunodeficiency virus (HIV) specific antibodies in a sample of a subject comprising the step of determining the presence and/or amount of antibodies binding to a) a peptide consisting of the amino acid sequence AIVCTRPNNNTRKSIRIGPGQVFYT (SEQ. ID No. 1), or b) a homolog having at least 70% identity with a peptide of a), or c) a fragment of a peptide of a) or b) consisting of 15 to 24 amino acid residues in said sample.

Disclosed herein are mosaic conserved region HIV polypeptides and immunogenic polypeptides including one or more of the mosaic conserved region polypeptides. In some embodiments, the immunogenic polypeptides are included in an immunogenic composition, such as a polyvalent immunogenic composition. Also disclosed herein are methods for treating or inhibiting HIV in a subject including administering one or more of the disclosed immunogenic polypeptides or compositions to a subject having or at risk of HIV infection. In some embodiments, the methods include inducing an immune response in a subject comprising administering to the subject at least one of the disclosed immunogenic polypeptides or a nucleic acid encoding at least one of the immunogenic polypeptides.

The present invention provides novel scaffolded HIV-1 vaccine immunogens. Some of the scaffolded immunogens contain a soluble gp140 trimer linked to the N-terminus of the nanoparticle subunit and a T-helper epitope that is fused via a short peptide spacer to the C-terminus of the nanoparticle subunit. Some other immunogens of the invention contain a soluble gp140 trimer protein that is linked to a stable nanoparticle via a short peptide spacer that is a T-helper epitope. Some of the scaffolded immunogens contain a gp140 trimer immunogen presented on a nanoparticle platform formed with I3-01 protein, E2p, or variants of protein 1VLW. Also provided in the invention are nucleic acids that encode the various vaccine immunogens described herein, and expression vectors and host cells harboring the nucleic acids. The invention further provides methods of using the scaffolded HIV-1 vaccine immunogens for preventing or treating HIV infections.

The present invention provides HIV-1 vaccine immunogens. Some of the immunogens contain a soluble gp140-derived protein that harbors a modified N-terminus of the HR1 region in gp41. Some of the immunogens contain an HIV-1 Env-derived trimer protein that is presented on a nanoparticle platform. The invention also provides methods of using the HIV-1 vaccine immunogens for eliciting an immune response or treating HIV infections.

Human immunodeficiency virus (HIV) envelope proteins having specified mutations that stabilize the trimeric form of the envelope protein are provided. The HIV envelope proteins described herein have an improved percentage of trimer formation and/or an improved trimer yield. Also provided are particles displaying the HIV envelope proteins, nucleic acid molecules and vectors encoding the HIV envelope proteins, as well as compositions containing the HIV envelope proteins, particles, nucleic acid, or vectors.