The present invention relates to broadly neutralizing anti-HIV-1 antibodies and isolated antigens. Also disclosed are related methods and compositions.

This invention relates to antibody therapies for human immunodeficiency virus (HIV). In particular, the invention provides methods of curing subjects infected with HIV and blocking HIV infections in subjects at risk of HIV transmission using a N332 glycan-dependent antibody (e.g., PGT121).

Fc domains and CH3 domains are disclosed that bind the neonatal Fc (FcRn) receptor and are at least 99% monomeric. Monomeric Fc domain molecules and CH3 domain molecules are disclosed herein that include a monomeric Fc domain or a monomeric CH3 domain and an effector molecule. In some embodiments, the monomeric Fc or monomeric CH3 domain include amino acid substitutions and/or CDR insertions in the beta strands such that they specifically bind an antigen. Methods for using these monomeric Fc domains, monomeric CH3 domains, monomeric Fc domain molecules and CH3 domain molecules are also provided.

The present invention relates to a VC-CAR molecule and a use thereof in removing HIV-1 infected cells. The VC-CAR molecule is characterized by linking an HIV-1 broad-spectrum neutralizing antibody VRC01 sourced scFv sequence and an intracellular domain sequence of a conventional CAR molecule which are respectively used as extracellular and intracellular domains. A T cell modified by the VC-CAR molecule can be specifically activated and secrete a great number of cytotoxicity-related cytokines, so that lysis of a target cell can be powerfully mediated, and it can be better used for anti-infection adoptive immunotherapy.

Embodiments of immunogens based on the outer domain of HIV-1 gp120 and methods of their use and production are disclosed. Nucleic acid molecules encoding the immunogens are also provided. In several embodiments, the immunogens can be used to prime an immune response to gp120 in a subject, for example, to treat or prevent an HIV-1 infection in the subject.

The present invention relates, in general, to human immunodeficiency virus (HIV), and, in particular, to a method of inducing neutralizing antibodies to HIV and to compounds and compositions suitable for use in such a method.

Embodiments of the present invention are directed to compositions and methods for anti-HIV (anti-CD4 binding site) potent VRC01-like (PVL) antibodies targeted to gp120 having an amino acid substitution at a residue in the anti-CD4 binding site PVL antibody that is equivalent to Phe43 in CD4, these antibodies having improved potency and breadth.

A method for detecting HIV infection in a mammal is disclosed. The method contains the steps of isolating exosomes from a urine sample of a mammal and detecting the presence of HIV-specific biomarker in said isolated exosomes. A method for diagnosing a mammal with an HIV-associated disease, in particular, HIV-associated nephropathy is also disclosed.

The invention provides a method for obtaining a broadly neutralizing antibody (bNab), including screening memory B cell cultures from a donor PBMC sample for neutralization activity against a plurality of HIV-1 species, cloning a memory B cell that exhibits broad neutralization activity; and rescuing a monoclonal antibody from that memory B cell culture. The resultant monoclonal antibodies may be characterized by their ability to selectively bind epitopes from the Env proteins in native or monomeric form, as well as to inhibit infection of HIV-1 species from a plurality of clades. Compositions containing human monoclonal anti-HIV antibodies used for prophylaxis, diagnosis and treatment of HIV infection are provided. Methods for generating such antibodies by immunization using epitopes from conserved regions within the variable loops of gp120 are provided. Immunogens for generating anti-HIV1 bNAbs are also provided. Furthermore, methods for vaccination using suitable epitopes are provided

The present invention provides novel nanoparticle presented vaccine compositions that are stabilized with a locking domain. Various immunogens can be employed in the preparation of the vaccine compositions, including viral immunogens such as HIV-1 and Ebola viral immunogens, and non-viral immunogens such as immunogens derived from bacteria, parasites and mammalian species. The invention also provides methods of using such vaccine compositions in various therapeutic applications, e.g., for preventing or treating viral infections.