Provided herein are antibodies that are useful for treating SARS-CoV-2 infections in a subject. Also provided herein are compositions comprising one or more antibodies, methods of treatment comprising administering one or more antibodies, and kits comprising one or more antibodies.

The present invention relates to methods for efficiently generating recombinant monoclonal antibodies derived from B cells of a non-human host which has been immunochallenged with one or more target antigens. The methods comprise the steps of identifying and isolating B cell that bind to the antigen by FACS, and recombining and enriching for thousands of cells to create a B cell library. Related products and methods, such as methods of producing expression libraries, are also disclosed.

Provided is method for producing a phage library displaying antibodies or antibody fragments, comprising providing a first polynucleotide containing LC, a second polynucleotide containing connexon, and a third polynucleotide containing HC, respectively introducing the first, second and third polynucleotides to first, second and third bacteria to obtain a light chain component bacterial library, a connexon component bacterial library, and a heavy chain component bacterial library, obtaining a light chain component plasmid, a connexon component plasmid, and a heavy chain component plasmid from the libraries, obtaining the released LC, released connexon and released HC from the plasmids, connecting the released display vector segments to form a connection product for display, introducing a third bacterium to obtain a display bacterial library, and using the display bacterial library to prepare the phage library for displaying the antibodies or antibody fragments. Also provided is a phage library produced according to the method.

Provided herein are methods and compositions relating to libraries of optimized antibodies having nucleic acids encoding for an antibody comprising modified sequences. Libraries described herein comprise nucleic acids encoding SARS-CoV-2 or ACE2 antibodies. Further described herein are protein libraries generated when the nucleic acid libraries are translated. Further described herein are cell libraries expressing variegated nucleic acid libraries described herein.

The present invention relates to a method for engineering an immunoglobulin comprising a variable domain and at least one modification in at least two structural loops of said immunoglobulin and determining the binding of said immunoglobulin to an epitope of an antigen, wherein the unmodified immunoglobulin does not significantly bind to said epitope, comprising the steps of: providing a nucleic acid encoding an immunoglobulin comprising at least two structural loops, modifying at least one nucleotide residue of each of said structural loops, transferring said modified nucleic acid in an expression System, expressing said modified immunoglobulin, contacting the expressed modified immunoglobulin with an epitope, and determining whether said modified immunoglobulin binds to said epitope, immunoglobulins produced by such a method and libraries of immunoglobulins.

The present invention relates to an antibody or antigen binding fragment thereof that binds specifically to IGFBP3 and does not displace the binding of IGF-I to IGFBP3. The antibody inhibits or reduces the binding of IGFBP3 to the TMEM219 receptor. The invention also relates to methods for their production, pharmaceutical compositions containing said antibodies, and uses thereof.

This disclosure relates to methods of generating antibody libraries, antibody libraries produced using such methods, and variant antibodies. Presently, methods of improving antibody binding (affinity maturation assays) require the screening of vast libraries of antibody variants (often >10.sup.10) to identify a small fraction of variants with improved characteristics. The present invention involves taking the nucleotide sequence of the framework and complementarity determining region of a target antibody and identifying motifs which would be recognised by deamination somatic hypermutation enzymes. A small library of variants is then created which incorporate one or more of these mutations. It was found that a relatively high proportion of the variants have an increased affinity. The technique of the present invention was demonstrated on the trastuzumab and Cathepsin S antibodies, and the variants produced are also claimed.

Provided herein are methods that enable parallel evaluation of multiple functional nucleic acids in individual cells or subpopulations of cells, in the context of incubation with other types of single cells. The key insight is concurrent measurement of polynucleic acids derived from small populations of at least two different cell types, such that function in one cell type is linked to the clonal identity of another cell. These methods simultaneously process thousands, millions, or more single cells or small populations of cells. The method integrates molecular, algorithmic, and engineering approaches. This invention has broad and useful application in a number of biological and medical fields, including immunology and drug discovery.

Disclosed is a library consisting essentially of a plurality of antigen-binding molecules differing in sequence from each other, wherein an antigen-binding domain in each of the antigen-binding molecules comprises at least one amino acid residue that changes the antigen-binding activity of the antigen-binding molecule depending on ion concentration conditions. Also disclosed are a composition comprising a plurality of polynucleotide molecules each encoding the antigen-binding molecules, a composition comprising a plurality of vectors each comprising the polynucleotide molecules, a method for selecting the antigen-binding molecules, a method for isolating the polynucleotide molecules, a method for producing the antigen-binding molecules, and a pharmaceutical composition comprising any of the antigen-binding molecules.

The present invention relates to a binding molecule having neutralizing activity against Middle East Respiratory Syndrome-Coronavirus (MERS-CoV). More particularly, the present invention relates to a binding molecule having strong ability to bind to an S protein of MERS-CoV and neutralizing activity against MERS-CoV and thus being very useful in the prevention, treatment or diagnosis of MERS-CoV infection.