The present disclosure provides instrumentation and automated methods for creating cell surface display libraries, where the cells of the library display engineered peptides on their cell surfaces for identification of antigens that bind to T-cell receptors. The engineered peptides may be putative antigens or binding regions of the T-cell receptors.

The invention is directed to virus-like particles (VLPs) of an RNA bacteriophage that (a) comprises a coat polypeptide of said phage modified by insertion of a heterologous peptide that is displayed on said VLP and (b) encapsidates said bacteriophage mRNA as well as populations of these VLPs, and their uses. The invention is further directed to VLPs that encapsidate heterologous substances, as well as populations of these VLPs and their uses.

The invention is directed to virus-like particles (VLPs) of an RNA bacteriophage that (a) comprises a coat polypeptide of said phage modified by insertion of a heterologous peptide that is displayed on said VLP and (b) encapsidates said bacteriophage mRNA as well as populations of these VLPs, and their uses. The invention is further directed to VLPs that encapsidate heterologous substances, as well as populations of these VLPs and their uses.

The present invention generally relates to amplification of biological entities, for example, for phage display. In one aspect, members of a library of biological entities are encapsulated in separate compartments (e.g., in separate microfluidic droplets) and amplified. As a specific example, by putting members of a phage display library into microfluidic droplets such that no droplet contains more than one member of the library, the library can be amplified without any substantial changes in growth rates or population distributions, or other artifacts created due to differences in growth rates or amplification between different members of the library. In some cases, the volume of the compartments can be used to control the copy number of a biological entity during amplification. In certain cases, biological entities with different amplification rates can be amplified independently of each other. In some embodiments, the ratio of a rapidly amplifying biological entity to a slowly amplifying biological entity can be controlled. This can be advantageous, for example, in preserving diversity within a library by preventing rapidly amplifying biological entities from outcompeting slowly amplifying biological entities. For example, certain methods and systems of the invention can be useful in situations where preferential amplification of library members can present a problem.

The present invention generally relates to amplification of biological entities, for example, for phage display. In one aspect, members of a library of biological entities are encapsulated in separate compartments (e.g., in separate microfluidic droplets) and amplified. As a specific example, by putting members of a phage display library into microfluidic droplets such that no droplet contains more than one member of the library, the library can be amplified without any substantial changes in growth rates or population distributions, or other artifacts created due to differences in growth rates or amplification between different members of the library. In some cases, the volume of the compartments can be used to control the copy number of a biological entity during amplification. In certain cases, biological entities with different amplification rates can be amplified independently of each other. In some embodiments, the ratio of a rapidly amplifying biological entity to a slowly amplifying biological entity can be controlled. This can be advantageous, for example, in preserving diversity within a library by preventing rapidly amplifying biological entities from outcompeting slowly amplifying biological entities. For example, certain methods and systems of the invention can be useful in situations where preferential amplification of library members can present a problem.

The invention provides a BASEHIT screening method for identifying proteins that are involved in host-microbe interactions which may function as therapeutic targets.

The invention provides a BASEHIT screening method for identifying proteins that are involved in host-microbe interactions which may function as therapeutic targets.

Antibody libraries comprising a plurality of heavy chain variable domains and/or a plurality of light chain variable domains, which comprise complementary determining regions (CDRs) found in naturally-occurring human antibodies, and methods of making such antibody libraries. The antibody libraries are free of members that comprise one or more liabilities affecting one or more features of such members. Further, the antibody libraries comprise members having heavy chain and/or light chain CDRs not found in the same naturally-occurring human antibody.

Provided are mutant viral capsid cell libraries, individual cells of such libraries, systems, vectors, and methods for generating the cell libraries, and methods of use thereof to screen for mutant viral capsids with desired characteristics.

Provided are mutant viral capsid cell libraries, individual cells of such libraries, systems, vectors, and methods for generating the cell libraries, and methods of use thereof to screen for mutant viral capsids with desired characteristics.