Methods for screening of affinity reagents for many target proteins of interest simultaneously. Arrayed targets (e.g., peptide, protein, RNA, cell, etc.) are used in affinity selection experiments to reduce the amount of target needed and to improve the throughput of discovering recombinant affinity reagents to a large collection of targets.

The present invention relates to a library of particles, the library displaying a plurality of different T cell receptors (TCRs), wherein the plurality of TCRs may consist essentially of TCRs which may comprise an alpha chain variable domain from a natural repertoire and a beta chain variable domain from a natural repertoire, wherein the alpha chain variable domain may comprise a TRAV12-2 or a TRAV21 gene product and the beta chain variable domain may comprise a TRBV6 gene product.

A method for displaying proteins and peptides is disclosed in which individual proteins or peptides remain associated with the DNA encoding them. Proteins or peptides can be generated by in vitro translation of DNA templates, either free in solution or arrayed on a solid support, such that the proteins or peptides remain immobilized on their DNA templates. In particular, high throughput sequencing can be combined with high throughput functional characterization of encoded proteins and peptides, wherein the identity of each protein or peptide is determined by DNA sequencing, and functional studies are carried out directly on each protein or peptide while immobilized on the DNA template encoding it. The methods of the invention should find numerous applications, for example, in high throughput genetic or pharmacological screening, epitope mapping, and protein engineering and directed evolution.

A binding agent to a target molecule, or method or kit where the binding agent is selected from a library where each variant has a circular permutation of the FHA domain where the rearrange does not substantially disrupt the FHA domain's beta-sheet scaffold or increase the stability of the beta-sheet scaffold. The randomized regions of the FHA domain include the endogenous binding interface the FHA domain, the region opposite of the endogenous binding interface, and the circular permutation region.

The present invention pertains to the field of protein engineering, and provides means for obtaining stable molecules that specifically bind to a target selected amongst a large variety of ligands families. In particular, the present invention provides methods for obtaining a molecule specifically binding to a target of interest, through a combinatorial mutation/selection approach with an OB-fold protein as a starting molecule. In particular, the target of interest can be of a different chemical nature form that of the native target of the OB-fold protein used as the starting molecule.

A method of assembling and immobilizing proteinaceous complexes is disclosed. In addition, methods of generating functional RNA polymerase and ribosomal subunits are disclosed.

A novel method for displaying proteins and peptides is disclosed in which individual proteins or peptides remain associated with the DNA encoding them. Proteins or peptides can be generated by in vitro translation of DNA templates, either free in solution or arrayed on a solid support, such that the proteins or peptides remain immobilized on their DNA templates. In particular, high throughput sequencing can be combined with high throughput functional characterization of encoded proteins and peptides, wherein the identity of each protein or peptide is determined by DNA sequencing, and functional studies are carried out directly on each protein or peptide while immobilized on the DNA template encoding it. The methods of the invention should find numerous applications, for example, in high throughput genetic or pharmacological screening, epitope mapping, and protein engineering and directed evolution.

The embodiment of the invention is to innovate immunogenic CoV-2, CoV-n B cell epitopes, which are selected from the loop regions constrained by the two constraining beta strands; or between one beta strand and one alpha-helical strand; or between two alpha-helical strands of CoV-2, CoV-n proteins, and such selected loops replace the native loops of the thermostable protein scaffolds, which provide thermostable constraint of the transplanted CoV-2, CoV-n loop antigens as well as CD4 helper T cell determinants to elicit CD4 dependent neutralizing and blocking antibodies against viral entry, replication and viral clearance. The B cell loops can be cleaved and processed as CD8 T cell epitopes for eliciting cytotoxic T lymphocyte (CTL) responses against and clear viral infected cells. MHCI viral peptide epitopes in nonamers, octamers, or decamers will be used as peptide vaccines along with viral CD4 helper peptide epitopes. These CTL peptides will be also inserted into the loop or replacing the native loop of the protein scaffolds. All the above sequences can be embodied in RNA vaccines to augment protection or suppress cytokine storms. And the embodiment of the invention is to employ CTL peptides and CD4 helper peptides inserted into each respective candidate loop of the protein scaffolds as CTL vaccines. Thus, the CTL vaccines safely eliminate infectious foci and reservoir of the offending virus and mutant viral strains.

Disclosed are methods, components, compositions, and kits for preparing and identifying engineered E. coli ribosomes. The E. coli ribosomes may be prepared and identified under a set of defined conditions, such as in the presences of antibiotics, in order to obtain an engineered ribosome that is resistant to the antibiotic.

Provided herein are methods and composition for immune repertoire sequencing and single cell barcoding. In some aspects, such methods may comprise steps of: (a) forming a plurality of first vessels each comprising: (i) a single cell, and (ii) a single solid support; (b) copying onto the single solid support: (i) a first copy of a first cell polynucleotide from the single cell, and (ii) a second copy of a second cell polynucleotide from the single cell; (c) forming a plurality of second vessels each comprising (i) a single solid support from the plurality of first vessels, and (ii) a barcoded polynucleotide; and (d) amplifying (i) the first copy and the second copy with a first primer set, and (ii) the barcode with a second primer set, wherein a primer of the first primer set is complementary to a primer of the second set; and (e) forming first and second single cell barcoded sequences.