Parallelization of single-molecule binding kinetic measurements via protein barcode sequencing

Screening protein variants for desired functions has long relied on coupling of genotype (gene sequence) to phenotype (protein function), limiting the use of powerful single-molecule (SM) techniques. Here, we introduce a scalable SM screening method that bypasses this constraint by linking SM functional analysis to protein identity through SM protein sequencing. Protein variants are tagged with unique C-terminal peptide barcodes and loaded onto a semiconductor chip containing millions of nanowells. Protein-ligand interactions are monitored in real time at the SM level, and a dye-cycling strategy extends the measurable dynamic range, enabling quantification of slow dissociation rates typical of high-affinity interactions. After functional analysis, each protein molecule is identified by sequencing its barcode. We apply this method to 20 barcoded nanobodies spanning over 1,000-fold in affinity, yielding results consistent with published values and individual SM measurements. Our approach should accelerate protein engineering by enabling rapid, multiplexed SM screening of protein libraries.