Optimization of multi-site nicking mutagenesis for generation of large, user-defined combinatorial libraries

Generating combinatorial libraries of specific sets of mutations are essential for addressing protein engineering questions involving contingency in molecular evolution, epistatic relationships between mutations, as well as functional antibody and enzyme engineering. Here we present optimization of a combinatorial mutagenesis method involving template-based nicking mutagenesis, which allows for the generation of libraries with >99% coverage for tens of thousands of user-defined variants. The non-optimized method resulted in low library coverage, which could be rationalized by a model of oligonucleotide annealing bias resulting from the nucleotide mismatch free-energy difference between mutagenic oligo and template. The optimized method mitigated this thermodynamic bias using longer primer sets and faster annealing conditions. Our updated method, applied to two antibody fragments, delivered between 99.0% (32451/32768 library members) to >99.9% coverage (32757/32768) for our desired libraries in 2 days and at an approximate 140-fold sequencing depth of coverage.

Automated summary

This study presents an optimized combinatorial mutagenesis method using template-based nicking mutagenesis to generate high coverage mutation libraries, which achieved 99% or higher coverage for two antibody fragments. The updated method allows for the quick generation of desired libraries in just 2 days with approximately 140-fold sequencing depth coverage.