Energy-guided combinatorial co-optimization of antibody affinity and stability

Affinity maturation is an essential process in antibody engineering. Although powerful, it is iterative and time-consuming and can result in trade-offs, where affinity is gained at the cost of other essential properties, such as specificity and stability. Here, we present a scalable structure- and energy-based strategy, called LAffAb, that starts from a crystallographic structure of the bound antibody-antigen complex and introduces combinations of mutations to optimize the energy. A combinatorial mutation library comprising 7,000 variants with up to nine mutations results in large gains of up to 1,000-fold in affinity while co-optimizing antibody stability. Surprisingly, the library does not converge on a single solution; instead, it favors diverse variants with a high mutational load. Applied in small scale (10 designs) to an antibody targeting a potential drug target, designs improved affinity by an order of magnitude with little loss in specificity or stability. We envision that LAffAb can be used to select stable, specific, and high-affinity binders and to improve our understanding of sequence, structure, and function relationships in antibodies.