Computational structure-based protein design programs are becoming an increasingly
important tool in molecular biology. These programs compute protein sequences that are …

The design of tailor-made enzymes is a major goal in biochemical research that can result in
wide-range applications and will lead to a better understanding of how proteins fold and …

We present osprey 3.0, a new and greatly improved release of the osprey protein design
software. Osprey 3.0 features a convenient new Python interface, which greatly improves its …

Computational protein design (CPD) algorithms that compute binding affinity, Ka, search for
sequences with an energetically favorable free energy of binding. Recent work shows that …

The K* algorithm provably approximates partition functions for a set of states (eg, protein,
ligand, and protein-ligand complex) to a user-specified accuracy ε. Often, reaching an ε …

Motivation When proteins mutate or bind to ligands, their backbones often move
significantly, especially in loop regions. Computational protein design algorithms must …

Most protein design algorithms assume that the conformational space of proteins is discrete
and that their energy is residue-pairwise, ie, a sum of terms that depend on the sequence …

Motivation Multistate protein design addresses real-world challenges, such as multi-
specificity design and backbone flexibility, by considering both positive and negative protein …

Protein design algorithms that model continuous sidechain flexibility and conformational
ensembles better approximate the in vitro and in vivo behavior of proteins. The previous …

Protein design algorithms that compute binding affinity search for sequences with an
energetically favorable free energy of binding. Recent work shows that the following design …