Installing Guest Molecules at Specific Sites within Scaffold Protein Crystals.

Protein crystals are porous self-assembling materials that can be rapidly evolved by mutagenesis. We aimed to develop scaffold assisted crystallography techniques in an engineered protein crystal with large pores (>13 nm). Guest molecules were installed via a single covalent bond to attempt to reduce the conformational freedom and achieve high-occupancy structures. We used four different conjugation strategies to attach guest molecules to three different cysteine sites within pre-existing protein crystals. In all but one case, the presence of the adduct was obvious in the electron density. Structure determination of larger guest molecules may be feasible due to the large pores of the engineered scaffold crystals.

Programmed Assembly of Host-Guest Protein Crystals.

The binding and release of guest fluorescent proteins inside a protein crystal with 13 nm axial pores is controlled. Spatially segregated guest protein loading is achieved via sequential binding and release stages. Additionally, selective stabilization of the crystal exterior results in hollow crystalline shells.