Multistep conformational changes leading to the gate opening of light-driven sodium pump rhodopsin.

Membrane transport proteins require a gating mechanism that opens and closes the substrate transport pathway to carry out unidirectional transport. The "gating" involves large conformational changes and is achieved via multistep reactions. However, these elementary steps have not been clarified for most transporters due to the difficulty of detecting the individual steps. Here, we propose these steps for the gate opening of the bacterial Na+ pump rhodopsin, which outwardly pumps Na+ upon illumination. We herein solved an asymmetric dimer structure of Na+ pump rhodopsin from the bacterium Indibacter alkaliphilus. In one protomer, the Arg108 sidechain is oriented toward the protein center and appears to block a Na+ release pathway to the extracellular (EC) medium. In the other protomer, however, this sidechain swings to the EC side and then opens the release pathway. Assuming that the latter protomer mimics the Na+-releasing intermediate, we examined the mechanism for the swing motion of the Arg108 sidechain. On the EC surface of the first protomer, there is a characteristic cluster consisting of Glu10, Glu159, and Arg242 residues connecting three helices. In contrast, this cluster is disrupted in the second protomer. Our experimental results suggested that this disruption is a key process. The cluster disruption induces the outward movement of the Glu159-Arg242 pair and simultaneously rotates the seventh transmembrane helix. This rotation resultantly opens a space for the swing motion of the Arg108 sidechain. Thus, cluster disruption might occur during the photoreaction and then trigger sequential conformation changes leading to the gate-open state.

Protein encapsulation in the hollow space of hemocyanin crystals containing a covalently conjugated ligand.

Encapsulation of guest molecules into the vacant space of biomacromolecular crystals has been utilized for various purposes including functioning as a protein container to protect against physical stress and structural determination of the guest. Todarodes pacificus hemocyanin (TpHc) is a hollow cylindrical decameric protein complex with an inner space 110 Šin diameter and 160 Šin height. In the crystal, TpHc forms a straw-like bundle and contains one reactive Cys (Cys3246) in the inner domain of each protomer. Here, we conjugated biotin onto Cys3246 of TpHc followed by incubation with streptavidin. The streptavidin was immobilized into the inner space of TpHc due to its interaction with biotin. Moreover, the complex containing TpHc and streptavidin was crystallized under the same conditions used for unmodified TpHc. In order to expand this methodology for a variety of proteins, we conjugated the ligand nitrilotriacetic acid (NTA) chelated to a Ni2+ ion (Ni2+-NTA) to TpHc. We found that His-tagged green fluorescent protein (GFP) was encapsulated into the Ni2+-NTA-conjugated TpHc via the interaction between the His-tag and the Ni2+-NTA group. X-ray crystallography demonstrated that the crystal packing of the complex containing TpHc and GFP was identical to that of the unmodified TpHc. Our guest immobilization method is distinct from previous approaches that are dependent on diffusion of the guest into the host crystal. Thus, our findings may accelerate the development of proteinaceous crystal engineering.