Tomomi Kitajima-Ihara

Salinibacter Sensory Rhodopsin SENSORY RHODOPSIN I-LIKE PROTEIN FROM A EUBACTERIUM

Halobacterium salinarum sensory rhodopsin I (HsSRI), a dual receptor regulating both negative and positive phototaxis in haloarchaea, transmits light signals through changes in protein-protein interactions with its transducer, halobacterial transducer protein I (HtrI). Haloarchaea also have another sensor pigment, sensory rhodopsin II (SRII), which functions as a receptor regulating negative phototaxis. Compared with HsSRI, the signal relay mechanism of SRII is well characterized because SRII from Natronomonus pharaonis (NpSRII) is much more stable than HsSRI and HsSRII, especially in dilute salt solutions and is much more resistant to detergents. Two genes encoding SRI homologs were identified from the genome sequence of the eubacterium Salinibacter ruber. Those sequences are distantly related to HsSRI (∼40% identity) and contain most of the amino acid residues identified as necessary for its function. To determine whether those genes encode functional protein(s), we cloned and expressed them in Escherichia coli. One of them (SrSRI) was expressed well as a recombinant protein having all-trans retinal as a chromophore. UV-Vis, low-temperature UV-Vis, pH-titration, and flash photolysis experiments revealed that the photochemical properties of SrSRI are similar to those of HsSRI. In addition to the expression system, the high stability of SrSRI makes it possible to prepare large amounts of protein and enables studies of mutant proteins that will allow new approaches to investigate the photosignaling process of SRI-HtrI.

Functionally important structural elements of the cyanobacterial clock-related protein Pex

Pex, a clock‐related protein involved in the input pathway of the cyanobacterial circadian clock system, suppresses the expression of clock gene kaiA and lengthens the circadian period. Here, we determined the crystal structure of Anabaena Pex (AnaPex; Anabaena sp. strain PCC 7120) and Synechococcus Pex (SynPex; Synechococcus sp. strain PCC 7942). Pex is a homodimer that forms a winged‐helix structure. Using the DNase I protection and electrophoresis mobility shift assays on a Synechococcus kaiA upstream region, we identified a minimal 25‐bp sequence that contained an imperfectly inverted repeat sequence as the Pex‐binding sequence. Based on crystal structure, we predicted the amino acid residues essential for Pexs DNA‐binding activity and examined the effects of various Ala‐substitutions in the α3 helix and wing region of Pex on in vitro DNA‐binding activity and in vivo rhythm functions. Mutant AnaPex proteins carrying a substitution in the wing region displayed no specific DNA‐binding activity, whereas those carrying a substitution in the α3 helix did display specific binding activity. But the latter were less thermostable than wild‐type AnaPex and their in vitro functions were defective. We concluded that Pex binds a kaiA upstream DNA sequence via its wing region and that its α3 helix is probably important to its stability.

Crystal Structure of Cruxrhodopsin-3 from Haloarcula vallismortis

Cruxrhodopsin-3 (cR3), a retinylidene protein found in the claret membrane of Haloarcula vallismortis, functions as a light-driven proton pump. In this study, the membrane fusion method was applied to crystallize cR3 into a crystal belonging to space group P321. Diffraction data at 2.1 Å resolution show that cR3 forms a trimeric assembly with bacterioruberin bound to the crevice between neighboring subunits. Although the structure of the proton-release pathway is conserved among proton-pumping archaeal rhodopsins, cR3 possesses the following peculiar structural features: 1) The DE loop is long enough to interact with a neighboring subunit, strengthening the trimeric assembly; 2) Three positive charges are distributed at the cytoplasmic end of helix F, affecting the higher order structure of cR3; 3) The cytoplasmic vicinity of retinal is more rigid in cR3 than in bacteriorhodopsin, affecting the early reaction step in the proton-pumping cycle; 4) the cytoplasmic part of helix E is greatly bent, influencing the proton uptake process. Meanwhile, it was observed that the photobleaching of retinal, which scarcely occurred in the membrane state, became significant when the trimeric assembly of cR3 was dissociated into monomers in the presence of an excess amount of detergent. On the basis of these observations, we discuss structural factors affecting the photostabilities of ion-pumping rhodopsins.

A photochromic photoreceptor from a eubacterium

Sensory rhodopsin I (SRI) is one of the most interesting photosensory receptors because of its function in using the photochromic reaction to mediate opposing signals which depend on the color of light. It was initially thought that SRI exists only in the archaea, but we recently reported for the first time a newly functional SRI from a eubacterium, Salinibacter ruber (SrSRI). The amino acid sequence of SrSRI shows 43% identity with the well-known SRI (HsSRI) and contains most of the amino acid residues identified as necessary for SRI function. The photochemical properties of SrSRI are similar to those of HsSRI. In addition, SrSRI is a highly stable protein, even in dilute salt conditions. Thus, SrSRI could be a key protein for characterizing its association with the SrSRI transducer protein, SrHtrI, and for elucidating structural changes of SRI and HtrI that occur during their function. Recently, new approaches to manipulate cellular functions with rhodopsins have been established. SRI can activate and deactivate a kinase, CheA, by the photochromic reaction. Kinases are key molecules for signal transduction in various organisms, and their cellular functions could potentially be manipulated by SRI.