Time-resolved FTIR study of light-driven sodium pump rhodopsins.

Light-driven sodium ion pump rhodopsin (NaR) is a new functional class of microbial rhodopsin. A previous flash photolysis study of Krokinobacter eikastus rhodopsin 2 (KR2) revealed the presence of three kinetically distinct intermediates: K, L/M, and O. Previous low-temperature Fourier-transform infrared (FTIR) spectroscopy of KR2 showed that photoisomerization from the all-trans to the 13-cis form is the primary event of the Na+ pumping photocycle, but structural information on the subsequent intermediates is limited. Here, we applied step-scan time-resolved FTIR spectroscopy to KR2 and Nonlabens dokdonensis rhodopsin 2 (NdR2). Both low-temperature static and time-resolved FTIR spectra resolved a K-like intermediate, and the corresponding spectra showed few differences. Strong hydrogen-out-of-plane (HOOP) vibrations, which appeared in the K intermediate, are common among other rhodopsins. It is, however, unique for NaR that such HOOP bands are persistent in late intermediates, such as L and O intermediates. This observation strongly suggests similar chromophore structures for the K, L, and O intermediates. In fact, an isotope-labeled study that used 12,14-D2 retinal revealed that the chromophore configuration of the O intermediate in NaR is 13-cis. In contrast to the vibrations of the chromophore, those of the protein differ among intermediates, and this is related to the sodium-pumping function. The molecular mechanism of the light-driven sodium pump is discussed on the basis of the present time-resolved FTIR results.

Low-temperature FTIR spectroscopy provides evidence for protein-bound water molecules in eubacterial light-driven ion pumps.

Light-driven H+, Na+ and Cl- pumps have been found in eubacteria, which convert light energy into a transmembrane electrochemical potential. A recent mutation study revealed asymmetric functional conversion between the two pumps, where successful functional conversions are achieved exclusively when mutagenesis reverses the evolutionary amino acid sequence changes. Although this fact suggests that the essential structural mechanism of an ancestral function is retained even after gaining a new function, questions regarding the essential structural mechanism remain unanswered. Light-induced difference FTIR spectroscopy was used to monitor the presence of strongly hydrogen-bonded water molecules for all eubacterial H+, Na+ and Cl- pumps, including a functionally converted mutant. This fact suggests that the strongly hydrogen-bonded water molecules are maintained for these new functions during evolution, which could be the reason for successful functional conversion from Na+ to H+, and from Cl- to H+ pumps. This also explains the successful conversion of the Cl- to the H+ pump only for eubacteria, but not for archaea. It is concluded that water-containing hydrogen-bonding networks constitute one of the essential structural mechanisms in eubacterial light-driven ion pumps.

Structural basis for Na(+) transport mechanism by a light-driven Na(+) pump.

Krokinobacter eikastus rhodopsin 2 (KR2) is the first light-driven Na(+) pump discovered, and is viewed as a potential next-generation optogenetics tool. Since the positively charged Schiff base proton, located within the ion-conducting pathway of all light-driven ion pumps, was thought to prohibit the transport of a non-proton cation, the discovery of KR2 raised the question of how it achieves Na(+) transport. Here we present crystal structures of KR2 under neutral and acidic conditions, which represent the resting and M-like intermediate states, respectively. Structural and spectroscopic analyses revealed the gating mechanism, whereby the flipping of Asp116 sequesters the Schiff base proton from the conducting pathway to facilitate Na(+) transport. Together with the structure-based engineering of the first light-driven K(+) pumps, electrophysiological assays in mammalian neurons and behavioural assays in a nematode, our studies reveal the molecular basis for light-driven non-proton cation pumps and thus provide a framework that may advance the development of next-generation optogenetics.

FTIR spectroscopy of a light-driven compatible sodium ion-proton pumping rhodopsin at 77 K.

Krokinobacter eikastus rhodopsin 2 (KR2) is a light-driven sodium ion pump that was discovered in marine bacteria. Although KR2 is able to pump lithium ions similarly, it is converted into a proton pump in potassium chloride or salts of larger cations. In this paper, we applied light-induced difference Fourier-transform infrared (FTIR) spectroscopy to KR2, a compatible sodium ion-proton pump, at 77 K. The first structural study of the functional cycle showed that the structure and structural changes in the primary processes of KR2 are common to all microbial rhodopsins. The red shifted K formation (KR2K) was accompanied by retinal photoisomerization from an all-trans to a 13-cis form, resulting in a distorted retinal chromophore. The observed hydrogen out-of-plane vibrations were H/D exchangeable, indicating that the chromophore distortion by retinal isomerization is located near the Schiff base region in KR2. This tendency was also the case for bacteriorhodopsin and halorhodopsin but not the case for sensory rhodopsin I and II. Therefore, ion pumps such as proton, chloride, and sodium pumps exhibit local structural perturbations of retinal at the Schiff base moiety, while photosensors show more extended structural perturbations of retinal. The retinal Schiff base of KR2 forms a hydrogen bond that is stronger than in BR. KR2 possesses more protein-bound water molecules than other microbial rhodopsins and contains strongly hydrogen-bonded water (O-D stretch at 2333 cm(-1) in D2O). The light-induced difference FTIR spectra at 77 K were identical between the two states functioning as light-driven sodium ion and proton pumps, indicating that the structural changes in the primary processes are identical between different ion pump functions in KR2. In other words, it is unknown which ions are transported by molecules when they absorb photons and photoisomerize. It is likely that the relaxation processes from the K state lead to an alternative function, namely a sodium ion pump or proton pump, depending on the environment.

Improved corneal toxicity and permeability of tranilast by the preparation of ophthalmic formulations containing its nanoparticles.

We prepared ophthalmic formulations containing 0.5% tranilast (TL) nanoparticles using 0.005% benzalkonium chloride (BAC), 0.5% D-mannitol, and 2-hydroxypropyl-ß-cyclodextrin (HPßCD), and investigated their usefulness in the ophthalmologic field by evaluating corneal toxicity and permeability. TL nanoparticles were prepared using zirconia beads and Bead Smash 12, which allowed the preparation of high quality dispersions containing 0.5% TL nanoparticles (particle size, 34 ± 20 nm, means ± S.D.). Dispersions containing TL nanoparticles are tolerated better by human corneal epithelium cells than a commercially available 0.5% TL preparation (RIZABEN(®) eye drops). In addition, the addition of TL nanoparticles to the dispersions does not affect the antimicrobial activity of BAC against Escherichia coli (ATCC 8739), and the corneal penetration of TL from dispersions containing TL nanoparticles was significantly higher than in the case of the commercially available 0.5% TL eye drops. It is possible that dispersions containing TL nanoparticles will show increased effectiveness against ocular inflammation, and that ocular drug delivery systems using drug nanoparticles may lead to an expansion of their usefulness for therapy in the ophthalmologic field.

A blue-shifted light-driven proton pump for neural silencing.

Ion-transporting rhodopsins are widely utilized as optogenetic tools both for light-induced neural activation and silencing. The most studied representative is Bacteriorhodopsin (BR), which absorbs green/red light (∼570 nm) and functions as a proton pump. Upon photoexcitation, BR induces a hyperpolarization across the membrane, which, if incorporated into a nerve cell, results in its neural silencing. In this study, we show that several residues around the retinal chromophore, which are completely conserved among BR homologs from the archaea, are involved in the spectral tuning in a BR homolog (HwBR) and that the combination mutation causes a large spectral blue shift (λmax = 498 nm) while preserving the robust pumping activity. Quantum mechanics/molecular mechanics calculations revealed that, compared with the wild type, the ß-ionone ring of the chromophore in the mutant is rotated ∼130° because of the lack of steric hindrance between the methyl groups of the retinal and the mutated residues, resulting in the breakage of the π conjugation system on the polyene chain of the retinal. By the same mutations, similar spectral blue shifts are also observed in another BR homolog, archearhodopsin-3 (also called Arch). The color variant of archearhodopsin-3 could be successfully expressed in the neural cells of Caenorhabditis elegans, and illumination with blue light (500 nm) led to the effective locomotory paralysis of the worms. Thus, we successfully produced a blue-shifted proton pump for neural silencing.

A light-driven sodium ion pump in marine bacteria.

Light-driven proton-pumping rhodopsins are widely distributed in many microorganisms. They convert sunlight energy into proton gradients that serve as energy source of the cell. Here we report a new functional class of a microbial rhodopsin, a light-driven sodium ion pump. We discover that the marine flavobacterium Krokinobacter eikastus possesses two rhodopsins, the first, KR1, being a prototypical proton pump, while the second, KR2, pumps sodium ions outward. Rhodopsin KR2 can also pump lithium ions, but converts to a proton pump when presented with potassium chloride or salts of larger cations. These data indicate that KR2 is a compatible sodium ion-proton pump, and spectroscopic analysis showed it binds sodium ions in its extracellular domain. These findings suggest that light-driven sodium pumps may be as important in situ as their proton-pumping counterparts.

Effects of granule-bound starch synthase I-defective mutation on the morphology and structure of pyrenoidal starch in Chlamydomonas.

Lowering of the CO2 concentration in the environment induces development of a pyrenoidal starch sheath, as well as that of pyrenoid and CO2-concentrating mechanisms, in many microalgae. In the green algae Chlamydomonas and Chlorella, activity of granule-bound starch synthase (GBSS) concomitantly increases under these conditions. In this study, effects of the GBSS-defective mutation (sta2) on the development of pyrenoidal starch were investigated in Chlamydomonas. Stroma starch- and pyrenoid starch-enriched samples were obtained from log-phase cells grown with air containing 5% CO2 (high-CO2 conditions favouring stromal starch synthesis) and from those transferred to low-CO2 conditions (air level, 0.04% CO2, favouring pyrenoidal starch synthesis) for 6h, respectively. In the wild type, total starch content per culture volume did not increase during the low-CO2 conditions, in spite of the development of pyrenoidal starch, suggesting that degradation of some part of stroma starch and synthesis of pyrenoid starch simultaneously occur under these conditions. Even in the GBSS-deficient mutants, pyrenoid and pyrenoid starch enlarged after lowering of the CO2 concentration. However, the morphology of the pyrenoid starch was thinner and more fragile than the wild type, suggesting that GBSS does affect the morphology of pyrenoidal starch. Surprisingly normal GBSS activity is shown to be required to obtain the high A-type crystallinity levels that we now report for pyrenoidal starch. A model is presented explaining how GBSS-induced starch granule fusion may facilitate the formation of the pyrenoidal starch sheath.