Yoshimasa Fukushima

A novel photoactive GAF domain of cyanobacteriochrome AnPixJ that shows reversible green/red photoconversion.

We report the discovery of a novel cyanobacteriochrome, the green/red photoreceptor AnPixJ (All1069), isolated from the heterocyst-forming cyanobacterium Anabaena (Nostoc) sp. PCC 7120. Cyanobacteriochromes are a recently emerging tetrapyrrole-based photoreceptor superfamily that are distantly related to the conventional red/far-red photoreceptor phytochromes (Phys). The chromophore-binding domains of AnPixJ produced in cyanobacterial and Escherichia coli cells both showed a reversible and full photoconversion between a green-absorbing form (lambda(max)=543 nm) and a red-absorbing form (lambda(max)=648 nm). Denaturation analysis revealed that the green-absorbing form and the red-absorbing form covalently ligated phycocyanobilin with E-configuration and Z-configuration at the C15C16 double bond, respectively. Time-resolved spectral analysis showed the formation of the first intermediate state peaking at 680 nm from the dark-stable red-absorbing form. This step resembles the first photoconversion step from the red-absorbing form to the red-shifted lumi-R intermediate state of the Phys. These results suggest that the Pr of AnPixJ is almost equivalent to that of the Phys and starts a primary photoreaction with Z-to-E isomerization in a mechanism similar to that in the Phys, but is finally photoconverted to the unique green-absorbing form.

Photoconversion Mechanism of a Green/Red Photosensory Cyanobacteriochrome AnPixJ: Time-Resolved Optical Spectroscopy and FTIR Analysis of the AnPixJ-GAF2 Domain

The photoconversion mechanism of a green/red sensory cyanobacteriochrome AnPixJ was studied. The phycocyanobilin-binding second GAF domain of AnPixJ of Anabaena sp. PCC 7120 was expressed in Escherichia coli cells. The His-tagged AnPixJ-GAF2 domain exhibited photoconversion between the green- and red-absorbing forms, APg(543) and APr(648), respectively. We detected four intermediate states in the photocycle between them, as follows: APr(648) → red light → APr(648)* → (with a rise time constant τ(r) of <100 ns) R1(650-80) (with a decay time constant τ(d) of <1 μs) → R2(610) (τ(d) = 920 μs) → APg(543) → green light → APg(543)* → (τ(r) < 50 ns) G1(570) (τ(d) = 190 μs) → G2(630) (τ(d) = 1.01 ms) → APr(648). These intermediates were named for their absorption peak wavelengths, which were estimated on the basis of the time-resolved difference spectra and global analysis of the time courses. The absorption spectrum of APr(648) resembles that of the Pr form of the phytochrome, while all the other states showed peaks at 530-650 nm and had wider bandwidths with smaller peak amplitudes. The fastest decay phases of fluorescence from APr(648)* and APg(543)* gave lifetimes of 200 and 42 ps, respectively, suggesting fast primary reactions. The APg(543)-minus-APr(648) difference FTIR spectrum in an H(2)O medium was significantly different from those reported for the Pfr/Pr difference spectra in phytochromes. Most of the peaks in the difference spectrum were shifted in the D(2)O medium, suggesting the high accessibility to the aqueous phase. The interactions of the phycocyanobilin chromophore with the surrounding amino acid residues, which are fairly different from those in the GAF domain of phytochromes, realize the unique green/red photocycle of AnPixJ.

Formation of interacting spins on flavosemiquinone and tyrosine radical in photoreaction of a blue light sensor BLUF protein TePixD.

Light-induced radicals were detected by electron paramagnetic resonance (EPR) and pulsed electron-nuclear double resonance (ENDOR) in the BLUF-domain protein TePixD of the thermophilic cyanobacterium Thermosynechococcus elongatus BP-1. The illumination of TePixD at 5-200 K derived an EPR signal with a separation of 85 G between the main peaks around g = 2, showing a typical Pakes pattern of magnetic dipole-dipole interaction between two nearby radicals. Longer illumination induced an EPR signal at g = 2.0045, which was assigned as a neutral flavosemiquinone FADH(*). The FADH(*) formation occurred in parallel with a decrease in Pakes doublet. The Pakes doublet was not detected in a mutant TePixD protein in which a tyrosine residue was replaced with phenylalanine (Y8F protein). A pulsed ENDOR study suggested that the Pakes doublet had arisen from the interaction between a neutral flavosemiquinone radical and a neutral tyrosine radical, i.e., the FADH(*)-Y8(*) state. An EPR simulation of the Pakes doublet showed that the distance between FAD and Y8 is 2.2 A shorter than that calculated from the X-ray crystallography structure in the dark-adapted state, suggesting the modification of the protein conformation in the photoinduced FADH(*)-Y8(*) state. The Pakes doublet signal was detected by 10 K illumination in the sample which was immediately frozen after 273 K illumination, corresponding to the red-shifted state F(490). On the other hand, the signal was not detected in the sample which was incubated for 10 min at 273 K in the dark after 273 K illumination, corresponding to the dark-adapted state D(471). In the sample annealed at 160 K for 10 min after 160 K illumination, corresponding to the partially red-shifted state J(11), the Pakes doublet signal was detected by the 10 K illumination. On the basis of these observations, we concluded that the interaction with the FADH(*)-Y8(*) state occurred after the second photoexcitation of the photoinduced red-shifted states in the photocycle of TePixD.

Three different mechanisms of energy dissipation of a desiccation-tolerant moss serve one common purpose: to protect reaction centres against photo-oxidation

Three different types of non-photochemical de-excitation of absorbed light energy protect photosystem II of the sun- and desiccation-tolerant moss Rhytidium rugosum against photo-oxidation. The first mechanism, which is light-induced in hydrated thalli, is sensitive to inhibition by dithiothreitol. It is controlled by the protonation of a thylakoid protein. Other mechanisms are activated by desiccation. One of them permits exciton migration towards a far-red band in the antenna pigments where fast thermal deactivation takes place. This mechanism appears to be similar to a mechanism detected before in desiccated lichens. A third mechanism is based on the reversible photo-accumulation of a radical that acts as a quencher of excitation energy in reaction centres of photosystem II. On the basis of absorption changes around 800 nm, the quencher is suggested to be an oxidized chlorophyll. The data show that desiccated moss is better protected against photo-oxidative damage than hydrated moss. Slow drying of moss thalli in the light increases photo-protection more than slow drying in darkness.

Acceleration of Electron-Transfer-Induced Fluorescence Quenching upon Conversion to the Signaling State in the Blue-Light Receptor, TePixD, from Thermosynechococcus elongatus

TePixD is a blue light using flavin (BLUF) protein of a thermophilic cyanobacterium, Thermosynechococcus elongatus. The fluorescence dynamics of TePixD was observed for the first time in both its dark-adapted and signaling (red-shifted) forms with a 200-fs time resolution. The fluorescence up-conversion setup was used in the time region up to 60 ps, and the streak-camera setup was used in the time region up to 1 ns. To avoid the accumulation of the red-shifted form by the exciting laser irradiation, the sample solution was circulated using a diaphragm pump. A handmade flow cuvette with a small cross section was used to achieve a fast flow of the solution in the excited region. The fluorescence decay times were unequivocally determined to be 13.6 and 114 ps for the dark-adapted form and 1.37 ps for the red-shifted form. The double-exponential fluorescence decay in the dark-adapted form suggested the coexistence of two conformations that have the 13.6- and 114-ps decay components, respectively. The single-exponential fluorescence decay in the red-shifted form suggested the elimination of heterogeneity in the conformation upon the light-induced conversion. The fast fluorescence-quenching components were almost eliminated in the mutant in which the conserved tyrosine Tyr8 is replaced by phenylalanine. Thus, the fluorescence quench was concluded to arise from the electron transfer from Tyr8, to the excited flavin chromophore. The 10-fold-faster quenching in the red-shifted form suggested the acceleration of the electron transfer. The faster decay time of 13.6 ps for the dark-adapted form was found to be almost temperature independent in the region from 10 to 40 degrees C. This suggested that the energy gap, DeltaG, in Marcuss electron-transfer theory is optimized to give the fastest rate. The acceleration of the electron transfer in the red-shifted form is interpreted to be due to the enhancement of the electronic-coupling factor between the donor and acceptor. A shortening of the Tyr8-flavin distance by 1.0-1.5 A was suggested if we adopt the empirical formula for the donor-acceptor distance dependence of the electron transfer rate.

Two functional sites of phosphatidylglycerol for regulation of reaction of plastoquinone QB in photosystem II

Functional roles of an anionic lipid phosphatidylglycerol (PG) were studied in pgsA-gene-inactivated and cdsA-gene-inactivated/phycobilisome-less mutant cells of a cyanobacterium Synechocystis sp. PCC 6803, which can grow only in PG-supplemented media. 1) A few days of PG depletion suppressed oxygen evolution of mutant cells supported by p-benzoquinone (BQ). The suppression was recovered slowly in a week after PG re-addition. Measurements of fluorescence yield indicated the enhanced sensitivity of Q(B) to the inactivation by BQ. It is assumed that the loss of low-affinity PG (PG(L)) enhances the affinity for BQ that inactivates Q(B). 2) Oxygen evolution without BQ, supported by the endogenous electron acceptors, was slowly suppressed due to the direct inactivation of Q(B) during 10 days of PG depletion, and was recovered rapidly within 10h upon the PG re-addition. It is concluded that the loss of high-affinity PG (PG(H)) displaces Q(B) directly. 3) Electron microscopy images of PG-depleted cells showed the specific suppression of division of mutant cells, which had developed thylakoid membranes attaching phycobilisomes (PBS). 4) Although the PG-depletion for 14 days decreased the chlorophyll/PBS ratio to about 1/4, flourescence spectra/lifetimes were not modified indicating the flexible energy transfer from PBS to different numbers of PSII. Longer PG-depletion enhanced allophycocyanin fluorescence at 683nm with a long 1.2ns lifetime indicating the suppression of energy transfer from PBS to PSII. 5) Action sites of PG(H), PG(L) and other PG molecules on PSII structure are discussed.

Two Intermediate States I and J Trapped at Low Temperature in the Photocycles of two BLUF Domain Proteins of Cyanobacteria Synechocystis sp. PCC6803 and Thermosynechococcus elongatus BP-1†

We identified the two intermediate states, I and J, that are common in the photocycles of the cyanobacterial BLUF (sensor of Blue Light Using Flavin) domain proteins of Slr1694 of Synechocystis sp. PCC6803 and Tll0078 of Thermosynechococcus elongatus BP‐1 by analyzing the absorption spectra at 5 K. Illumination at 5 K accumulated intermediate forms (designated as I5 and I9), which showed 5 and 9 nm redshifts of the absorption bands of flavin in the Tll0078 and Slr1694 proteins, respectively. I5 (I9) was converted into the next intermediate, which have 11 nm (14 nm) red‐shifted absorption bands J11 (J14) after dark annealing at 230 K (240 K). Further dark annealing at 280 K (270 K) of J11 (J14) produced the signal‐transmitting final form F490 (F495), with a small increase in the absorption at around 490 nm (495 nm). The results indicate that the BLUF proteins of Tll0078 and Slr1694 exhibit the common photocycle of D471 (D467) →I5 (I9) →J11 (J14) →F490 (F495) at low temperature. The transition temperatures for these intermediate forms differ for two proteins. The amount of I5 (I9) accumulated at 5 K was small and increased at a higher temperature, suggesting heterogeneity of the protein structure that determines the reaction pathway.

Photoreaction of Cyanobacterial BLUF Protein PixD Studied by Low Temperature Spectroscopy and Site-Directed Mutagenesis

Bluf Domain (Sensor Of Blue Light Using Fad) Is A Newly Identified Class Of Flavinbinding Photoreceptor Domain. Cyanobacterial Bluf-Domain Protein Pixd Has Been Revealed To Regulate The Positive Phototaxis Of Cells In The Cyanobacterium Synechocystis Sp. Pcc6803. Bluf Proteins Show 10–20 Nm Red-Shifts Of Their Flavin Absorption Bands Upon The Blue-Light Absorption. In This Study, We Studied The Photoconversion Mechanisms Of Tepixd Protein Of The Thermophilic Cyanobacterium Thermosynechococcus Elongatus Bp-1 By Low Temperature Spectroscopy And Sitedirected Mutagenesis. Although The Deletion Of The Tyr8 Residue Of Pixd Protein Had Been Shown To Abolish The Photoconversion At Room Temperature, We Show Here That Illumination At 80 K Produces A Normal Red-Shift Even In Y8F And Y8A Mutant Proteins. The Red-Shifted Forms That Are Trapped At 80 Kare Stable In The Dark, And Decay By Dark Annealing At 280 K. The Illumination At 150 K Of Y8F And Y8A Mutant Proteins, On The Other Hand, Formed An Anionic Form Of Flavin Suggesting The Existence Of Multiple Reaction Pathways. The Accumulations Of The Red-Shifted Forms In Y8F And Y8A Mutant Proteins At 80 K Occurred With 43- And 137-Times Slower Than That Of Wildtype Protein, Respectively, With The Extents At About 1/2 And 1/4 Of That Of Wild-Type. It Is Shown That The Photoconversion Of The Bluf-Domain Protein Occurs Even Without The Tyr8 Residue, And That Tyr8 Is Necessary To Enhance The Photoconversion Efficiency.