Ryouta Takahashi scite author profile

The redox-active tyrosine YZ (D1-Tyr161) in photosystem II (PSII) functions as an immediate electron acceptor of the Mn4Ca cluster, which is the catalytic center of photosynthetic water oxidation. YZ is also located in the hydrogen bond network that connects the Mn4Ca cluster to the lumen and hence is possibly related to the proton transfer process during water oxidation. To understand the role of YZ in the water oxidation mechanism, we have studied the hydrogen bonding interactions of YZ and its photooxidized neutral radical YZ(•) together with the interaction of the coupled His residue, D1-His190, using light-induced Fourier transform infrared (FTIR) difference spectroscopy. The YZ(•)-minus-YZ FTIR difference spectrum of Mn-depleted PSII core complexes exhibited a broad positive feature around 2800 cm(-1), which was absent in the corresponding spectrum of another redox-active tyrosine YD (D2-Tyr160). Analyses by (15)N and H/D substitutions, examination of the pH dependence, and density functional theory and quantum mechanics/molecular mechanics (QM/MM) calculations showed that this band arises from the N-H stretching vibration of the protonated cation of D1-His190 forming a charge-assisted strong hydrogen bond with YZ(•). This result provides strong evidence that the proton released from YZ upon its oxidation is trapped in D1-His190 and a positive charge remains on this His. The broad feature of the ~2800 cm(-1) band reflects a large proton polarizability in the hydrogen bond between YZ(•) and HisH(+). QM/MM calculations further showed that upon YZ oxidation the hydrogen bond network is rearranged and one water molecule moves toward D1-His190. From these data, a novel proton transfer mechanism via YZ(•)-HisH(+) is proposed, in which hopping of the polarizable proton of HisH(+) to this water triggers the transfer of the proton from substrate water to the luminal side. This proton transfer mechanism could be functional in the S2 → S3 transition, which requires proton release before electron transfer because of an excess positive charge on the Mn4Ca cluster.

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Correlation between the Hydrogen-Bond Structures and the C═O Stretching Frequencies of Carboxylic Acids as Studied by Density Functional Theory Calculations: Theoretical Basis for Interpretation of Infrared Bands of Carboxylic Groups in Proteins

Takei

Takahashi

Noguchi

2008

J. Phys. Chem. B

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Carboxylic groups (COOH) of Asp and Glu side chains often function as key components in enzymatic reactions, and identifying their H-bond structures in the active sites is essential for understanding the reaction mechanisms. In this study, the correlation between the H-bond structures and the C=O stretching (nuC=O) frequencies of COOH groups was studied using density functional theory calculations. The nuC=O frequencies and their shifts upon OH deuteration were calculated for model complexes of acetic acid and propionic acid H bonded at different sites with various compounds. Calculation results together with some experimental data showed that, upon direct H bonding at the C=O group, the nuC=O frequencies downshift from the free value (1770-1780 cm(-1) in an Ar matrix) to 1745-1760 cm(-1), while H bonding at the OH hydrogen induce even larger downshifts to provide the frequencies at 1720-1745 cm(-1). In contrast, when the COH oxygen is H-bonded, the nuC=O frequencies upshift to 1785-1800 cm(-1). In double and multiple H-bond forms, H-bonding effects at individual sites are basically additive, and complexes in which the C=O and the OH hydrogen are simultaneously H bonded exhibit significantly low nuC=O frequencies at 1725-1700 cm(-1), while complexes H bonded at the oxygen of the COH in addition to either at the C=O or the OH hydrogen exhibit medium frequencies of 1740-1765 cm(-1). The nuC=O frequencies linearly correlate with the C=O lengths, which are changed by H bonding at different sites. Upon OH deuteration, all the complexes showed nuC=O downshifts mostly by approximately 10 cm(-1) and in some cases as large as approximately 20 cm(-1), and hence deuteration-induced downshifts can be a good indicator, irrespective of H-bond forms, for assignments of the nuC=O bands of carboxylic groups. The results in this study provide the criteria for determining the H-bond structures of Asp and Glu side chains in proteins using their nuC=O bands in Fourier transform infrared spectra.

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Structures and Binding Sites of Phenolic Herbicides in the Q_B Pocket of Photosystem II

Takahashi

Hasegawa²,

Takano

et al. 2010

Biochemistry

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Herbicides targeting photosystem II (PSII) block the electron transfer beyond Q(A) by binding to the Q(B) site. Upon binding, the redox potential of Q(A) shifts differently depending on the types of herbicides. In this study, we have investigated the structures, interactions, and locations of phenolic herbicides in the Q(B) site to clarify the molecular mechanism of the Q(A) potential shifts by herbicides. Fourier transform infrared (FTIR) difference spectra upon photoreduction of the preoxidized non-heme iron (Fe(2+)/Fe(3+) difference) were measured with PSII membranes in the presence of bromoxynil or ioxynil. The CN and CO stretching vibrations of these phenolic herbicides were identified at 2215-2200 and 1516-1505 cm(-1), respectively, in the Fe(2+)/Fe(3+) difference spectra. Comparison with the spectra of bromoxynil in ethanol solutions along with density functional theory analysis strongly suggests that the phenolic herbicides take a deprotonated form in the binding pocket. In addition, the CN stretching, NH bending, and NH stretching vibrations of a His side chain, which were found at 1109-1101, 1187-1185, and 3000-2500 cm(-1), respectively, in the Fe(2+)/Fe(3+) difference spectra, showed characteristic features in the presence of phenolic herbicides. These signals are probably attributed to D1-His215, one of the ligands to the non-heme iron. Docking calculations for herbicides to the Q(B) pocket confirmed the binding of deprotonated bromoxynil to D1-His215 at the CO group, whereas the protonated form of bromoxynil and DCMU were found to bind to the opposite side of the pocket without an interaction with D1-His215. From these results, it is proposed that a strong hydrogen bond of the phenolate CO group with D1-His215 induces the change in the hydrogen bond strength of the Q(A) CO group through the Q(A)-His-Fe-His-phenolate bridge causing the downshift of the Q(A) redox potential.

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FTIR Study on the Hydrogen Bond Structure of a Key Tyrosine Residue in the Flavin-Binding Blue Light Sensor TePixD fromThermosynechococcus elongatus

et al. 2007

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The BLUF (sensor of blue light using FAD) domain is a blue light receptor possessing a flavin molecule as an active cofactor. A conserved Tyr residue located adjacent to flavin has been proposed to be a key amino acid in the mechanism of the photoreaction of the BLUF domain. We have studied the structure of this key Tyr residue and the relevance to the photoreaction in the BLUF protein of the cyanobacterium Thermosynechococcus elongatus, TePixD, by means of Fourier transform infrared (FTIR) difference spectroscopy and density functional theory (DFT) calculations. Light-induced FTIR difference spectra of unlabeled and [4-13C]Tyr-labeled TePixD in H2O and D2O revealed that the nuCO/deltaCOH vibrations of a photosensitive Tyr side chain are located at 1265/1242 cm-1 in the dark-adapted state and at 1273/1235 cm-1 in the light-induced signaling state. These signals were assigned to the vibrations of Tyr8 near flavin from the absence of the effect of [4-13C]Tyr labeling in the Tyr8Phe mutant. DFT calculations of H-bonded complexes of p-cresol with amides as models of the Tyr8-Gln50 interactions showed that Tyr8 acts as a H-bond donor to the Gln50 in both of the dark and light states. Further DFT analysis suggested that this H-bond is strengthened upon photoconversion to the light state accompanied with a change in the H-bond angle. The change in the H-bond structure of Tyr8 is coupled to the flavin photoreaction probably through the Tyr8-Gln50-flavin H-bond network, suggesting a significant role of Tyr8 in the photoreaction mechanism of TePixD.

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