Photosynthetic water oxidation in Synechocystis sp. PCC6803: mutations D1-E189K, R and Q are without influence on electron transfer at the donor side of photosystem II

Clausen, Jürgen; Winkler, Stephanie; Hays, Anna-Maria A.; Hundelt, Monika; Debus, Richard J.; Junge, Wolfgang

doi:10.1016/s0005-2728(01)00217-1

Cited by 32 publications

(48 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This conclusion would be consistent with the earlier spectroscopic analyses of D1-Glu189 mutants (14,15,20), but presents another challenge: it requires that the proximity of D1-Glu189 to Mn in the X-ray crystallographic structural models be an artifact of the radiation-induced reduction of the Mn 4 cluster that occurred during the collection of the X-ray diffraction data. However, as noted earlier, recent X-ray absorption studies of PSII single crystals (21) and PSII membrane multilayers (22) show that the X-ray doses that were used in the crystallographic studies to irradiate the PSII crystals would have caused a surprisingly rapid reduction of the Mn 4 cluster's oxidized Mn(III/IV) ions to their fully reduced Mn(II) states and substantially modified the structure of the Mn 4 cluster.…”

Section: Discussionsupporting

confidence: 83%

“…The lower O 2 evolving activity of PSII in the D1-E189Q and D1-E189R mutants (60 − 70 % compared to wild-type) has been noted previously (14,15,46). Similarly, the lower O 2 evolving activity of PSII in the D2-H189Q mutant (40 − 50 % compared to wild-type) has been noted previously (39,50).…”

Section: Resultssupporting

confidence: 59%

“…• during the S 1 → S 2 , S 2 → S 3 , and S 3 → S 0 transitions (15), (3) D1-E189K and D1-E189R PSII particles exhibit normal rates of electron transfer from Y Z to P 680 •+ and from the Mn 4 cluster to Y Z…”

mentioning

confidence: 99%

“…It was proposed that this hydrogen bond network is maintained by Gln because of its hydrogen bonding characteristics and by Lys and Arg because of their flexibility and hydrogen bonding characteristics (14,16) and that this network compensates for the change in charge that is created when D1-Glu189 is changed to Gln, Lys, or Arg 2 (15).…”

mentioning

confidence: 99%

See 3 more Smart Citations

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II

2006

View full text Add to dashboard Cite

In the recent X-ray crystallographic structural models of photosystem II, Glu189 of the D1 polypeptide is assigned as a ligand of the oxygen-evolving Mn 4 cluster. To determine if D1-Glu189 ligates a Mn ion that undergoes oxidation during one or more of the S 0 → S 1 , S 1 → S 2 , and S 2 → S 3 transitions, the FTIR difference spectra of the individual S state transitions in D1-E189Q and D1-E189R mutant PSII particles from the cyanobacterium Synechocystis sp. PCC 6803 were compared with those in wild-type PSII particles. Remarkably, the data show that neither mutation significantly alters the mid-frequency regions (1800 − 1200 cm −1 ) of any of the FTIR difference spectra. Importantly, neither mutation eliminates any specific symmetric or asymmetric carboxylate stretching mode that might have been assigned to D1-Glu189. The small spectral alterations that are observed are similar in amplitude to those that are observed in wild-type PSII particles that have been exchanged into FTIR analysis buffer by different methods or those that are observed in D2-H189Q mutant PSII particles (the residue D2-His189 is located > 25 Å from the Mn 4 cluster and accepts a hydrogen bond from Tyr Y D ). The absence of significant mutation-induced spectral alterations in the D1-Glu189 mutants shows that the oxidation of the Mn 4 cluster does not alter the frequencies of the carboxylate stretching modes of D1-Glu189 during the S 0 → S 1 , S 1 → S 2 , or S 2 → S 3 transitions. One explanation of these data is that D1-Glu189 ligates a Mn ion that does not increase its charge or oxidation state during any of these S state transitions. However, because the same conclusion was reached previously for D1-Asp170, and because the recent X-ray crystallographic structural models assign D1-Asp170 and D1-Glu189 as ligating different Mn ions, this explanation requires that (1) the extra positive charge that develops on the Mn 4 cluster during the S 1 → S 2 transition be localized on the Mn ion that is ligated by the α-COO − group of D1-Ala344 and (2) any increase in positive charge that develops on the Mn 4 cluster during the S 0 → S 1 and S 2 → S 3 transitions be localized on the one Mn ion that is not ligated by D1-Asp170, D1-Glu189, or D1-Ala344. An alternative explanation of the FTIR data is that D1-Glu189 does not ligate the Mn 4 cluster. This conclusion would be consistent with earlier spectroscopic analyses of D1-Glu189

show abstract

Section: Discussionsupporting

confidence: 83%

Section: Resultssupporting

confidence: 59%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II

2006

View full text Add to dashboard Cite

show abstract

“…O 2 -evolving PSII-cc were isolated from modified WT cells of Synechocystis sp. PCC6803 as described earlier (38). Typical rates of O 2 evolution under continuous illumination were 2,000-3,000 μmol ðO 2 Þ × mgðChlÞ −1 × h −1 (38) (see also SI Text).…”

Section: Methodsmentioning

confidence: 97%

Membrane-inlet mass spectrometry reveals a high driving force for oxygen production by photosystem II

Shevela

Beckmann

Clausen

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

View full text Add to dashboard Cite

Oxygenic photosynthesis is the basis for aerobic life on earth. The catalytic Mn 4 O x CaY Z center of photosystem II (PSII), after fourfold oxidation, extracts four electrons from two water molecules to yield dioxygen. This reaction cascade has appeared as a single four-electron transfer that occurs in typically 1 ms. Inevitable redox intermediates have so far escaped detection, probably because of very short lifetime. Previous attempts to stabilize intermediates by high O 2 -back pressure have revealed controversial results. Here we monitored by membrane-inlet mass spectrometry (MIMS) the production of 18 O 2 from 18 O-labeled water against a high background of 16 O 2 in a suspension of PSII-core complexes. We found neither an inhibition nor an altered pattern of O 2 production by up to 50-fold increased concentration of dissolved O 2 . Lack of inhibition is in line with results from previous X-ray absorption and visible-fluorescence experiments, but contradictory to the interpretation of previous UV-absorption data. Because we used essentially identical experimental conditions in MIMS as had been used in the UV work, the contradiction was serious, and we found it was not to be resolved by assuming a significant slowdown of the O 2 release kinetics or a subsequent slow conformational relaxation. This calls for reevaluation of the less direct UV experiments. The direct detection of O 2 release by MIMS shows unequivocally that O 2 release in PSII is highly exothermic. Under the likely assumption that one H þ is released in the S 4 → S 0 transition, the driving force at pH 6.5 and atmospheric O 2 pressure is at least 220 meV, otherwise 160 meV.water oxidation | oxygen evolution | isotope-ratio mass spectrometry | bioenergetics O xygenic photosynthesis is the metabolic basis for the most successful forms of life on earth. In cyanobacteria, algae and plants photosystem II (PSII) uses sunlight to split water into dioxygen and reducing equivalents, and it generates proton motive force. The catalytic centre of O 2 production in PSII, coined the OEC (oxygen evolving complex), comprises the manganese-oxygen-calcium (Mn 4 O x Ca) complex and its ligands, which include two substrate "water" molecules of undefined protonation state. It also includes a redox-active tyrosine residue, coined tyrosine ZðY Z Þ, which is the essential electron transfer link to the photoactive reaction center of PSII. Over 40 years ago Kok et al. (1) proposed-on the basis of flash-induced O 2 -evolution patterns (2)-that PSII, clocked and driven by four quanta of light, cycles through five different redox states, named S i (i ¼ 0;…;4), where i is the number of stored oxidizing equivalents. Once four oxidizing equivalents are accumulated O 2 is produced in the spontaneous reaction from S 4 to yield S 0 .In this S i state transition four electrons are transferred from two bound substrate water molecules that were partially or fully deprotonated (m ¼ 0-2) during the S i state cycle. In addition, one or two new substrate water molecules (n ¼ 1;2) bin...

show abstract

Protons, proteins and ATP

Junge

Discoveries in Photosynthesis

View full text Add to dashboard Cite

Photosynthetic water oxidation in Synechocystis sp. PCC6803: mutations D1-E189K, R and Q are without influence on electron transfer at the donor side of photosystem II

Cited by 32 publications

References 66 publications

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II

Membrane-inlet mass spectrometry reveals a high driving force for oxygen production by photosystem II

Protons, proteins and ATP

Contact Info

Product

Resources

About

Photosynthetic water oxidation in Synechocystis sp. PCC6803: mutations D1-E189K, R and Q are without influence on electron transfer at the donor side of photosystem II

Cited by 32 publications

References 66 publications

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S0 to S1, S1 to S2, or S2 to S3 Transitions in Photosystem II

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S0 to S1, S1 to S2, or S2 to S3 Transitions in Photosystem II

Membrane-inlet mass spectrometry reveals a high driving force for oxygen production by photosystem II

Protons, proteins and ATP

Contact Info

Product

Resources

About

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II

No Evidence from FTIR Difference Spectroscopy That Glutamate-189 of the D1 Polypeptide Ligates a Mn Ion That Undergoes Oxidation during the S₀ to S₁, S₁ to S₂, or S₂ to S₃ Transitions in Photosystem II