Excited-State Dynamics of Protochlorophyllide Revealed by Subpicosecond Infrared Spectroscopy

Colindres-Rojas, Miriam; Wolf, Matthias; Gross, Ruth T.; Seidel, Sonja; Dietzek, Benjamin; Schmitt, Michael; Popp, Jürgen; Hermann, Gudrun; Diller, Rolf

doi:10.1016/j.bpj.2010.11.054

Cited by 11 publications

(29 citation statements)

References 45 publications

(115 reference statements)

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“…[21] Global analysis was used to model the time-resolved absorption difference spectra from these measurements by fitting the data to yield species associated difference spectra (SADS). [22] Thee volution of the spectral features allows the mechanism of intermediate formation to be determined, whilst the kinetic parameters are indicative of the overall rate of loss of each species,i ncluding both conversion to the proceeding state and return to the ground state (see the Supporting Information for further detail). Small differences in fitted lifetimes between the visible and IR datasets can be attributed to differences in solvation (H 2 O in visible or D 2 Oi nI R) and lower signal-to-noise ratios at longer IR time delays.For clarity only the SADS are shown in the main manuscript, whereas ground-state absorption spectra ( Figure S1), raw time-resolved data ( Figures S2-8) and an analysis of the global fitting ( Figures S9-11) can be found in the Supporting Information.…”

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confidence: 99%

“…[15,22,23] In the Pchlide only sample the data can be modeled with four component lifetimes.T he short-lived S1 component is resolved in the IR data, but not in the visible data, due to the smaller initial step sizes.T he lifetimes of the slower components are similar in both the visible and IR measurements.T he SADS,w hich have been fitted with ac ombination of Gaussian components (Figure S9), show that the proposed solvation of the ICT state (SADS3) is accompanied by changes in the 1550 cm À1 region ( Figure 2C and Figure S9). This is in agreement with previous ultrafast time-resolved IR measurements,w hich suggested that this step is associated with structural changes to the C13 carbonyl and delocalized C=Cand C=Nmodes.…”

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confidence: 99%

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Excited‐State Charge Separation in the Photochemical Mechanism of the Light‐Driven Enzyme Protochlorophyllide Oxidoreductase

et al. 2014

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The unique light-driven enzyme protochlorophyllide oxidoreductase (POR) is an important model system for understanding how light energy can be harnessed to power enzyme reactions.T he ultrafast photochemical processes, essential for capturing the excitation energy to drive the subsequent hydride-and proton-transfer chemistry,h ave so far proven difficult to detect. We have used ac ombination of time-resolved visible and IR spectroscopy, providing complete temporal resolution over the picosecond-microsecond time range,t op ropose an ew mechanism for the photochemistry. Excited-state interactions between active site residues and acarboxyl group on the Pchlide molecule result in apolarized and highly reactive double bond. This so-called "reactive" intramolecular charge-transfer state creates an electron-deficient site across the double bond to trigger the subsequent nucleophilic attacko fN ADPH, by the negatively charged hydride from nicotinamide adenine dinucleotide phosphate. This work provides the crucial, missing link between excitedstate processes and chemistry in POR. Moreover,i tp rovides important insight into how light energy can be harnessed to drive enzyme catalysis with implications for the design of lightactivated chemical and biological catalysts.

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Excited‐State Charge Separation in the Photochemical Mechanism of the Light‐Driven Enzyme Protochlorophyllide Oxidoreductase

et al. 2014

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“…All these experiments were also performed on recombinant enzymes expressed in Escherichia coli or on a pigment-free, monomeric enzyme isolated from etiolated oat (Avena sativa) seedlings. [24] The absorbance spectra of the reconstituted POR-PChlide-NADPH complexes are strictly reproducible and, as can be seen from Figure S1 of our manuscript L. O. Bjçrn is referring to, not disturbed by scattered light. In the article of L. O. Bjçrn the results obtained from those enzymes are subjected to criticisms in so far as they would differ from those published more than 40 years ago.…”

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confidence: 56%

“…[24] The absorbance spectra of the reconstituted POR-PChlide-NADPH complexes are strictly reproducible and, as can be seen from Figure S1 (0,2)]. The enzymes from barley do not include the transit peptide, which is only necessary to import the precursor proteins from the cytoplasm into plastids.…”

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confidence: 93%

Response to the Comments by L. O. Björn on our Paper “Catalytic Efficiency of a Photoenzyme—An Adaptation to Natural Light Conditions”

Hermann

Schmitt²,

Dietzek

et al. 2013

ChemPhysChem

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NADPH:protochlorophyllide oxidoreductase (POR) is one of only two enzymes in nature, in which the enzymatic activity is switched on by the absorption of light. The pre-formation of the enzyme-substrate complex in the dark and the initiation of catalysis by light make the POR enzyme an excellent model for studying the initial, ultrafast steps of enzymatic reactions in real time. Throughout the last decade a series of such studies have been reported. They all include recombinant POR enzymes, which were expressed in Escherichia coli and reconstituted to the ternary enzyme complexes by addition of the substrate and coenzyme, protochlorophyllide (PChlide) and NADPH, respectively. [1][2][3][4][5][6][7] In addition, the thermodynamics of substrate/coenzyme binding as well as the complete POR catalytic cycle have been investigated by spectroscopic techniques in conjunction with low-temperature and stopped flow methods. All these experiments were also performed on recombinant enzymes expressed in Escherichia coli or on a pigment-free, monomeric enzyme isolated from etiolated oat (Avena sativa) seedlings. [8][9][10][11][12][13][14][15][16][17][18] As in the studies cited above, [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] we have used purified recombinant POR enzymes in our experiments aimed to determine the quantum yield for the POR catalyzed photoreduction. In the article of L. O. Bjçrn the results obtained from those enzymes are subjected to criticisms in so far as they would differ from those published more than 40 years ago. However, most of the differences can be explained by the different types and aggregation states of the enzymes examined. In the work referred by L. O. Bjçrn, POR bound to natural membranes and POR isolated from etiolated plant material was investigated. [19][20][21] There is strong evidence that POR associates with membranes under natural conditions and exists in an aggregated state as dimer or larger sized oligomer. [22] In a similar manner, the enzymes obtained from the extraction of etiolated plant material, PChlide holochromes, form high molecular weight complexes (~600 kDa), too. [19,21,23] The photochemistry of aggregated PChlide-POR complexes is impaired by pigment-pigment interactions, energy transfer between PChlide and chlorophyllide (the product of the enzymatic reaction) and further affected by protein-lipid interactions.Nowadays, considerable effort has therefore been made to substitute the aggregated POR complexes by recombinant monomeric enzymes, which are catalytically active. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] The reason is that such minimal photoactive POR complexes consisting of the natural constituents-photoenzyme, substrate, and cofactor-should allow a more precise insight into the molecular mechanism of POR.As outlined in the supplement of our paper, the POR enzymes used in our experiments are monomers and were obtained from heterologous expression of the POR A and POR B gen from barley (Hordeum vulgare) and the POR gen from Syn...

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“…Preparation of PChlide-PChlide a was isolated from 5-dayold, dark grown oat seedlings (Avena sativa L.) as reported recently (28). Briefly, the coleoptiles were treated with 15 mM 5-aminolevulinic acid in 35 mM potassium phosphate buffer for 48 h. Following disruption of the coleoptiles by homogenization, PChlide was extracted into an ice-cold 10 mM Tricine buffer, pH 7.5, 75% acetone (v/v) mixture.…”

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confidence: 99%

Plant Protochlorophyllide Oxidoreductases A and B

Garrone

Archipowa

Zipfel

et al. 2015

Journal of Biological Chemistry

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Background:In plants, a key regulatory step in chlorophyll biosynthesis is catalyzed by two light-dependent isozymes. Results: The two isozymes operate via the same reaction mechanism but differ in their catalytic efficiencies. Conclusion: Different substrate affinities and conformational flexibilities modulate the catalytic reaction. Significance: Detailed understanding of light-driven reactions in nature has a big impact on the development of artificial energy conversion systems.

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Excited-State Dynamics of Protochlorophyllide Revealed by Subpicosecond Infrared Spectroscopy

Cited by 11 publications

References 45 publications

Excited‐State Charge Separation in the Photochemical Mechanism of the Light‐Driven Enzyme Protochlorophyllide Oxidoreductase

Excited‐State Charge Separation in the Photochemical Mechanism of the Light‐Driven Enzyme Protochlorophyllide Oxidoreductase

Response to the Comments by L. O. Björn on our Paper “Catalytic Efficiency of a Photoenzyme—An Adaptation to Natural Light Conditions”

Plant Protochlorophyllide Oxidoreductases A and B

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