Your search keyword '"Bacteriochlorophylls metabolism"' showing total 21 results

1. Cryo-EM structures of light-harvesting 2 complexes from Rhodopseudomonas palustris reveal the molecular origin of absorption tuning.

Author

Qian P, Nguyen-Phan CT, Gardiner AT, Croll TI, Roszak AW, Southall J, Jackson PJ, Vasilev C, Castro-Hartmann P, Sader K, Hunter CN, and Cogdell RJ

Subjects

Bacterial Proteins metabolism, Cryoelectron Microscopy, Light-Harvesting Protein Complexes metabolism, Peptides metabolism, Bacteriochlorophylls metabolism, Rhodopseudomonas genetics

Abstract

The genomes of some purple photosynthetic bacteria contain a multigene puc family encoding a series of α- and β-polypeptides that together form a heterogeneous antenna of light-harvesting 2 (LH2) complexes. To unravel this complexity, we generated four sets of puc deletion mutants in Rhodopseudomonas palustris , each encoding a single type of pucBA gene pair and enabling the purification of complexes designated as PucA-LH2, PucB-LH2, PucD-LH2, and PucE-LH2. The structures of all four purified LH2 complexes were determined by cryogenic electron microscopy (cryo-EM) at resolutions ranging from 2.7 to 3.6 Å. Uniquely, each of these complexes contains a hitherto unknown polypeptide, γ, that forms an extended undulating ribbon that lies in the plane of the membrane and that encloses six of the nine LH2 αβ-subunits. The γ-subunit, which is located near to the cytoplasmic side of the complex, breaks the C9 symmetry of the LH2 complex and binds six extra bacteriochlorophylls (BChls) that enhance the 800-nm absorption of each complex. The structures show that all four complexes have two complete rings of BChls, conferring absorption bands centered at 800 and 850 nm on the PucA-LH2, PucB-LH2, and PucE-LH2 complexes, but, unusually, the PucD-LH2 antenna has only a single strong near-infared (NIR) absorption peak at 803 nm. Comparison of the cryo-EM structures of these LH2 complexes reveals altered patterns of hydrogen bonds between LH2 αβ-side chains and the bacteriochlorin rings, further emphasizing the major role that H bonds play in spectral tuning of bacterial antenna complexes.

Published

2022

2. Acquirement of water-splitting ability and alteration of the charge-separation mechanism in photosynthetic reaction centers.

Author

Tamura H, Saito K, and Ishikita H

Subjects

Amino Acids, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Electron Transport, Oxygen metabolism, Photosynthetic Reaction Center Complex Proteins chemistry, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex metabolism, Protein Subunits chemistry, Protein Subunits metabolism, Proteobacteria metabolism, Water chemistry, Electrons, Photosynthetic Reaction Center Complex Proteins metabolism, Water metabolism

Abstract

In photosynthetic reaction centers from purple bacteria (PbRC) and the water-oxidizing enzyme, photosystem II (PSII), charge separation occurs along one of the two symmetrical electron-transfer branches. Here we report the microscopic origin of the unidirectional charge separation, fully considering electron-hole interaction, electronic coupling of the pigments, and electrostatic interaction with the polarizable entire protein environments. The electronic coupling between the pair of bacteriochlorophylls is large in PbRC, forming a delocalized excited state with the lowest excitation energy (i.e., the special pair). The charge-separated state in the active branch is stabilized by uncharged polar residues in the transmembrane region and charged residues on the cytochrome c 2 binding surface. In contrast, the accessory chlorophyll in the D1 protein (Chl D1 ) has the lowest excitation energy in PSII. The charge-separated state involves Chl D1 •+ and is stabilized predominantly by charged residues near the Mn 4 CaO 5 cluster and the proceeding proton-transfer pathway. It seems likely that the acquirement of water-splitting ability makes Chl D1 the initial electron donor in PSII., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

3. A photosynthetic antenna complex foregoes unity carotenoid-to-bacteriochlorophyll energy transfer efficiency to ensure photoprotection.

Author

Niedzwiedzki DM, Swainsbury DJK, Canniffe DP, Hunter CN, and Hitchcock A

Subjects

Bacterial Proteins chemistry, Carotenoids chemistry, Energy Transfer, Kinetics, Light-Harvesting Protein Complexes chemistry, Photosynthesis, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides metabolism, Bacterial Proteins metabolism, Bacteriochlorophylls metabolism, Carotenoids metabolism, Light-Harvesting Protein Complexes metabolism

Abstract

Carotenoids play a number of important roles in photosynthesis, primarily providing light-harvesting and photoprotective energy dissipation functions within pigment-protein complexes. The carbon-carbon double bond (C=C) conjugation length of carotenoids ( N ), generally between 9 and 15, determines the carotenoid-to-(bacterio)chlorophyll [(B)Chl] energy transfer efficiency. Here we purified and spectroscopically characterized light-harvesting complex 2 (LH2) from Rhodobacter sphaeroides containing the N = 7 carotenoid zeta (ζ)-carotene, not previously incorporated within a natural antenna complex. Transient absorption and time-resolved fluorescence show that, relative to the lifetime of the S 1 state of ζ-carotene in solvent, the lifetime decreases ∼250-fold when ζ-carotene is incorporated within LH2, due to transfer of excitation energy to the B800 and B850 BChls a These measurements show that energy transfer proceeds with an efficiency of ∼100%, primarily via the S 1 → Q x route because the S 1 → S 0 fluorescence emission of ζ-carotene overlaps almost perfectly with the Q x absorption band of the BChls. However, transient absorption measurements performed on microsecond timescales reveal that, unlike the native N ≥ 9 carotenoids normally utilized in light-harvesting complexes, ζ-carotene does not quench excited triplet states of BChl a , likely due to elevation of the ζ-carotene triplet energy state above that of BChl a These findings provide insights into the coevolution of photosynthetic pigments and pigment-protein complexes. We propose that the N ≥ 9 carotenoids found in light-harvesting antenna complexes represent a vital compromise that retains an acceptable level of energy transfer from carotenoids to (B)Chls while allowing acquisition of a new, essential function, namely, photoprotective quenching of harmful (B)Chl triplets., Competing Interests: The authors declare no competing interest.

Published

2020

4. Switching sides-Reengineered primary charge separation in the bacterial photosynthetic reaction center.

Author

Laible PD, Hanson DK, Buhrmaster JC, Tira GA, Faries KM, Holten D, and Kirmaier C

Subjects

Bacteriochlorophylls metabolism, Electron Transport, Molecular Dynamics Simulation, Mutation, Pheophytins metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Protein Engineering, Amino Acid Substitution, Pheophytins chemistry, Photosynthetic Reaction Center Complex Proteins chemistry, Rhodobacter sphaeroides metabolism

Abstract

We report 90% yield of electron transfer (ET) from the singlet excited state P* of the primary electron-donor P (a bacteriochlorophyll dimer) to the B-side bacteriopheophytin (H B ) in the bacterial photosynthetic reaction center (RC). Starting from a platform Rhodobacter sphaeroides RC bearing several amino acid changes, an Arg in place of the native Leu at L185-positioned over one face of H B and only ∼4 Å from the 4 central nitrogens of the H B macrocycle-is the key additional mutation providing 90% yield of P + H B - This all but matches the near-unity yield of A-side P + H A - charge separation in the native RC. The 90% yield of ET to H B derives from (minimally) 3 P* populations with distinct means of P* decay. In an ∼40% population, P* decays in ∼4 ps via a 2-step process involving a short-lived P + B B - intermediate, analogous to initial charge separation on the A side of wild-type RCs. In an ∼50% population, P* → P + H B - conversion takes place in ∼20 ps by a superexchange mechanism mediated by B B An ∼10% population of P* decays in ∼150 ps largely by internal conversion. These results address the long-standing dichotomy of A- versus B-side initial charge separation in native RCs and have implications for the mechanism(s) and timescale of initial ET that are required to achieve a near-quantitative yield of unidirectional charge separation., Competing Interests: The authors declare no competing interest.

Published

2020

5. Macrocycle ring deformation as the secondary design principle for light-harvesting complexes.

Author

De Vico L, Anda A, Osipov VA, Madsen AØ, and Hansen T

Subjects

Alphaproteobacteria metabolism, Bacterial Proteins metabolism, Bacteriochlorophylls metabolism, Light-Harvesting Protein Complexes metabolism, Photosynthesis physiology, Alphaproteobacteria chemistry, Bacterial Proteins chemistry, Bacteriochlorophylls chemistry, Light-Harvesting Protein Complexes chemistry

Abstract

Natural light-harvesting is performed by pigment-protein complexes, which collect and funnel the solar energy at the start of photosynthesis. The identity and arrangement of pigments largely define the absorption spectrum of the antenna complex, which is further regulated by a palette of structural factors. Small alterations are induced by pigment-protein interactions. In light-harvesting systems 2 and 3 from Rhodoblastus acidophilus , the pigments are arranged identically, yet the former has an absorption peak at 850 nm that is blue-shifted to 820 nm in the latter. While the shift has previously been attributed to the removal of hydrogen bonds, which brings changes in the acetyl moiety of the bacteriochlorophyll, recent work has shown that other mechanisms are also present. Using computational and modeling tools on the corresponding crystal structures, we reach a different conclusion: The most critical factor for the shift is the curvature of the macrocycle ring. The bending of the planar part of the pigment is identified as the second-most important design principle for the function of pigment-protein complexes-a finding that can inspire the design of novel artificial systems., Competing Interests: The authors declare no conflict of interest.

Published

2018

6. Nature does not rely on long-lived electronic quantum coherence for photosynthetic energy transfer.

Author

Duan HG, Prokhorenko VI, Cogdell RJ, Ashraf K, Stevens AL, Thorwart M, and Miller RJD

Subjects

Bacterial Proteins chemistry, Bacteriochlorophylls metabolism, Light-Harvesting Protein Complexes chemistry, Photons, Photosynthesis physiology, Quantum Theory, Spectrum Analysis methods, Bacterial Proteins metabolism, Bacterial Proteins physiology, Energy Transfer physiology, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes physiology

Abstract

During the first steps of photosynthesis, the energy of impinging solar photons is transformed into electronic excitation energy of the light-harvesting biomolecular complexes. The subsequent energy transfer to the reaction center is commonly rationalized in terms of excitons moving on a grid of biomolecular chromophores on typical timescales [Formula: see text]100 fs. Today's understanding of the energy transfer includes the fact that the excitons are delocalized over a few neighboring sites, but the role of quantum coherence is considered as irrelevant for the transfer dynamics because it typically decays within a few tens of femtoseconds. This orthodox picture of incoherent energy transfer between clusters of a few pigments sharing delocalized excitons has been challenged by ultrafast optical spectroscopy experiments with the Fenna-Matthews-Olson protein, in which interference oscillatory signals up to 1.5 ps were reported and interpreted as direct evidence of exceptionally long-lived electronic quantum coherence. Here, we show that the optical 2D photon echo spectra of this complex at ambient temperature in aqueous solution do not provide evidence of any long-lived electronic quantum coherence, but confirm the orthodox view of rapidly decaying electronic quantum coherence on a timescale of 60 fs. Our results can be considered as generic and give no hint that electronic quantum coherence plays any biofunctional role in real photoactive biomolecular complexes. Because in this structurally well-defined protein the distances between bacteriochlorophylls are comparable to those of other light-harvesting complexes, we anticipate that this finding is general and directly applies to even larger photoactive biomolecular complexes., Competing Interests: Conflict of interest statement: H.-G.D., V.I.P., and M.T. have a common publication in the New Journal of Physics with Shaul Mukamel as coauthor in 2015 on two-dimensional spectroscopy of a simple dye molecule. M.T. has a common publication with Shaul Mukamel in The Journal of Chemical Physics in 2014 on excitation energy transfer in molecules with orthogonal dipoles.

Published

2017

7. Three classes of oxygen-dependent cyclase involved in chlorophyll and bacteriochlorophyll biosynthesis.

Author

Chen GE, Canniffe DP, and Hunter CN

Subjects

Bacteriochlorophylls chemistry, Chlorophyll chemistry, Chlorophyll metabolism, Photosynthesis physiology, Synechocystis genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacteriochlorophylls metabolism, Metalloproteins chemistry, Metalloproteins genetics, Metalloproteins metabolism, Oxygen metabolism, Synechocystis enzymology

Abstract

The biosynthesis of (bacterio)chlorophyll pigments is among the most productive biological pathways on Earth. Photosynthesis relies on these modified tetrapyrroles for the capture of solar radiation and its conversion to chemical energy. (Bacterio)chlorophylls have an isocyclic fifth ring, the formation of which has remained enigmatic for more than 60 y. This reaction is catalyzed by two unrelated cyclase enzymes using different chemistries. The majority of anoxygenic phototrophic bacteria use BchE, an O 2 -sensitive [4Fe-4S] cluster protein, whereas plants, cyanobacteria, and some phototrophic bacteria possess an O 2 -dependent enzyme, the major catalytic component of which is a diiron protein, AcsF. Plant and cyanobacterial mutants in ycf54 display impaired function of the O 2 -dependent enzyme, accumulating the reaction substrate. Swapping cyclases between cyanobacteria and purple phototrophic bacteria reveals three classes of the O 2 -dependent enzyme. AcsF from the purple betaproteobacterium Rubrivivax ( Rvi. ) gelatinosus rescues the loss not only of its cyanobacterial ortholog, cycI , in Synechocystis sp. PCC 6803, but also of ycf54 ; conversely, coexpression of cyanobacterial cycI and ycf54 is required to complement the loss of acsF in Rvi. gelatinosus These results indicate that Ycf54 is a cyclase subunit in oxygenic phototrophs, and that different classes of the enzyme exist based on their requirement for an additional subunit. AcsF is the cyclase in Rvi. gelatinosus , whereas alphaproteobacterial cyclases require a newly discovered protein that we term BciE, encoded by a gene conserved in these organisms. These data delineate three classes of O 2 -dependent cyclase in chlorophototrophic organisms from higher plants to bacteria, and their evolution is discussed herein., Competing Interests: The authors declare no conflict of interest.

Published

2017

8. Evidence for a cysteine-mediated mechanism of excitation energy regulation in a photosynthetic antenna complex.

Author

Orf GS, Saer RG, Niedzwiedzki DM, Zhang H, McIntosh CL, Schultz JW, Mirica LM, and Blankenship RE

Subjects

Aerobiosis, Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacteriochlorophylls metabolism, Carotenoids metabolism, Chlorobi genetics, Crystallography, X-Ray, Cysteine chemistry, Cysteine genetics, Electron Transport genetics, Energy Transfer, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes genetics, Models, Molecular, Mutagenesis, Protein Conformation, Sequence Homology, Amino Acid, Bacterial Proteins metabolism, Chlorobi metabolism, Cysteine metabolism, Light-Harvesting Protein Complexes metabolism, Photosynthesis

Abstract

Light-harvesting antenna complexes not only aid in the capture of solar energy for photosynthesis, but regulate the quantity of transferred energy as well. Light-harvesting regulation is important for protecting reaction center complexes from overexcitation, generation of reactive oxygen species, and metabolic overload. Usually, this regulation is controlled by the association of light-harvesting antennas with accessory quenchers such as carotenoids. One antenna complex, the Fenna-Matthews-Olson (FMO) antenna protein from green sulfur bacteria, completely lacks carotenoids and other known accessory quenchers. Nonetheless, the FMO protein is able to quench energy transfer in aerobic conditions effectively, indicating a previously unidentified type of regulatory mechanism. Through de novo sequencing MS, chemical modification, and mutagenesis, we have pinpointed the source of the quenching action to cysteine residues (Cys49 and Cys353) situated near two low-energy bacteriochlorophylls in the FMO protein from Chlorobaculum tepidum Removal of these cysteines (particularly removal of the completely conserved Cys353) through N-ethylmaleimide modification or mutagenesis to alanine abolishes the aerobic quenching effect. Electrochemical analysis and electron paramagnetic resonance spectra suggest that in aerobic conditions the cysteine thiols are converted to thiyl radicals which then are capable of quenching bacteriochlorophyll excited states through electron transfer photochemistry. This simple mechanism has implications for the design of bio-inspired light-harvesting antennas and the redesign of natural photosynthetic systems.

Published

2016

9. Photoprotection in a purple phototrophic bacterium mediated by oxygen-dependent alteration of carotenoid excited-state properties.

Author

Šlouf V, Chábera P, Olsen JD, Martin EC, Qian P, Hunter CN, and Polívka T

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Carotenoids chemistry, Cell Membrane metabolism, Energy Transfer radiation effects, Light, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes metabolism, Molecular Structure, Proteobacteria chemistry, Proteobacteria metabolism, Rhodobacter sphaeroides chemistry, Spectrophotometry, Carotenoids metabolism, Oxygen metabolism, Rhodobacter sphaeroides metabolism

Abstract

Carotenoids are known to offer protection against the potentially damaging combination of light and oxygen encountered by purple phototrophic bacteria, but the efficiency of such protection depends on the type of carotenoid. Rhodobacter sphaeroides synthesizes spheroidene as the main carotenoid under anaerobic conditions whereas, in the presence of oxygen, the enzyme spheroidene monooxygenase catalyses the incorporation of a keto group forming spheroidenone. We performed ultrafast transient absorption spectroscopy on membranes containing reaction center-light-harvesting 1-PufX (RC-LH1-PufX) complexes and showed that when oxygen is present the incorporation of the keto group into spheroidene, forming spheroidenone, reconfigures the energy transfer pathway in the LH1, but not the LH2, antenna. The spheroidene/spheroidenone transition acts as a molecular switch that is suggested to twist spheroidenone into an s-trans configuration increasing its conjugation length and lowering the energy of the lowest triplet state so it can act as an effective quencher of singlet oxygen. The other consequence of converting carotenoids in RC-LH1-PufX complexes is that S(2)/S(1)/triplet pathways for spheroidene is replaced with a new pathway for spheroidenone involving an activated intramolecular charge-transfer (ICT) state. This strategy for RC-LH1-PufX-spheroidenone complexes maintains the light-harvesting cross-section of the antenna by opening an active, ultrafast S(1)/ICT channel for energy transfer to LH1 Bchls while optimizing the triplet energy for singlet oxygen quenching. We propose that spheroidene/spheroidenone switching represents a simple and effective photoprotective mechanism of likely importance for phototrophic bacteria that encounter light and oxygen.

Published

2012

10. Electron transfer in the Rhodobacter sphaeroides reaction center assembled with zinc bacteriochlorophyll.

Author

Lin S, Jaschke PR, Wang H, Paddock M, Tufts A, Allen JP, Rosell FI, Mauk AG, Woodbury NW, and Beatty JT

Subjects

Electrochemical Techniques, Electron Transport, Evolution, Molecular, Kinetics, Photochemical Processes, Photosynthetic Reaction Center Complex Proteins chemistry, Spectrophotometry, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides metabolism, Zinc chemistry, Zinc metabolism

Abstract

The cofactor composition and electron-transfer kinetics of the reaction center (RC) from a magnesium chelatase (bchD) mutant of Rhodobacter sphaeroides were characterized. In this RC, the special pair (P) and accessory (B) bacteriochlorophyll (BChl) -binding sites contain Zn-BChl rather than BChl a. Spectroscopic measurements reveal that Zn-BChl also occupies the H sites that are normally occupied by bacteriopheophytin in wild type, and at least 1 of these Zn-BChl molecules is involved in electron transfer in intact Zn-RCs with an efficiency of >95% of the wild-type RC. The absorption spectrum of this Zn-containing RC in the near-infrared region associated with P and B is shifted from 865 to 855 nm and from 802 to 794 nm respectively, compared with wild type. The bands of P and B in the visible region are centered at 600 nm, similar to those of wild type, whereas the H-cofactors have a band at 560 nm, which is a spectral signature of monomeric Zn-BChl in organic solvent. The Zn-BChl H-cofactor spectral differences compared with the P and B positions in the visible region are proposed to be due to a difference in the 5th ligand coordinating the Zn. We suggest that this coordination is a key feature of protein-cofactor interactions, which significantly contributes to the redox midpoint potential of H and the formation of the charge-separated state, and provides a unifying explanation for the properties of the primary acceptor in photosystems I (PS1) and II (PS2).

Published

2009

11. Structure of the light-harvesting bacteriochlorophyll c assembly in chlorosomes from Chlorobium limicola determined by solid-state NMR.

Author

Egawa A, Fujiwara T, Mizoguchi T, Kakitani Y, Koyama Y, and Akutsu H

Subjects

Chlorobium radiation effects, Diffusion, Dimerization, Models, Molecular, Protein Structure, Quaternary, Protein Structure, Tertiary, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Chlorobium chemistry, Chlorobium metabolism, Nuclear Magnetic Resonance, Biomolecular

Abstract

We have determined the atomic structure of the bacteriochlorophyll c (BChl c) assembly in a huge light-harvesting organelle, the chlorosome of green photosynthetic bacteria, by solid-state NMR. Previous electron microscopic and spectroscopic studies indicated that chlorosomes have a cylindrical architecture with a diameter of approximately 10 nm consisting of layered BChl molecules. Assembly structures in huge noncrystalline chlorosomes have been proposed based mainly on structure-dependent chemical shifts and a few distances acquired by solid-state NMR, but those studies did not provide a definite structure. Our approach is based on (13)C dipolar spin-diffusion solid-state NMR of uniformly (13)C-labeled chlorosomes under magic-angle spinning. Approximately 90 intermolecular C C distances were obtained by simultaneous assignment of distance correlations and structure optimization preceded by polarization-transfer matrix analysis. It was determined from the approximately 90 intermolecular distances that BChl c molecules form piggyback-dimer-based parallel layers. This finding rules out the well known monomer-based structures. A molecular model of the cylinder in the chlorosome was built by using this structure. It provided insights into the mechanisms of efficient light harvesting and excitation transfer to the reaction centers. This work constitutes an important advance in the structure determination of huge intact systems that cannot be crystallized.

Published

2007

12. Three semidominant barley mutants with single amino acid substitutions in the smallest magnesium chelatase subunit form defective AAA+ hexamers.

Author

Hansson A, Willows RD, Roberts TH, and Hansson M

Subjects

Adenosine Triphosphate metabolism, Amino Acid Substitution, Bacteriochlorophylls chemistry, Bacteriochlorophylls genetics, Bacteriochlorophylls metabolism, Ca(2+) Mg(2+)-ATPase chemistry, Ca(2+) Mg(2+)-ATPase genetics, Ca(2+) Mg(2+)-ATPase metabolism, DNA, Plant genetics, Genes, Bacterial, Genes, Dominant, Genes, Plant, Hordeum metabolism, Hydrolysis, Lyases metabolism, Models, Molecular, Mutation, Protein Structure, Quaternary, Protein Subunits, Rhodobacter capsulatus genetics, Surface Plasmon Resonance, Hordeum enzymology, Hordeum genetics, Lyases chemistry, Lyases genetics

Abstract

Many enzymes of the bacteriochlorophyll and chlorophyll biosynthesis pathways have been conserved throughout evolution, but the molecular mechanisms of the key steps remain unclear. The magnesium chelatase reaction is one of these steps, and it requires the proteins BchI, BchD, and BchH to catalyze the insertion of Mg(2+) into protoporphyrin IX upon ATP hydrolysis. Structural analyses have shown that BchI forms hexamers and belongs to the ATPases associated with various cellular activities (AAA(+)) family of proteins. AAA(+) proteins are Mg(2+)-dependent ATPases that normally form oligomeric ring structures in the presence of ATP. By using ATPase-deficient BchI subunits, we demonstrate that binding of ATP is sufficient to form BchI oligomers. Further, ATPase-deficient BchI proteins can form mixed oligomers with WT BchI. The formation of BchI oligomers is not sufficient for magnesium chelatase activity when combined with BchD and BchH. Combining WT BchI with ATPase-deficient BchI in an assay disrupts the chelatase reaction, but the presence of deficient BchI does not inhibit ATPase activity of the WT BchI. Thus, the ATPase of every WT segment of the hexamer is autonomous, but all segments of the hexamer must be capable of ATP hydrolysis for magnesium chelatase activity. We suggest that ATP hydrolysis of each BchI within the hexamer causes a conformational change of the hexamer as a whole. However, hexamers containing ATPase-deficient BchI are unable to perform this ATP-dependent conformational change, and the magnesium chelatase reaction is stalled in an early stage.

Published

2002

13. An alternative carotenoid-to-bacteriochlorophyll energy transfer pathway in photosynthetic light harvesting.

Author

Papagiannakis E, Kennis JT, van Stokkum IH, Cogdell RJ, and van Grondelle R

Subjects

Kinetics, Lasers, Light, Photons, Rhodobacter sphaeroides metabolism, Rhodospirillum rubrum metabolism, Spectrophotometry, Time Factors, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Carotenoids chemistry, Carotenoids metabolism, Energy Transfer, Photosynthesis

Abstract

Blue and green sunlight become available for photosynthetic energy conversion through the light-harvesting (LH) function of carotenoids, which involves transfer of carotenoid singlet excited states to nearby (bacterio)chlorophylls (BChls). The excited-state manifold of carotenoids usually is described in terms of two singlet states, S(1) and S(2), of which only the latter can be populated from the ground state by the absorption of one photon. Both states are capable of energy transfer to (B)Chl. We recently showed that in the LH1 complex of the purple bacterium Rhodospirillum rubrum, which is rather inefficient in carotenoid-to-BChl energy transfer, a third additional carotenoid excited singlet state is formed. This state, which we termed S*, was found to be a precursor on an ultrafast fission reaction pathway to carotenoid triplet state formation. Here we present evidence that S* is formed with significant yield in the LH2 complex of Rhodobacter sphaeroides, which has a highly efficient carotenoid LH function. We demonstrate that S* is actively involved in the energy transfer process to BChl and thus have uncovered an alternative pathway of carotenoid-to-BChl energy transfer. In competition with energy transfer to BChl, fission occurs from S*, leading to ultrafast formation of carotenoid triplets. Analysis in terms of a kinetic model indicates that energy transfer through S* accounts for 10-15% of the total energy transfer to BChl, and that inclusion of this pathway is necessary to obtain a highly efficient LH function of carotenoids.

Published

2002

14. Anaerobic chlorophyll isocyclic ring formation in Rhodobacter capsulatus requires a cobalamin cofactor.

Author

Gough SP, Petersen BO, and Duus JO

Subjects

Amino Acid Sequence, Anaerobiosis, Chromatography, Thin Layer, Cobamides physiology, Iron physiology, Molecular Sequence Data, Mutation, Oxygenases, Porphyrins metabolism, Rhodobacter capsulatus genetics, Bacteriochlorophylls metabolism, Rhodobacter capsulatus metabolism, Vitamin B 12 physiology

Abstract

The isocyclic ring of bacteriochlorophyll (BChl) is formed by the conversion of Mg-protoporphyrin monomethyl ester (MPE) to protochlorophyllide (PChlide). Similarities revealed by blast searches with the putative anaerobic MPE-cyclase BchE suggested to us that this protein also uses a cobalamin cofactor. We found that vitamin B(12) (B(12))-requiring mutants of the bluE and bluB genes of Rhodobacter capsulatus, grown without B(12), accumulated Mg-porphyrins. Laser desorption/ionization time-of-flight (LDI-TOF) MS and NMR spectroscopy identified them as MPE and its 3-vinyl-8-ethyl (mvMPE) derivative. An in vivo assay was devised for the cyclase converting MPE to PChlide. Cyclase activity in the B(12)-dependent mutants required B(12) but not protein synthesis. The following reaction mechanism is proposed for this MPE-cyclase reaction. Adenosylcobalamin forms the adenosyl radical, which leads to withdrawal of a hydrogen atom and formation of the benzylic-type 13(1)-radical of MPE. Withdrawal of an electron gives the 13(1)-cation of MPE. Hydroxyl ion attack on the cation gives 13(1)-hydroxy-MPE. Withdrawal of three hydrogen atoms leads successively to 13(1)-keto-MPE, its 13(2)-radical, and cyclization to PChlide.

Published

2000

15. Multiple pathways for ultrafast transduction of light energy in the photosynthetic reaction center of Rhodobacter sphaeroides.

Author

van Brederode ME, van Mourik F, van Stokkum IH, Jones MR, and van Grondelle R

Subjects

Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Dimerization, Electron Transport, Kinetics, Light, Light-Harvesting Protein Complexes, Photosynthetic Reaction Center Complex Proteins radiation effects, Spectrophotometry, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins metabolism, Rhodobacter sphaeroides metabolism

Abstract

A pathway of electron transfer is described that operates in the wild-type reaction center (RC) of the photosynthetic bacterium Rhodobacter sphaeroides. The pathway does not involve the excited state of the special pair dimer of bacteriochlorophylls (P*), but instead is driven by the excited state of the monomeric bacteriochlorophyll (BA*) present in the active branch of pigments along which electron transfer occurs. Pump-probe experiments were performed at 77 K on membrane-bound RCs by using different excitation wavelengths, to investigate the formation of the charge separated state P+HA-. In experiments in which P or BA was selectively excited at 880 nm or 796 nm, respectively, the formation of P+HA- was associated with similar time constants of 1.5 ps and 1. 7 ps. However, the spectral changes associated with the two time constants are very different. Global analysis of the transient spectra shows that a mixture of P+BA- and P* is formed in parallel from BA* on a subpicosecond time scale. In contrast, excitation of the inactive branch monomeric bacteriochlorophyll (BB) and the high exciton component of P (P+) resulted in electron transfer only after relaxation to P*. The multiple pathways for primary electron transfer in the bacterial RC are discussed with regard to the mechanism of charge separation in the RC of photosystem II from higher plants.

Published

1999

16. Long-time quantum simulation of the primary charge separation in bacterial photosynthesis.

Author

Makri N, Sim E, Makarov DE, and Topaler M

Subjects

Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Computer Simulation, Kinetics, Light-Harvesting Protein Complexes, Mathematics, Models, Theoretical, Pheophytins metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Quantum Theory, Rhodobacter sphaeroides metabolism, Thermodynamics, Time Factors, Models, Molecular, Pheophytins chemistry, Photosynthesis, Photosynthetic Reaction Center Complex Proteins chemistry

Abstract

Accurate quantum mechanical simulations of the primary charge transfer in photosynthetic reaction centers are reported. The process is modeled by three coupled electronic states corresponding to the photoexcited chlorophyll special pair (donor), the reduced bacteriopheophytin (acceptor), and the reduced accessory chlorophyll (bridge) that interact with a dissipative medium of protein and solvent degrees of freedom. The time evolution of the excited special pair is followed over 17 ps by using a fully quantum mechanical path integral scheme. We find that a free energy of the reduced accessory chlorophyll state approximately equal to 400 cm(-1) lower than that of the excited special pair state yields state populations in agreement with experimental results on wild-type and modified reaction centers. For this energetic configuration electron transfer is a two-step process.

Published

1996

17. Primary electron transfer kinetics in bacterial reaction centers with modified bacteriochlorophylls at the monomeric sites BA,B.

Author

Finkele U, Lauterwasser C, Struck A, Scheer H, and Zinth W

Subjects

Bacteriochlorophylls metabolism, Binding Sites, Electron Transport, Kinetics, Oxidation-Reduction, Photosynthesis, Rhodobacter sphaeroides, Spectrum Analysis, Structure-Activity Relationship, Bacteriochlorophylls chemistry

Abstract

The primary electron transfer has been investigated by femtosecond time-resolved absorption spectroscopy in two chemically modified reaction centers (RC) of Rhodobacter sphaeroides, in which the monomeric bacteriochlorophylls BA and BB have both been exchanged by 13(2)-hydroxybacteriochlorophyll a or [3-vinyl]-13(2)-hydroxybacteriochlorophyll a. The kinetics of the primary electron transfer are not influenced by the 13(2)-hydroxy modification. In RCs containing [3-vinyl]-13(2)-hydroxybacteriochlorophyll a the primary rate is reduced by a factor of 10.

Published

1992

18. Femtosecond dynamics of energy transfer in B800-850 light-harvesting complexes of Rhodobacter sphaeroides.

Author

Trautman JK, Shreve AP, Violette CA, Frank HA, Owens TG, and Albrecht AC

Subjects

Bacteriochlorophylls metabolism, Carotenoids metabolism, Energy Transfer, Kinetics, Lasers, Light, Light-Harvesting Protein Complexes, Photosynthetic Reaction Center Complex Proteins, Spectrophotometry, Time Factors, Chlorophyll metabolism, Plant Proteins metabolism, Rhodobacter sphaeroides metabolism

Abstract

We report femtosecond transient absorption studies of energy transfer dynamics in the B800-850 light-harvesting complex (LHC) of Rhodobacter sphaeroides 2.4.1. For complexes solubilized in lauryldimethylamine-N-oxide (LDAO), the carotenoid to bacteriochlorophyll (Bchl) B800 and carotenoid to Bchl B850 energy transfer times are 0.34 and 0.20 ps, respectively. The B800 to B850 energy transfer time is 2.5 ps. For complexes treated with lithium dodecyl sulfate (LDS), a carotenoid to B850 energy transfer time of less than or equal to 0.2 ps is seen, and a portion of the total carotenoid population is decoupled from Bchl. In both LDAO-solubilized and LDS-treated complexes an intensity-dependent picosecond decay component of the excited B850 population is ascribed to excitation annihilation within minimal units of the LHC.

Published

1990

19. Biosynthesis of vitamin B12: mode of incorporation of factor III into cobyrinic acid.

Author

Nussbaumer C, Imfeld M, Wörner G, Müller G, and Arigoni D

Subjects

Bacteriochlorophylls metabolism, Chemical Phenomena, Chemistry, Propionibacterium metabolism, Vitamin B 12 analogs & derivatives, Vitamin B 12 biosynthesis

Abstract

Extensive chemical degradation of cobyrinic acid biosynthesized from a sample of factor III radiochemically labeled in its three methyl groups demonstrates that label is retained exclusively in the two methyl groups at positions C-2 and C-7 and confirms that the C-20 methyl group of the precursor is lost during formation of the corrin ring system.

Published

1981

20. Primary charge separation in bacterial photosynthesis: oxidized chlorophylls and reduced pheophytin.

Author

Fajer J, Brune DC, Davis MS, Forman A, and Spaulding LD

Subjects

Computers, Electron Spin Resonance Spectroscopy, Molecular Conformation, Oxidation-Reduction, Potentiometry, Spectrophotometry, Spectrophotometry, Ultraviolet, Bacteriochlorophylls metabolism, Chlorophyll analogs & derivatives, Pheophytins metabolism, Photosynthesis

Abstract

Bacteriopheophytin, the magnesium-free base of bacteriochlorophyll, undergoes reversible one-electron reduction in organic solvents to yield an anionic free radical with characteristic optical and electron spin resonance spectra. The reduction potential of bacteriopheophytin, E1/2 approximately --0.55 V against a normal hydrogen electrode, compared to E1/2 approximately --0.85 V for bacteriochlorophyll, renders it a likely electron acceptor in the primary charge separation of photosynthesis. Comparison of these data with picosecond optical changes recently observed upon pulsed laser excitation of bacterial reaction centers leads us to propose that bacteriopheophytin is indeed a transient electron acceptor and that the primary charge separation of bacterial photosynthesis occurs between the bacteriochlorophyll complex P870 and bacteriopheophytin to yield the radicals of the oxidized chlorophyll dimer cation and reduced pheophytin anion.

Published

1975

21. Biosynthesis of vitamin B12: identity of fragment extruded during ring contraction to the corrin macrocycle.

Author

Battersby AR, Bushell MJ, Jones C, Lewis NG, and Pfenninger A

Subjects

Acetates biosynthesis, Bacteriochlorophylls metabolism, Cell-Free System, Chemical Phenomena, Chemistry, Corrinoids, Propionibacterium metabolism, Vitamin B 12 metabolism, Vitamin B 12 biosynthesis

Abstract

Incorporation experiments with labeled sirohydrochlorin and trimethylisobacteriochlorin demonstrate that ring contraction in vivo to the corrin macrocycle of vitamin B12 liberates acetic acid. The C-20 atom of the precursors becomes the acetate carboxyl carbon.

Published

1981