Your search keyword '"Beatty JT"' showing total 19 results

1. Introduction of the Menaquinone Biosynthetic Pathway into Rhodobacter sphaeroides and de Novo Synthesis of Menaquinone for Incorporation into Heterologously Expressed Integral Membrane Proteins.

Author

Jun D, Richardson-Sanchez T, Mahey A, Murphy MEP, Fernandez RC, and Beatty JT

Subjects

Chromatography, High Pressure Liquid, Electron Transport, Kinetics, Photobleaching, Photosynthetic Reaction Center Complex Proteins genetics, Plasmids genetics, Plasmids metabolism, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides genetics, Spectrometry, Mass, Electrospray Ionization, Ubiquinone analysis, Ubiquinone metabolism, Vitamin K 2 chemistry, Bacterial Proteins genetics, Membrane Proteins genetics, Metabolic Engineering methods, Rhodobacter sphaeroides metabolism, Vitamin K 2 metabolism

Abstract

Quinones are redox-active molecules that transport electrons and protons in organelles and cell membranes during respiration and photosynthesis. In addition to the fundamental importance of these processes in supporting life, there has been considerable interest in exploiting their mechanisms for diverse applications ranging from medical advances to innovative biotechnologies. Such applications include novel treatments to target pathogenic bacterial infections and fabricating biohybrid solar cells as an alternative renewable energy source. Ubiquinone (UQ) is the predominant charge-transfer mediator in both respiration and photosynthesis. Other quinones, such as menaquinone (MK), are additional or alternative redox mediators, for example in bacterial photosynthesis of species such as Thermochromatium tepidum and Chloroflexus aurantiacus . Rhodobacter sphaeroides has been used extensively to study electron transfer processes, and recently as a platform to produce integral membrane proteins from other species. To expand the diversity of redox mediators in R. sphaeroides , nine Escherichia coli genes encoding the synthesis of MK from chorismate and polyprenyl diphosphate were assembled into a synthetic operon in a newly designed expression plasmid. We show that the menFDHBCE, menI, menA , and ubiE genes are sufficient for MK synthesis when expressed in R. sphaeroides cells, on the basis of high performance liquid chromatography and mass spectrometry. The T. tepidum and C. aurantiacus photosynthetic reaction centers produced in R. sphaeroides were found to contain MK. We also measured in vitro charge recombination kinetics of the T. tepidum reaction center to demonstrate that the MK is redox-active and incorporated into the Q A pocket of this heterologously expressed reaction center.

Published

2020

2. Electron Transfer in Bacterial Reaction Centers with the Photoactive Bacteriopheophytin Replaced by a Bacteriochlorophyll through Coordinating Ligand Substitution.

Author

Pan J, Saer R, Lin S, Beatty JT, and Woodbury NW

Subjects

Kinetics, Ligands, Bacteriochlorophylls chemistry, Electron Transport, Pheophytins chemistry, Photosynthetic Reaction Center Complex Proteins chemistry

Abstract

The influence of amino acid substitutions at position M214 (M-subunit, residue 214) on the rate and pathway of electron transfer involving the bacteriopheophytin cofactor, HA, in a bacterial photosynthetic reaction center has been explored in a series of Rhodobacter sphaeroides mutants. The M214 leucine (L) residue of the wild type was replaced with histidine (H), glutamine (Q), and asparagine (N), creating the mutants M214LH, M214LQ, and M214LN, respectively. As has been reported previously for M214LH, each of these mutations resulted in a bacteriochlorophyll molecule in place of a bacteriopheophytin in the HA pocket, forming so-called β-type mutants (in which the HA cofactor is called βA). In addition, these mutations changed the properties of the surrounding protein environment in terms of charge distribution and the amino acid side chain volume. Electron transfer reactions from the excited primary donor P to the acceptor QA were characterized using ultrafast transient absorption spectroscopic techniques. Similar to that of the previously characterized M214LH (β mutant), the strong energetic mixing of the P(+)BA(-) and P(+)βA(-) states (the mixed anion is denoted I(-)) increased the rate of charge recombination between P(+) and I(-) in competition with the I(-) → QA forward reaction. This reduced the overall yield of charge separation forming the P(+)QA(-) state. While the kinetics of the primary electron transfer forming P(+)I(-) were essentially identical in all three β mutants, the rates of the βA(-) (I(-)) → QA electron transfer in M214LQ and M214LH were very similar but quite different from that of the M214LN mutant. The observed yield changes and the differences in kinetics are correlated more closely with the volume of the mutated amino acid than with their charge characteristics. These results are consistent with those of previous studies of a series of M214 mutants with different sizes of amino acid side chains that did not alter the HA cofactor composition [Pan, J., et al. (2013) J. Phys. Chem. B 117, 7179-7189]. Both studies indicate that protein relaxation in this region of the reaction center plays a key role in stabilizing charge-separated states involving the HA or βA cofactor. The effect is particularly pronounced for reactions occurring on time scales of tens and hundreds of picoseconds (forward transfer to the QA and charge recombination).

Published

2016

3. Mutation-Induced Changes in the Protein Environment and Site Energies in the (M)L214G Mutant of the Rhodobacter sphaeroides Bacterial Reaction Center.

Author

Jankowiak R, Rancova O, Chen J, Kell A, Saer RG, Beatty JT, and Abramavicius D

Subjects

Computer Simulation, Electrons, Ferricyanides chemistry, Models, Molecular, Mutagenesis, Site-Directed, Oxidation-Reduction, Pheophytins chemistry, Pheophytins metabolism, Photosynthetic Reaction Center Complex Proteins chemistry, Protons, Quantum Theory, Rhodobacter sphaeroides genetics, Spectrum Analysis, Temperature, Mutation, Photosynthetic Reaction Center Complex Proteins genetics, Photosynthetic Reaction Center Complex Proteins metabolism, Rhodobacter sphaeroides chemistry

Abstract

This work focuses on the low-temperature (5 K) photochemical (transient) hole-burned (HB) spectra within the P870 absorption band, and their theoretical analysis, for the (M)L214G mutant of the photosynthetic Rhodobacter sphaeroides bacterial reaction center (bRC). To provide insight into system-bath interactions of the bacteriochlorophyll a (BChl a) special pair, i.e., P870, in the mutated bRC, the optical line shape function for the P870 band is calculated numerically. On the basis of the modeling studies, we demonstrate that (M)L214G mutation leads to a heterogeneous population of bRCs with modified (increased) total electron-phonon coupling strength of the special pair BChl a and larger inhomogeneous broadening. Specifically, we show that after mutation in the (M)L214G bRC a large fraction (∼50%) of the bacteriopheophytin (HA) chromophores shifts red and the 800 nm absorption band broadens, while the remaining fraction of HA cofactors retains nearly the same site energy as HA in the wild-type bRC. Modeling using these two subpopulations allowed for fits of the absorption and nonresonant (transient) HB spectra of the mutant bRC in the charge neutral, oxidized, and charge-separated states using the Frenkel exciton Hamiltonian, providing new insight into the mutant's complex electronic structure. Although the average (M)L214G mutant quantum efficiency of P(+)QA(-) state formation seems to be altered in comparison with the wild-type bRC, the average electron transfer time (measured via resonant transient HB spectra within the P870 band) was not affected. Thus, mutation in the vicinity of the electron acceptor (HA) does not tune the charge separation dynamics. Finally, quenching of the (M)L214G mutant excited states by P(+) is addressed by persistent HB spectra burned within the B band in chemically oxidized samples.

Published

2016

4. Large photocurrent response and external quantum efficiency in biophotoelectrochemical cells incorporating reaction center plus light harvesting complexes.

Author

Yaghoubi H, Lafalce E, Jun D, Jiang X, Beatty JT, and Takshi A

Subjects

Bacterial Proteins radiation effects, Benzoquinones chemistry, Electricity, Electrodes, Immobilized Proteins radiation effects, Light-Harvesting Protein Complexes radiation effects, Rhodobacter sphaeroides enzymology, Sunlight, Bacterial Proteins chemistry, Bioelectric Energy Sources, Immobilized Proteins chemistry, Light-Harvesting Protein Complexes chemistry

Abstract

Bacterial photosynthetic reaction centers (RCs) are promising materials for solar energy harvesting, due to their high ratio of photogenerated electrons to absorbed photons and long recombination time of generated charges. In this work, photoactive electrodes were prepared from a bacterial RC-light-harvesting 1 (LH1) core complex, where the RC is encircled by the LH1 antenna, to increase light capture. A simple immobilization method was used to prepare RC-LH1 photoactive layer. Herein, we demonstrate that the combination of pretreatment of the RC-LH1 protein complexes with quinone and the immobilization method results in biophotoelectrochemical cells with a large peak transient photocurrent density and photocurrent response of 7.1 and 3.5 μA cm(-2), respectively. The current study with monochromatic excitation showed maximum external quantum efficiency (EQE) and photocurrent density of 0.21% and 2 μA cm(-2), respectively, with illumination power of ∼6 mW cm(-2) at ∼875 nm, under ambient conditions. This work provides new directions to higher performance biophotoelectrochemical cells as well as possibly other applications of this broadly functional photoactive material.

Published

2015

5. A DNA-directed light-harvesting/reaction center system.

Author

Dutta PK, Levenberg S, Loskutov A, Jun D, Saer R, Beatty JT, Lin S, Liu Y, Woodbury NW, and Yan H

Subjects

Coloring Agents chemistry, Coloring Agents metabolism, DNA chemistry, Energy Transfer, Models, Molecular, Nanostructures chemistry, Photosynthetic Reaction Center Complex Proteins chemistry, Rhodobacter sphaeroides chemistry, DNA metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Rhodobacter sphaeroides metabolism

Abstract

A structurally and compositionally well-defined and spectrally tunable artificial light-harvesting system has been constructed in which multiple organic dyes attached to a three-arm-DNA nanostructure serve as an antenna conjugated to a photosynthetic reaction center isolated from Rhodobacter sphaeroides 2.4.1. The light energy absorbed by the dye molecules is transferred to the reaction center, where charge separation takes place. The average number of DNA three-arm junctions per reaction center was tuned from 0.75 to 2.35. This DNA-templated multichromophore system serves as a modular light-harvesting antenna that is capable of being optimized for its spectral properties, energy transfer efficiency, and photostability, allowing one to adjust both the size and spectrum of the resulting structures. This may serve as a useful test bed for developing nanostructured photonic systems.

Published

2014

6. Reengineering the optical absorption cross-section of photosynthetic reaction centers.

Author

Dutta PK, Lin S, Loskutov A, Levenberg S, Jun D, Saer R, Beatty JT, Liu Y, Yan H, and Woodbury NW

Subjects

Absorption, Cytochromes c metabolism, Energy Transfer, Models, Molecular, Oxidation-Reduction, Photosynthetic Reaction Center Complex Proteins metabolism, Protein Conformation, Rhodobacter sphaeroides enzymology, Optical Phenomena, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins genetics, Protein Engineering methods

Abstract

Engineered cysteine residues near the primary electron donor (P) of the reaction center from the purple photosynthetic bacterium Rhodobacter sphaeroides were covalently conjugated to each of several dye molecules in order to explore the geometric design and spectral requirements for energy transfer between an artificial antenna system and the reaction center. An average of 2.5 fluorescent dye molecules were attached at specific locations near P. The enhanced absorbance cross-section afforded by conjugation of Alexa Fluor 660 dyes resulted in a 2.2-fold increase in the formation of reaction center charge-separated state upon intensity-limited excitation at 650 nm. The effective increase in absorbance cross-section resulting from the conjugation of two other dyes, Alexa Fluor 647 and Alexa Fluor 750, was also investigated. The key parameters that dictate the efficiency of dye-to-reaction center energy transfer and subsequent charge separation were examined using both steady-state and time-resolved fluorescence spectroscopy as well as transient absorbance spectroscopy techniques. An understanding of these parameters is an important first step toward developing more complex model light-harvesting systems integrated with reaction centers.

Published

2014

7. The protein environment of the bacteriopheophytin anion modulates charge separation and charge recombination in bacterial reaction centers.

Author

Pan J, Saer RG, Lin S, Guo Z, Beatty JT, and Woodbury NW

Subjects

Anions chemistry, Anions metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Electron Transport, Kinetics, Models, Molecular, Pheophytins chemistry, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides genetics, Bacterial Proteins metabolism, Pheophytins metabolism, Rhodobacter sphaeroides metabolism

Abstract

The kinetics and pathway of electron transfer has been explored in a series of reaction center mutants from Rhodobacter sphaeroides, in which the leucine residue at M214 near the bacteriopheophytin cofactor in the A-branch has been replaced with methionine, cysteine, alanine, and glycine. These amino acids have substantially different volumes, both from each other and, except for methionine, from the native leucine. Though the mutation site of M214 is close to the bacteriopheophytin cofactor, which is involved in the electron transfer, none of the mutations alter the cofactor composition of the reaction center and the primary charge separation reaction is essentially undisturbed. However, the kinetics of electron transfer from HA(-) → QA becomes both slower and substantially heterogeneous in three of the four mutants. The decreased HA(-) → QA electron transfer rate allows charge recombination between P(+) and HA(-) to compete with the forward reaction, resulting in a drop in the overall yield of charge separation. Both the yield change and the variation in kinetics correlate well with the volume of the mutant amino acid side chains. Analysis of the kinetics suggests that the introduction of a smaller side chain at M214 results in greater protein structural heterogeneity and dynamics on multiple time scales, resulting in perturbation of the electronic environment and its evolution in the vicinity of the early charge-separated radical pair, P(+)HA(-), and the subsequent acceptor QA, affecting both the extent and time scale of dielectric relaxation. It appears that the reaction center has been optimized not only in terms of its static structure-function relationships, but also finely tuned to favor particular reaction pathways on particular time scales by adjusting protein dynamics.

Published

2013

8. Role of Rhodobacter sphaeroides photosynthetic reaction center residue M214 in the composition, absorbance properties, and conformations of H(A) and B(A) cofactors.

Author

Saer RG, Hardjasa A, Rosell FI, Mauk AG, Murphy ME, and Beatty JT

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacteriochlorophylls metabolism, Crystallography, X-Ray, Models, Molecular, Mutagenesis, Site-Directed, Pheophytins metabolism, Photosynthetic Reaction Center Complex Proteins genetics, Photosynthetic Reaction Center Complex Proteins metabolism, Protein Conformation, Rhodobacter sphaeroides genetics, Rhodobacter sphaeroides growth & development, Rhodobacter sphaeroides metabolism, Bacterial Proteins chemistry, Bacteriochlorophylls analysis, Pheophytins analysis, Photosynthetic Reaction Center Complex Proteins chemistry, Rhodobacter sphaeroides chemistry

Abstract

In the native reaction center (RC) of Rhodobacter sphaeroides, the side chain of (M)L214 projects orthogonally toward the plane and into the center of the A branch bacteriopheophytin (BPhe) macrocycle. The possibility that this side chain is responsible for the dechelation of the central Mg(2+) of bacteriochlorophyll (BChl) was investigated by replacement of (M)214 with residues possessing small, nonpolar side chains that can neither coordinate nor block access to the central metal ion. The (M)L214 side chain was also replaced with Cys, Gln, and Asn to evaluate further the requirements for assembly of the RC with BChl in the HA pocket. Photoheterotrophic growth studies showed no difference in growth rates of the (M)214 nonpolar mutants at a low light intensity, but the growth of the amide-containing mutants was impaired. The absorbance spectra of purified RCs indicated that although absorbance changes are associated with the nonpolar mutations, the nonpolar mutant RC pigment compositions are the same as in the wild-type protein. Crystal structures of the (M)L214G, (M)L214A, and (M)L214N mutants were determined (determined to 2.2-2.85 Å resolution), confirming the presence of BPhe in the HA pocket and revealing alternative conformations of the phytyl tail of the accessory BChl in the BA site of these nonpolar mutants. Our results demonstrate that (i) BChl is converted to BPhe in a manner independent of the aliphatic side chain length of nonpolar residues replacing (M)214, (ii) BChl replaces BPhe if residue (M)214 has an amide-bearing side chain, (iii) (M)214 side chains containing sulfur are not sufficient to bind BChl in the HA pocket, and (iv) the (M)214 side chain influences the conformation of the phytyl tail of the BA BChl.

Published

2013

9. Electron transfer in Rhodobacter sphaeroides reaction centers containing Zn-bacteriochlorophylls: a hole-burning study.

Author

Neupane B, Jaschke P, Saer R, Beatty JT, Reppert M, and Jankowiak R

Subjects

Bacteriochlorophylls metabolism, Binding Sites, Electron Transport, Mutagenesis, Site-Directed, Photosynthetic Reaction Center Complex Proteins genetics, Photosynthetic Reaction Center Complex Proteins metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Spectrophotometry, Temperature, Photosynthetic Reaction Center Complex Proteins chemistry, Rhodobacter sphaeroides metabolism, Zinc chemistry

Abstract

Nonresonant and resonant transient, photochemical hole-burned (HB) spectra are presented for primary electron donor states of a novel bacterial reaction center (Zn-RC) of Rhodobacter sphaeroides, containing six Zn-bacteriochlorophylls (Zn-BChls). A "Zn-β-RC" in which the Zn-BChl in the bacteriopheophytin (BPhe)-binding site on the A side (H(A)) has the Zn penta-coordinated, was also studied. The fifth ligand comes from a histidine introduced by site-directed mutagenesis. Formation of the P(+)Q(A)(-) state was observed in both types of RC, although under identical experimental conditions a significantly deeper P(-) band (corresponding to the lower-energy, special pair, excitonic component) was revealed in the Zn-RC. Assuming a similar lifetime of the P(+)Q(A)(-) state, the quantum yield of P(+)Q(A)(-) formation decreased by ~60% in the Zn-β-RC (compared to the Zn-RC), as was seen in a comparison of analogous (Mg) BChl-containing wild type and β-RCs of Rb. sphaeroides [Kirmaier et al. Science1991, 251, 922]. However, the average (weakly frequency-dependent) low-temperature electron transfer (ET) rates of the Zn-RC and Zn-β-RC (measured from zero phonon holes in resonant transient HB spectra) were both ~1 ps and similar to a rate previously measured in the Rb. sphaeroides native RC [Johnson et al. J. Phys. Chem. 1989, 93, 5953]. Electron transfer rates observed in this work on the Zn-RC yielded a P870* decay rate in good agreement with recent room-temperature, time-domain data [Lin et al. Proc. Natl. Acad. Sci. 2009, 106, 8537]. A lack of correlation observed between the holes near 810 and 883 nm, accounting for electrochromically induced shifts of the Zn-BChl transitions in the B(A,B) and H(A,B) binding sites, produced by formation of the P(+)BHQ(A)(-) state, indicates that the 810 nm bleach does not correspond to the P(+) (upper excitonic component of the dimer) band and is mostly contributed to by a shift of the B(B) absorption band. ZPH-action spectra indicated inhomogeneous broadening (Γ(inh)) of ~110 cm(-1) (Zn-RC) and ~130 cm(-1) (Zn-β-RC). Experimentally determined Γ(inh) decreased the number of variables in theoretical fits of the absorption and frequency-dependent shapes of resonant HB spectra, leading to more reliable Huang-Rhys factors for both low-frequency phonons and a pseudolocalized phonon, ω(SP), often referred to as the special pair marker mode., (© 2012 American Chemical Society)

Published

2012

10. The photosystem of Rhodobacter sphaeroides assembles with zinc bacteriochlorophyll in a bchD (magnesium chelatase) mutant.

Author

Jaschke PR and Beatty JT

Subjects

Blotting, Western, Electrophoresis, Polyacrylamide Gel, Lyases genetics, Protein Binding, Spectrophotometry, Ultraviolet, Bacteriochlorophylls metabolism, Lyases metabolism, Multienzyme Complexes metabolism, Mutation, Rhodobacter sphaeroides metabolism

Abstract

A Rhodobacter sphaeroides bchD (magnesium chelatase) mutant was studied to determine the properties of its photosystem in the absence of bacteriochlorophyll (BChl). Western blots of reaction center H, M, and L (RC H/M/L) proteins from mutant membranes showed levels of 12% RC H, 32% RC L, and 46% RC M relative to those of the wild type. Tricine-SDS-PAGE revealed 52% light-harvesting complex alpha chain and 14% beta chain proteins compared to those of the wild type. Pigment analysis of bchD cells showed the absence of BChl and bacteriopheophytin (BPhe), but zinc bacteriochlorophyll (Zn-BChl) was discovered. Zn-BChl binds to light-harvesting 1 (LH1) and 2 (LH2) complexes in place of BChl in bchD membranes, with a LH2:LH1 ratio resembling that of wild-type cells under BChl-limiting conditions. Furthermore, the RC from the bchD mutant contained Zn-BChl in the special pair and accessory BChl binding sites, as well as carotenoid and quinone, but BPhe was absent. Comparison of the bchD mutant RC absorption spectrum to that of Acidiphilium rubrum, which contains Zn-BChl in the RC, suggests the RC protein environment at L168 contributes to A. rubrum special pair absorption characteristics rather than solely Zn-BChl. We speculate that Zn-BChl is synthesized via the normal BChl biosynthetic pathway, but with ferrochelatase supplying zinc protoporphyrin IX for enzymatic steps following the nonfunctional magnesium chelatase. The absence of BPhe in bchD cells is likely related to Zn2+ stability in the chlorin macrocycle and consequently high resistance of Zn-BChl to pheophytinization (dechelation). Possible agents prevented from dechelating Zn-BChl include the RC itself, a hypothetical dechelatase enzyme, and spontaneous processes.

Published

2007

11. Rhodopseudomonas palustris CGA009 has two functional ppsR genes, each of which encodes a repressor of photosynthesis gene expression.

Author

Braatsch S, Bernstein JR, Lessner F, Morgan J, Liao JC, Harwood CS, and Beatty JT

Subjects

Aerobiosis, Anaerobiosis, Base Sequence, Binding Sites, Molecular Sequence Data, Multigene Family genetics, Mutation genetics, RNA, Messenger genetics, Repressor Proteins chemistry, Rhodopseudomonas chemistry, Rhodopseudomonas classification, Sequence Alignment, Spectrum Analysis, Transcription, Genetic genetics, Gene Expression Regulation, Bacterial genetics, Photosynthesis, Repressor Proteins genetics, Repressor Proteins metabolism, Rhodopseudomonas genetics, Rhodopseudomonas metabolism

Abstract

The PpsR protein is a regulator of redox-dependent photosystem development in purple phototrophic bacteria. In contrast to most species, Rhodopseudomonas palustris contains two ppsR genes. We show that the inactivation of each of the R. palustris strain CGA009 ppsR genes results in an elevated level of formation of the photosystem under dark aerobic conditions. Absorption spectra of the two PpsR mutants revealed qualitative and quantitative differences in light-harvesting peak amplitude increases. A sequence difference in the helix-turn-helix DNA binding motif of PpsR2 (Arg 439 to Cys) between R. palustris strains CEA001 and CGA009 is shown to be a natural polymorphism that does not inactivate the repressor activity of the protein. To evaluate which photosynthesis genes are regulated by the two PpsR proteins, transcriptome profiles of the CGA009 and PpsR mutant strains were analyzed in microarray experiments. Transcription of most but not all photosystem genes was derepressed in the mutant strains to levels consistent with the in vivo absorption spectra, mathematical analyses of peak shapes and amplitudes, reaction center protein levels, and real-time PCR of selected mRNAs. Closely spaced PpsR binding motif repeats were identified 5' of genes that were derepressed in the transcriptome analysis of PpsR mutants. This work shows that both the PpsR1 and PpsR2 proteins from R. palustris strain CGA009 function as oxygen-responsive transcriptional repressors.

Published

2006

12. Determination and comparison of the baseline proteomes of the versatile microbe Rhodopseudomonas palustris under its major metabolic states.

Author

VerBerkmoes NC, Shah MB, Lankford PK, Pelletier DA, Strader MB, Tabb DL, McDonald WH, Barton JW, Hurst GB, Hauser L, Davison BH, Beatty JT, Harwood CS, Tabita FR, Hettich RL, and Larimer FW

Subjects

Aerobiosis physiology, Anaerobiosis physiology, Chromatography, Liquid, Light, Nitrogen Fixation, Spectrometry, Mass, Electrospray Ionization, Bacterial Proteins metabolism, Gene Expression Regulation, Bacterial, Proteome, Rhodopseudomonas metabolism

Abstract

Rhodopseudomonas palustris is a purple nonsulfur anoxygenic phototrophic bacterium that is ubiquitous in soil and water. R. palustris is metabolically versatile with respect to energy generation and carbon and nitrogen metabolism. We have characterized and compared the baseline proteome of a R. palustris wild-type strain grown under six metabolic conditions. The methodology for proteome analysis involved protein fractionation by centrifugation, subsequent digestion with trypsin, and analysis of peptides by liquid chromatography coupled with tandem mass spectrometry. Using these methods, we identified 1664 proteins out of 4836 predicted proteins with conservative filtering constraints. A total of 107 novel hypothetical proteins and 218 conserved hypothetical proteins were detected. Qualitative analyses revealed over 311 proteins exhibiting marked differences between conditions, many of these being hypothetical or conserved hypothetical proteins showing strong correlations with different metabolic modes. For example, five proteins encoded by genes from a novel operon appeared only after anaerobic growth with no evidence of these proteins in extracts of aerobically grown cells. Proteins known to be associated with specialized growth states such as nitrogen fixation, photoautotrophic, or growth on benzoate, were observed to be up-regulated under those states.

Published

2006

13. Mechanism of proton transfer inhibition by Cd(2+) binding to bacterial reaction centers: determination of the pK(A) of functionally important histidine residues.

Author

Paddock ML, Sagle L, Tehrani A, Beatty JT, Feher G, and Okamura MY

Subjects

Aspartic Acid chemistry, Aspartic Acid metabolism, Binding Sites, Cadmium chemistry, Electron Transport, Hydrogen-Ion Concentration, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Photosynthetic Reaction Center Complex Proteins genetics, Protein Binding, Protons, Quinones chemistry, Quinones metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Rhodobacter sphaeroides metabolism, Cadmium metabolism, Cadmium pharmacology, Histidine chemistry, Histidine metabolism, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins metabolism

Abstract

The bacterial photosynthetic reaction center (RC) uses light energy to catalyze the reduction of a bound quinone molecule Q(B) to quinol Q(B)H(2). In RCs from Rhodobacter sphaeroides the protons involved in this process come from the cytoplasm and travel through pathways that involve His-H126 and His-H128 located near the proton entry point. In this study, we measured the pH dependence from 4.5 to 8.5 of the binding of the proton transfer inhibitor Cd(2+), which ligates to these surface His in the RC and inhibits proton-coupled electron transfer. At pH <6, the negative slope of the logarithm of the dissociation constant, K(D), versus pH approaches 2, indicating that, upon binding of Cd(2+), two protons are displaced; i.e., the binding is electrostatically compensated. At pH >7, K(D) becomes essentially independent of pH. A theoretical fit to the data over the entire pH range required two protons with pK(A) values of 6.8 and 6.3 (+/-0.5). To assess the contribution of His-H126 and His-H128 to the observed pH dependence, K(D) was measured in mutant RCs that lack the imidazole group of His-H126 or His-H128 (His --> Ala). In both mutant RCs, K(D) was approximately pH independent, showing that Cd(2+) does not displace protons upon binding in the mutant RCs, in contrast to the native RC in which His-H126 and His-H128 are the predominant contributors to the observed pH dependence of K(D). Thus, Cd(2+) inhibits RC function by binding to functionally important histidines.

Published

2003

14. Effects of photosynthetic reaction center H protein domain mutations on photosynthetic properties and reaction center assembly in Rhodobacter sphaeroides.

Author

Tehrani A, Prince RC, and Beatty JT

Subjects

Amino Acid Sequence, Bacterial Proteins biosynthesis, Cell Membrane chemistry, DNA-Binding Proteins biosynthesis, Gene Expression Regulation, Bacterial, Molecular Sequence Data, Photolysis, Photosynthetic Reaction Center Complex Proteins biosynthesis, Plasmids, Protein Structure, Tertiary genetics, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides growth & development, Rhodopseudomonas chemistry, Rhodopseudomonas genetics, Sequence Homology, Amino Acid, Solubility, Spectrophotometry, Subcellular Fractions chemistry, Bacterial Proteins chemistry, Bacterial Proteins genetics, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, Mutagenesis, Site-Directed, Photosynthesis genetics, Photosynthetic Reaction Center Complex Proteins chemistry, Photosynthetic Reaction Center Complex Proteins genetics, Rhodobacter sphaeroides genetics

Abstract

Purple bacterial photosynthetic reaction center (RC) H proteins comprise three cellular domains: an 11 amino acid N-terminal sequence on the periplasmic side of the inner membrane; a single transmembrane alpha-helix; and a large C-terminal, globular cytoplasmic domain. We studied the roles of these domains in Rhodobacter sphaeroides RC function and assembly, using a mutagenesis approach that included domain swapping with Blastochloris viridis RC H segments and a periplasmic domain deletion. All mutations that affected photosynthesis reduced the amount of the RC complex. The RC H periplasmic domain is shown to be involved in the accumulation of the RC H protein in the cell membrane, while the transmembrane domain has an additional role in RC complex assembly, perhaps through interactions with RC M. The RC H cytoplasmic domain also functions in RC complex assembly. There is a correlation between the amounts of membrane-associated RC H and RC L, whereas RC M is found in the cell membrane independently of RC H and RC L. Furthermore, substantial amounts of RC M and RC L are found in the soluble fraction of cells only when RC H is present in the membrane. We suggest that RC M provides a nucleus for RC complex assembly, and that a RC H/M/L assemblage results in a cytoplasmic pool of soluble RC M and RC L proteins to provide precursors for maximal production of the RC complex.

Published

2003

15. Determination of proton transfer rates by chemical rescue: application to bacterial reaction centers.

Author

Paddock ML, Adelroth P, Feher G, Okamura MY, and Beatty JT

Subjects

Bicarbonates chemistry, Binding Sites genetics, Cacodylic Acid chemistry, Catalysis, Cations chemistry, Hydrogen-Ion Concentration, Kinetics, Models, Chemical, Mutagenesis, Site-Directed, Oxidation-Reduction, Photosynthetic Reaction Center Complex Proteins genetics, Potassium Chloride chemistry, Rhodobacter sphaeroides, Salts chemistry, Photosynthetic Reaction Center Complex Proteins chemistry, Protons

Abstract

The bacterial reaction center (RC) converts light into chemical energy through the reduction of an internal quinone molecule Q(B) to Q(B)H(2). In the native RC, proton transfer is coupled to electron transfer and is not rate-controlling. Consequently, proton transfer is not directly observable, and its rate was unknown. In this work, we present a method for making proton transfer rate-controlling, which enabled us to determine its rate. The imidazole groups of the His-H126 and His-H128 proton donors, located at the entrance of the transfer pathways, were removed by site-directed mutagenesis (His --> Ala). This resulted in a reduction in the observed proton-coupled electron transfer rate [(Q(A)(-)(*)Q(B))Glu(-) + H(+) --> (Q(A)Q(B)(-)(*))GluH], which became rate-controlled by proton uptake to Glu-L212 [Adelroth, P., et al. (2001) Biochemistry 40, 14538-14546]. The proton uptake rate was enhanced (rescued) in a controlled fashion by the addition of imidazole or other amine-containing acids. From the dependence of the observed rate on acid concentration, an apparent second-order rate constant k((2)) for the "rescue" of the rate was determined. k((2)) is a function of the proton transfer rate and the binding of the acid. The dependence of k((2)) on the acid pK(a) (i.e., the proton driving force) was measured over 9 pK(a) units, resulting in a Brönsted plot that was characteristic of general acid catalysis. The results were fitted to a model that includes the binding (facilitated by electrostatic attraction) of the cationic acid to the RC surface, proton transfer to an intermediate proton acceptor group, and subsequent proton transfer to Glu-L212. A proton transfer rate constant of approximately 10(5) s(-)(1) was determined for transfer from the bound imidazole group to Glu-L212 (over a distance of approximately 20 A). The same method was used to determine a proton transfer rate constant of 2 x 10(4) s(-)(1) for transfer to Q(B)(-)(*). The relatively fast proton transfer rates are explained by the presence of an intermediate acceptor group that breaks the process into sequential proton transfer steps over shorter distances. This study illustrates an approach that could be generally applied to obtain information about the individual rates and energies for proton transfer processes, as well as the pK(a)s of transfer components, in a variety of proton translocating systems.

Published

2002

16. Identification of the proton pathway in bacterial reaction centers: decrease of proton transfer rate by mutation of surface histidines at H126 and H128 and chemical rescue by imidazole identifies the initial proton donors.

Author

Adelroth P, Paddock ML, Tehrani A, Beatty JT, Feher G, and Okamura MY

Subjects

Alanine genetics, DNA Mutational Analysis, Electron Transport, Histidine genetics, Imidazoles, Models, Molecular, Photosynthetic Reaction Center Complex Proteins genetics, Protein Binding, Protons, Quinones metabolism, Alanine metabolism, Histidine metabolism, Photosynthetic Reaction Center Complex Proteins metabolism, Point Mutation, Rhodobacter sphaeroides metabolism

Abstract

The pathway for proton transfer to Q(B) was studied in the reaction center (RC) from Rhodobacter sphaeroides. The binding of Zn(2+) or Cd(2+) to the RC surface at His-H126, His-H128, and Asp-H124 inhibits the rate of proton transfer to Q(B), suggesting that the His may be important for proton transfer [Paddock, M. L., Graige, M. S., Feher, G. and Okamura, M. Y. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 6183-6188]. To assess directly the role of the histidines, mutant RCs were constructed in which either one or both His were replaced with Ala. In the single His mutant RCs, no significant effects were observed. In contrast, in the double mutant RC at pH 8.5, the observed rates of proton uptake associated with both the first and the second proton-coupled electron-transfer reactions k(AB)(()(1)()) [Q(A)(-)(*)Q(B)-Glu(-) + H(+) --> Q(A)(-)(*)Q(B)-GluH --> Q(A)Q(B)(-)(*)-GluH] and k(AB)(()(2)()) [Q(A)(-)(*)Q(B)(-)(*) + H(+) --> Q(A)(-)(*)(Q(B)H)(*) --> Q(A)(Q(B)H)(-)], were found to be slowed by factors of approximately 10 and approximately 4, respectively. Evidence that the observed changes in the double mutant RC are due to a reduction in the proton-transfer rate constants are provided by the observations: (i) k(AB)(1) at pH approximately pK(a) of GluH became biphasic, indicating that proton transfer is slower than electron transfer and (ii) k(AB)(2) became independent of the driving force for electron transfer, indicating that proton transfer is the rate-limiting step. These changes were overcome by the addition of exogenous imidazole which acts as a proton donor in place of the imidazole groups of His that were removed in the double mutant RC. Thus, we conclude that His-H126 and His-H128 facilitate proton transfer into the RC, acting as RC-bound proton donors at the entrance of the proton-transfer pathways.

Published

2001

17. Analysis of sulfur biochemistry of sulfur bacteria using X-ray absorption spectroscopy.

Author

Pickering IJ, George GN, Yu EY, Brune DC, Tuschak C, Overmann J, Beatty JT, and Prince RC

Subjects

Chlorobi growth & development, Chromatiaceae growth & development, Particle Size, Proteobacteria growth & development, Spectrometry, Fluorescence, Spectrum Analysis methods, X-Rays, Chlorobi chemistry, Chromatiaceae chemistry, Proteobacteria chemistry, Sulfur chemistry

Abstract

Many sulfide-oxidizing organisms, including the photosynthetic sulfur bacteria, store sulfur in "sulfur globules" that are readily detected microscopically. The chemical form of sulfur in these globules is currently the focus of a debate, because they have been described as "liquid" by some observers, although no known allotrope of sulfur is liquid at physiological temperatures. In the present work we have used sulfur K-edge X-ray absorption spectroscopy to identify and quantify the chemical forms of sulfur in a variety of bacterial cells, including photosynthetic sulfur bacteria. We have also taken advantage of X-ray fluorescence self-absorption to derive estimates of the size and density of the sulfur globules in photosynthetic bacteria. We find that the form of sulfur that most resembles the globule sulfur is simply solid S(8), rather than more exotic forms previously proposed.

Published

2001

18. Effect of metal binding on electrogenic proton transfer associated with reduction of the secondary electron acceptor (QB) in Rhodobacter sphaeroides chromatophores.

Author

Keller S, Beatty JT, Paddock M, Breton J, and Leibl W

Subjects

Alanine genetics, Bacterial Chromatophores genetics, Binding Sites genetics, Cadmium chemistry, Histidine genetics, Mutagenesis, Site-Directed, Nickel chemistry, Oxidation-Reduction, Photochemistry instrumentation, Photochemistry methods, Photolysis, Photosynthetic Reaction Center Complex Proteins genetics, Rhodobacter sphaeroides genetics, Zinc chemistry, Bacterial Chromatophores chemistry, Metals, Heavy chemistry, Photosynthetic Reaction Center Complex Proteins chemistry, Protons, Quinones chemistry, Rhodobacter sphaeroides chemistry

Abstract

The influence of metal ion (Cd(2+), Zn(2+), Ni(2+)) binding on the electrogenic phases of proton transfer connected with reduction of quinone Q(B) in chromatophores from Rhodobacter sphaeroides was studied by time-resolved electric potential changes. In the presence of metals, the electrogenic transients associated with proton transfer on first and second flash at pH 8 were found to be slower by factors of 3-6. This is essentially the same effect of metal binding that was observed on optical transients in isolated reaction centers (RC), where the metal ion was shown to inhibit proton transfer [Paddock, M. L., Graige, M. S., Feher, G., and Okamura, M. Y. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 6183-6188]. The effect of metal binding on the kinetics in chromatophores is, therefore, similarly attributed to inhibition of proton uptake, which becomes rate-limiting. A striking observation was an increase in the amplitude of the electrogenic proton-uptake phase after the first flash with bound metal ion. We attribute this to a loss of internal proton rearrangement, requiring that the protons that stabilize Q(B)(-) come from solution. In mutant RCs, in which His-H126 and His-H128 are replaced with Ala, the apparent binding of Cd(2+) and Ni(2+) was decreased, showing that the binding site of these metal ions is the same as found in RC crystals [Axelrod, H. L., Abresch, E. C., Paddock, M. L., Okamura, M. Y., and Feher, G. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 1542-1547]. Therefore, the unique proton entry point near His-H126, His-H128, and Asp-M17 that was identified in isolated RCs is also the entry point in chromatophores.

Published

2001

19. Isolation of the PufX protein from Rhodobacter capsulatus and Rhodobacter sphaeroides: evidence for its interaction with the alpha-polypeptide of the core light-harvesting complex.

Author

Recchia PA, Davis CM, Lilburn TG, Beatty JT, Parkes-Loach PS, Hunter CN, and Loach PA

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Circular Dichroism, Genes, Bacterial, Molecular Sequence Data, Sequence Homology, Amino Acid, Bacterial Proteins isolation & purification, Bacterial Proteins metabolism, Light-Harvesting Protein Complexes, Photosynthetic Reaction Center Complex Proteins metabolism, Rhodobacter capsulatus chemistry, Rhodobacter sphaeroides chemistry

Abstract

Using mutant strains of Rhodobacter capsulatus and Rhodobacter sphaeroides in which the pufX gene had been deleted, it was possible to identify by HPLC membrane protein components present in pufX+ cells but absent in pufX- cells. In parallel preparations, membrane proteins soluble in chloroform/methanol containing ammonium acetate were first extracted from lyophilized membrane fractions of the pufX+ cells and separated from pigments and larger protein material by gel-filtration chromatography. Protein-containing fractions were examined by HPLC, and several peaks were collected from pufX+ material that were not present in pufX- material. From N-terminal amino acid sequencing, the PufX protein of Rb. capsulatus was identified, and from positive interaction with a PufX protein antibody, the Rb. sphaeroides PufX protein was identified. Although overall yields were very small, sufficient quantities of these proteins were isolated to evaluate their effect on the reconstitution of the core light-havesting antenna (LH1) and its subunit complex. From the behavior of the PufX protein and the alpha-polypeptide of LH1 on HPLC, qualitative evidence was obtained that the two proteins have a high affinity for each other. In reconstitution assays with bacteriochlorophyll (Bchl) and the LH1 alpha- and beta-polypeptides of Rb. capsulatus, the PufX protein of Rb. capsulatus was inhibitory to LH1 formation at low concentration. A similar inhibition was exhibited by Rb. sphaeroides PufX protein for reconstitution of LH1 with Bchl and the LH1 alpha- and beta-polypeptides of Rb. sphaeroides. In both cases, the ratios of concentrations of the PufX protein to the alpha-polypeptide causing 50% inhibition were approximately 0.5. Formation of the heterologous (alpha beta) subunit-type complex formed with Bchl and the alpha- and beta-polypeptides of LH1 of Rb. capsulatus was also inhibited by low concentrations of the Rb. capsulatus PufX protein (approximately 50% inhibition at PufX:alpha-polypeptide ratios = 0.5). However, neither PufX protein inhibited formation of a homologous (beta beta) subunit-type complex, which indicates that the PufX proteins do not interact with the beta-polypeptides.

Published

1998