The golden age of biochemical research in photosynthesis

The perspectives and enthusiasms recorded in this review describe the events I witnessed and, in small ways, contributed to. Two great rewards emerged from my experiences – the pleasure of doing experiments and the great wealth of friendships with students and colleagues. As a graduate student, phenomena appeared at the bench before me which clarified the coupling of electron transport to ATP synthesis. My first PhD graduate student measured concentrations of pyridine nucleotides in chloroplasts and his results have been often confirmed and well used. All of the many graduate students who followed contributed to our understanding of photosynthesis. I have taken much pleasure from documenting the details of photosynthetic phosphorylation and electron transport in cyanobacteria. Studies of the `c' type cytochromes in these organisms continue to fascinate me. My experiences in government in its efforts to promote research are unusual, perhaps unique. A rare event outside the laboratory – a natural bloom of cyanobacteria – stimulated new thoughts and special opportunities for laboratory science. Photosynthesis seems magisterial in its shaping of our planet and its biology and in the details of its cleverness that were revealed in the time of my witness. This revised version was published online in June 2006 with corrections to the Cover Date.     

Roles of respiratory oxidases in protecting Escherichia coli K12 from oxidative stress

Isogenic strains of Escherichia coli that were defective in either of the two major aerobic terminal respiratory oxidases (cytochromes bo and bd) or in the putative third oxidase (cytochrome bd-II) were studied to elucidate role(s) for oxidases in protecting cells from oxidative stress in the form of H₂O₂ and paraquat. Exponential phase cultures of all three oxidase mutants exhibited a greater decline in cell viability when exposed to H₂O₂ stress compared to the isogenic parent wild-type strain. Cytochrome bo mutants showed the greatest sensitivity to H₂O₂ under all conditions studied indicating that this oxidase was crucial for protection from H₂O₂ in E. coli. Cell killing of all oxidase mutants by H₂O₂ was by an uncharacterized mechanism (mode 2 killing) with cell growth rate affected. The expression of (katG-lacZ), an indicator of intracellular H₂O₂, was 2-fold higher in a cydAB::kan mutant compared to the wild-type strain at low H₂O₂ concentrations (< 100 M) suggesting that cytochrome bd mutants were experiencing higher intracellular levels of H₂O₂. Protein fusions to the three oxidase genes demonstrated that expression of genes encoding cytochrome bd, but not cytochrome bo or cytochrome bd-II was increased in the presence of external H₂O₂. This increase in expression of (cydA-lacZ) by H₂O₂ was further enhanced in a cyo::kan mutant. The level of cytochrome bd determined spectrally and (cydA-lacZ) expression was 5-fold and 2-fold higher respectively in an rpoS mutant compared to isogenic wild-type cells suggesting that RpoS was a negative regulator of cytochrome bd. Whether the effect of RpoS is direct or indirect remains to be determined.     

Identification of human liver cytochromes P450 by using MALDI-TOF mass spectrometry

Proteomic approaches have been used for detection and identification of cytochromes P450 forms from highly purified membrane preparations of human liver. These included the protein separation by 2D-and/or 1D-electrophoresis and molecular scanning of a SDS-PAGE gel fragment in a range 45–66 kDa (this area corresponds molecular weights of cytochromes P450). The analysis of protein content was statistically evaluated by means of an original 1D-ZOOMER software package which allowed to carry out the processing of mass spectra mixture instead of individual mass spectra used by standard techniques. In the range 45–66 kDa we identified 13 microsomal membrane proteins including such cytochrome P450 forms as CYPs 1A2, 1B1, 2A6, 2E1, 2C8, 2C9, 2C10, 2D6, 3A4, 4A11, 4F2. Study of enzymatic activities of human liver microsomal cytochrome P450 isoforms CYP 1A, 2B, 3A, and 2E revealed the decrease in the rates of O-dealkylation and N-demethylation catalyzed by CYP 450 1A1/1A2 and 3A4 under pathological conditions, whereas 7-benzyloxyresorufin-O-debenzylase activity (which characterizes the total activity of CYP 2B and CYP 2C), the activities of CYP 2E1 (methanol oxidation), 7-pentoxyresorufin-O-dealkylation (CYP 2B), 7-ethoxy-and 7-methoxycoumarin-O-dealkylases (CYP 2B1) remained basically unchanged.     

烷烃对P450酶的诱导及二元酸发酵工艺改进

α、ω 长链二元酸 (Ｌｏｎｇ ｃｈａｉｎα ,ω ｄｉｃａｒｂｏｘｙｌｉｃａｃｉｄ ,ＤＣＡ)是一种重要的化工原料 ,是合成工程塑料、香料、耐寒性增塑剂、涂料、液晶等物质的重要原料。目前主要利用热带假丝酵母 (Ｃａｎｄｉｄａｔｒｏｐｌｉｃａｌｉｓ)转化烷烃生产[1,2 ] 。在以往发酵的过程中 ,通常在初始培养液中加入 5 %～10 %的烷烃。且有文献表明在发酵初期加入烷烃有利于产酸的提高。但我们的研究表明 ,在发酵初期加入烷烃也有其不利的一面 ,如高浓度的烷烃对于菌体的生长有一定的抑制作用。而且有实验表明 :适当提高细胞的培养液…     

Prediction of amino acid residues participated in substrate recognition by cytochrome P450 subfamilies with broad substrate specificity

Cytochromes P450 comprise a large superfamily and several of their isoforms play a crucial role in metabolism of xenobiotics, including drugs. Although these enzymes demonstrate broad and cross‐substrate specificity, different cytochrome P450 subfamilies exhibit certain selectivity for some types of substrates. Analysis of amino acid residues of the active sites of six cytochrome subfamilies (CYP1А, CYP2А, CYP2С, CYP2D, CYP2E and CYP3А) enables to define subfamily‐specific patterns that consist of four residues. These residues are located on the periphery of the active sites of these cytochromes. We suggest that they can form a primary binding site at the entrance to the active site, defining cytochrome substrate recognition. Copyright © 2013 John Wiley & Sons, Ltd.     

Regulation of Metabolic and Electron Transport Pathways in the Freshwater Bacterium Beggiatoa leptomitiformis D-402

The biomass yield of freshwater filamentous sulfur bacteria of the genus Beggiatoa, when grown lithoheterotrophically or mixotrophically, has been shown to increase 2 to 2.5 times under microaerobic conditions (0.12 mg/l oxygen) as compared to aerobic conditions (9 mg/l oxygen). The activity of the glyoxylate cycle key enzymes have been found to increase two to three times under microaerobic conditions (at an O₂ concentration of 2 mg/l), and the activities of the sulfur metabolism enzymes increased three to five times (at an O₂ concentration of 0.1–0.5 mg/l). It has also been found that, under microaerobic conditions, thiosulfate was almost completely oxidized to sulfate by the bacteria, without accumulation of intermediate metabolites. At the same time, a 2- to 15-fold decrease in the activities of the tricarboxylic acid cycle enzymes involved in the reduction of NAD and FAD was observed. Reorganization of the respiratory chain after changes in aeration and type of nutrition was also observed. It has been found that, in cells grown heterotrophically, the terminal part of the respiratory chain contained an aa ₃-type oxidase, whereas, during mixotrophic, lithoheterotrophic, and autotrophic growth, aa ₃-type oxidase synthesis was inhibited, and the synthesis of a cbb ₃-type oxidase, which is induced under microaerobic conditions, was activated. The gene of the catalytic subunit CcoN of the cbb ₃-type oxidase was sequenced and proved to be highly homologous to the corresponding genes of other proteobacteria.__________Translated from Mikrobiologiya, Vol. 74, No. 4, 2005, pp. 452–459.Original Russian Text Copyright © 2005 by Muntyan, Grabovich, Patritskaya, Dubinina.     

Half reduction potentials and oxygen affinity of the cytochromes of Pseudomonas carboxydovorans

Abstract The midpoint redox potentials (E'₀) of the cytochromes of Pseudomonas carboxydovorans have been studied by means of coupled spectrum deconvolution and potentiometric analysis. Membranes of cells grown on different substrates (CO; H₂+ CO₂; or pyruvate) contained cytochromes with similar absorption peaks and redox potentials. The cytochromes of the CO-sensitive main electron pathway of the respiratory chain revealed redox potentials in the same range as mitochondrial cytochromes (cytochrome b -555, about −20 mV; cytochrome c and cytochrome a , about +220 mV). For the cytochromes of the CO-insensitive alternative electron pathway, which allows uninhibited growth and respiration in the presence of high concentrations of CO, redox potentials of approx. +50 mV (cytochrome b -558) and −11 to −215 mV (cytochrome b -561) were determined. Cytochrome [ib-561], earlier proposed as the alternative terminal oxidase o in this organism, was shown to possess the lowest half reduction potential of all the cytochromes present in the cells. Measurements of the apparent K _m value for oxygen revealed a low affinity of cytochrome a ( K _m/ 5 υ M O₂) and a very high affinity of the CO-insensitive oxidase ( K _m < 0.5 μ M O₂). The high affinity to oxygen might be responsible for the CO-insensitivity of this unusual cytochrome o .     

Glucosinolate biosynthetic genes in Brassica rapa

Glucosinolates (GS) are a group of amino acid-derived secondary metabolites found throughout the Cruciferae family. Glucosinolates and their degradation products play important roles in pathogen and insect interactions, as well as in human health. In order to elucidate the glucosinolate biosynthetic pathway in Brassica rapa, we conducted comparative genomic analyses of Arabidopsis thaliana and B. rapa on a genome-wide level. We identified 102 putative genes in B. rapa as the orthologs of 52 GS genes in A. thaliana. All but one gene was successfully mapped on 10 chromosomes. Most GS genes exist in more than one copy in B. rapa. A high co-linearity in the glucosinolate biosynthetic pathway between A. thaliana and B. rapa was also established. The homologous GS genes in B. rapa and A. thaliana share 59-91% nucleotide sequence identity and 93% of the GS genes exhibit synteny between B. rapa and A. thaliana. Moreover, the structure and arrangement of the B. rapa GS (BrGS) genes correspond with the known evolutionary divergence of B. rapa, and may help explain the profiles and accumulation of GS in B. rapa.     

Electron transfer reactions of high-potential cytochromes in the reaction centre of Chromatium tepidum

In the thermophilic purple bacterium C. tepidum, the reaction centre (RC) has a bound cytochrome, containing two high-potential hemes (E_m above +350 mV) and two low-potential hemes (E_m below +150 mV), which re-reduces the photooxidized primary donor, P⁺. We have studied the effects of ambient redox potential and of temperature on the kinetics of that reaction by kinetic flash absorption spectroscopy in chromatophores and isolated reaction centers. When both high-potential hemes are reduced prior to excitation by a short flash of light, the halftime increases slightly between 294 K (t_1/2 = 500 ns) and 217 K (t_1/2 = 1040 ns) indicating an activation energy of 5.0 kJ mol^–1. The fraction of P⁺ which decays by this fast reaction decreases rather steeply around 220 K from nearly 100% at 294 K to nearly 0% below 190 K where P⁺ decays slowly (t_1/2 2.5 ms), probably by return of an electron from the quinone acceptors. When the high-potential hemes are partially oxidized prior to the flash, an additional kinetic phase having a halftime of 30 µs at 294 K is observed. The fractions of RCs that give rise to the individual kinetic phases of P⁺ reduction have been monitored as a function of redox potential. The results can be interpreted in terms of two high-potential hemes which have similar midpoint potentials of +380 ±10 mV and a weak electrostatic interaction.     

The primary quinone acceptor and the membrane-bound c-type cytochromes of the halophilic purple nonsulfur bacterium Rhodospirillum salinarum: A spectroscopic and thermodynamic study

The mid-point potential (Em_7.0) of the primary quinone acceptor (Qa) and the biochemical features (Em_7.0 and apparent molecular mass, MM) of the membrane bound c-type cytochromes (cyt) involved in photosynthetic electron transfer of the halophilic phototrophic bacterium Rhodospirillum (Rs.) salinarum were determined. A tetrahemic RC bound cytochrome was found (MM of 39.8 kDa) with Em_7.0 of the hemes equal to +304, +98, +21, –134 (± 8) mV as determined by dark equilibrium redox titrations in the isolated purified form. The highest potential heme (Em_7.0 = +304 mV, band at 556 nm) was able to reduce the photo-oxidized reaction center (P⁺) in a sub-millisecond ( 20 s) time scale reaction, acting most likely as the direct electron donor to P⁺). The midpoint potential of the primary electron donor (Em_7.0 = + 455 mV) was found to be close to that reported for the primary donor of the non-halophilic Rhodospirillum species Rs. rubrum, whereas the quinone primary electron acceptor (Qa) was different showing the spectral features of a menaquinone molecule with Em_7.0 at –128 (± 5) mV. A membrane bound c-type heme with Em_7.0 of 259 (± 1) and MM of 40 kDa was also isolated and referred to an orthodox cytochrome c₁). The present data on the photosynthetic apparatus, along with the previous results on the respiratory system [Moschettini et al. (1997) Arch Microbiol 168: 302-309], suggest that Rs. salinarum is biochemically distinct from Rs. rubrum, the most representative specie of the genus.