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The photoreaction center from Rhodospirillum rubrum contains about 90% protein, 6% pigment, mere traces of lipids, and no cytochromes. It also contains at least 1 mol of ubiquinone and 1 iron atom per mol. Its three-component polypeptide chains were isolated by preparative electrophoresis, and their molar stoichiometry was established as 1:1:1. The amino acid composition of the photoreaction center from strain S1 and from its subunits is reported. The protein as a whole contains about 65% nonpolar residues, and the degree of hydrophobicity of its subunits is alpha less than beta less than gamma. The minimal molecular weight based on the extinction coefficient and on the amino acid content is 90 000. This corresponds to a half-cystine mole number of 6.
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PMID:Photoreaction center of photosynthetic bacteria. 1. Further chemical characterization of the photoreaction center from Rhodospirillum rubrum. 11 12

1. The membrane of Rhodospirillum rubrum chromatophores was disintegrated with mild detergents (cholate and deoxycholate) in order to study the spatial arrangement of the functional proteins in the photochemical apparatus and the electron transport system in the membrane. 2. The components solubilized from the membrane by a mixture of cholate and deoxycholate (C-DOC) were separated into four fractions by molecular-sieve chromatography in the presence of C-DOC; they were designated as F1, F2, F3, and F4 in the order of elution. The fractions were further purified by repeated molecular-sieve chromatography in the presence of C-DOC until each fraction was chromatographically homogeneous. 3. F1 appeared to be conjugated forms of F2. 4. The purified F2 was composed of a rigid complex having a weight of 7 X 10(5) daltons, containing approximately 10 different kinds of protein species with molecular weights of 3.8 X 10(4), 3.6 X 10(4), 3.5 X 10(4), 2.8 X 10(4), 2.7 X 10(4), 2.6 X 10(4), 1.3 X 10(4), 1.2 X 10(4), 1.1 X 10(4), and 1.0 X 10(4). The complex contained 33 bacteriochlorophylls, 4 iron atoms, and 90 phosphates, but no cytochrome, ubiquinone, or phospholipid. It showed the same reaction center activity as chromatophores, indicating that the complex was a unit of the photochemical apparatus (photoreaction unit). Each chromatophore of average size was estimated to possess about 24 photoreaction units. 5. The purified F3 showed an absorbance spectrum characteristic of reaction centers, and contained 3.4 bacteriochlorophylls, 2.0 bacteriopheophytins, and 1.9 acid-labile iron atoms, but no cytochrome or ubiquinone (C-DOC reaction center). It had a weight of 1.2 X 10(5) daltons, and the main components were 4 protein species with molecular weights of 2.8 X 10(4), 2.7 X 10(4), 2.6 X 10(4), and 1.0 X 10(4). 6. The purified F4 showed a molecular weight of about 11,000, and contained one mole of ubiquinone-10 per mole (ubiquinone-10 protein). 7. The reaction center activity of C-DOC reaction centers was stimulated by ubiquinone-10 protein. In addition, the reaction center oxidized reduced cytochrome c2 in the light, provided that ubiquinone-10 protein was present (photo-oxidase activity).
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PMID:Disintegration of Rhodospirillum rubrum chromatophore membrane into photoreaction units, reaction centers, and ubiquinone-10 protein with mixture of cholate and deoxycholate. 11 65

Some of the unusual molecular and catalytic properties of a high molecular weight dihydro-orotate dehydrogenase (DHOD) from Neurospora crassa have been determined. Comparison of the properties of this enzyme with the properties of the soluble biosynthetic enzyme of prokaryotes has revealed several important differences. The fungal enzyme is located in a mitochondrial membrane in a position consistent with linkage with the respiratory chain through ubiquinone (Miller, R. W.: Arch. Biochem, Biophys. 146, 256-270 (1971)). Release of the enzyme from the membrane results in a solubilized protein complex containing bound lipids and inactive hydrophobic proteins. Non-specific protein aggregation is minimized during purification by Triton-X-100 and phospholipase treatments. The catalytically active enzyme has an apparent molecular weight of 210 000. In contrast to soluble DHOD preparations the high molecular weight enzyme has no endogenous dihydro-orotate oxidase (EC 1.3.3.1) activity and is relatively insensitive to inactivation by sulfhydryl-reactive reagents in the presence of dihydro-orotate (DHO). The enzyme activity is highly sensitive to conditions causing oxidation of flavin mononucleotide (FMN). The activity cannot be restored by cysteine or other means. FMN is present in all purified preparations in a bound, non-fluorescent (reduced) form until dihydro-orotic acid is removed or oxidized. Catalytic efficiency of the purified enzyme was 12 000 mol DHO oxidized per minute per mole FMN. This high turnover rate is due in part to the small flavin content of the purified enzyme, equivalent to 1 mol FMN per 120 000 g of catalytically active protein. Iron was detected in the purified enzyme by atomic absorption spectroscopy but labile sulfide was absent. Thenoyltrifluoroacetone, an iron chelator, only partially inhibited DHO oxidation regardless of electron acceptor. Fatty acids interact with a hydrophobic site of the enzyme in non-competitive fashion but under certain conditions appear to significantly alter the Km for ubiquinone. Orotate, by comparison, is a purely competitive inhibitor. Both types of inhibitor may function to regulate the biosynthesis of orotate in vivo. Superoxide anion is not produced in significant quantities by the DHO-reduced enzyme unless both ubiquinone and a suitable single electron carrier such as phenazine methosulfate are present. DHOD has been proposed as a source of superoxide anion in mammalian mitochondria (Forman, H. J. & Kennedy, J. A.: J. Biol. Chem. 250, 4322-4326 (1975)).
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PMID:A high molecular weight dihydro-orotate dehydrogenase of Neurospora crassa. Purification and properties of the enzyme. 13 Jan 99

Dihydroorotate dehydrogenase (DHODase) has been purified 400-fold from the rodent malaria parasite Plasmodium berghei to apparent homogeneity by Triton X-100 solubilization followed by anion-exchange, Cibacron Blue F3GA-agarose affinity, and gel filtration chromatography. The purified enzyme has a molecular mass of 52 +/- 2 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and of 55 +/- 6 kDa by gel filtration chromatography, and it has a pI of 8.2. It is active in monomeric form, contains 2.022 mol of iron and 1.602 acid-labile sulfurs per mole of enzyme, and does not contain a flavin cofactor. The purified DHODase exhibits optimal activity at pH 8.0 in the presence of the ubiquinone coenzyme CoQ6, CoQ7, CoQ9, or CoQ10. The Km values for L-DHO and CoQ6 are 7.9 +/- 2.5 microM and 21.6 +/- 5.5 microM, respectively. The kcat values for both substrates are 11.44 min-1 and 11.70 min-1, respectively. The reaction product orotate and an orotate analogue, 5-fluoroorotate, are competitive inhibitors of the enzyme-catalyzed reaction with Ki values of 30.5 microM and 34.9 microM, respectively. The requirement of the long-chain ubiquinones for activity supports the hypothesis of the linkage of pyrimidine biosynthesis to the electron transport system and oxygen utilization in malaria by DHODase via ubiquinones [Gutteridge, W. E., Dave, D., & Richards, W. H. G. (1979) Biochim. Biophys. Acta 582, 390-401].
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PMID:Purification and characterization of dihydroorotate dehydrogenase from the rodent malaria parasite Plasmodium berghei. 184 78

NADH-ubiquinone (Q) reductase isolated from beef heart mitochondria exhibited, upon reduction by NADH, a prominent EPR signal at room temperature attributable to stable ubisemiquinone radical(s). The concentration of the ubisemiquinone radical reached as high as 40% of the total Q content in the reductase. The radical was virtually abolished by adding rotenone, whereas rotenone had no effect on the reduction of FMN by NADH. The radical showed an EPR signal of g = 2.0042 at approximately 9.5 GHz with no resolved hyperfine structure and had a line width of 6.8 Gauss at 23 degrees C. The Q-band EPR spectra at 35 GHz showed well resolved g-anisotropy and had a field separation between derivative extrema of 24 Gauss. These results substantiate the fact that this radical was bound to a protein; we call it ubiquinone protein-N (QP-N). The pH dependence of the EPR signals demonstrated that the species of the ubisemiquinone radical(s) consisted of not only an anionic form but also a neutral form. Only about half of the QP-N radical formed by NADH reduction was abolished by p-chloromercuric sulfonate. The microwave power saturation curve of the radical was biphasic; the first phase leveled off at about 5 milliwatts and then at about 20 milliwatts. These results suggested that the ubisemiquinone radical from QP-N was heterogenous, consisting of at least two populations of stable ubisemiquinone radical(s). It is suggested that two kinds of QP-N exist in NADH-Q reductase. Each mole of protein may bind two mol of Q.
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PMID:Evidence of an ubisemiquinone radical(s) from the NADH-ubiquinone reductase of the mitochondrial respiratory chain. 629 5

Reaction centers of Rhodobacter sphaeroides undergo a approximately 20 A3/mole volume contraction in < 50 ns after excitation. The rapid volume change is tentatively assigned to electrostriction. From its magnitude, we infer that the effective dielectric coefficient is 10-15 if the compressibility of the reaction center is similar to that of globular proteins. The volume contraction is not sensitive to replacement of the natural ubiquinone at the QA site by other quinones or to the occupancy of the QB site. The quenching caused by pressure on the reaction centers most likely occurs on a faster time scale than that of electron transfer.
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PMID:Volume contraction on photoexcitation of the reaction center from Rhodobacter sphaeroides R-26: internal probe of dielectrics. 771 Dec 51

Chronocoulometry was used to characterize the fluidity and lateral diffusion coefficient of supported phospholipid bilayer assemblies. The bilayers were formed on the inner surfaces of the microporous template films of aluminum oxide on gold electrodes. The lipid monolayers were formed by adsorption and fusion of phospholipid vesicles on alkylated oxide surfaces. Octadecyltrichlorosilane (OTS) was used in the initial alkylation step. The surface concentration of the lipids in monolayer assemblies was measured by a radioactive assay method. Surface densities corresponding to 48 +/- 10 A2/molecule (DPPC) and 56 +/- 11 A2/molecule (DMPC) were obtained (for exposure times > 120 min) independent of the temperature of the vesicle's fusion (below or above chain-melting transition). Octadecylviologen (C18MV2+) was used as an electroactive probe species. Its limiting lateral diffusion coefficient in DMPC monolayers was 5 x 10(-8) cm2/s, measured as C18MV2+ mole fraction extrapolated to 0 decreasing linearly from 20 to below 1 mol%. Linear Arrhenius plots for C18MV2+ diffusion in DMPC monolayers were obtained with slopes of approximately 40 kJ/mol between 18 and 45 degrees C, demonstrating homogeneity and fluidity of the lipid monolayers. Chronocoulometry was also used to obtain lateral diffusion coefficient of ubiquinone in DMPC/OTS bilayers. A value of 1.9 x 10(-8) cm2/s at 30 degrees C was obtained.
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PMID:Electrochemical measurements of the lateral diffusion of electroactive amphiphiles in supported phospholipid monolayers. 801 7

Physiological mole fractions of long isoprenic chain ubiquinone (UQ[10]) and plastoquinone (PQ9) were incorporated inside a supported bilayer by vesicle fusion. The template of the bilayer was an especially designed microporous electrode that allows the direct electrochemistry of water insoluble molecules in a water environment. The artificial structure, made by self-assembly procedures, consisted of a bilayer laterally in contact with a built-in gold electrode at which direct electron transfers between the redox heads of the quinones molecules and the electrode can proceed. The mass balances of quinone and lipid in the structure were determined by radiolabeling and spectrophotometry. A dimyristoyl phosphatdylcholine stable surface concentration of 250 +/- 50 pmol x cm(-2), unaffected by the presence of the quinone, was measured in the fluid monolayer. The mole fraction of quinone was between 1 and 3 mol%, remaining unchanged when going from the vesicles to the supported layers. The lipid molecules and the quinone pool were both laterally mobile, and cyclic voltammetry was used to investigate the redox properties of UQ10 and PQ9 over a wide pH range. Below pH 12, the two electrons-two protons electrochemical process at the gold electrode appeared under kinetic control. Thus all thermodynamic deductions must be anchored in the observed reversibility of the quinone/hydroquinol anion transformation at pH > 13. Within the experimental uncertainty, the standard potentials and the pK(a)'s of the pertinent redox forms of UQ10 and PQ9 were found to be essentially identical. This differs slightly from the literature in which the constants were deduced from the studies of model quinones in mixed solvents or of isoprenic quinones without a lipidic environment.
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PMID:An electrochemical approach of the redox behavior of water insoluble ubiquinones or plastoquinones incorporated in supported phospholipid layers. 916 43

Stable aqueous dispersions of ubiquinone-10 (UQ) were obtained by cosonication with dipalmitoylphosphatidylcholine (DPPC) in the UQ mole fraction range 0.1-0.7. To clarify the dispersal mechanism, the dispersed particles were characterized, and the interaction between UQ and DPPC was investigated using several physicochemical techniques. Dynamic light scattering (DLS) measurements showed that the diameter of the dispersed particles was 50-70 nm. A limited amount of UQ was incorporated into DPPC bilayer membranes (approximately 5 mol%). The trapped aqueous volume inside the particles was determined fluorometrically using the aqueous space marker calcein, and the volume in the UQ/DPPC particles decreased remarkably with the addition of UQ into small unilamellar vesicles of DPPC. The decline in the fraction of vesicular particles was also confirmed by fluorescence quenching of N-dansylhexadecylamine in the DPPC membrane by the addition of the quencher CuSO4. These results indicate that the excess UQ separated from the DPPC bilayers is stabilized as emulsion particles by the DPPC surface monolayer.
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PMID:Interaction of ubiquinone-10 with dipalmitoylphosphatidylcholine and their formation of small dispersed particles. 1067 14

Proton and/or sodium electrochemical gradients are critical to energy handling at the plasma membranes of all living cells. Sodium gradients are used for animal plasma membranes, all other living organisms use proton gradients. These chemical and electrical gradients are either created by a cation pumping ATPase or are created by photons or redox, used to make ATP. It has been established that both hydrogen and sodium ions leak through lipid bilayers at approximately the same rate at the concentration they occur in living organisms. Although the gradients are achieved by pumping the cations out of the cell, the plasma membrane potential enhances the leakage rate of these cations into the cell because of the orientation of the potential. This review proposes that cells use certain lipids to inhibit cation leakage through the membrane bilayers. It assumes that Na(+) leaks through the bilayer by a defect mechanism. For Na(+) leakage in animal plasma membranes, the evidence suggests that cholesterol is a key inhibitor of Na(+) leakage. Here I put forth a novel mechanism for proton leakage through lipid bilayers. The mechanism assumes water forms protonated and deprotonated clusters in the lipid bilayer. The model suggests how two features of lipid structures may inhibit H(+) leakage. One feature is the fused ring structure of sterols, hopanoids and tetrahymenol which extrude water and therefore clusters from the bilayer. The second feature is lipid structures that crowd the center of the bilayer with hydrocarbon. This can be accomplished either by separating the two monolayers with hydrocarbons such as isoprenes or isopranes in the bilayer's cleavage plane or by branching the lipid chains in the center of the bilayers with hydrocarbon. The natural distribution of lipids that contain these features are examined. Data in the literature shows that plasma membranes exposed to extreme concentrations of cations are particularly rich in the lipids containing the predicted qualities. Prokaryote plasma membranes that reside in extreme acids (acidophiles) contain both hopanoids and iso/anteiso- terminal lipid branching. Plasma membranes that reside in extreme base (alkaliphiles) contain both squalene and iso/anteiso- lipids. The mole fraction of squalene in alkaliphile bilayers increases, as they are cultured at higher pH. In eukaryotes, cation leak inhibition is here attributed to sterols and certain isoprenes, dolichol for lysosomes and peroxysomes, ubiquinone for these in addition to mitochondrion, and plastoquinone for the chloroplast. Phytosterols differ from cholesterol because they contain methyl and ethyl branches on the side chain. The proposal provides a structure-function rationale for distinguishing the structures of the phytosterols as inhibitors of proton leaks from that of cholesterol which is proposed to inhibit leaks of Na(+). The most extensively studied of sterols, cholesterol, occurs only in animal cells where there is a sodium gradient across the plasma membrane. In mammals, nearly 100 proteins participate in cholesterol's biosynthetic and degradation pathway, its regulatory mechanisms and cell-delivery system. Although a fat, cholesterol yields no energy on degradation. Experiments have shown that it reduces Na(+) and K(+) leakage through lipid bilayers to approximately one third of bilayers that lack the sterol. If sterols significantly inhibit cation leakage through the lipids of the plasma membrane, then the general role of all sterols is to save metabolic ATP energy, which is the penalty for cation leaks into the cytosol. The regulation of cholesterol's appearance in the plasma membrane and the evolution of sterols is discussed in light of this proposed role.
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PMID:Do sterols reduce proton and sodium leaks through lipid bilayers? 1141 94

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