NADH-sensitive propionyl-CoA hydrolase in brown-adipose-tissue mitochondria of the rat

Acyl-CoA hydrolase activity was studied in brown adipose tissue (BAT) mitochondria of rats. The substrate specificity was investigated: total hydrolase activity showed two activity peaks, one sharp peak for propionyl-CoA and a broad peak at medium- to long-chain acyl-CoAs. The propionyl-CoA activity fully comigrated with a mitochondrial matrix marker enzyme in fractionation studies of tissue and mitochondria. The hydrolytic activity against short-chain acyl-CoAs was inhibited by NADH, and analyses of the substrate specificity of the hydrolases in the presence and absence of NADH allowed for the delineation of two distinct acyl-CoA hydrolases. These hydrolases could also be separated by gel filtration. It was concluded that rat BAT mitochondria possess at least two matrix acyl-CoA hydrolases: one broad-spectrum acyl-CoA hydrolase with an apparent native molecular weight of less than 100,000, and a specific propionyl-CoA hydrolase with an apparent native molecular weight at least 240,000; this hydrolase is regulated by NADH. It is suggested that the function of the propionyl-CoA hydrolase is to ensure that the level of propionyl-CoA in the mitochondria is not detrimentally increased.     

Chromophore distortions in the bacteriorhodopsin photocycle: evolution of the H-C14-C15-H dihedral angle measured by solid-state NMR.

In recent years, structural information about bacteriorhodopsin has grown substantially with the publication of several crystal structures. However, precise measurements of the chromophore conformation in the various photocycle states are still lacking. This information is critical because twists about the chromophore backbone chain can influence the Schiff base nitrogen position, orientation, and proton affinity. Here, we focus on the C14-C15 bond, using solid-state nuclear magnetic resonance spectroscopy to measure the H-C14-C15-H dihedral angle. In the resting state (bR(568)), we obtain an angle of 164 +/- 4 degrees, indicating a 16 degrees distortion from a planar all-trans chromophore. The dihedral angle is found to decrease to 147 +/- 10 degrees in the early M intermediate (M(o)) and to 150 +/- 4 degrees in the late M intermediate (M(n)). These results demonstrate changes in the chromophore conformation undetected by recent X-ray diffraction studies.     

The molecular and crystal structures of 4-N-(2-acetamido-2-deoxy-β-d-glucopyranosyl)-l-asparagine trihydrate and 4-N-(β-d-glucopyranosyl)-l-asparagine monohydrate. The X-ray analysis of a carbohydrate–peptide linkage

X-ray analyses have shown that the glucopyranose rings of GlcNAc-Asn [4-N-(2-acetamido-2-deoxy-beta-d-glucopyranosyl)-l-asparagine] and Glc-Asn [4-N-(beta-d-glucopyranosyl)-l-asparagine] both have the C-1 chair conformation and also that the glucose-asparagine linkage of each molecule is present in the beta-anomeric configuration. The dimensions (the estimated standard deviations of the last digit are in parentheses) of the glycosidic bond in GlcNAc-Asn and Glc-Asn are, respectively, C((1))-N((1)) 0.1441(6)nm, 0.146(2)nm; angle O((5))-C((1))-N((1)) 106.8(3) degrees , 105.7(8) degrees ; angle C((2))-C((1))-N((1)) 111.1(4) degrees , 110.4(9) degrees ; angle C((1))-N((1))-C((9)) 121.4(4) degrees , 120.5(9) degrees . The glycosidic torsion angle C((9))-N((1))-C((1))-C((2)) is 141.0 degrees and 157.6 degrees in GlcNAc-Asn and Glc-Asn respectively. Hydrogen-bonding is extensive in these two crystal structures and does affect one torsion angle in particular. Two very different values of chi(1)(N-C(alpha)-C(beta)-C(gamma)) occur for the asparagine residue of the two different molecules; the values of chi(1), -69.0 degrees in GlcNAc-Asn and 61.9 degrees in Glc-Asn, correspond to two different staggered conformations about the C(alpha)-C(beta) bond as the NH(3) (+) group is adjusted to different hydrogen-bonding patterns. The two trans-peptide groups in GlcNAc-Asn show small distortions in planarity whereas that in Glc-Asn is more non-planar. The mean plane through the atoms of the amide group at C((2)) in GlcNAc-Asn is approximately perpendicular (69 degrees ) to the mean plane through the C((2)), C((3)), C((5)) and O((5)) atoms of the glucose ring and that at C((1)) is less perpendicular (65 degrees ). The mean plane through the atoms of the amide group in Glc-Asn makes an angle of only 55 degrees with the mean plane through these same four atoms of the glucose ring. The N((1))-H bond of the amide at C((1)) is trans to the C((1))-H bond in these two compounds; the N((2))-H bond of the amide at C((2)) is trans to the C((2))-H bond in GlcNAc-Asn. The values of the observed and final calculated structure amplitudes have been deposited as Supplementary Publication SUP 50035 (26 pages) at the British Library (Lending Division), (formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7BQ, U.K., from whom copies may be obtained on the terms given in Biochem. J. (1973) 131, 5.     

Conformational spaces of Cinchona alkaloids

A systematic and comprehensive study of the conformational spaces of the Cinchona alkaloids quinine, quinidine, cinchonine, cinchonidine, epiquinine, epiquinidine, epicinchonine, and epicinchonidine using the semiempirical PM3 method is described. The results were analyzed in terms of syn/anti and open/closed/hindered and alpha/beta/gamma conformations. Special emphasis was given to the torsion angles T(1) (C(4a')-C(4')-C(9)-C(8)), T(2) (C(4')-C(9)-C(8)-N(1)) and T(3) (H-O(9)-C(9)-C(8)) that define the backbone and the hydroxy conformation, respectively. The results reveal the quasi-enantiomeric relationships between quinine and quinidine and between epiquinine and epiquinidine, and the main structural differences that exist between the therapeutically active Cinchona alkaloids, quinine and quinidine, and their inactive epimers, epiquinine and epiquinidine. The lowest energy conformation of quinine and quinidine is anti-closed-alpha. The lowest energy conformations of epiquinine and epiquinidine are anti-open-beta and anti-open-alpha, respectively. Low energy conformations with an intramolecular hydrogen bond (N(1.)H(.)O(9)) were found in epiquinine (the global minimum) and epiquinidine, but not in quinine and quinidine.     

Characterization of acetyl-CoA/propionyl-CoA carboxylase in Metallosphaera sedula. Carboxylating enzyme in the 3-hydroxypropionate cycle for autotrophic carbon fixation.

Autotrophic Archaea of the family Sulfolobaceae (Crenarchaeota) use a modified 3-hydroxypropionate cycle for carbon dioxide assimilation. In this cycle the ATP-dependent carboxylations of acetyl-CoA and propionyl-CoA to malonyl-CoA and methylmalonyl-CoA, respectively, represent the key CO2 fixation reactions. These reactions were studied in the thermophilic and acidophilic Metallosphaera sedula and are shown to be catalyzed by one single large enzyme, which acts equally well on acetyl-CoA and propionyl-CoA. The carboxylase was purified and characterized and the genes were cloned and sequenced. In contrast to the carboxylase of most other organisms, acetyl-CoA/propionyl-CoA carboxylase from M. sedula is active at 75 degrees C and is isolated as a stabile functional protein complex of 560 +/- 50 kDa. The enzyme consists of two large subunits of 57 kDa each representing biotin carboxylase (alpha) and carboxytransferase (gamma), respectively, and a small 18.6 kDa biotin carrier protein (beta). These subunits probably form an (alpha beta gamma)4 holoenzyme. It has a catalytic number of 28 s-1 at 65 degrees C and at the optimal pH of 7.5. The apparent Km values were 0.06 mm for acetyl-CoA, 0.07 mm for propionyl-CoA, 0.04 mm for ATP and 0.3 mm for bicarbonate. Acetyl-CoA/propionyl-CoA carboxylase is considered the main CO2 fixation enzyme of autotrophic members of Sulfolobaceae and the sequenced genomes of these Archaea contain the respective genes. Due to its stability the archaeal carboxylase may prove an ideal subject for further structural studies.     

Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple

Redox state is a term used widely in the research field of free radicals and oxidative stress. Unfortunately, it is used as a general term referring to relative changes that are not well defined or quantitated. In this review we provide a definition for the redox environment of biological fluids, cell organelles, cells, or tissue. We illustrate how the reduction potential of various redox couples can be estimated with the Nernst equation and show how pH and the concentrations of the species comprising different redox couples influence the reduction potential. We discuss how the redox state of the glutathione disulfide-glutathione couple (GSSG/2GSH) can serve as an important indicator of redox environment. There are many redox couples in a cell that work together to maintain the redox environment; the GSSG/2GSH couple is the most abundant redox couple in a cell. Changes of the half-cell reduction potential (E(hc)) of the GSSG/2GSH couple appear to correlate with the biological status of the cell: proliferation E(hc) approximately -240 mV; differentiation E(hc) approximately -200 mV; or apoptosis E(hc) approximately -170 mV. These estimates can be used to more fully understand the redox biochemistry that results from oxidative stress. These are the first steps toward a new quantitative biology, which hopefully will provide a rationale and understanding of the cellular mechanisms associated with cell growth and development, signaling, and reductive or oxidative stress.     

Spectroelectrochemical studies of the corrinoid/iron-sulfur protein involved in acetyl coenzyme A synthesis by Clostridium thermoaceticum

An 88-kDa corrinoid/iron-sulfur protein (C/Fe-SP) is the methyl carrier protein in the acetyl-CoA pathway of Clostridium thermoaceticum. In previous studies, it was found that this C/Fe-SP contains (5-methoxybenzimidazolyl)cobamide and a [4Fe-4S]2+/1+ center, both of which undergo redox cycling during catalysis, and that the benzimidazole base is uncoordinated to the cobalt (base off) in all three redox states, 3+, 2+, and 1+ [Ragsdale, S.W., Lindahl, P.A., & Münck, E. (1987) J. Biol. Chem. 262, 14289-14297]. In this paper, we have determined the midpoint reduction potentials for the metal centers in this C/Fe-SP by electron paramagnetic resonance and UV-visible spectroelectrochemical methods. The midpoint reduction potentials for the Co3+/2+ and the Co2+/1 couples of the corrinoid were found to be 300-350 and -504 mV (+/- 3 mV) in Tris-HCl at pH 7.6, respectively. We also removed the (5-methoxybenzimidazolyl)cobamide cofactor from the C/Fe-SP and determined that its Co3+/2+ reduction potential is 207 mV at pH 7.6. The midpoint potential for the [4Fe-4S]2+/1+ couple in the C/Fe-SP was determined to be -523 mV (+/- 5 mV). Removal of this cluster totally inactivates the protein; however, there is little effect of cluster removal on the midpoint potential of the Co2+/1+ couple. In addition, removal of the cobamide has an insignificant effect on the midpoint reduction potential of the [4Fe-4S] cluster. A 27-kDa corrinoid protein (CP) also was studied since it contains (5-methoxybenzimidazolyl)cobamide in the base-on form.(ABSTRACT TRUNCATED AT 250 WORDS)     

Assessing the reversibility of the anaplerotic reactions of the propionyl-CoA pathway in heart and liver

While a number of studies underline the importance of anaplerotic pathways for hepatic biosynthetic functions and cardiac contractile activity, much remains to be learned about the sites and regulation of anaplerosis in these tissues. As part of a study on the regulation of anaplerosis from propionyl-CoA precursors in rat livers and hearts, we investigated the degree of reversibility of the reactions of the propionyl-CoA pathway. Label was introduced into the pathway via NaH13CO3, [U-13C3]propionate, or [U-13C3]lactate + [U-13C3]pyruvate, under various concentrations of propionate. The mass isotopomer distributions of propionyl-CoA, methylmalonyl-CoA, and succinyl-CoA revealed that, in intact livers and hearts, (i) the propionyl-CoA carboxylase reaction is slightly reversible only at low propionyl-CoA flux, (ii) the methylmalonyl-CoA racemase reaction keeps the methylmalonyl-CoA enantiomers in isotopic equilibrium under all conditions tested, and (iii) the methylmalonyl-CoA mutase reaction is reversible, but its reversibility decreases as the flow of propionyl-CoA increases. The thermodynamic dis-equilibrium of the combined reactions of the propionyl-CoA pathway explains the effectiveness of anaplerosis from propionyl-CoA precursors such as heptanoate.     

Primary quinone (QA) binding site of bacterial photosynthetic reaction centers: mutations at residue M265 probed by FTIR spectroscopy

In the primary quinone (Q(A)) binding site of Rb. sphaeroides reaction centers (RCs), isoleucine M265 is in extensive van der Waals contact with the ubiquinone headgroup. Substitution of threonine or serine for this residue (mutants M265IT and M265IS), but not valine (mutant M265IV), lowers the redox midpoint potential of Q(A) by about 100 mV (Takahashi et al. (2001) Biochemistry 40, 1020-1028). The unexpectedly large effect of the polar substitutions is not due to reorientation of the methoxy groups as similar redox potential changes are seen for these mutants with either ubiquinone or anthraquinone as Q(A). Using FTIR spectroscopy to compare Q(A)(-)/Q(A) IR difference spectra for wild type and the M265 mutant RCs, we found changes in the polar mutants (M265IT and M265IS) in the quinone C[double bond]O and C[double bond]C stretching region (1600-1660 cm(-1)) and in the semiquinone anion band (1440-1490 cm(-1)), as well as in protein modes. Modeling the mutations into the X-ray structure of the wild-type RC indicates that the hydroxyl group of the mutant polar residues, Thr and Ser, is hydrogen bonded to the peptide C[double bond]O of Thr(M261). It is suggested that the mutational effect is exerted through the extended backbone region that includes Ala(M260), the hydrogen bonding partner to the C1 carbonyl of the quinone headgroup. The resulting structural perturbations are likely to include lengthening of the hydrogen bond between the quinone C1[double bond]O and the peptide NH of Ala(M260). Possible origins of the IR spectroscopic and redox potential effects are discussed.     

Structural and biochemical characterization of the C₃-C₄ intermediate Brassica gravinae and relatives, with particular reference to cellular distribution of Rubisco

On the basis of its CO(2) compensation concentration, Brassica gravinae Ten. has been reported to be a C(3)-C(4) intermediate. This study investigated the structural and biochemical features of photosynthetic metabolism in B. gravinae. The cellular distribution of ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) was also examined in B. gravinae, B. napus L. (C(3)), Raphanus sativus L. (C(3)), and Diplotaxis tenuifolia (L.) DC. (C(3)-C(4)) by immunogold electron microscopy to elucidate Rubisco expression during the evolution from C(3) to C(3)-C(4) intermediate plants. The bundle sheath (BS) cells of B. gravinae contained centrifugally located chloroplasts as well as centripetally located chloroplasts and mitochondria. Glycine decarboxylase P-protein was localized in the BS mitochondria. Brassica gravinae had low C(4) enzyme activities and high activities of Rubisco and photorespiratory enzymes, suggesting that it reduces photorespiratory CO(2) loss by the glycine shuttle. In B. gravinae, the labelling density of Rubisco was higher in the mesophyll chloroplasts than in the BS chloroplasts. A similar cellular pattern was found in other Brassicaceae species. These data demonstrate that, during the evolution from C(3) to C(3)-C(4) intermediate plants, the intercellular pattern of Rubisco expression did not change greatly, although the amount of chloroplasts in the BS cells increased. It also appears that intracellular variation in Rubisco distribution may occur within the BS cells of B. gravinae.     

Redox potentials and kinetic properties of fumarate reductase complex from Vibrio succinogenes

The isolated menaquinol: fumarate oxidoreductase (fumarate reductase complex) from Vibrio succinogenes was investigated with respect to the redox potentials and the kinetic response of the prosthetic groups. The following results were obtained. (1) The redox state of the components was measured as a function of the redox potential established by the fumarate/succinate couple, after freezing of the samples (173 K). From these measurements, the midpoint potential of the [2Fe-2S] cluster (−59 mV), the [4Fe-4S] cluster (−24 mV) and the flavin/flavosemiquinone couple (about −20 mV) was obtained. (2) Potentiometric titration of the enzyme in the presence of electron-mediating chemicals gave, after freezing, apparent midpoint potentials that were 30–100 mV more negative than those found with the fumarate/succinate couple. (3) The rate constants of reduction of the components on the addition of succinate or 2,3-dimethyl-1,4-naphthoquinol were as great as or greater than the corresponding turnover numbers of the enzyme in quinone reduction by succinate or fumarate reduction by the quinol. In the oxidation of the reduced enzyme by fumarate, cytochrome b oxidation was about as fast as the corresponding turnover number of quinol oxidation by fumarate, while the [2Fe-2S] and half of the [4Fe-4S] cluster responded more than 2-times slower. The rate constant of the other half of the 4-Fe cluster was one order of magnitude smaller than the turnover number.     

Oxidoreduction of cytochrome b in the presence of antimycin

1. The effect of oxidizing equivalents on the redox state of cytochrome b in the presence of antimycin has been studied in the presence and absence of various redox mediators.

2. The antimycin-induced extra reduction of cytochrome b is always dependent on the initial presence of an oxidant such as oxygen. After removal of the oxidant this effect remains or is partially (under some conditions even completely) abolished depending on the redox potential of the substrate used and the leak through the antimycin-inhibited site.

3. The increased reduction of cytochrome b induced by oxidant in the presence of antimycin involves all three spectroscopically resolvable b components (b-562, b-566 and b-558.

4. Redox mediators with an actual redox potential of less than 100–170 mV cause the oxidation of cytochrome b reduced under the influence of antimycin and oxidant.

5. Redox titrations of cytochrome b with the succinate/fumarate couple were performed aerobically in the presence of cyanide. In the presence of antimycin two b components are separated potentiometrically, one with an apparent midpoint potential above 80 mV (at pH 7.0), outside the range of the succinate/fumurate couple, and one with an apparent midpoint potential of 40 mV and an n value of 2. In the absence of antimycin cytochrome b titrates essentially as one species with a midpoint potential of 39 mV (at pH 7.0) and n = 1.14.

6. The increased reducibility of cytochrome b induced by antimycin plus oxidant is considered to be the result of two effects: inhibition of oxidation of ferrocytochrome b by ferricytochrome c₁ (the effect of antimycin), and oxidation of the semiquinone form of a two-equivalent redox couple such as ubiquinone/ubiquinol by the added oxidant, leading to a decreased redox potential of the QH₂/QH^• couple and reduction of cytochrome b.     

CH...Metal(II) axial interaction in planar complexes (metal=Cu, Pd) and implications for possible environmental effects of alkyl groups at biological copper sites

Intramolecular M(II)...H-C interactions (M(II)=Cu(II), Pd(II)) involving a side chain alkyl group of planar d8 and d9 metal complexes of the N-alkyl (R) derivatives of N,N-bis(2-pyridylmethyl)amine with an N3Cl donor set were established by structural and spectroscopic methods. The methyl group from the branched alkyl group (R=2,2-dimethylpropyl and 2-methylbutyl) axially interacts with the metal ion with the M...C and M...H distances of 3.056(3)-3.352(9) and 2.317(1)-2.606(1) A, respectively, and the M-H-C angles of 122.4-162.3 degrees . The Cu(II) complexes showing the interaction have a higher redox potential as compared with those without it, and the (1)H NMR signals of the interacting methyl group in Pd(II) complexes shifted downfield relative to the ligand signals. Dependence of the downshift values on the dielectric constants of the solvents used indicated that the M(II)...H-C interaction is mainly electrostatic in nature and may be regarded as a weak hydrogen bond. Implications for possible environmental effects of the leucine alkyl group at the type 1 Cu site of fungal laccase are also discussed.     

Panicum milioides (C(3)-C(4)) does not have improved water or nitrogen economies relative to C(3) and C(4) congeners exposed to industrial-age climate change

The physiological implications of C(3)-C(4) photosynthesis were investigated using closely related Panicum species exposed to industrial-age climate change. Panicum bisulcatum (C(3)), P. milioides (C(3)-C(4)), and P. coloratum (C(4)) were grown in a glasshouse at three CO(2) concentrations ([CO(2)]: 280, 400, and 650?μl l(-1)) and two air temperatures [ambient (27/19?°C day/night) and ambient + 4?°C] for 12 weeks. Under current ambient [CO(2)] and temperature, the C(3)-C(4) species had higher photosynthetic rates and lower stomatal limitation and electron cost of photosynthesis relative to the C(3) species. These photosynthetic advantages did not improve leaf- or plant-level water (WUE) or nitrogen (NUE) use efficiencies of the C(3)-C(4) relative to the C(3) Panicum species. In contrast, the C(4) species had higher photosynthetic rates and WUE but similar NUE to the C(3) species. Increasing [CO(2)] mainly stimulated photosynthesis of the C(3) and C(3)-C(4) species, while high temperature had no or negative effects on photosynthesis of the Panicum species. Under ambient temperature, increasing [CO(2)] enhanced the biomass of the C(3) species only. Under high temperature, increasing [CO(2)] enhanced the biomass of the C(3) and C(3)-C(4) species to the same extent, indicating increased CO(2) limitation in the C(3)-C(4) intermediate at high temperature. Growth [CO(2)] and temperature had complex interactive effects, but did not alter the ranking of key physiological parameters amongst the Panicum species. In conclusion, the ability of C(3)-C(4) intermediate species partially to recycle photorespired CO(2) did not improve WUE or NUE relative to congeneric C(3) or C(4) species grown under varying [CO(2)] and temperature conditions.     

Disulfide bridge reorganization induced by proline mutations in maurotoxin

Maurotoxin (MTX) is a 34-residue toxin that has been isolated from the venom of the chactidae scorpion Scorpio maurus palmatus, and characterized. Together with Pi1 and HsTx1, MTX belongs to a family of short-chain four-disulfide-bridged scorpion toxins acting on potassium channels. However, contrary to other members of this family, MTX exhibits an uncommon disulfide bridge organization of the type C1-C5, C2-C6, C3-C4 and C7-C8, versus C1-C5, C2-C6, C3-C7 and C4-C8 for both Pi1 and HsTx1. Here, we report that the substitution of MTX proline residues located at positions 12 and/or 20, adjacent to C3 (Cys(13)) and C4 (Cys(19)), results in conventional Pi1- and HsTx1-like arrangement of the half-cystine pairings. In this case, this novel disulfide bridge arrangement is without obvious incidence on the overall three-dimensional structure of the toxin. Pharmacological assays of this structural analog, [A(12),A(20)]MTX, reveal that the blocking activities on Shaker B and rat Kv1.2 channels remain potent whereas the peptide becomes inactive on rat Kv1.3. These data indicate, for the first time, that discrete point mutations in MTX can result in a marked reorganization of the half-cystine pairings, accompanied with a novel pharmacological profile for the analog.     

Chiral discrimination of N-carbazole-carbonyl derivatives of alpha-amino acids with a short linear alkyl side chain by bovine serum albumin

Chiral discrimination of racemic carbazole carbonyl (CC)-amino acids with linear alkyl sidechain (C(1)-C(4)) by bovine serum albumin (BSA) was investigated by competitive replacement experiments using dansyl-L-proline and dansyl-D-norvaline as fluorescent probes. It was found that the CC derivatives of the D-forms of alanine (C(1)), amino butyric acid (C(2)), norvaline (C(3)), and norleucine (C(4)) bound to the dansyl-L-proline site much more strongly than their L-forms, whereas the interactions between both enantiomers of these amino acids with dansyl-D-norvaline site were slight.     

Molecular dissection of human methionine synthase reductase: determination of the flavin redox potentials in full-length enzyme and isolated flavin-binding domains

Human methionine synthase reductase (MSR) catalyzes the NADPH-dependent reductive methylation of methionine synthase. MSR is 78 kDa flavoprotein belonging to a family of diflavin reductases, with cytochrome P450 reductase (CPR) as the prototype. MSR and its individual flavin-binding domains were cloned as GST-tagged fusion proteins for expression and purification from Escherichia coli. The isolated flavin domains of MSR retain UV-visible and secondary structural properties indicative of correctly folded flavoproteins. Anaerobic redox titrations on the individual domains assisted in assignment of the midpoint potentials for the high- and low-potential flavin. For the isolated FMN domain, the midpoint potentials for the oxidized/semiquinone (ox/sq) couple and semiquinone/hydroquinone (sq/hq) couple are -112 and -221 mV, respectively, at pH 7.0 and 25 degrees C. The corresponding couples in the isolated FAD domain are -222 mV (ox/sq) and -288 mV (sq/hq). Both flavins form blue neutral semiquinone species characterized by broad absorption peaks in the long-wavelength region during anaerobic titration with sodium dithionite. In full-length MSR, the values of the FMN couples are -109 mV (ox/sq) and -227 mV (sq/hq), and the corresponding couple values for FAD are -254 mV (ox/sq) and -291 mV (sq/hq). Separation of the MSR flavins does not perturb their thermodynamic properties, as midpoint potentials for all four couples are similar in isolated domains and in full-length MSR. The redox properties of MSR are discussed in relation to other members of the diflavin oxidoreductase family and the mechanism of electron transfer.     

Alanine and aspartate formation during growth on valine-C14 by Pseudomonas aeruginosa

Sokatch, J. R. (University of Oklahoma School of Medicine, Oklahoma City). Alanine and aspartate formation during growth on valine-C(14) by Pseudomonas aeruginosa. J. Bacteriol. 92:72-75. 1966.-Pseudomonas aeruginosa grown with dl-valine-4,4'-C(14) synthesized alanine labeled mainly in carbons 1 and 3, indicating that the isopropyl carbons of valine were the precursors of pyruvate for alanine formation by a pathway which did not involve randomization of isotope. Alanine from cells grown on valine-1-C(14) contained isotope only in the carboxyl carbon, suggesting another route to pyruvate from valine by carbon dioxide fixation. Oxidation of valine to propionyl-coenzyme A (CoA), as it occurs in animal tissues, followed by the oxidation of propionyl-CoA to acrylyl-CoA, lactyl-CoA, and pyruvate, would account for the isotope data. Cells grown on valine oxidized valine, isobutyrate, and propionate immediately, whereas cells grown on acetate did not oxidize valine or isobutyrate and required an induction period before propionate was oxidized. P. aeruginosa grown with propionate-1-C(14) or propionate-2-C(14) formed alanine-1-C(14) and alanine-2-C(14), respectively, which agrees with the contention that at least part of the propionate is oxidized via the acrylate pathway. Aspartate formed from valine-1-C(14) was labeled only in the carboxyl carbons, whereas that formed from valine-4,4'-C(14) was labeled in all four carbons, but most heavily in carbons 1 and 3. These data suggest that the main route for the formation of the carbon skeleton of aspartate was by a C(3) plus C(1) condensation, with the C(3) unit derived from the isopropyl carbons of valine and the C(1) unit probably from carbon dioxide.     

Redox thermodynamics of mutant forms of the rubredoxin from Clostridium pasteurianum: identification of a stable FeIII(S-Cys)3(OH) centre in the C6S mutant

Redox thermodynamic data provide a detailed insight into control of the reduction potential E degrees' of the [Fe(S-Cys)4] site in rubredoxin. Mutant forms were studied in which specific structural changes were made in both the primary and secondary coordination spheres. Those changes have been probed by resonance Raman spectroscopy. The decrease of approximately 200 mV in E degrees' observed for the [Fe(S-Cys)3(O-Ser)]-/2- couples in the surface ligand mutants C9S and C42S is essentially enthalpic in origin and associated with the substitution of ligand thiolate by ligand olate. However, the pH dependence of the potentials below characteristic pKa(red) approximately equals 7 is an entropic contribution, plausibly associated with increased conformational flexibility induced by a longer Fe(II)-O(H)-Ser bond in the reduced form. The presence of a second surface Ser ligand in the new double mutant protein C9S/C42S affects the enthalpic term primarily for pH>pKa(red) > or = 9.3, but for pHpKa approximately 9: [Fe(III)(S-Cys)3(OH)]- + e- --> [Fe(II)(S-Cys)3(OH)]2-. pH [Fe(II)(S-Cys)3(OH2)]-.     

E. coli propionyl-CoA synthetase is regulated in vitro by an intramolecular disulfide bond

The E. coli propionyl-CoA synthetase (PCS) was cloned, expressed, purified, and analyzed. Kinetic analyses suggested that the enzyme preferred propionate as substrate but would also use acetate. The purified, stored protein had relatively low activity but was activated up to about 10-fold by incubation with dithiothreitol (DTT). The enzyme activation by DTT was reversed by diamide. This suggests that the protein contains a regulatory disulfide bond and that the reduction to two sulfhydryl groups activates PCS while the oxidation to a disulfide leads to its inactivation. This idea was tested by sequential mutagenesis of the 9 Cys in the protein to Ala. It was revealed that the C128A and C315A mutants had wildtype enzyme activity but were no longer activated by DTT or inhibited by diamide. The data obtained indicate that two Cys residues could be involved in redox-regulated system through formation of an intramolecular disulfide bridge in PCS.