Kinetic effects of the electrochemical proton gradient on plastoquinone reduction at the Qi site of the cytochrome b6f complex

We have investigated the effects of the light-induced thylakoid transmembrane potential on the turnover of the b(6)f complex in cells of the unicellular green alga Chlamydomonas reinhardtii. The reduction of the potential by either decreasing the light intensity or by adding increasing concentrations of the ionophore carbonylcyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) revealed a marked inhibition of the cytochrome b(6) oxidation rate (10-fold) without substantial modifications of cytochrome f oxidation kinetics. Partial recovery of this inhibition could be obtained in the presence of ionophores provided that the membrane potential was re-established by illumination with a train of actinic flashes fired at a frequency higher than its decay. Measurements of isotopic effects on the kinetics of cytochrome b(6) oxidation revealed a synergy between the effects of ionophores and the H(2)O-D(2)O exchange. We propose therefore, that protonation events influence the kinetics of cytochrome b(6) oxidation at the Qi site and that these reactions are strongly influenced by the light-dependent generation of a transmembrane potential.     

Roles of the heme distal residues of FixL in O2 sensing: a single convergent structure of the heme moiety is relevant to the downregulation of kinase activity

FixL is a heme-based O(2) sensor, in which the autophosphorylation is regulated by the binding of exogenous ligands such as O(2) and CN(-). In this study, mutants of the heme distal Arg200, Arg208, Ile209, Ile210, and Arg214 residues of SmFixL were characterized biochemically and physicochemically, because it has been suggested that they are significant residues in ligand-linked kinase regulation. Measurements of the autoxidation rate, affinities, and kinetics of ligand binding revealed that all of the above residues are involved in stabilization of the O(2)-heme complex of FixL. However, Arg214 was found to be the only residue that is directly relevant to the ligand-dependent regulation of kinase activity. Although the wild type and R214K and R214Q mutants exhibited normal kinase regulation, R214A, R214M, R214H, and R214Y did not. (13)C and (15)N NMR analyses for (13)C(15)N(-) bound to the truncated heme domains of the Arg214 mutants indicated that, in the wild type and the foregoing two mutants, the heme moiety is present in a single conformation, but in the latter four, the conformations fluctuate possibly because of the lack of an interaction between the iron-bound ligand and residue 214. It is likely that such a rigid conformation of the ligand-bound form is important for the downregulation of histidine kinase activity. Furthermore, a comparison of the NMR data between the wild type and R214K and R214Q mutants suggests that a strong electrostatic interaction between residue 214 and the iron-bound ligand is not necessarily required for the single convergent structure and eventually for the downregulation of FixL.     

Electron transfer and stability of the cytochrome b6f complex in a small domain deletion mutant of cytochrome f

The lumen segment of cytochrome f consists of a small and a large domain. The role of the small domain in the biogenesis and stability of the cytochrome b(6)f complex and electron transfer through the cytochrome b(6)f complex was studied with a small domain deletion mutant in Chlamydomonas reinhardtii. The mutant is able to grow photoautotrophically but with a slower rate than the wild type strain. The heme group is covalently attached to the polypeptide, and the visible absorption spectrum of the mutant protein is identical to that of the native protein. The kinetics of electron transfer in the mutant were measured by flash kinetic spectroscopy. Our results show that the rate for the oxidation of cytochrome f was unchanged (t(12) = approximately 100 micros), but the half-time for the reduction of cytochrome f is increased (t(12) = 32 ms; for wild type, t(12) = 2.1 ms). Cytochrome b(6) reduction was slower than that of the wild type by a factor of approximately 2 (t(12) = 8.6 ms; for wild type, t(12) = 4.7 ms); the slow phase of the electrochromic band shift also displayed a slower kinetics (t(12) = 5.5 ms; for wild type, t(12) = 2.7 ms). The stability of the cytochrome b(6)f complex in the mutant was examined by following the kinetics of the degradation of the individual subunits after inhibiting protein synthesis in the chloroplast. The results indicate that the cytochrome b(6)f complex in the small domain deletion mutant is less stable than in the wild type. We conclude that the small domain is not essential for the biogenesis of cytochrome f and the cytochrome b(6)f complex. However, it does have a role in electron transfer through the cytochrome b(6)f complex and contributes to the stability of the complex.     

Effects of inhibitors on the activity of the cytochrome b(6)f complex: evidence for the existence of two binding pockets in the lumenal site.

The effects of two inhibitors of electron transfer in the cytochrome b(6)f complex have been studied in whole cells of Chlamydomonas reinhardtii. DNP-INT affected equally the two steps of the concerted oxidation of plastoquinol at the Q(o) site; it decreased the rates of both cytochrome f reduction and cytochrome b(6) turnover, without affecting the amplitude of their redox signals. On the contrary, DBMIB inhibited only the rate of cytochrome f reduction while reducing, at the same time, the amplitude of cytochrome b(6) signals. The accessibility of DNP-INT to the Q(o) site was unaffected by preillumination, while that of DBMIB was greatly enhanced, even after a single turnover of the cytochrome b(6)f complex. Similar results were obtained with a mutant strain (FUD2) where the Q(o) site has an affinity for plastoquinol that is diminished by a factor of approximately 50 [Finazzi, G., et al. (1997) Biochemistry 36, 2867-2874]. However, the binding of the two inhibitors was differentially influenced by the mutation: a factor of approximately 250 was calculated for DNP-INT and a factor of only approximately 5 for DBMIB. This suggests that they bind within the Q(o) site in two distinct pockets, which are differentially involved in the process of quinol oxidation, in agreement with a recent model where two distinct positions for the reduced and semireduced quinones are considered [Crofts, A. R., and Berry, E. A. (1998) Curr. Opin. Struct. Biol. 8, 501-509].     

New insights on the proton pump associated with cytochrome b6f turnovers from the study of H/D substitution effects on the electrogenicity and electron transfer reactions

We have studied the effect of protium/deuterium substitution on different kinetics associated with the turnovers of cytochrome b(6)f complex in whole cells of Chlamydomonas reinhardtii. Both the oxidation of cytochrome f and the reduction of hemes b were only little affected by the isotopic substitution. Contrasting with this, the initial slope of the electrogenic phase associated with cytochrome b(6)f turnover was slowed by a factor of 4 by H(2)O/D(2)O substitution. Whereas in the presence of H(2)O the electrogenic phase developed concomitantly with cytochrome b reduction, it lagged for a few hundreds of microseconds after cytochrome b reduction in the presence of D(2)O. We propose that a proton pump is triggered by the oxidation of plastoquinol at the Q(o) site. The proton transfer is specifically delayed upon isotopic substitution, accounting for the lack of significant effect on the electron-transfer reaction as well as for the strong decrease of the initial rate of the electrogenic phase.     

Essential role of conserved arginine 160 in intramolecular electron transfer in human sulfite oxidase

Arginine 160 in human sulfite oxidase (SO) is conserved in all SO species sequenced to date. Previous steady-state kinetic studies of the R160Q human SO mutant showed a remarkable decrease in k(cat)/K(m)(sulfite) of nearly 1000-fold, which suggests that Arg 160 in human SO makes an important contribution to the binding of sulfite near the molybdenum cofactor [Garrett, R. M., Johnson, J. L., Graf, T. N., Feigenbaum, A., Rajagopalan, K. V. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 6394-6398]. In the crystal structure of chicken SO, Arg 138, the equivalent of Arg 160 in human SO, is involved in the formation of a positively charged sulfite binding site [Kisker, C., Schindelin, H., Pacheco, A., Wehbi, W., Garnett, R. M., Rajagopalan, K. V., Enemark, J. H., Rees, D. C. (1997) Cell 91, 973-983]. To further assess the role of Arg 160 in human SO, intramolecular electron transfer (IET) rates between the reduced heme [Fe(II)] and oxidized molybdenum [Mo(VI)] centers in the wild type, R160Q, and R160K human SO forms were investigated by laser flash photolysis. In the R160Q mutant, the IET rate constant at pH 6.0 was decreased by nearly 3 orders of magnitude relative to wild type, which indicates that the positive charge of Arg 160 is essential for efficient IET in human SO. Furthermore, the IET rate constant for the R160K mutant is about one-fourth that of the wild type enzyme, which strongly indicates that it is the loss of charge of Arg 160, and not its precise location, that is responsible for the much larger decrease in IET rates in the R160Q mutant. Steady-state kinetic measurements indicate that IET is rate-limiting in the catalytic cycle of the R160Q mutant. Thus, the large decrease in the IET rate constant rationalizes the fatal impact of this mutation in patients with this genetic disorder.     

Heterologous expression of enzymopenic methemoglobinemia variants using a novel NADH:cytochrome c reductase fusion protein

Hereditary enzymopenic methemoglobinemia is a rare disease that predominantly results from defects in either the erythrocytic (type I) or microsomal (type II) forms of the enzyme NADH:cytochrome b5 reductase (EC 1.6.2.2). All 25 currently identified type I and type II methemoglobinemia mutants have been expressed in Escherichia coli using a novel six histidine-tagged rat cytochrome b5/cytochrome b5 reductase fusion protein designated NADH:cytochrome c reductase (H6NCR). All 25 H6NCR variants were isolated and demonstrated to result in two groups of expression products. The first group of 16 mutants, which included the majority of the type I mutants, included K116Q, P131L, L139P, T183S, M193V, S194P, P211L, L215P, A245T, A245V, C270Y, E279K, V305R, V319M, M340-, and F365-, and yielded full-length fusion proteins that retained variable levels of NADH:cytochrome c reductase (NADH:CR) activity, ranging from approximately 2% (M340-) to 92% (K116Q) of that of the wild-type fusion protein. In contrast, the remaining nine mutants that represented the majority of the type II variants, comprised a second group that included Y109*, R124Q, Q143*, R150*, P162H, V172M, R226*, C270R, and R285*, and resulted in truncated H6NCR variants that retained the amino-terminal cytochrome b5 domain but were devoid of NADH:CR activity due to the absence of the cytochrome b5 reductase flavin domain. Kinetic analyses of the first group of full-length mutant fusion proteins indicated that values for both kcat and Km(NADH) were decreased and increased, respectively, indicating that the various mutations affected both substrate affinity and/or turnover. However, for the second group, the truncated products were the result of incomplete production of the carboxyl-terminal flavin-containing domain or instability of the expression products due to improper folding and/or lack of flavin incorporation.     

A cluster of positively charged amino acids in the C4BP alpha-chain is crucial for C4b binding and factor I cofactor function.

C4b-binding protein (C4BP) is a regulator of the classical complement pathway, acting as a cofactor to factor I in the degradation of C4b. Computer modeling and structural analysis predicted a cluster of positively charged amino acids at the interface between complement control protein modules 1 and 2 of the C4BP alpha-chain to be involved in C4b binding. Three C4BP mutants, R39Q, R64Q/R66Q, and R39Q/R64Q/R66Q, were expressed and assayed for their ability to bind C4b and to function as factor I cofactors. The apparent affinities of R39Q, R64Q/R66Q, and R39Q/R64Q/R66Q for immobilized C4b were 15-, 50-, and 140-fold lower, respectively, than that of recombinant wild type C4BP. The C4b binding site demonstrated herein was also found to be a specific heparin binding site. In C4b degradation, the mutants demonstrated decreased ability to serve as factor I cofactors. In particular, the R39Q/R64Q/R66Q mutant was inefficient as cofactor for cleavage of the Arg937-Thr938 peptide bond in C4b. In contrast, the factor I mediated cleavage of Arg1317-Asn1318 bond was less affected by the C4BP mutations. In conclusion, we identify a cluster of amino acids that is part of a C4b binding site involved in the regulation of the complement system.     

Inhibitor-complexed structures of the cytochrome bc1 from the photosynthetic bacterium Rhodobacter sphaeroides

The cytochrome bc(1) complex (bc(1)) is a major contributor to the proton motive force across the membrane by coupling electron transfer to proton translocation. The crystal structures of wild type and mutant bc(1) complexes from the photosynthetic purple bacterium Rhodobacter sphaeroides (Rsbc(1)), stabilized with the quinol oxidation (Q(P)) site inhibitor stigmatellin alone or in combination with the quinone reduction (Q(N)) site inhibitor antimycin, were determined. The high quality electron density permitted assignments of a new metal-binding site to the cytochrome c(1) subunit and a number of lipid and detergent molecules. Structural differences between Rsbc(1) and its mitochondrial counterparts are mostly extra membranous and provide a basis for understanding the function of the predominantly longer sequences in the bacterial subunits. Functional implications for the bc(1) complex are derived from analyses of 10 independent molecules in various crystal forms and from comparisons with mitochondrial complexes.     

Methane monooxygenase component B mutants alter the kinetics of steps throughout the catalytic cycle

Component interactions play important roles in the regulation of catalysis by methane monooxygenase (MMO). The binding of component B (MMOB) to the hydroxylase component (MMOH) has been shown in previous studies to cause structural changes in MMOH that result in altered thermodynamic and kinetic properties during the reduction and oxygen binding steps of the catalytic cycle. Here, specific amino acid residues of MMOB that play important roles in the interconversion of several intermediates of the MMO cycle have been identified. Both of the histidine residues in Methylosinus trichosporium OB3b MMOB (H5 and H33) were chemically modified by diethylpyrocarbonate (DEPC). Although the DEPC--MMOB species exhibited only minor changes relative to unmodified MMOB in steady-state MMO turnover, large decreases in the formation rate constants of the reaction cycle intermediates, compound P and compound Q, were observed. The site specific mutants H5A, H33A, and H5A/H33A were made and characterized. H5A and wild type MMOB elicited similar steady-state and transient kinetics, although the mutant caused a slightly lower rate constant for Q formation. Conversely, H33A exhibited a >50-fold decrease in the P formation rate constant, which resulted in slower formation of Q. The kinetics of the double mutant (H5A/H33A) were similar to those of H33A, suggesting that the highly conserved residue, H33, has the most significant effect on the efficient progress of the cycle. Ongoing NMR investigations of residues perturbed by formation of the MMOH-MMOB complex suggested construction of the MMOB N107G/S109A/S110A/T111A quadruple mutant. This mutant was found to elicit a nearly 2-fold increase in specific activity for steady-state MMO turnover of large substrates such as furan and nitrobenzene but caused no similar increase for the physiological substrate, methane. While the quadruple mutant did not have a significant effect on P and Q formation, it caused an almost 3-fold increase in the decay rate constant of Q for furan oxidation and a 2-fold faster product release rate constant for p-nitrophenol resulting from nitrobenzene oxidation. Conversely, this mutant caused the Q decay rate constant to decrease 7-fold for methane oxidation but left the product release step unaffected. These results show for the first time that MMOB exerts influence at late as well as early steps in the catalytic cycle. They also suggest that MMOB plays a critical role in determining the ability of MMO to distinguish between methane and larger substrates.     

A tryptophan that modulates tetrahydrobiopterin-dependent electron transfer in nitric oxide synthase regulates enzyme catalysis by additional mechanisms

Nitric oxide synthases (NOSs) are flavo-heme enzymes that require (6R)-tetrahydrobiopterin (H(4)B) for activity. Our single-catalytic turnover study with the inducible NOS oxygenase domain showed that a conserved Trp that interacts with H(4)B (Trp457 in mouse inducible NOS) regulates the kinetics of electron transfer between H(4)B and an enzyme heme-dioxy intermediate, and this in turn alters the kinetics and extent of Arg hydroxylation [Wang, Z.-Q., et al. (2001) Biochemistry 40, 12819-12825]. To investigate the impact of these effects on NADPH-driven NO synthesis by NOS, we generated and characterized the W457A mutant of inducible NOS and the corresponding W678A and W678F mutants of neuronal NOS. Mutant defects in protein solubility and dimerization were overcome by purifying them in the presence of sufficient Arg and H(4)B, enabling us to study their physical and catalytic profiles. Optical spectra of the ferric, ferrous, heme-dioxy, ferrous-NO, ferric-NO, and ferrous-CO forms of each mutant were similar to that of the wild type. However, the mutants had higher apparent K(m) values for H(4)B and in one mutant for Arg (W457A). They all had lower NO synthesis activities, uncoupled NADPH consumption, and a slower and less prominent buildup of enzyme heme-NO complex during steady-state catalysis. Further analyses showed the mutants had normal or near-normal heme midpoint potential and heme-NO complex reactivity with O(2), but had somewhat slower ferric heme reduction rates and markedly slower reactivities of their heme-dioxy intermediate. We conclude that the conserved Trp (1) has similar roles in two different NOS isozymes and (2) regulates delivery of both electrons required for O(2) activation (i.e., kinetics of ferric heme reduction by the NOS flavoprotein domain and reduction of the heme-dioxy intermediate by H(4)B). However, its regulation of H(4)B electron transfer is most important because this ensures efficient coupling of NADPH oxidation and NO synthesis by NOS.     

Arginine residues in the D2 polypeptide may stabilize bicarbonate binding in photosystem II of Synechocystis sp. PCC

Bicarbonate (HCO3-) causes a significant and reversible stimulation of anion-inhibited electron flow in photosystem II of higher plants and cyanobacteria. To test if selected arginine (Arg) residues are involved in the binding of HCO3-, we utilized oligonucleotide-directed mutagenesis to construct Synechocystis sp. PCC 6803 mutants carrying mutations in Arg residues in the D2 protein. Measurements of oxygen evolution showed that the D2 mutants R233Q (arginine-233----glutamine) and R251S (arginine-251----serine) were 10-fold more sensitive to formate than the wild type. The formate concentration giving half-maximal inhibition of the steady-state oxygen evolution rate was 48 mM, 4.5 mM and 4 mM for the wild type, R233Q and R251S, respectively. Measurements of oxygen evolution in single-turnover flashes confirm that the mutants are more sensitive to formate than the wild type. Measurements of chlorophyll a fluorescence decay kinetics after the second saturating actinic flash indicated that, after formate treatment, the halftime of QA- oxidation was decreased by approximately a factor of 2, 4 and 6 in the wild type, R251S and R233Q, respectively. The recombination rate between QA- and S2 was approx. 2-fold slower in R251S and R233Q than in the wild type. In the presence of 100 mM sodium formate, reactivation of the Hill reaction by bicarbonate showed that the wild type had an apparent Km for bicarbonate of 0.5 mM, while the Km values for R233Q and R251S were 1.4 and 1.5 mM, respectively. We suggest that Arg-233 and Arg-251 in the D2 polypeptide contribute to stabilization of HCO3- binding in Photosystem II.     

Physico-chemical properties of R140G and K141Q mutants of human small heat shock protein HspB1 associated with hereditary peripheral neuropathies

Some physico-chemical properties of R140G and K141Q mutants of human small heat shock protein HspB1 associated with hereditary peripheral neuropathy were analyzed. Mutation K141Q did not affect intrinsic Trp fluorescence and interaction with hydrophobic probe bis-ANS, whereas mutation R140G decreased both intrinsic fluorescence and fluorescence of bis-ANS bound to HspB1. Both mutations decreased thermal stability of HspB1. Mutation R140G increased, whereas mutation K141Q decreased the rate of trypsinolysis of the central part (residues 5–188) of HspB1. Both the wild type HspB1 and its K141Q mutant formed large oligomers with apparent molecular weight ∼560 kDa. The R140G mutant formed two types of oligomers, i.e. large oligomers tending to aggregate and small oligomers with apparent molecular weight ∼70 kDa. The wild type HspB1 formed mixed homooligomers with R140G mutant with apparent molecular weight ∼610 kDa. The R140G mutant was unable to form high molecular weight heterooligomers with HspB6, whereas the K141Q mutant formed two types of heterooligomers with HspB6. In vitro measured chaperone-like activity of the wild type HspB1 was comparable with that of K141Q mutant and was much higher than that of R140G mutant. Mutations of homologous hot-spot Arg (R140G of HspB1 and R120G of αB-crystallin) induced similar changes in the properties of two small heat shock proteins, whereas mutations of two neighboring residues (R140 and K141) induced different changes in the properties of HspB1.     

QO site deficiency can be compensated by extragenic mutations in the hinge region of the iron-sulfur protein in the bc1 complex of Saccharomyces cerevisiae

The mitochondrial bc(1) complex catalyzes the oxidation of ubiquinol and the reduction of cytochrome (cyt) c. The cyt b mutation A144F has been introduced in yeast by the biolistic method. This residue is located in the cyt b cd(1) amphipathic helix in the quinol-oxidizing (Q(O)) site. The resulting mutant was respiration-deficient and was affected in the quinol binding and electron transfer rates at the Q(O) site. An intragenic suppressor mutation was selected (A144F+F179L) that partially alleviated the defect of quinol oxidation of the original mutant A144F. The suppressor mutation F179L, located at less than 4 A from A144F, is likely to compensate directly the steric hindrance caused by phenylalanine at position 144. A second set of suppressor mutations was obtained, which also partially restored the quinol oxidation activity of the bc(1) complex. They were located about 20 A from A144F in the hinge region of the iron-sulfur protein (ISP) between residues 85 and 92. This flexible region is crucial for the movement of the ISP between cyt b and cyt c(1) during enzyme turnover. Our results suggested that the compensatory effect of the mutations in ISP was due to the repositioning of this subunit on cyt b during quinol oxidation. This genetic and biochemical study thus revealed the close interaction between the cyt b cd(1) helix in the quinol-oxidizing Q(O) site and the ISP via the flexible hinge region and that fine-tuning of the Q(O) site catalysis can be achieved by subtle changes in the linker domain of the ISP.     

The cytochrome P-450cam binding surface as defined by site-directed mutagenesis and electrostatic modeling

Cytochrome P-450cam cationic surface charges at Lys 344, Arg 72, and Lys 392 have been altered by site-directed mutagenesis techniques. The residues at Lys 344 and Arg 72 were previously suggested as salt bridge contacts in the cytochrome b5-cytochrome P-450cam association complex and implicated in the physiological putidaredoxin-cytochrome P-450cam complex [Stayton, P. S., Poulos, T. L., & Sligar, S. G. (1989) Biochemistry 28, 8201-8205]. Mutations to neutralize the basic charge at Arg 72 (R72Q) and to both neutralize and reverse the charge at Lys 344 (K344Q, K344E) resulted in alteration of NADH oxidation rates in the reconstituted physiological electron-transfer system, which is rate limited by putidaredoxin-cytochrome P-450cam electron transfer. The steady-state Vmax values were apparently unperturbed, suggesting that the observed rate differences were largely attributable to Km effects. The Km values observed for the K344Q (24 microM) and K344E (32 microM) mutants are in the direction expected for neutralization and reversal of a salt bridge charge interaction. A control mutation at a basic surface charge located away from the proposed site of interaction, Lys 392 (K392Q), resulted in overall activities quantitated by NADH oxidation rates that are similar to that of wild-type cytochrome P-450cam. Calculation of the cytochrome P-450cam electrostatic field revealed a patch of positive potential at the modeled cytochrome b5 interaction site lying directly above the nearest proximal approach to the buried heme prosthetic group. These results provide experimental and theoretical evidence for the modeled cytochrome P-450cam binding site implicated in both cytochrome b5 and putidaredoxin association.(ABSTRACT TRUNCATED AT 250 WORDS)     

Point mutation in cytochrome b of yeast ubihydroquinone:cytochrome-c oxidoreductase causing myxothiazol resistance and facilitated dissociation of the iron-sulfur subunit.

Cytochrome-c reductase was isolated from Saccharomyces cerevisiae GM50-3C. A tenth subunit was detected with molecular mass 8.5 kDa on SDS/PAGE. Two yeast mutants selected for resistance to myxothiazol, an inhibitor of the Q0 center (Q, ubiquinone) of cytochrome-c reductase, were analysed. The single amino acid substitution in the cytochrome-b subunit, N256Y in the mutant Myx-119 and G137R in the mutant Myx-118, caused a general resistance to all methoxyacrylate inhibitors to about fivefold higher concentrations. The kinetic measurements with the substrate analogue nonylbenzohydroquinone revealed a decrease in the Km by fivefold and of the maximal turnover number by fourfold in the N256Y mutant. The Km of the G137R mutant was not affected and the Vmax was 50% higher. Cytochrome-c reductase was isolated from mutants to allow determination of the Kd values of methoxyacrylate-stilbene and myxothiazol by means of fluorescence-quench and red-shift titration. Changes in the structure of the multisubunit complex due to a single amino acid exchange became obvious during the purification procedure. SDS/PAGE of the purified enzyme revealed that the substitution N256Y in cytochrome b led to a loss of the iron-sulfur protein and the fifth small subunit with no change in the pattern of the remaining eight subunits. The subunit pattern of the G137R mutant was identical to the wild type. This is the first report of a single amino acid exchange in the catalytic subunit of cytochrome b, greatly affecting the iron-sulfur protein, the second important catalytic subunit of the Q0 center. This is a new approach to obtain structural information about the interaction of cytochrome b with the iron-sulfur subunit.     

Identification by mutagenesis of arginines in the substrate binding site of the porcine NADP-dependent isocitrate dehydrogenase

Pig heart mitochondrial NADP-dependent isocitrate dehydrogenase is the most extensively studied among the mammalian isocitrate dehydrogenases. The crystal structure of Escherichia coli isocitrate dehydrogenase and sequence alignment of porcine with E. coli isocitrate dehydrogenase suggests that the porcine Arg(101), Arg(110), Arg(120), and Arg(133) are candidates for roles in substrate binding. The four arginines were separately mutated to glutamine using a polymerase chain reaction method. Wild type and mutant enzymes were each expressed in E. coli, isolated as maltose binding fusion proteins, then cleaved with thrombin, and purified to yield homogeneous porcine isocitrate dehydrogenase. The R120Q mutant has a specific activity, as well as K(m) values for isocitrate, Mn(2+), and NADP(+) similar to wild type enzyme, indicating that Arg(120) is not needed for function. The specific activities of R101Q, R110Q, and R133Q are 1.73, 1.30, and 19.7 micromols/min/mg, respectively, as compared with 39.6 units/mg for wild type enzyme. The R110Q and R133Q enzymes exhibit K(m) values for isocitrate that are increased more than 400- and 165-fold, respectively, as compared with wild type. The K(m) values for Mn(2+), but not for NADP(+), are also elevated indicating that binding of the metal-isocitrate complex is impaired in these mutants. It is proposed that the positive charges of Arg(110) and Arg(133) normally strengthen the binding of the negatively charged isocitrate by electrostatic attraction. The R101Q mutant shows smaller, but significant increases in the K(m) values for isocitrate and Mn(2+); however, the marked decrease in k(cat) suggests a role for Arg(101) in catalysis. The V(max) of wild type enzyme depends on the ionized form of an enzymic group of pK 5.5, and this pK(aes) is similar for the R101Q and R120Q enzymes. In contrast, the pK(aes) for R110Q and R133Q enzymes increases to 6.4 and 7.4, respectively, indicating that the positive charges of Arg(110) and Arg(133) normally lower the pK of the nearby catalytic base to facilitate its ionization. These results may be understood in terms of the structure of the porcine NADP-specific isocitrate dehydrogenase generated by the Insight II Modeler Program, based on the x-ray coordinates of the E. coli enzyme.     

Functional characterization of Chlamydomonas mutants defective in cytochrome f maturation.

We have altered the N terminus of cytochrome f by site-directed mutagenesis of the chloroplast petA gene in Chlamydomonas reinhardtii. We have replaced the tyrosine residue, Tyr(32), located immediately downstream of the processing site Ala(29)-Gln(30)-Ala(31) by a proline. Tyr(32) is the N terminus of the mature protein and serves as the sixth axial ligand to the heme iron. This mutant, F32P, accumulated different forms of holocytochrome f and assembled them into the cytochrome b(6)f complex. The strain was able to grow phototrophically. Our results therefore contradict a previous report (Zhou, J., Fernandez-Velasco, J. G., and Malkin, R. (1996) J. Biol. Chem. 271, 1-8) that a mutation, considered to be identical to the mutation described here, prevented cytochrome b(6)f assembly. A comparative functional characterization of F32P with F29L-31L, a site-directed processing mutant in which we had replaced the processing site by a Leu(29)-Gln(30)-Leu(31) sequence (2), revealed that both mutants accumulate high spin cytochrome f, with an unusual orientation of the heme and low spin cytochrome f with an alpha-band peak at 552 nm. Both hemes have significantly lower redox potentials than wild type cytochrome f. We attribute the high spin form to uncleaved pre-holocytochrome f and the low spin form to misprocessed forms of cytochrome f that were cleaved at a position different from the regular Ala(29)-Gln-Ala(31) motif. In contrast to F29L-31L, F32P displayed a small population of functional cytochrome f, presumably cleaved at Ala(29), with characteristics close to those of wild type cytochrome f. The latter form would account for cytochrome b(6)f turnover and photosynthetic electron transfer that sustain phototrophic growth of F32P.     

Three mammalian cytochromes b561 are ascorbate-dependent ferrireductases

Cytochromes b(561) are a family of transmembrane proteins found in most eukaryotic cells. Three evolutionarily closely related mammalian cytochromes b(561) (chromaffin granule cytochrome b, duodenal cytochrome b, and lysosomal cytochrome b) were expressed in a Saccharomyces cerevisiaeDeltafre1Deltafre2 mutant, which lacks almost all of its plasma membrane ferrireductase activity, to study their ability to reduce ferric iron (Fe(3+)). The expression of each of these cytochromes b(561) was able to rescue the growth defect of the Deltafre1Deltafre2 mutant cells in iron-deficient conditions, suggesting their involvement in iron metabolism. Plasma membrane ferrireductase activities were measured using intact yeast cells. Each cytochrome b(561) showed significant FeCN and Fe(3+)-EDTA reductase activities that were dependent on the presence of intracellular ascorbate. Site-directed mutagenesis of lysosomal cytochrome b was conducted to identify amino acids that are indispensable for its activity. Among more than 20 conserved or partially conserved amino acids that were investigated, mutations of four His residues (H47, H83, H117 and H156), one Tyr (Y66) and one Arg (R67) completely abrogated the FeCN reductase activity, whereas mutations of Arg (R149), Phe (F44), Ser (S115), Trp (W119), Glu (E196), and Gln (Q131) affected the ferrireductase activity to some degree. These mutations may affect the heme coordination, ascorbate binding, and/or ferric substrate binding. Possible roles of these residues in lysosomal cytochrome b are discussed. This study demonstrates the ascorbate-dependent transmembrane ferrireductase activities of members of the mammalian cytochrome b(561) family of proteins.