Gene cluster of Rhodothermus marinus high-potential iron-sulfur Protein: oxygen oxidoreductase, a caa(3)-type oxidase belonging to the superfamily of heme-copper oxidases

The respiratory chain of the thermohalophilic bacterium Rhodothermus marinus contains an oxygen reductase, which uses HiPIP (high potential iron-sulfur protein) as an electron donor. The structural genes encoding the four subunits of this HiPIP:oxygen oxidoreductase were cloned and sequenced. The genes for subunits II, I, III, and IV (named rcoxA to rcoxD) are found in this order and seemed to be organized in an operon of at least five genes with a terminator structure a few nucleotides downstream of rcoxD. Examination of the amino acid sequence of the Rcox subunits shows that the subunits of the R. marinus enzyme have homology to the corresponding subunits of oxidases belonging to the superfamily of heme-copper oxidases. RcoxB has the conserved histidines involved in binding the binuclear center and the low-spin heme. All of the residues proposed to be involved in proton transfer channels are conserved, with the exception of the key glutamate residue of the D-channel (E(278), Paracoccus denitrificans numbering). Analysis of the homology-derived structural model of subunit I shows that the phenol group of a tyrosine (Y) residue and the hydroxyl group of the following serine (S) may functionally substitute the glutamate carboxyl in proton transfer. RcoxA has an additional sequence for heme C binding, after the Cu(A) domain, that is characteristic of caa(3) oxidases belonging to the superfamily. Homology modeling of the structure of this cytochrome domain of subunit II shows no marked electrostatic character, especially around the heme edge region, suggesting that the interaction with a redox partner is not of an electrostatic nature. This observation is analyzed in relation to the electron donor for this caa(3) oxidase, the HiPIP. In conclusion, it is shown that an oxidase, which uses an iron-sulfur protein as an electron donor, is structurally related to the caa(3) class of heme-copper cytochrome c oxidases. The data are discussed in the framework of the evolution of oxidases within the superfamily of heme-copper oxidases.     

Helix switching of a key active-site residue in the cytochrome cbb3 oxidases

In the respiratory chains of mitochondria and many aerobic prokaryotes, heme-copper oxidases are the terminal enzymes that couple the reduction of molecular oxygen to proton pumping, contributing to the protonmotive force. The cbb(3) oxidases belong to the superfamily of enzymes that includes all of the heme-copper oxidases. Sequence analysis indicates that the cbb(3) oxidases are missing an active-site tyrosine residue that is absolutely conserved in all other known heme-copper oxidases. In the other heme-copper oxidases, this tyrosine is known to be subject to an unusual post-translational modification and to play a critical role in the catalytic mechanism. The absence of this tyrosine in the cbb(3) oxidases raises the possibility that the cbb(3) oxidases utilize a different catalytic mechanism from that of the other members of the superfamily. Using homology modeling, quantum chemistry, and molecular dynamics, a model of the structure of subunit I of a cbb(3) oxidase (Vibrio cholerae) was constructed. The model predicts that a tyrosine residue structurally analogous to the active-site tyrosine in other oxidases is present in the cbb(3) oxidases but that the tyrosine originates from a different transmembrane helix within the protein. The predicted active-site tyrosine is conserved in the sequences of all of the known cbb(3) oxidases. Mutagenesis of the tyrosine to phenylalanine in the V. cholerae oxidase resulted in a fully assembled enzyme with nativelike structure but lacking catalytic activity. These findings strongly suggest that all of the heme-copper oxidases utilize the same catalytic mechanism and provide an unusual example in which a critical active-site residue originates from different places within the primary sequence for different members of the same superfamily.     

A tyrosine residue deprotonates during oxygen reduction by the caa3 reductase from Rhodothermus marinus

Heme-copper oxygen reductases catalyze proton translocation across the cellular membrane; this takes place during the reaction of oxygen to water. We demonstrate with attenuated total reflection-Fourier transform infrared (ATR-FTIR) difference spectroscopy that a tyrosine residue of the oxygen reductase from the thermohalophilic Rhodothermus marinus becomes deprotonated in the transition from the oxidized state to the catalytic intermediate ferryl state P(M). This tyrosine residue is most probably Y256, the helix VI tyrosine residue proposed to substitute for the D-channel glutamic acid that is absent in this enzyme. Comparison with the mitochondrial like oxygen reductase from Rhodobacter sphaeroides suggests that proton transfer from a strategically situated donor to the active site is a crucial step in the reaction mechanism of oxygen reductases.     

Proton translocation by cytochrome c oxidase can take place without the conserved glutamic acid in subunit I

A glutamic acid residue in subunit I of the heme-copper oxidases is highly conserved and has been directly implicated in the O(2) reduction and proton-pumping mechanisms of these respiratory enzymes. Its mutation to residues other than aspartic acid dramatically inhibits activity, and proton translocation is lost. However, this glutamic acid is replaced by a nonacidic residue in some structurally distant members of the heme-copper oxidases, which have a tyrosine residue in the vicinity. Here, using cytochrome c oxidase from Paracoccus denitrificans, we show that replacement of the glutamic acid and a conserved glycine nearby lowers the catalytic activity to <0.1% of the wild-type value. But if, in addition, a phenylalanine that lies close in the structure is changed to tyrosine, the activity rises more than 100-fold and proton translocation is restored. Molecular dynamics simulations suggest that the tyrosine can support a transient array of water molecules that may be essential for proton transfer in the heme-copper oxidases. Surprisingly, the glutamic acid is thus not indispensable, which puts important constraints on the catalytic mechanism of these enzymes.     

Sequence analysis of the cbb3 oxidases and an atomic model for the Rhodobacter sphaeroides enzyme

The cbb3-type oxidases are members of the heme-copper oxidase superfamily, distant by sequence comparisons, but sharing common functional characteristics. To understand the minimal common properties of the superfamily, and to learn about cbb3-type oxidases specifically, we have analyzed a wide set of heme-copper oxidase sequences and built a homology model of the catalytic subunit of the cbb3 oxidase from Rhodobacter sphaeroides. We conclude that with regard to the active site surroundings, the cbb3 oxidases greatly resemble the structurally known oxidases, while major differences are found in three segments: the additional N-terminal stretch of ca. 60 amino acids, the segment following helix 3 to the end of helix 5, and the C-terminus from helix 11 onward. The conserved core contains the active site tyrosine and also an analogue of the K-channel of proton transfer, but centered on a well-conserved histidine in the lower part of helix 7. Modeling the variant parts of the enzyme suggests that two periplasmic loops (between helices 3 and 4 and between helices 11 and 12) could interact with each other as a part of the active site structure and might have an important role in proton pumping. An analogue of the D-channel is not found, but an alternative channel might form around helix 9. A preliminary packing model of the trimeric enzyme is also presented.     

Substitutions for glutamate 101 in subunit II of cytochrome c oxidase from Rhodobacter sphaeroides result in blocking the proton-conducting K-channel

Two functional input pathways for protons have been characterized in the heme-copper oxidases: the D-channel and the K-channel. These two proton-conducting channels have different functional roles and have been defined both by X-ray crystallography and by the characterization of site-directed mutants. Whereas the entrance of the D-channel is well-defined as D132(I) (subunit I; Rhodobacter sphaeroides numbering), the entrance of the K-channel has not been clearly defined. Previous mutagenesis studies of the cytochrome bo(3) quinol oxidase from Escherichia coli implicated an almost fully conserved glutamic acid residue within subunit II as a likely candidate for the entrance of the K-channel. The current work examines the properties of mutants of this conserved glutamate in the oxidase from R. sphaeroides (E101(II)I,A,C,Q,D,N,H) and residues in the immediate vicinity of E101(II). It is shown that virtually any substitution for E101(II), including E101(II)D, strongly reduces oxidase turnover (to 8-29%). Furthermore, the low steady-state activity correlates with an inhibition of the rate of reduction of heme a(3) prior to the reaction with O(2). These are phenotypes expected of K-channel mutants. It is concluded that the predominant entry point for protons going into the K-channel of cytochrome oxidase is the surface-exposed glutamic acid E101(II) in subunit II.     

The causes of reduced proton-pumping efficiency in type B and C respiratory heme-copper oxidases,and in some mutated variants of type A

The heme-copper oxidases may be divided into three categories, A, B, and C, which include cytochrome c and quinol-oxidising enzymes. All three types are known to be proton pumps and are found in prokaryotes, whereas eukaryotes only contain A-type cytochrome c oxidase in their inner mitochondrial membrane. However, the bacterial B- and C-type enzymes have often been reported to pump protons with an H⁺/e^- ratio of only one half of the unit stoichiometry in the A-type enzyme. We will show here that these observations are likely to be the result of difficulties with the measuring technique together with a higher sensitivity of the B- and C-type enzymes to the protonmotive force that opposes pumping. We find that under optimal conditions the H⁺/e^- ratio is close to unity in all the three heme-copper oxidase subfamilies. A higher tendency for proton leak in the B- and C-type enzymes may result from less efficient gating of a proton pump mechanism that we suggest evolved before the so-called D-channel of proton transfer. There is also a discrepancy between results using whole bacterial cells vs. phospholipid vesicles inlaid with oxidase with respect to the observed proton pumping after modification of the D-channel residue asparagine-139 (Rhodobacter sphaeroides numbering) to aspartate in A-type cytochrome c oxidase. This discrepancy might also be explained by a higher sensitivity of proton pumping to protonmotive force in the mutated variant. This article is part of a Special Issue entitled: 18th European Bioenergetic Conference.     

A novel scenario for the evolution of haem-copper oxygen reductases

The increasing sequence information on oxygen reductases of the haem-copper superfamily, together with the available three-dimensional structures, allows a clear identification of their common, functionally important features. Taking into consideration both the overall amino acid sequences of the core subunits and key residues involved in proton transfer, a novel hypothesis for the molecular evolution of these enzymes is proposed. Three main families of oxygen reductases are identified on the basis of common features of the core subunits, constituting three lines of evolution: (i) type A (mitochondrial-like oxidases), (ii) type B (ba3-like oxidases) and (iii) type C (cbb3-type oxidases). The first group can be further divided into two subfamilies, according to the helix VI residues at the hydrophobic end of one of the proton pathways (the so-called D-channel): (i) type A1, comprising the enzymes with a glutamate residue in the motif -XGHPEV-, and (ii) type A2, enzymes having instead a tyrosine and a serine in the alternative motif -YSHPXV-. This second subfamily of oxidases is shown to be ancestor to the one containing the glutamate residue, which in the Bacteria domain is only present in oxidases from Gram-positive or purple bacteria. It is further proposed that the Archaea domain acquired terminal oxidases by gene transfer from the Gram-positive bacteria, implying that these enzymes were not present in the last common ancestor before the divergence between Archaea and Bacteria. In fact, most oxidases from archaea have a higher amino acid sequence identity and similarity with those from bacteria, mainly from the Gram-positive group, than with oxidases from other archaea. Finally, a possible relation between the dihaemic subunit (FixP) of the cbb3 oxidases and subunit II of caa3 oxidases is discussed. As the families of haem-copper oxidases can also be identified by their subunit II, a parallel evolution of subunits I and II is suggested.     

Molecular cloning, sequencing, and physiological characterization of the qox operon from Bacillus subtilis encoding the aa3-600 quinol oxidase.

Bacillus subtilis contains two aa3-type terminal oxidases (caa3-605 and aa3-600) catalyzing cytochrome c and quinol oxidation, respectively, with the concomitant reduction of O2 to H2O (Lauraeus, M., Haltia, T., Saraste, M., and Wikstr?m, M. (1991) Eur. J. Biochem. 197, 699-705). Previous studies characterized only the structural genes of caa3-605 oxidase. We isolated the genes coding for the four subunits of a B. subtilis terminal oxidase from a genomic DNA library. These genes, named qoxA to qoxD, are organized in an operon. Examination of the deduced amino acid sequence of Qox subunits showed that this oxidase is structurally related to the large family of mitochondrial-type aa3 terminal oxidases. In particular, the amino acid sequences are very similar to those of subunits of Escherichia coli bo quinol oxidase and B. subtilis caa3-605 cytochrome c oxidase. We produced, by in vitro mutagenesis, a mutation in the qox operon. From the phenotype of the mutant strain devoid of Qox protein, the study of expression of the qox operon in different growth conditions, and the analysis of the deduced amino acid sequence of the subunits, we concluded that Qox protein and aa3-600 quinol oxidase are the same protein. Although several terminal oxidases are found in B. subtilis, Qox oxidase (aa3-600) is predominant during the vegetative growth and its absence leads to important alterations of the phenotype of B. subtilis.     

A mutation in subunit I of cytochrome oxidase from Rhodobacter sphaeroides results in an increase in steady-state activity but completely eliminates proton pumping

The heme-copper oxidases convert the free energy liberated in the reduction of O(2) to water into a transmembrane proton electrochemical potential (protonmotive force). One of the essential structural elements of the enzyme is the D-channel, which is thought to be the input pathway, both for protons which go to form H(2)O ("chemical protons") and for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel contains a chain of water molecules extending about 25 A from an aspartic acid (D132 in the Rhodobacter sphaeroides oxidase) near the cytoplasmic ("inside") enzyme surface to a glutamic acid (E286) in the protein interior. Mutations in which either of these acidic residues is replaced by their corresponding amides (D132N or E286Q) result in severe inhibition of enzyme activity. In the current work, an asparagine located in the D-channel has been replaced by the corresponding acid (N139 to D; N98 in bovine enzyme) with dramatic consequences. The N139D mutation not only completely eliminates proton pumping but, at the same time, confers a substantial increase (150-300%) in the steady-state cytochrome oxidase activity. The N139D mutant of the R. sphaeroides oxidase was further characterized by examining the rates of individual steps in the catalytic cycle. Under anaerobic conditions, the rate of reduction of heme a(3) in the fully oxidized enzyme, prior to the reaction with O(2), is identical to that of the wild-type oxidase and is not accelerated. However, the rate of reaction of the fully reduced enzyme with O(2) is accelerated by the N139D mutation, as shown by a more rapid F --> O transition. Whereas the rates of formation and decay of the oxygenated intermediates are altered, the nature of the oxygenated intermediates is not perturbed by the N139D mutation.     

Specific inhibition of proton pumping by the T315V mutation in the K channel of cytochrome ba3 from Thermus thermophilus

Cytochrome ba₃ from Thermus thermophilus belongs to the B family of heme-copper oxidases and pumps protons across the membrane with an as yet unknown mechanism. The K channel of the A family heme-copper oxidases provides delivery of a substrate proton from the internal water phase to the binuclear heme-copper center (BNC) during the reductive phase of the catalytic cycle, while the D channel is responsible for transferring both substrate and pumped protons. By contrast, in the B family oxidases there is no D-channel and the structural equivalent of the K channel seems to be responsible for the transfer of both categories of protons. Here we have studied the effect of the T315V substitution in the K channel on the kinetics of membrane potential generation coupled to the oxidative half-reaction of the catalytic cycle of cytochrome ba₃. The results suggest that the mutated enzyme does not pump protons during the reaction of the fully reduced form with molecular oxygen in a single turnover. Specific inhibition of proton pumping in the T315V mutant appears to be a consequence of inability to provide rapid (τ ~ 100 μs) reprotonation of the internal transient proton donor(s) of the K channel. In contrast to the A family, the K channel of the B-type oxidases is necessary for the electrogenic transfer of both pumped and substrate protons during the oxidative half-reaction of the catalytic cycle.     

Investigation of protonatable residues in Rhodothermus marinus caa 3 haem-copper oxygen reductase: comparison with Paracoccus denitrificans aa 3 haem-copper oxygen reductase

The Rhodothermus marinus caa ₃ haem-copper oxygen reductase contains all the residues of the so-called D- and K-proton channels, with the notable exception of the helix VI glutamate residue (Glu278^I in Paracoccus denitrificans aa ₃), being nevertheless a true oxygen reductase reducing O₂ to water, and an efficient proton pump. Instead, in the same helix, but one turn below, it has a tyrosine residue (Tyr256^I, R. marinus caa ₃ numbering), whose hydroxyl group occupies the same spatial position as the carboxylate group of Glu278^I, as deduced by comparative modelling techniques. Therefore, we proposed previously that this tyrosine residue could play an important role in the proton pathway. In this article we further study this hypothesis, by investigating the equilibrium thermodynamics of protonation in R. marinus caa ₃, using theoretical methodologies based on the structural model previously obtained. Control calculations are also performed for the P. denitrificans aa ₃ oxygen reductase. In both oxygen reductases we find several residues that are proton active (i.e., that display partial protonation) at physiological pH, some of them being redox sensitive (i.e., sensitive to the protein redox state). However, the caa ₃ Tyr256^I is not proton active at physiological pH, in contrast to the aa ₃ Glu278^I which is both proton active at physiological pH and shows a high redox sensitivity. In R. marinus caa ₃ we do not find any other residues in the same protein zone that can have this property. Therefore, there are no putative D-channel residues that are proton active in this oxidase. The protonatable residues of the K-channel are much more functionally conserved in both oxygen reductases than the same type of residues in the D-channel. Two (Tyr262^I and Lys336^I, caa ₃ numbering) out of three protonatable K-channel residues are proton active and redox sensitive in both proteins.     

Mutagenesis of tyrosine residues within helix VII in subunit I of the cytochrome <Emphasis Type="Italic">cbb</Emphasis><Subscript>3</Subscript> oxidase from <Emphasis Type="Italic">Rhodobacter capsulatus</Emphasis>

The cbb ₃-type oxidases are members of the heme-copper oxidase superfamily, distant by sequence comparisons, but sharing common functional characteristics. The cbb ₃ oxidases are missing an active-site tyrosine residue that is absolutely conserved in all A and B-type heme-copper oxidases. This tyrosine is known to play a critical role in the catalytic mechanisms of A and B-type oxidases. The absence of this tyrosine in the cbb ₃ oxidases raises the possibility that the cbb ₃ oxidases utilize a different catalytic mechanism from that of the other members of the superfamily, or have this conserved residue in different helices. Recently sequence comparisons indicate that, a tyrosine residues that might be analogous to the active-site tyrosine in other oxidases are present in the cbb ₃ oxidases but these tyrosines originates from a different transmembrane helix within the protein. In this research, three conserved tyrosine residues, Y294, Y308 and Y318, in helix VII were substituted for phenylalanine. Y318F mutant in the Rhodobacter capsulatus oxidase resulted in a fully assembled enzyme with nativelike structure and activity, but Y294F mutant is not assembled and have a catalytic activity. On the other hand, Y308F mutant is fully assembled enzyme with nativelike structure, but lacking catalytic activity. This result indicates that Y308 should be crucial in catalytic activity of the cbb ₃ oxidase of R. capsulatus. These findings support the assumption that all of the heme-copper oxidases utilize the same catalytic mechanism and provide a residue originates from different places within the primary sequence for different members of the same superfamily.     

Structure at 1.3 A resolution of Rhodothermus marinus caa(3) cytochrome c domain

The cytochrome c domain of subunit II from the Rhodothermus marinus caa(3) HiPIP:oxygen oxidoreductase, a member of the superfamily of heme-copper-containing terminal oxidases, was produced in Escherichia coli and characterised. The recombinant protein, which shows the same optical absorption and redox properties as the corresponding domain in the holo enzyme, was crystallized and its structure was determined to a resolution of 1.3 A by the multiwavelength anomalous dispersion (MAD) technique using the anomalous dispersion of the heme iron atom. The model was refined to final R(cryst) and R(free) values of 13.9% and 16.7%, respectively. The structure reveals the insertion of two short antiparallel beta-strands forming a small beta-sheet, an interesting variation of the classical all alpha-helical cytochrome c fold. This modification appears to be common to all known caa(3)-type terminal oxidases, as judged by comparative modelling and by analyses of the available amino acid sequences for these enzymes. This is the first high-resolution crystal structure reported for a cytochrome c domain of a caa(3)-type terminal oxidase. The R.marinus caa(3) uses HiPIP as the redox partner. The calculation of the electrostatic potential at the molecular surface of this extra C-terminal domain provides insights into the binding to its redox partner on one side and its interaction with the remaining subunit II on the other side.     

G204D, a mutation that blocks the proton-conducting D-channel of the aa3-type cytochrome c oxidase from Rhodobacter sphaeroides

Cytochrome c oxidase uses the free energy of oxygen reduction to establish a transmembrane proton gradient. The proton-conducting D-channel in this enzyme is the major input pathway for protons which go to the binuclear center for water formation ("chemical protons") and likely the only input pathway for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel starts at an acidic residue near the protein surface (D132, Rhodobacter sphaeroides numbering) and leads to another acidic residue near the binuclear center. Recent studies have shown that mutants that introduce an additional acidic residue in the channel (N139D) have the remarkable effect of accelerating steady-state oxidase activity but completely eliminating proton pumping. In this work, an aspartic acid was introduced at the position of glycine 204, G204D, which is also within the D-channel, and the effects were examined. In contrast to N139D, the G204D mutation results in a dramatic decrease of the steady-state oxygen reductase activity (<2% of wild type) [Aagaard, A., and Brzezinski, P. (2001) FEBS Lett. 494, 157-160]. The residual activity is not coupled to the proton pump, and furthermore, in reconstituted vesicles the mutant enzyme exhibits a reverse respiration control ratio; i.e., the mutant oxidase activity is stimulated rather than inhibited when working against a protonmotive force. Hence, the mutant behaves very much like the D132N, which blocks proton uptake through the D-channel. Single-turnover experiments show that the rate-limiting step in the reaction of O2 with the fully reduced G204D mutant is the F --> O transition, similar to the D132N mutant. The block of the D-channel in the D132N mutant can be partly bypassed by biochemically removing subunit III from the enzyme, indicating that removal of the subunit reveals an alternate entrance for protons to the channel. However, this is not observed with the G204D mutant. This suggests that the cryptic entrance to the D-channel that is revealed by the removal of subunit III is between the levels of G204 and D132.     

Terminal oxidases of Bacillus subtilis strain 168: one quinol oxidase, cytochrome aa(3) or cytochrome bd, is required for aerobic growth

The gram-positive endospore-forming bacterium Bacillus subtilis has, under aerobic conditions, a branched respiratory system comprising one quinol oxidase branch and one cytochrome oxidase branch. The system terminates in one of four alternative terminal oxidases. Cytochrome caa(3) is a cytochrome c oxidase, whereas cytochrome bd and cytochrome aa(3) are quinol oxidases. A fourth terminal oxidase, YthAB, is a putative quinol oxidase predicted from DNA sequence analysis. None of the terminal oxidases are, by themselves, essential for growth. However, one quinol oxidase (cytochrome aa(3) or cytochrome bd) is required for aerobic growth of B. subtilis strain 168. Data indicating that cytochrome aa(3) is the major oxidase used by exponentially growing cells in minimal and rich medium are presented. We show that one of the two heme-copper oxidases, cytochrome caa(3) or cytochrome aa(3), is required for efficient sporulation of B. subtilis strain 168 and that deletion of YthAB in a strain lacking cytochrome aa(3) makes the strain sporulation deficient.     

Defining the proton entry point in the bacterial respiratory nitric-oxide reductase

The bacterial respiratory nitric-oxide reductase (NOR) is a member of the superfamily of O(2)-reducing, proton-pumping, heme-copper oxidases. Even although nitric oxide reduction is a highly exergonic reaction, NOR is not a proton pump and rather than taking up protons from the cytoplasmic (membrane potential-negative) side of the membrane, like the heme-copper oxidases, NOR derives its substrate protons from the periplasmic (membrane potential-positive) side of the membrane. The molecular details of this non-electrogenic proton transfer are not yet resolved, so in this study we have explored a role in a proposed proton pathway for a conserved surface glutamate (Glu-122) in the catalytic subunit (NorB). The effect of substituting Glu-122 with Ala, Gln, or Asp on a single turnover of the reduced NOR variants with O(2), an alternative and experimentally tractable substrate for NOR, was determined. Electron transfer coupled to proton uptake to the bound O(2) is severely and specifically inhibited in both the E122A and E122Q variants, establishing the importance of a protonatable side chain at this position. In the E122D mutant, proton uptake is retained but it is associated with a significant increase in the observed pK(a) of the group donating protons to the active site. This suggests that Glu-122 is important in defining this proton donor. A second nearby glutamate (Glu-125) is also required for the electron transfer coupled to proton uptake, further emphasizing the importance of this region of NorB in proton transfer. Because Glu-122 is predicted to lie near the periplasmic surface of NOR, the results provide strong experimental evidence that this residue contributes to defining the aperture of a non-electrogenic "E-pathway" that serves to deliver protons from the periplasm to the buried active site in NOR.     

Probing protonation/deprotonation of tyrosine residues in cytochrome ba3 oxidase from Thermus thermophilus by time-resolved step-scan Fourier transform infrared spectroscopy

Elucidating the properties of the heme Fe-Cu(B) binuclear center and the dynamics of the protein response in cytochrome c oxidase is crucial to understanding not only the dioxygen activation and bond cleavage by the enzyme but also the events related to the release of the produced water molecules. The time-resolved step-scan FTIR difference spectra show the ν(7a)(CO) of the protonated form of Tyr residues at 1247 cm(-1) and that of the deprotonated form at 1301 cm(-1). By monitoring the intensity changes of the 1247 and 1301 cm(-1) modes as a function of pH, we measured a pK(a) of 7.8 for the observed tyrosine. The FTIR spectral changes associated with the tyrosine do not belong to Tyr-237 but are attributed to the highly conserved in heme-copper oxidases Tyr-136 and/or Tyr-133 residue (Koutsoupakis, K., Stavrakis, S., Pinakoulaki, E., Soulimane, T., and Varotsis, C. (2002) J. Biol. Chem. 277, 32860-32866). The oxygenation of CO by the mixed-valence form of the enzyme revealed the formation of the ～607 nm P (Fe(IV)=O) species in the pH 6-9 range and the return to the oxidized form without the formation of the 580 nm F form. The data indicate that Tyr-237 is not involved in the proton transfer pathway in the oxygenation of CO by the mixed-valence form of the enzyme. The implication of these results with respect to the role of Tyr-136 and Tyr-133 in proton transfer/gating along with heme a(3) ring D propionate-H(2)O-ring A propionate-Asp-372 site to the exit/output proton channel (H(2)O pool) is discussed.     

Fourier transform infrared (FTIR) and step-scan time-resolved FTIR spectroscopies reveal a unique active site in cytochrome caa3 oxidase from Thermus thermophilus

Fourier transform infrared (FTIR) and step-scan time-resolved FTIR difference spectra are reported for the [carbonmonoxy]cytochrome caa(3) from Thermus thermophilus. A major C-O mode of heme a(3) at 1958 cm(-1) and two minor modes at 1967 and 1975 cm(-1) (7:1:1) have been identified at room temperature and remained unchanged in H(2)O/D(2)O exchange. The observed C-O frequencies are 10 cm(-1) higher than those obtained previously at 21 K (Einarsdóttir, O., Killough, P. M., Fee, J. A., and Woodruff, W. H. (1989) J. Biol. Chem. 264, 2405-2408). The time-resolved FTIR data indicate that the transient Cu(B)(1+)-CO complex is formed at room temperature as revealed by the CO stretching mode at 2062 cm(-1). Therefore, the caa(3) enzyme is the only documented member of the heme-copper superfamily whose binuclear center consists of an a(3)-type heme of a beta-form and a Cu(B) atom of an alpha-form. These results illustrate that the properties of the binuclear center in other oxidases resulting in the alpha-form are not required for enzymatic activity. Dissociation of the transient Cu(B)(1+)-CO complex is biphasic. The rate of decay is 2.3 x 10(4) s(-1) (fast phase, 35%) and 36.3 s(-1) (slow phase, 65%). The observed rate of rebinding to heme a(3) is 34.1 s(-1). The implications of these results with respect to the molecular motions that are general to the photodynamics of the binuclear center in heme-copper oxidases are discussed.     

Effects of site-directed mutagenesis of protolytic residues in subunit I of Bacillus subtilis aa3-600 quinol oxidase. Role of lysine 304 in proton translocation

Various protolytic residues in subunit I of aa3-600 quinol oxidase of the aerobic Gram-positive Bacillus subtilis were mutagenized to nonpolar residues. Two of the mutations, Y284F and K304L, impaired the bioenergetic function of the microorganism. The Y284F mutation suppressed the electron-transfer activity of quinol oxidase and altered its interaction with CO and H2O2, thus showing destruction of the binuclear domain as observed for the bo3 quinol oxidase of Escherichia coli. The K304L mutation did not alter significantly the redox activity of the oxidase and its interaction with CO and H2O2 but suppressed the proton pumping activity of the enzyme. These results show that the K304 residue, which is invariantly conserved (as K or R) in practically all the sequences of the heme-copper oxidases so far available (around 100), is essential for the proton pumping activity of the oxidase.