SYMPTOMATOLOGY AND TREATMENT OF COVID-19 AFFECTING SKIN APPENDAGES: A NARRATIVE REVIEW BEYOND COVID-TOES

SARS-CoV-2 is the cause of COVID-19 disease and responsible for a pandemic since the 2020. Multiple organ involvement has been described including cutaneous symptoms. Affection of skin appendages, however, seems to be under-reported except for COVID-toes. We performed a PUBMED research for "COVID-19" OR "SARS-CoV-2" AND "skin appendages", "hair", "nails", and "skin glands" from January 2020 to April 2022. COVID toes were excluded since this symptom had extensively been discussed. The focus of this narrative review was laid on clinical presentation, association to the course of COVID-19 disease and treatment options. Skin appendages can be affected by COVID-19 disease beyond COVID-toes, both by symptomatic and asymptomatic course. Telogen effluvium, androgenetic alopecia, and alopecia areata are the most common hair disorders in COVID-19 patients. Nails are less commonly affected by COVID-19 than hair. Splinter hemorrhages and leukonychia are the most frequent findings. While sebaceous glands seem to be uninvolved, SARS-CoV-2 spike proteins have been identified in eccrine sweat glands. Alopecia areata is often seen among asymptomatic COVID-19 patients while telogen effluvium is observed in symptomatic and asymptomatic patients. The half-moon sign on the nails could be a red flag for a more severe course of COVID-19. Treatment options are summarized. Skin appendages are not spared by COVID-19. Their knowledge will help to identify asymptomatic patients and patients at risk for a more severe course of the viral disease.

Children with psoriasis and COVID-19: factors associated with an unfavourable COVID-19 course, and the impact of infection on disease progression (Chi-PsoCov registry)

BACKGROUND

The COVID-19 pandemic has raised questions regarding the management of chronic skin diseases, especially in patients on systemic treatments. Data concerning the use of biologics in adults with psoriasis are reassuring, but data specific to children are missing. Moreover, COVID-19 could impact the course of psoriasis in children.

OBJECTIVES

The aim of this study was therefore to assess the impact of COVID-19 on the psoriasis of children, and the severity of the infection in relation to systemic treatments.

METHODS

We set up an international registry of paediatric psoriasis patients. Children were included if they were under 18 years of age, had a history of psoriasis, or developed it within 1 month of COVID-19 and had COVID-19 with or without symptoms.

RESULTS

One hundred and twenty episodes of COVID-19 in 117 children (mean age: 12.4 years) were reported. The main clinical form of psoriasis was plaque type (69.4%). Most children were without systemic treatment (54.2%); 33 (28.3%) were on biologic therapies, and 24 (20%) on non-biologic systemic drugs. COVID-19 was confirmed in 106 children (88.3%) and 3 children had two COVID-19 infections each. COVID-19 was symptomatic for 75 children (62.5%) with a mean duration of 6.5 days, significantly longer for children on non-biologic systemic treatments (P = 0.02) and without systemic treatment (P = 0.006) when compared with children on biologics. The six children who required hospitalization were more frequently under non-biologic systemic treatment when compared with the other children (P = 0.01), and particularly under methotrexate (P = 0.03). After COVID-19, the psoriasis worsened in 17 cases (15.2%). Nine children (8%) developed a psoriasis in the month following COVID-19, mainly a guttate form (P = 0.01).

DISCUSSION

Biologics appear to be safe with no increased risk of severe form of COVID-19 in children with psoriasis. COVID-19 was responsible for the development of psoriasis or the worsening of a known psoriasis for some children.

Partial Ribosomal Nontranscribed Spacer Sequences Distinguish Rhagoletis zephyria (Diptera: Tephritidae) From the Apple Maggot, R. pomonella

The apple maggot, Rhagoletis pomonella (Walsh), was introduced into the apple-growing regions of the Pacific Northwest in the U.S.A. during the past 60-100 yr. Apple maggot (larvae, puparia, and adults) is difficult to distinguish from its morphologically similar sister species, Rhagoletis zephyria Snow, which is native and abundant in the Pacific Northwest. While morphological identifications are common practice, a simple, inexpensive assay based on genetic differences would be very useful when morphological traits are unclear. Here we report nucleotide substitution and insertion-deletion mutations in the nontranscribed spacer (NTS) of the ribosomal RNA gene cistron of R. pomonella and R. zephyria that appear to be diagnostic for these two fly species. Insertion-deletion variation is substantial and results in a 49 base-pair difference in PCR amplicon size between R. zephyria and R. pomonella that can be scored using agarose gel electrophoresis. PCR amplification and DNA sequencing of 766 bp of the NTS region from 38 R. pomonella individuals and 35 R. zephyria individuals from across their geographic ranges led to the expected PCR fragments of approx. 840 bp and 790 bp, respectively, as did amplification and sequencing of a smaller set of 26 R. pomonella and 16 R. zephyria flies from a sympatric site in Washington State. Conversely, 633 bp mitochondrial COI barcode sequences from this set of flies were polyphyletic with respect to R. pomonella and R. zephyria. Thus, differences in NTS PCR products on agarose gels potentially provide a simple way to distinguish between R. pomonella and R. zephyria.

Electron-transport-driven proton pumps display nonhyperbolic kinetics: Simulation of the steady-state kinetics of cytochrome c oxidase

A reaction cycle for electron-transportdriven proton pumps is proposed. It includes two distinct conformational states of the pump protein in which the primary electron acceptor has different reduction potentials. This has as an unavoidable consequence that the steady-state rate equation for the catalytic reaction driving the pump is nonhyperbolic. The model can be used to simulate experimental results for the kinetics of cytochrome oxidase (EC 1.9.3.1) in a wide range of experimental conditions (ionic strength, pH, temperature). It is thus not necessary to invoke more than one binding site for cytochrome c to account for the biphasic response of the oxidase activity to the concentration of this substrate.

Ligand binding and the catalytic reaction of cytochrome caa(3) from the thermophilic bacterium Rhodothermus marinus

The ligand-binding dynamics and the reaction with O(2) of the fully (five-electron) reduced cytochrome caa(3) from the thermohalophilic bacterium Rhodothermus (R.) marinus were investigated. The enzyme is a proton pump which has all the residues of the proton-transfer pathways found in the mitochondrial-like enzymes conserved, except for one of the key elements of the D-pathway, the helix-VI glutamate [Glu(I-286), R. sphaeroides numbering]. In contrast to what has been suggested previously as general characteristics of thermophilic enzymes, during formation of the R. marinus caa(3)-CO complex, CO binds weakly to Cu(B), and is rapidly (k(Ba) = 450 s(-1)) trapped by irreversible (K(Ba) = 4.5 x 10(3)) binding to heme a(3). Upon reaction of the fully reduced enzyme with O(2), four kinetic phases were resolved during the first 10 ms after initiation of the reaction. On the basis of a comparison to reactions observed with the bovine enzyme, these phases were attributed to the following transitions between intermediates (pH 7.8, 1 mM O(2)): R --> A (tau congruent with 8 micros), A --> P(r) (tau congruent with 35 micros), P(r) --> F (tau congruent with 240 micros), F --> O (tau congruent with 2.5 ms), where the last two phases were associated with proton uptake from the bulk solution. Oxidation of heme c was observed only during the last two reaction steps. The slower transition times as compared to those observed with the bovine enzyme most likely reflect the replacement of Glu(I-286) of the helix-VI motif -XGHPEV- by a tyrosine in the R. marinus enzyme in the motif -YSHPXV-. The presence of an additional, fifth electron in the enzyme was reflected by two additional kinetic phases with time constants of approximately 20 and approximately 720 ms during which the fifth electron reequilibrated within the enzyme.

Photochemically induced electron transfer

Biochemical reactions involving electron transfer between substrates or enzyme cofactors are both common and physiologically important; they have been studied by means of a variety of techniques. In this paper we review the application of photochemical methods to the study of intramolecular electron transfer in hemoproteins, thus selecting a small, well-defined sector of this otherwise enormous field. Photoexcitation of the heme populates short-lived excited states which decay by thermal conversion and do not usually transfer electrons, even when a suitable electron acceptor is readily available, e.g., in the form of a second oxidized heme group in the same protein; because of this, the experimental setup demands some manipulation of the hemoprotein. In this paper we review three approaches that have been studied in detail: (i) the covalent conjugation to the protein moiety of an organic ruthenium complex, which serves as the photoexcitable electron donor (in this case the heme acts as the electron acceptor); (ii) the replacement of the heme group with a phosphorescent metal-substituted porphyrin, which on photoexcitation populates long-lived excited states, capable of acting as electron donors (clearly the protein must contain some other cofactor acting as the electron acceptor, most often a second heme group in the oxidized state); (iii) the combination of the reduced heme with CO (the photochemical breakdown of the iron-CO bond yields transiently the ground-state reduced heme which is able to transfer one electron (or a fraction of it) to an oxidized electron acceptor in the protein; this method uses a "mixed-valence hybrid" state of the redox active hemoprotein and has the great advantage of populating on photoexcitation an electron donor at physiological redox potential).

On the role of the K-proton transfer pathway in cytochrome c oxidase

Cytochrome c oxidase is a membrane-bound enzyme that catalyzes the four-electron reduction of oxygen to water. This highly exergonic reaction drives proton pumping across the membrane. One of the key questions associated with the function of cytochrome c oxidase is how the transfer of electrons and protons is coupled and how proton transfer is controlled by the enzyme. In this study we focus on the function of one of the proton transfer pathways of the R. sphaeroides enzyme, the so-called K-proton transfer pathway (containing a highly conserved Lys(I-362) residue), leading from the protein surface to the catalytic site. We have investigated the kinetics of the reaction of the reduced enzyme with oxygen in mutants of the enzyme in which a residue [Ser(I-299)] near the entry point of the pathway was modified with the use of site-directed mutagenesis. The results show that during the initial steps of oxygen reduction, electron transfer to the catalytic site (to form the "peroxy" state, P(r)) requires charge compensation through the proton pathway, but no proton uptake from the bulk solution. The charge compensation is proposed to involve a movement of the K(I-362) side chain toward the binuclear center. Thus, in contrast to what has been assumed previously, the results indicate that the K-pathway is used during oxygen reduction and that K(I-362) is charged at pH approximately 7.5. The movement of the Lys is proposed to regulate proton transfer by "shutting off" the protonic connectivity through the K-pathway after initiation of the O(2) reduction chemistry. This "shutoff" prevents a short-circuit of the proton-pumping machinery of the enzyme during the subsequent reaction steps.

Zinc ions inhibit oxidation of cytochrome c oxidase by oxygen

Cytochrome c oxidase is a membrane-bound enzyme that catalyses the reduction of O2 to H2O and uses part of the energy released in this reaction to pump protons across the membrane. We have investigated the effect of addition of Zn2+ on the kinetics of two reaction steps in cytochrome c oxidase that are associated with proton pumping; the peroxy to oxo-ferryl (P(r)-->F) and the oxo-ferryl to oxidised (F-->O) transitions. The Zn2+ binding resulted in a decrease of the F-->O rate from 820 s(-1) (no Zn2+) to a saturating value of approximately 360 s(-1) with an apparent K(D) of approximately 2.6 microM. The P(r)-->F rate (approximately 10[(4) s(-1)] before addition of Zn2+) decreased more slowly with increasing Zn2+ concentration and a K(D) of approximately 120 microM was observed. The effects on both kinetic phases were fully reversible upon addition of EDTA. Since both the P(r)-->F and F-->O transitions are associated with proton uptake through the D-pathway, a Zn2+-binding site is likely to be located at the entry point of this pathway, where several carboxylates and histidine residues are found that may co-ordinate Zn2+.

Kinetics of electron and proton transfer during O(2) reduction in cytochrome aa(3) from A. ambivalens: an enzyme lacking Glu(I-286)

Acidianus ambivalens is a hyperthermoacidophilic archaeon which grows optimally at approximately 80 degrees C and pH 2.5. The terminal oxidase of its respiratory system is a membrane-bound quinol oxidase (cytochrome aa(3)) which belongs to the heme-copper oxidase superfamily. One difference between this quinol oxidase and a majority of the other members of this family is that it lacks the highly-conserved glutamate (Glu(I-286), E. coli ubiquinol oxidase numbering) which has been shown to play a central role in controlling the proton transfer during reaction of reduced oxidases with oxygen. In this study we have investigated the dynamics of the reaction of the reduced A. ambivalens quinol oxidase with O(2). With the purified enzyme, two kinetic phases were observed with rate constants of 1.8&z.ccirf;10(4) s(-1) (at 1 mM O(2), pH 7.8) and 3. 7x10(3) s(-1), respectively. The first phase is attributed to binding of O(2) to heme a(3) and oxidation of both hemes forming the 'peroxy' intermediate. The second phase was associated with proton uptake from solution and it is attributed to formation of the 'oxo-ferryl' state, the final state in the absence of quinol. In the presence of bound caldariella quinol (QH(2)), heme a was re-reduced by QH(2) with a rate of 670 s(-1), followed by transfer of the fourth electron to the binuclear center with a rate of 50 s(-1). Thus, the results indicate that the quinol donates electrons to heme a, followed by intramolecular transfer to the binuclear center. Moreover, the overall electron and proton-transfer kinetics in the A. ambivalens quinol oxidase are the same as those in the E. coli ubiquinol oxidase, which indicates that in the A. ambivalens enzyme a different pathway is used for proton transfer to the binuclear center and/or other protonatable groups in an equivalent pathway are involved. Potential candidates in that pathway are two glutamates at positions (I-80) and (I-83) in the A. ambivalens enzyme (corresponding to Met(I-116) and Val(I-119), respectively, in E. coli cytochrome bo(3)).

Redesign of the proton-pumping machinery of cytochrome c oxidase: proton pumping does not require Glu(I-286)

One of the putative proton-transfer pathways leading from solution toward the binuclear center in many cytochrome c oxidases is the D-pathway, so-called because it starts with a highly conserved aspartate [D(I-132)] residue. Another highly conserved amino acid residue in this pathway, glutamate(I-286), has been indicated to play a central role in the proton-pumping machinery of mitochondrial-type enzymes, a role that requires a movement of the side chain between two distinct positions. In the present work we have relocated the glutamate to the opposite side of the proton-transfer pathway by constructing the double mutant EA(I-286)/IE(I-112). This places the side chain in about the same position in space as in the original enzyme, but does not allow for the same type of movement. The results show that the introduction of the second-site mutation, IE(I-112), in the EA(I-286) mutant enzyme results in an increase of the enzyme activity by a factor of >10. In addition, the double mutant enzyme pumps approximately 0.4 proton per electron. This observation restricts the number of possible mechanisms for the operation of the redox-driven proton pump. The proton-pumping machinery evidently does require the presence of a protonatable/polar residue at a specific location in space, presumably to stabilize an intact water chain. However, this residue does not necessarily have to be at a strictly conserved location in the amino acid sequence. In addition, the results indicate that E(I-286) is not the "proton gate" of cytochrome c oxidase controlling the flow of pumped protons from one to the other side of the membrane.

Formation of the "peroxy" intermediate in cytochrome c oxidase is associated with internal proton/hydrogen transfer

When dioxygen is reduced to water by cytochrome c oxidase a sequence of oxygen intermediates are formed at the reaction site. One of these intermediates is called the "peroxy" (P) intermediate. It can be formed by reacting the two-electron reduced (mixed-valence) cytochrome c oxidase with dioxygen (called P(m)), but it is also formed transiently during the reaction of the fully reduced enzyme with oxygen (called P(r)). In recent years, evidence has accumulated to suggest that the O-O bond is cleaved in the P intermediate and that the heme a(3) iron is in the oxo-ferryl state. In this study, we have investigated the kinetic and thermodynamic parameters for formation of P(m) and P(r), respectively, in the Rhodobacter sphaeroides enzyme. The rate constants and activation energies for the formation of the P(r) and P(m) intermediates were 1.4 x 10(4) s(-1) ( approximately 20 kJ/mol) and 3 x 10(3) s(-1) ( approximately 24 kJ/mol), respectively. The formation rates of both P intermediates were independent of pH in the range 6.5-9, and there was no proton uptake from solution during P formation. Nevertheless, formation of both P(m) and P(r) were slowed by a factor of 1.4-1.9 in D(2)O, which suggests that transfer of an internal proton or hydrogen atom is involved in the rate-limiting step of P formation. We discuss the origin of the difference in the formation rates of the P(m) and P(r) intermediates, the formation mechanisms of P(m)/P(r), and the involvement of these intermediates in proton pumping.

Proton-coupled structural changes upon binding of carbon monoxide to cytochrome cd1: a combined flash photolysis and X-ray crystallography study

We have investigated dynamic events after flash photolysis of CO from reduced cytochrome cd(1) nitrite reductase (NiR) from Paracoccus pantotrophus (formerly Thiosphaera pantotropha). Upon pulsed illumination of the cytochrome cd(1)-CO complex, at 460 nm, a rapid (<50 ns) absorbance change, attributed to dissociation of CO, was observed. This was followed by a biphasic rearrangement with rate constants of 1.7 x 10(4) and 2.5 x 10(3) s(-1) at pH 8.0. Both parts of the biphasic rearrangement phases displayed the same kinetic difference spectrum in the region of 400-660 nm. The slower of the two processes was accompanied by proton uptake from solution (0.5 proton per active site at pH 7.5-8.5). After photodissociation, the CO ligand recombined at a rate of 12 s(-1) (at 1 mM CO and pH 8.0), accompanied by proton release. The crystal structure of reduced cytochrome cd(1) in complex with CO was determined to a resolution of 1.57 A. The structure shows that CO binds to the iron of the d(1) heme in the active site. The ligation of the c heme is unchanged in the complex. A comparison of the structures of the reduced, unligated NiR and the NiR-CO complex indicates changes in the puckering of the d(1) heme as well as rearrangements in the hydrogen-bonding network and solvent organization in the substrate binding pocket at the d(1) heme. Since the CO ligand binds to heme d(1) and there are structural changes in the d(1) pocket upon CO binding, it is likely that the proton uptake or release observed after flash-induced CO dissociation is due to changes of the protonation state of groups in the active site. Such proton-coupled structural changes associated with ligand binding are likely to affect the redox potential of heme d(1) and may regulate the internal electron transfer from heme c to heme d(1).

Proton transfer from glutamate 286 determines the transition rates between oxygen intermediates in cytochrome c oxidase

We have investigated the electron-proton coupling during the peroxy (P(R)) to oxo-ferryl (F) and F to oxidised (O) transitions in cytochrome c oxidase from Rhodobacter sphaeroides. The kinetics of these reactions were investigated in two different mutant enzymes: (1) ED(I-286), in which one of the key residues in the D-pathway, E(I-286), was replaced by an aspartate which has a shorter side chain than that of the glutamate and, (2) ML(II-263), in which the redox potential of Cu(A) is increased by approximately 100 mV, which slows electron transfer to the binuclear centre during the F-->O transition by a factor of approximately 200. In ED(I-286) proton uptake during P(R)-->F was slowed by a factor of approximately 5, which indicates that E(I-286) is the proton donor to P(R). In addition, in the mutant enzyme the F-->O transition rate displayed a deuterium isotope effect of approximately 2.5 as compared with approximately 7 in the wild-type enzyme. Since the entire deuterium isotope effect was shown to be associated with a single proton-transfer reaction in which the proton donor and acceptor must approach each other (M. Karpefors, P. Adelroth, P. Brzezinski, Biochemistry 39 (2000) 6850), the smaller deuterium isotope effect in ED(I-286) indicates that proton transfer from E(I-286) determines the rate also of the F-->O transition. In ML(II-263) the electron-transfer to the binuclear centre is slower than the intrinsic proton-transfer rate through the D-pathway. Nevertheless, both electron and proton transfer to the binuclear centre displayed a deuterium isotope effect of approximately 8, i.e., about the same as in the wild-type enzyme, which shows that these reactions are intimately coupled.

Localized control of proton transfer through the D-pathway in cytochrome c oxidase: application of the proton-inventory technique

In the reaction cycle of cytochrome c oxidase from Rhodobacter sphaeroides, one of the steps that are coupled to proton pumping, the oxo-ferryl-to-oxidized transition (F --> O), displays a large kinetic deuterium isotope effect of about 7. In this study we have investigated in detail the dependence of the kinetics of this reaction step ¿k(FO)(chi) on the fraction (chi) D(2)O in the enzyme solution (proton-inventory technique). According to a simplified version of the Gross-Butler equation, from the shape of the graph describing k(FO)(chi)/k(FO)(0), conclusions can be drawn concerning the number of protonatable sites involved in the rate-limiting proton-transfer reaction step. Even though the proton-transfer reaction during the F --> O transition takes place over a distance of at least 30 A and involves a large number of protonatable sites, the proton-inventory analysis displayed a linear dependence, which indicates that the entire deuterium isotope effect of 7 is associated with a single protonatable site. On the basis of experiments with site-directed mutants of cytochrome c oxidase, this localized proton-transfer rate control is proposed to be associated with glutamate (I-286) in the D-pathway. Consequently, the results indicate that proton transfer from the glutamate controls the rate of all events during the F --> O reaction step. The proton-inventory analysis of the overall enzyme turnover reveals a nonlinear plot characteristic of at least two protonatable sites involved in the rate-limiting step in the transition state, which indicates that this step does not involve proton transfer through the same pathway (or through the same mechanism) as during the F --> O transition.

The onset of the deuterium isotope effect in cytochrome c oxidase

We have investigated the dynamics of proton equilibration within the proton-transfer pathway of cytochrome c oxidase from bovine heart that is used for the transfer of both substrate and pumped protons during reaction of the reduced enzyme with oxygen (D-pathway). The kinetics of the slowest phase in the oxidation of the enzyme (the oxo-ferryl --> oxidized transition, F --> O), which is associated with proton uptake, were studied by monitoring absorbance changes at 445 nm. The rate constant of this transition, which is 800 s(-)(1) in H(2)O (at pH approximately 7.5), displayed a kinetic deuterium isotope effect of approximately 4 (i.e., the rate was approximately 200 s(-)(1) in 100% D(2)O). To investigate the kinetics of the onset of the deuterium isotope effect, fully reduced, solubilized CO-bound cytochrome c oxidase in H(2)O was mixed rapidly at a ratio of 1:5 with a D(2)O buffer saturated with oxygen. After a well-defined time period, CO was flashed off using a short laser flash. The time between mixing and flashing off CO was varied within the range 0. 04-10 s. The results show that for the bovine enzyme, the onset of the deuterium isotope effect takes place within two time windows of </=100 ms and approximately 1 s, respectively. The slow onset of the deuterium isotope effect indicates that the rate-limiting step during the F --> O transition is internal proton transfer from a site, proposed to be Glu (I-286) (R. sphaeroides amino acid residue numbering), to the binuclear center. The spontaneous equilibration of protons/deuterons with this site in the interior of the protein is slow (approximately 1 s).

Examination of the reaction of fully reduced cytochrome oxidase with hydrogen peroxide by flow-flash spectroscopy

The reaction of cytochrome c oxidase with hydrogen peroxide has been of great value in generating and characterizing oxygenated species of the enzyme that are identical or similar to those formed during turnover of the enzyme with dioxygen. Most previous studies have utilized relatively low peroxide concentrations (millimolar range). In the current work, these studies have been extended to the examination of the kinetics of the single turnover of the fully reduced enzyme using much higher concentrations of peroxide to avoid limitations by the bimolecular reaction. The flow-flash method is used, in which laser photolysis of the CO adduct of the fully reduced enzyme initiates the reaction following rapid mixing of the enzyme with peroxide, and the reaction is monitored by observing the absorbance changes due to the heme components of the enzyme. The following reaction sequence is deduced from the data. (1) The initial product of the reaction appears to be heme a(3) oxoferryl (Fe(4+)=O(2)(-) + H(2)O). Since the conversion of ferrous to ferryl heme a(3) (Fe(2+) to Fe(4+)) is sufficient for this reaction, presumably Cu(B) remains reduced in the product, along with Cu(A) and heme a. (2) The second phase of the reaction is an internal rearrangement of electrons and protons in which the heme a(3) oxoferryl is reduced to ferric hydroxide (Fe(3+)OH(-)). In about 40% of the population, the electron comes from heme a, and in the remaining 60% of the population, Cu(B) is oxidized. This step has a time constant of about 65 micros. (3) The third apparent phase of the reaction includes two parallel reactions. The population of the enzyme with an electron in the binuclear center reacts with a second molecule of peroxide, forming compound F. The population of the enzyme with the two electrons on heme a and Cu(A) must first transfer an electron to the binuclear center, followed by reaction with a second molecule of peroxide, also yielding compound F. In each of these reaction pathways, the reaction time is 100-200 micros, i.e., much faster than the rate of reaction of peroxide with the fully oxidized enzyme. Thus, hydrogen peroxide is an efficient trap for a single electron in the binuclear center. (4) Compound F is then reduced by the final available electron, again from heme a, at the same rate as observed for the reduction of compound F formed during the reaction of the fully reduced oxidase with dioxygen. The product is the fully oxidized enzyme (heme a(3) Fe(3+)OH(-)), which reacts with a third molecule of hydrogen peroxide, forming compound P. The rate of this final reaction step saturates at high concentrations of peroxide (V(max) = 250 s(-)(1), K(m) = 350 mM). The data indicate a reaction mechanism for the steady-state peroxidase activity of the enzyme which, at pH 7.5, proceeds via the single-electron reduction of the binuclear center followed by reaction with peroxide to form compound F directly, without forming compound P. Peroxide is an efficient trap for the one-electron-reduced state of the binuclear center. The results also suggest that the reaction of hydrogen peroxide to the fully oxidized enzyme may be limited by the presence of hydroxide associated with the heme a(3) ferric species. The reaction of hydrogen peroxide with heme a(3) is very substantially accelerated by the availability of an electron on heme a, which is presumably transferred to the binuclear center concomitant with a proton that can convert the hydroxide to water, which is readily displaced.

Glutamate-89 in subunit II of cytochrome bo3 from Escherichia coli is required for the function of the heme-copper oxidase

Recent electrostatics calculations on the cytochrome c oxidase from Paracoccus denitrificans revealed an unexpected coupling between the redox state of the heme-copper center and the state of protonation of a glutamic acid (E78II) that is 25 A away in subunit II of the oxidase. Examination of more than 300 sequences of the homologous subunit in other heme-copper oxidases shows that this residue is virtually totally conserved and is in a cluster of very highly conserved residues at the "negative" end (bacterial cytoplasm or mitochondrial matrix) of the second transmembrane helix. The functional importance of several residues in this cluster (E89II, W93II, T94II, and P96II) was examined by site-directed mutagenesis of the corresponding region of the cytochrome bo(3) quinol oxidase from Escherichia coli (where E89II is the equivalent of residue E78II of the P. denitrificans oxidase). Substitution of E89II with either alanine or glutamine resulted in reducing the rate of turnover to about 43 or 10% of the wild-type value, respectively, whereas E89D has only about 60% of the activity of the control oxidase. The quinol oxidase activity of the W93V mutant is also reduced to about 30% of that of the wild-type oxidase. Spectroscopic studies with the purified E89A and E89Q mutants indicate no perturbation of the heme-copper center. The data suggest that E89II (E. coli numbering) is critical for the function of the heme copper oxidases. The proximity to K362 suggests that this glutamic acid residue may regulate proton entry or transit through the K-channel. This hypothesis is supported by the finding that the degree of oxidation of the low-spin heme b is greater in the steady state using hydrogen peroxide as an oxidant in place of dioxygen for the E89Q mutant. Thus, it appears that the inhibition resulting from the E89II mutation is due to a block in the reduction of the heme-copper binuclear center, expected for K-channel mutants.

Dynamics of the binuclear center of the quinol oxidase from Acidianus ambivalens

We have investigated the kinetic and thermodynamic properties of carbon monoxide binding to the fully reduced quinol oxidase (cytochrome aa(3)) from the hyperthermophilic archaeon Acidianus ambivalens. After flash photolysis of CO from heme a(3), the complex recombines with an apparent rate constant of approximately 3 s(-1), which is much slower than with the bovine cytochrome c oxidase (approximately 80 s(-1)). Investigation of the CO-recombination rate as a function of the CO concentration shows that the rate saturates at high CO concentrations, which indicates that CO must bind transiently to Cu(B) before binding to heme a(3). With the A. ambivalens enzyme the rate reached 50% of its maximum level (which reflects the dissociation constant of the Cu(B)(CO) complex) at approximately 13 microM CO, which is a concentration approximately 10(3) times smaller than for the bovine enzyme (approximately 11 mM). After CO dissociation we observed a rapid absorbance relaxation with a rate constant of approximately 1.4 x 10(4) s(-1), tentatively ascribed to a heme-pocket relaxation associated with release of CO after transient binding to Cu(B). The equilibrium constant for CO transfer from Cu(B) to heme a(3) was approximately 10(4) times smaller for the A. ambivalens than for the bovine enzyme. The approximately 10(3) times smaller Cu(B)(CO) dissociation constant, in combination with the approximately 10(4) times smaller equilibrium constant for the internal CO transfer, results in an apparent dissociation constant of the heme a(3)(CO) complex which is "only" about 10 times larger for the A. ambivalens ( approximately 4 x 10(-3) mM) than for the bovine (0.3 x 10(-3) mM) enzyme. In summary, the results show that while the basic mechanism of CO binding to the binuclear center is similar in the A. ambivalens and bovine (and R. sphaeroides) enzymes, the heme-pocket dynamics of the two enzymes are dramatically different, which is discussed in terms of the different structural details of the A. ambivalens quinol oxidase and adaptation to different living conditions.

Internal electron transfer and structural dynamics of cd1 nitrite reductase revealed by laser CO photodissociation

Laser photolysis techniques have been employed to investigate the internal electron transfer (eT) reaction within Pseudomonas aeruginosa nitrite reductase (Pa-NiR). We have measured the (d1--> c) internal eT rate for the wild-type protein and a site-directed mutant (Pa-NiR H327A) which has a substitution in the d1-heme binding pocket; we found the rate of eT to be fast, keT = 2.5 x 10(4) and 3.5 x 10(4) s-1 for the wild-type and mutant Pa-NiR, respectively. We also investigated the photodissociation of CO from the fully reduced proteins and observed microsecond first-order relaxations; these imply that upon breakage of the Fe2+-CO bond, both Pa-NiR and Pa-NiR H327A populate a nonequilibrium state which decays to the ground state with a complex time course that may be described by two exponential processes (k1 = 3 x 10(4) s-1 and k2 = 0.25 x 10(4) s-1). These relaxations do not have a kinetic difference spectrum characteristic of CO recombination, and therefore we conclude that Pa-NiR undergoes structural rearrangements upon dissociation of CO. The bimolecular rate of CO rebinding is 5 times faster in Pa-NiR H327A than in the wild-type enzyme (1.1 x 10(5) M-1 s-1 compared to 2 x 10(4) M-1 s-1), indicating that this mutation in the active site alters the CO diffusion properties of the protein, probably reducing steric hindrance. CO rebinding to the wild-type mixed valence enzyme (c3+d12+) which is very slow (k = 0.25 s-1) is proposed to be rate-limited by the c --> d1 internal eT event, involving the oxidized d1-heme which has a structure characteristic of the fully oxidized and partially oxidized Pa-NiR.

Aspartate-132 in cytochrome c oxidase from Rhodobacter sphaeroides is involved in a two-step proton transfer during oxo-ferryl formation

The aspartate-132 in subunit I (D(I-132)) of cytochrome c oxidase from Rhodobacter sphaeroides is located on the cytoplasmic surface of the protein at the entry point of a proton-transfer pathway used for both substrate and pumped protons (D-pathway). Replacement of D(I-132) by its nonprotonatable analogue asparagine (DN(I-132)) has been shown to result in a reduced overall activity of the enzyme and impaired proton pumping. The results from this study show that during oxidation of the fully reduced enzyme the reaction was inhibited after formation of the oxo-ferryl (F) intermediate (tau congruent with 120 microseconds). In contrast to the wild-type enzyme, in the mutant enzyme formation of this intermediate was not associated with proton uptake from solution, which is the reason the DN(I-132) enzyme does not pump protons. The proton needed to form F was presumably taken from a protonatable group in the D-pathway (e.g., E(I-286)), which indicates that in the wild-type enzyme the proton transfer during F formation takes place in two steps: proton transfer from the group in the pathway is followed by faster reprotonation from the bulk solution, through D(I-132). Unlike the wild-type enzyme, in which F formation is coupled to internal electron transfer from CuA to heme a, in the DN(I-132) enzyme this electron transfer was uncoupled from formation of the F intermediate, which presumably is due to the impaired charge-compensating proton uptake from solution. In the presence of arachidonic acid which has been shown to stimulate the turnover activity of the DN(I-132) enzyme (Fetter et al. (1996) FEBS Lett. 393, 155), proton uptake with a time constant of approximately 2 ms was observed. However, no proton uptake associated with formation of F (tau congruent with 120 micros) was observed, which indicates that arachidonic acid can replace the role of D(I-132), but it cannot transfer protons as fast as the Asp. The results from this study show that D(I-132) is crucial for efficient transfer of protons into the enzyme and that in the DN(I-132) mutant enzyme there is a "kinetic barrier" for proton transfer into the D-pathway.

Observation of a novel transient ferryl complex with reduced CuB in cytochrome c oxidase

The reaction between mixed-valence (MV) cytochrome c oxidase from beef heart with H2O2 was investigated using the flow-flash technique with a high concentration of H2O2 (1 M) to ensure a fast bimolecular interaction with the enzyme. Under anaerobic conditions the reaction exhibits 3 apparent phases. The first phase (tau congruent with 25 micros) results from the binding of one molecule of H2O2 to reduced heme a3 and the formation of an intermediate which is heme a3 oxoferryl (Fe4+=O2-) with reduced CuB (plus water). During the second phase (tau congruent with 90 micros), the electron transfer from CuB+ to the heme oxoferryl takes place, yielding the oxidized form of cytochrome oxidase (heme a3 Fe3+ and CuB2+, plus hydroxide). During the third phase (tau congruent with 4 ms), an additional molecule of H2O2 binds to the oxidized form of the enzyme and forms compound P, similar to the product observed upon the reaction of the mixed-valence (i.e., two-electron reduced) form of the enzyme with dioxygen. Thus, within about 30 ms the reaction of the mixed-valence form of the enzyme with H2O2 yields the same compound P as does the reaction with dioxygen, as indicated by the final absorbance at 436 nm, which is the same in both cases. This experimental approach allows the investigation of the form of cytochrome c oxidase which has the heme a3 oxoferryl intermediate but with reduced CuB. This state of the enzyme cannot be obtained from the reaction with dioxygen and is potentially useful to address questions concerning the role of the redox state in CuB in the proton pumping mechanism.

Measurements Using the Quartz Crystal Microbalance Technique of Ferritin Monolayers on Methyl-Thiolated Gold: Dependence of Energy Dissipation and Saturation Coverage on Salt Concentration

The adsorption kinetics of ferritin as a function of ionic strength has been studied with a new quartz crystal microbalance technique, allowing simultaneous measurement of the frequency shift (proportional to the mass uptake under certain conditions) and of changes in the energy dissipation caused by the adlayer. The measurements were performed with methyl-terminated (hydrophobic) thiol-covered gold surfaces, at pH 7.0 and ionic strengths in the range 1-200 mM KCl. The saturation uptake increases rapidly with increasing ionic strength in the range 20-50 mM and is then independent of ionic strength at >100 mM. The dissipation factor reveals, in the low coverage regime, distinct differences in the adlayer properties at low and high ionic strength, respectively. These results are briefly discussed in terms of the screening properties of the solvent and its influence on the protein-protein interaction in solution and on the surface. Copyright 1998 Academic Press.

Proton uptake controls electron transfer in cytochrome c oxidase

In cytochrome c oxidase, a requirement for proton pumping is a tight coupling between electron and proton transfer, which could be accomplished if internal electron-transfer rates were controlled by uptake of protons. During reaction of the fully reduced enzyme with oxygen, concomitant with the "peroxy" to "oxoferryl" transition, internal transfer of the fourth electron from CuA to heme a has the same rate as proton uptake from the bulk solution (8,000 s-1). The question was therefore raised whether the proton uptake controls electron transfer or vice versa. To resolve this question, we have studied a site-specific mutant of the Rhodobacter sphaeroides enzyme in which methionine 263 (SU II), a CuA ligand, was replaced by leucine, which resulted in an increased redox potential of CuA. During reaction of the reduced mutant enzyme with O2, a proton was taken up at the same rate as in the wild-type enzyme (8,000 s-1), whereas electron transfer from CuA to heme a was impaired. Together with results from studies of the EQ(I-286) mutant enzyme, in which both proton uptake and electron transfer from CuA to heme a were blocked, the results from this study show that the CuA --> heme a electron transfer is controlled by the proton uptake and not vice versa. This mechanism prevents further electron transfer to heme a3-CuB before a proton is taken up, which assures a tight coupling of electron transfer to proton pumping.

Structural changes in hemoglobin during adsorption to solid surfaces: effects of pH, ionic strength, and ligand binding

We have studied the adsorption of two structurally similar forms of hemoglobin (met-Hb and HbCO) to a hydrophobic self-assembled methyl-terminated thiol monolayer on a gold surface, by using a Quartz Crystal Microbalance (QCM) technique. This technique allows time-resolved simultaneous measurements of changes in frequency (f) (c.f. mass) and energy dissipation (D) (c.f. rigidity/viscoelastic properties) of the QCM during the adsorption process, which makes it possible to investigate the viscoelastic properties of the different protein layers during the adsorption process. Below the isoelectric points of both met-Hb and HbCO, the DeltaD vs. Deltaf graphs displayed two phases with significantly different slopes, which indicates two states of the adsorbed proteins with different visco-elastic properties. The slope of the first phase was smaller than that of the second phase, which indicates that the first phase was associated with binding of a more rigidly attached, presumably denatured protein layer, whereas the second phase was associated with formation of a second layer of more loosely bound proteins. This second layer desorbed, e.g., upon reduction of Fe3+ of adsorbed met-Hb and subsequent binding of carbon monoxide (CO) forming HbCO. Thus, the results suggest that the adsorbed proteins in the second layer were in a native-like state. This information could only be obtained from simultaneous, time-resolved measurements of changes in both D and f, demonstrating that the QCM technique provides unique information about the mechanisms of protein adsorption to solid surfaces.

Factors determining electron-transfer rates in cytochrome c oxidase: investigation of the oxygen reaction in the R. sphaeroides enzyme

We have investigated the kinetics of the single-turnover reaction of fully reduced solubilised cytochrome c oxidase (cytochrome aa3) from Rhodobacter sphaeroides with dioxygen using the flow-flash methodology and compared the results to those obtained with the well-characterised bovine mitochondrial enzyme. The overall reaction sequence was the same in the two enzymes, but the extents and rates of the electron-transfer reactions differed, implying differences in redox potentials, and/or interaction energies between electrons and protons during oxygen reduction. As with the bovine enzyme, the R. sphaeroides enzyme displayed two major kinetic phases of proton uptake with rate constants of approximately 5000 s-1 and approximately 500 s-1 at pH 7.9, concomitant with the peroxy to oxoferryl and oxoferryl to oxidised states. The net number of protons taken up in the R. sphaeroides enzyme was about approximately 1.9, which implies that upon reduction, the enzyme has to pick up approximately 2.1 H+ from the medium. On the basis of the comparison of electron-transfer reactions in the two enzymes, we conclude that the transfer rate of the fourth electron to the binuclear centre is not only determined by the electron-transfer rate from haem a to the binuclear centre, but also by the electron equilibrium between CuA and haem a. In addition, in contrast to the bovine enzyme, where the electron- and proton-transfer rates during oxidation of the fully reduced enzyme by O2 are all faster than the overall turnover rate, in the R. sphaeroides enzyme, the slowest kinetic phase was rate limiting for the overall turnover. Moreover, the comparison of the reactions in the two systems shows that in the R. sphaeroides enzyme, the electrons are more evenly distributed among the redox centres during oxygen reduction. This enables investigations of effects also of minor perturbations on, e.g., the electron-transfer characteristics in mutant enzymes, for which this study forms the basis.

Charge displacements in interfacial layers containing reaction centers

Reaction centers from the photosynthetic bacterium Rhodobacter sphaeroides were oriented in phospholipid interfacial layers adsorbed to a Teflon film separating two electrolyte-filled compartments of a Teflon cell. Light-induced voltage changes were measured as a function of time across electrodes immersed in the cell compartments. The experimental system is characterized both experimentally and theoretically to relate the measured signals to the light-induced displacement currents in the reaction centers. Mathematical relations between the measured signals and the distances and geometries of the charge-transfer reactions are derived. At pH 8.0 the reaction centers were found to be oriented with approximately 60% of the population oriented with the donor facing the aqueous phase. The density of the reaction centers in the layer was approximately 10(11) cm-2, which is close to that found in the native system. Reconstitution of the secondary quinone, QB, in 90% of the RCs was achieved with an approximately 100-fold excess of ubiquinone in the vesicle preparation.

Proton-controlled electron transfer in cytochrome c oxidase: functional role of the pathways through Glu 286 and Lys 362

We have used a combination of site-directed mutagenesis and spectroscopic techniques to investigate electron-transfer reactions between hemes a and a3 in cytochrome c oxidase. A state of the enzyme was prepared in which heme a/CuA are oxidized and heme a3/CuB are reduced with CO bound to heme a3, which stabilizes the reduced state of the binuclear center. In addition, in this state the pKs of protonatable groups in the vicinity of the binuclear center, interacting electrostatically with heme a3, are larger than with oxidized heme a3. Upon flash photolysis of CO from the two-electron reduced enzyme electrons at heme a3 equilibrate rapidly with heme a. In the R. sphaeroides enzyme the electron-transfer rates from heme a to a3 and from heme a3 to a were, deconvoluted and were found to be approximately 1.5.10(5) s-1 and approximately 1.4.10(5) s-1, respectively. After this rapid electron equilibration between hemes a and a3, protons are released from groups interacting electrostatically with heme a3, which is associated with additional electron transfer from heme a3 to heme a. The proton-coupled electron transfer displays a pH dependent extent and rate. In addition, it displays a deuterium-isotope effect of a factor of about three. The reaction sequence is compatible with the three-dimensional cytochrome c oxidase structure, which shows that more protonatable groups are found around heme a3 than around heme a and supports the involvement of the binuclear center in proton pumping. Proton uptake/release upon reduction/oxidation of heme a3 takes place through a proton pathway including residues Thr(I-359) and Lys(I-362) (K-pathway), but not through the pathway including residues Asp(I-132) and Glu(I-286) (D-pathway). During reaction of the reduced enzyme with O2, both substrate and pumped protons are taken up through the D-pathway.

The proton collecting function of the inner surface of cytochrome c oxidase from Rhodobacter sphaeroides

The experiments presented in this study address the problem of how the cytoplasmic surface (proton-input side) of cytochrome c oxidase interacts with protons in the bulk. For this purpose, the cytoplasmic surface of the enzyme was labeled with a fluorescein (Flu) molecule covalently bound to Cys223 of subunit III. Using the Flu as a proton-sensitive marker on the surface and phiOH as a soluble excited-state proton emitter, the dynamics of the acid-base equilibration between the surface and the bulk was measured in the time-resolved domain. The results were analyzed by using a rigorous kinetic analysis that is based on numeric integration of coupled nonliner differential rate equations in which the rate constants are used as adjustable parameters. The analysis of 11 independent measurements, carried out under various initial conditions, indicated that the protonation of the Flu proceeds through multiple pathways involving diffusion-controlled reactions and proton exchange among surface groups. The surface of the protein carries an efficient system made of carboxylate and histidine moieties that are sufficiently close to each other as to form a proton-collecting antenna. It is the passage of protons among these sites that endows cytochrome c oxidase with the capacity to pick up protons from the buffered cytoplasmic matrix within a time frame compatible with the physiological turnover of the enzyme.

Electron-proton interactions in terminal oxidases

The cytochrome c and ubiquinol oxidases discussed in this article are membrane-bound redox-driven proton pumps which couple an electron current to a proton current across the membrane. This coupling requires a control of the thermodynamics and/or rates of internal electron- and proton-transfer reactions (termed 'gating'). Therefore, to understand the structure-function relation of these proton pumps, individual electron- and proton-transfer reactions must be investigated. We have undertaken such studies by using a combination of site-directed mutagenesis and spectroscopic techniques. The results show that proton uptake/release upon reduction/oxidation of heme a3 takes place on a ms-time scale through the K-pathway (including Thr(I-359) and Lys(I-362)), but not through the D-pathway (including Asp(I-132) and Glu(I-286)). During reaction of the reduced enzyme with O2, both substrate and pumped protons are taken up through the D-pathway (but not through the K-pathway) in a biphasic process with time constants of 100 microseconds and 1 ms. Thus, the original assignment of the role of the D-pathway (used only for pumped protons) must be revised. Dynamic studies of proton uptake to the enzyme surface show that on the proton-input side, the surface carries a proton-collecting antenna made of carboxylate and histidine residues which enable the enzyme to pick up protons with a rate compatible to the enzyme turnover rate. These results are consistent with the three-dimensional cytochrome c oxidase structure which shows that the entry point to the D-pathway (but not to the K-pathway) is surrounded by a network of histidine residues within a negative electrostatic potential.

Photoinduced electron transfer from carboxymethylated cytochrome c to plastocyanin

Photoinduced electron transfer from cytochrome c to plastocyanin was investigated using a novel method. Reduced carboxymethylated cytochrome c (CmCyt c), with carbon monoxide bound to the heme iron, and oxidized plastocyanin were mixed. At 1 mM CO the reduced state of CmCyt c is stabilized by about 350 meV. After flash photolysis of CO the apparent redox potential of CmCyt c drops resulting in electron transfer to plastocyanin. The electron transfer characteristics were investigated at approximately 30 different wavelengths in the range 390-460 nm. A global fit of the data showed that the electron transfer rate is 960+/-30 s-1 at pH 7.

Simultaneous frequency and dissipation factor QCM measurements of biomolecular adsorption and cell adhesion

We have measured the energy dissipation of the quartz crystal microbalance (QCM), operating in the liquid phase, when mono- or multi-layers of biomolecules and biofilms form on the QCM electrode (with a time resolution of ca. 1 s). Examples are taken from protein adsorption, lipid vesicle adsorption and cell adhesion studies. Our results show that even very thin (a few nm) biofilms dissipate a significant amount of energy owing to the QCM oscillation. Various mechanisms for this energy dissipation are discussed. Three main contributions to the measured increase in energy dissipation are considered. (i) A viscoelastic porous structure (the biofilm) that is strained during oscillation, (ii) trapped liquid that moves between or in and out of the pores due to the deformation of the film and (iii) the load from the bulk liquid which increases the strain of the film. These mechanisms are, in reality, not entirely separable, rather, they constitute an effective viscoelastic load. The biofilms can therefore not be considered rigidly coupled to the QCM oscillation. It is further shown theoretically that viscoelastic layers with thicknesses comparable to the biofilms studied in this work can induce energy dissipation of the same magnitude as the measured ones.

Role of the pathway through K(I-362) in proton transfer in cytochrome c oxidase from R. sphaeroides

In this study we have combined the use of site-directed mutants with time-resolved optical absorption spectroscopy to investigate the role of the protonatable subunit-I residues lysine-362 (K(I-362)) and threonine-359 (T(I-359)) in cytochrome c oxidase from Rhodobacter sphaeroides in electron and proton transfer. These residues have been proposed to be part of a proton-transfer pathway in cytochrome oxidases from Paracoccus denitrificans and bovine heart. Mutation of K(I-362) and T(I-359) to methionine and alanine, respectively, results in reduction of the overall turnover activities to <2% and approximately 35%, respectively, of those in the wild-type enzyme. The results show that in the absence of dioxygen, electron transfer between hemes a3 and a with a time constant of approximately 3 micros, not coupled to protonation reactions, is not affected in the mutant enzymes. However, the slower electron transfer between hemes a3 and a, coupled to proton release with a time constant of approximately 3 ms (at pH 9.0) is impaired in the KM(I-362) and TA(I-359) mutant enzymes. This is consistent with the slow reduction rate of heme a3 in the oxidized KM(I-362) enzyme because in the wild-type enzyme reduction of heme a3 is coupled to proton uptake. On the other hand, when reacting with O2, both the wild-type and mutant fully reduced enzymes become oxidized in approximately 5 ms, and proton uptake on this time scale is not affected. Hence, the results indicate that the KM(I-362) mutant enzyme is inactive because the proton-transfer pathway through K(I-362) and T(I-359) is involved in proton uptake during reduction of the oxidized binuclear center. Proton uptake during oxidation of the fully reduced enzyme takes place through a different pathway [through E(I-286) (Adelroth, P., et al. (1997) Biochemistry 36, 13824-13829)].

Pathways of proton transfer in cytochrome c oxidase

During the last few years our knowledge of the structure and function of heme copper oxidases has greatly profited from the use of site-directed mutagenesis in combination with biophysical techniques. This, together with the recently-determined crystal structures of cytochrome c oxidase, has now made it possible to design experiments aimed at targeting specific pump mechanisms. Here, we summarize results from our recent kinetic studies of electron and proton-transfer reactions in wild-type and mutant forms of cytochrome c oxidase from Rhodobacter sphaeroides. These studies have made it possible to identify amino acid residues involved in proton transfer during specific reaction steps and provide a basis for discussion of mechanisms of electron and proton transfer in terminal oxidases. The results indicate that the pathway through K(I-362)/T(I-359), but not through D(I-132)/E(I-286), is used for proton transfer to a protonatable group interacting electrostatically with heme a3, i.e., upon reduction of the binuclear center. The pathway through D(I-132)/E(I-286) is used for uptake of pumped and substrate protons during the pumping steps during O2 reduction.

Glutamate 286 in cytochrome aa3 from Rhodobacter sphaeroides is involved in proton uptake during the reaction of the fully-reduced enzyme with dioxygen

The reaction with dioxygen of solubilized fully-reduced wild-type and EQ(I-286) (exchange of glutamate 286 of subunit I for glutamine) mutant cytochrome c oxidase from Rhodobacter sphaeroides has been studied using the flow-flash technique in combination with optical absorption spectroscopy. Proton uptake was measured using a pH-indicator dye. In addition, internal electron-transfer reactions were studied in the absence of oxygen. Glutamate 286 is found in a proton pathway proposed to be used for pumped protons from the crystal structure of cytochrome c oxidase from Paracoccus denitrificans [Iwata et al. (1995) Nature 376, 660-669; E278 in P.d. numbering]. It is the residue closest to the oxygen-binding binuclear center that is clearly a part of the pathway. The results show that the wild-type enzyme becomes fully oxidized in a few milliseconds at pH 7.4 and displays a biphasic proton uptake from the medium. In the EQ(I-286) mutant enzyme, electron transfer after formation of the peroxy intermediate is impaired, CuA remains reduced, and no protons are taken up from the medium. Thus, the results suggest that E(I-286) is necessary for proton uptake after formation of the peroxy intermediate and transfer of the fourth electron to the binuclear center. The results also indicate that the proton uptake associated with formation of the ferryl intermediate controls the electron transfer from CuA to heme a.

Factors determining electron-transfer rates in cytochrome c oxidase: studies of the FQ(I-391) mutant of the Rhodobacter sphaeroides enzyme

The mechanisms of internal electron transfer and oxygen reduction were investigated in cytochrome c oxidase from Rhodobacter sphaeroides (cytochrome aa3) using site-directed mutagenesis in combination with time-resolved optical absorption spectroscopy. Electron-transfer reactions in the absence of O2 were studied after flash photolysis of CO from the partly-reduced enzyme and the reaction of the fully-reduced enzyme with O2 was studied using the so-called flow-flash technique. Results from studies of the wild-type and mutant enzyme in which phenylalanine-391 of subunit I was replaced by glutamine (FQ(I-391)) were compared. The turnover activity of the mutant enzyme was approximately 2% ( approximately 30 s-1) of that of the wild-type enzyme. After flash photolysis of CO from the partly-reduced mutant enzyme approximately 80% of CuA was reduced, which is a much larger fraction than in the wild-type enzyme, and the rate of this electron transfer was 3.2 x 10(3) s-1, which is significantly slower than in the wild-type enzyme. The redox potentials of hemes a and a3 in the mutant enzyme were found to be shifted by about +30 and -70 mV, respectively, as compared to the wild-type enzyme. During the reaction of the fully-reduced FQ(I-391) mutant enzyme with O2 a rapid kinetic phase with a rate constant of 1.2 x 10(5) s-1, presumably associated with O2 binding, was followed by formation of the P intermediate with electrons from heme a3 and CuB with a rate of approximately 4 x 10(3) s-1, and oxidation of the enzyme with a rate of approximately 30 s-1. The dramatically slower electron transfer between the hemes during O2 reduction in the mutant enzyme is not only due to the slower intrinsic electron transfer, but also due to the altered redox potentials. In addition, the results show that the reduced overall activity of the mutant enzyme is due to the slower electron transfer from heme a to the binuclear center during O2 reduction. The relation between the intrinsic heme a/heme a3 electron-transfer rate and equilibrium constant, and the electron-transfer rate from heme a to the binuclear center during O2 reduction is discussed.

Light-induced electrogenic events associated with proton uptake upon forming QB- in bacterial wild-type and mutant reaction centers

Light-induced voltage changes (electrogenic events) were measured in wild-type and site-directed mutants of reaction centers (RCs) from Rhodobacter sphaeroides oriented in a lipid monolayer adsorbed to a Teflon film. A rapid increase in voltage associated with charge separation was followed by a slower increase attributed to proton transfer from solution to protonatable amino-acid residues in the vicinity of the QB site. In native reaction centers the proton-transfer voltage had a pH-dependent amplitude with two peaks at pH 4.5 and pH 9.7, respectively. In the Glu-L212-->Gln RCs the high-pH peak was absent, whereas in the Asp-L213-->Asn RCs the low-pH peak was absent and the high-pH peak was shifted to lower pH by about 1.3 pH units. The amplitudes of the electrogenic phases as a function of pH follow approximately the measured proton uptake from solution (P.H. McPherson, M.Y. Okamura, G. Feher, Biochim. Biophys. Acta, vol. 934, 1988, pp. 348-368) and are ascribed to proton transfer to amino acid residues upon QB- formation. The peak around pH 9.7 is ascribed to proton uptake predominantly by Glu-L212 and the peak around pH 4.5 to proton uptake predominantly by Asp-L213 or a residue strongly interacting with Asp-L213.

Photochemical electron injection into redox-active proteins

A new method is presented that makes it possible to inject electrons rapidly into redox-active proteins by means of a short light flash. Reduced carboxymethylated cytochrome c (CmCyt c) with carbon monoxide bound to the heme iron is mixed with the oxidized acceptor protein. Upon rapid photodissociation of CO the apparent redox potential of CmCyt c drops, resulting in electron transfer to the electron acceptor. In this study we have used mitochondrial cytochrome c oxidase as the acceptor protein, but the method also can be used to investigate electron transfer to other proteins that can interact with cytochrome c. In principle, it can be used with any redox protein into which a CO binding site at the heme iron can be engineered.

Oxidation of ubiquinol by cytochrome bo3 from Escherichia coli: kinetics of electron and proton transfer

In this study we have used the so-called flow-flash technique to investigate electron and proton transfer during the reaction between cytochrome bo3 with bound ubiquinol (QH2) and dioxygen. The results are compared to those from the well-characterized mitochondrial cytochrome alpha alpha3. Qualitatively, the same type of absorbance changes associated with electron transfer were observed in both enzymes whereas the protonation reactions were markedly different. In the bacterial QH2-bound enzyme, three kinetic phases with time constants of approximately 45 micros, approximately 700 micros, and approximately 4 ms associated with electron-transfer reactions were observed. The first phase is attributed to oxidation of hemes b and o3 and formation of the "peroxy" intermediate. The second and third phases were not observed after addition of the herbicide HQNO, which displaces QH2 from its binding site. They are attributed to electron transfer from QH2 to heme b and from heme b to the binuclear center, respectively. In both enzymes, the initial electron transfer was followed by a slower uptake of 0.9 +/- 0.3 proton per enzyme molecule (tau approximately 90 micros), previously attributed to protonation of a group near the binuclear center. Only in the bacterial enzyme, the second electron-transfer reaction was accompanied by a net release of 1.1 +/- 0.3 H+, which is attributed to proton release during oxidation of QH2. It was followed by a slower uptake of 1.2 +/- 0.4 H+ during transfer of the fourth electron to the binuclear center. The two slowest protonation reactions were not observed in the presence of HQNO.

A flash-photolysis study of the reactions of a caa3-type cytochrome oxidase with dioxygen and carbon monoxide

The time course of absorbance changes following flash photolysis of the fully-reduced carboxycytochrome oxidase from Bacillus PS3 in the presence of O2 has been followed at 445, 550, 605, and 830 nm, and the results have been compared with the corresponding changes in bovine cytochrome oxidase. The PS3 enzyme has a covalently bound cytochrome c subunit and the fully-reduced species therefore accommodates five electrons instead of four as in the bovine enzyme. In the bovine enzyme, following CO dissociation, four phases were observed with time constants of about 10 microseconds, 30 microseconds, 100 microseconds, and I ms at 445 nm. The initial, 10-microsecond absorbance change at 445 nm is similar in the two enzymes. The subsequent phases involving heme a and CuA are not seen in the PS3 enzyme at 445 nm, because these redox centers are re-reduced by the covalently bound cytochrome c, as indicated by absorbance changes at 550 nm. A reaction scheme consistent with the experimental observations is presented. In addition, internal electron-transfer reactions in the absence of O2 were studied following flash-induced CO dissociation from the mixed-valence enzyme. Comparisons of the CO recombination rates in the mixed-valence and fully-reduced oxidases indicate that more electrons were transferred from heme a3 to a in PS3 oxidase compared to the bovine enzyme.

Kinetic coupling between electron and proton transfer in cytochrome c oxidase: simultaneous measurements of conductance and absorbance changes

Bovine heart cytochrome c oxidase is an electron-current driven proton pump. To investigate the mechanism by which this pump operates it is important to study individual electron- and proton-transfer reactions in the enzyme, and key reactions in which they are kinetically and thermodynamically coupled. In this work, we have simultaneously measured absorbance changes associated with electron-transfer reactions and conductance changes associated with protonation reactions following pulsed illumination of the photolabile complex of partly reduced bovine cytochrome c oxidase and carbon monoxide. Following CO dissociation, several kinetic phases in the absorbance changes were observed with time constants ranging from approximately 3 microseconds to several milliseconds, reflecting internal electron-transfer reactions within the enzyme. The data show that the rate of one of these electron-transfer reactions, from cytochrome a3 to a on a millisecond time scale, is controlled by a proton-transfer reaction. These results are discussed in terms of a model in which cytochrome a3 interacts electrostatically with a protonatable group, L, in the vicinity of the binuclear center, in equilibrium with the bulk through a proton-conducting pathway, which determines the rate of proton transfer (and indirectly also of electron transfer). The interaction energy of cytochrome a3 with L was determined independently from the pH dependence of the extent of the millisecond-electron transfer and the number of protons released, as determined from the conductance measurements. The magnitude of the interaction energy, 70 meV (1 eV = 1.602 x 10(-19) J), is consistent with a distance of 5-10 A between cytochrome a3 and L. Based on the recently determined high-resolution x-ray structures of bovine and a bacterial cytochrome c oxidase, possible candidates for L and a physiological role for L are discussed.

Kinetics of electron and proton transfer during the reaction of wild type and helix VI mutants of cytochrome bo3 with oxygen

Site-directed mutagenesis was used to investigate the mechanism of electron and proton transfer in the ubiquinol oxidase, cytochrome bo3, from Escherichia coli. The reaction between the fully reduced form of the enzyme and dioxygen was studied using the flow--flash method. After rapid mixing of CO-bound enzyme with an O2-containing solution, CO was photodissociated, and the subsequent electron- and proton-transfer reactions were measured spectrophotometrically, the latter using a pH-indicator dye. In the wild-type, pure bo3 enzyme, without bound quinones, we observed a single kinetic phase with a rate constant of about 2.4 x 10(4) s-1, associated with formation of the ferry1 oxygen intermediate, followed by proton uptake from solution with a rate constant of about 1.2 x 10(4) s-1. Enzyme in which heme o instead of heme b was incorporated into the low-spin site displayed a slower ferry1 formation with a rate constant of about 3.6 x 10(3) s-1. Upon replacement of the acidic residue glutamate 286 in helix VI of subunit I with a nonprotonatable residue, electron transfer was slightly accelerated, and proton uptake was impaired. Mutations of other residues in the vicinity of E286 also resulted in a dramatic decrease of proton uptake, suggesting that the environment of this residue is important for efficient proton transfer. In the closely related cytochrome aa3 from P. denitrificans, the corresponding residue (E278) has been suggested to be part of a proton-transfer pathway [Iwata, S., Ostermeier, C., Ludwig, B., & Michel, H. (1995) Nature 376, 660-669]. The results are discussed in terms of a model for electron-proton coupling during dioxygen reduction.

Electron transfer in zinc-reconstituted nitrite reductase from Pseudomonas aeruginosa

1. The catalytic cycle of the haem-containing nitrite reductase (NIR) from Pseudomonas aeruginosa involves electron transfer between the two prosthetic groups of the enzyme, the c-haem and the d1-haem; this reaction was shown to be slow by stopped-flow analysis. The recombinant enzyme, expressed in Pseudomonas putida, contains the c-haem but no d1-haem; we have reconstituted this protein with Zn-protoporphyrin IX in the place of the d1-haem. 2. Photoexcitation of Zn-NIR is followed by electron transfer from the triplet excited state of the Zn-porphyrin to the oxidized c-haem, with a rate constant of 7 x 10(5) s-1; since the intermediate with reduced c-haem is not significantly populated, we conclude that the back reaction is probably as fast. 3. Even taking into account that in the native NIR the driving force is close to zero, the rate constant for the c-->d1 electron transfer, estimated from our experiments, is still much higher than that observed by stopped flow (k = 0.3 s-1) using reduced azurin as the electron donor. This finding may be a direct kinetic indication that reduction of the d1-haem is associated with a substantial reorganization of the co-ordination of the metal, as shown by spectroscopy of the oxidized and reduced NIR.

Site-directed mutagenesis of residues lining a putative proton transfer pathway in cytochrome c oxidase from Rhodobacter sphaeroides

Several putative proton transfer pathways have been identified in the recent crystal structures of the cytochrome oxidases from Paracoccus denitrificans [Iwata et al. (1995) Nature 376, 660-669] and bovine [Tsukihara (1996) Science 272, 1138-1144]. A series of residues along one face of the amphiphilic transmembrane helix IV lie in one of these proton transfer pathways. The possible role of these residues in proton transfer was examined by site-directed mutagenesis. The three conserved residues of helix IV that have been implicated in the putative proton transfer pathway (Ser-201, Asn-207, and Thr-211) were individually changed to alanine. The mutants were purified, analyzed for steady-state turnover rate and proton pumping efficiency, and structurally probed with resonance Raman spectroscopy and FTIR difference spectroscopy. The mutation of Ser-201 to alanine decreased the enzyme turnover rate by half, and was therefore further characterized using EPR spectroscopy and rapid kinetic methods. The results demonstrate that none of these hydrophilic residues are essential for proton pumping or oxygen reduction activities, and suggest a model of redundant or flexible proton transfer pathways. Whereas previously reported mutants at the start of this putative channel (e.g., Asp-132-Asn) dramatically influence both enzyme turnover and coupling to proton pumping, the current work shows that this is not the case for all residues observed in this channel.