Functional binding of cardiolipin to cytochromec oxidase

Bovine cytochromec oxidase usually contains 3–4 mol of tightly bound cardiolipin per cytochromeaa ₃ complex. At least two of these cardiolipins are required for full electron transport activity. Without the tightly bound cardiolipin, cytochromec oxidase has only 40–50% of its original activity when assayed in detergents that support activity, e.g., dodecyl maltoside. By measuring the restoration of electron transport activity, functional binding constants for cardiolipin and a number of cardiolipin analogues have been evaluated (K _d,app=1 µM for cardiolipin). These binding constants agree reasonably well with direct measurement of the binding using [¹⁴C]-acetyl-cardiolipin (K _d <0.1 µM) when the enzyme is solubilized with Triton X-100. These data are discussed in relationship to the wealth of data that is known about the association of cardiolipin with cytochromec oxidase and the other mitochrondrial electron transport complexes and transporters.     

Inhibition of the phosphate-stimulated cytochromec oxidase activity by thiophosphate

Yeast and mammalian cytochromec oxidase activity is inhibited by thiophosphate. This inhibition was observed when using either whole mitochondria or the isolated or reconstituted enzyme. The kinetics of the reduction reaction enabled us to demonstrate that thiophosphate acted on th electrons transfer between hemesa anda ₃. With whole mitochondria, phosphate alone stimulated respiration. The inhibition induced by thiophosphate was suppressed by phosphate only in mitochondria, but not when the isolated enzyme was used. The possibility of a kinetic regulation is discussed.Abbreviations CCCP p-carbonylcyanidem-chlorophenylhydrazone - TMPD N,N,N,N-tetramethylp-phenylenediamine - SPi thiophosphate     

The kinetics of electron entry in cytochromec oxidase

Summary The kinetics of electron entry in beef heart cytochromec oxidase have been studied by stopped-flow spectroscopy following chemical modification of the Cu_A site with mercurials. In this derivative Cu_A is no longer reducible by cytochrome c while cytochromea may accept electrons from the latter with rates comparable to the native enzyme. The results indicate that Cu_A is not the exclusive electron entry site in cytochromec oxidase.     

Low temperature optical spectroscopy of cobalt-substituted hemocyanin from Carcinus maenas

In this work we report the optical absorption spectra of three cobalt-substituted derivatives of hemocyanin (He) from Carcinus maenas, in the temperature range 300–20 K. The derivatives studied are the mononuclear (Co²⁺)-He with a single cobalt ion in the Cu_A site, the binuclear (Co²⁺)₂-He and the binuclear mixed metal (Co²⁺-Cu¹⁺)-He. At low temperature three main bands are clearly resolved; the temperature dependence of their zeroth, first and second moments sheds light on the stereodynamic properties in the surroundings of the chromophore. Within the limits of the reported analysis, in the binuclear derivatives the motions coupled to the chromophore appear to be essentially harmonic in the whole temperature range investigated; moreover the data are consistent with the presence of an exogenous ligand strongly bound to the two metal ions. For the mononuclear derivative an essentially harmonic behavior is evident only up to 200 K where the data are consistent with the presence of an exogenous ligand much less strongly bound, while at higher temperatures the behavior of the spectra indicates the onset of very large anharmonic contributions to motions, that plausibly involve the above exogenous ligand and, quite likely, the entire active site.Abbreviations He Hemocyanin - M₀ zeroth moment - M₁ first moment - M₂ second moment - (Co^2–)₂-He binuclear bicobalt hemocyanin derivative - (Co²⁺)-He mononuclear monocobalt hemocyanin derivative - (Co²⁺-Cu¹⁺)-He binuclear mixed metals hemocyanin derivative - LFT ligand field theory - CT charge transfer - EPR electronic paramagnetic resonance - XANES X-ray absorption near edge structure Correspondence to: L. Cordone     

On the role of subunit III in proton translocation in cytochromec oxidase

Mammalian mitochondrial cytochromec oxidase catalyzes the transfer of electrons from ferrocytochromec to molecular oxygen in the respiratory chain, while conserving the energy released during its electron transfer reactions by the vectorial movement of protons across the inner membrane of the mitochondrion. The protein domain that translocates the protons across the membrane is currently unknown. Recent research efforts have investigated the role of one of the transmembrane subunits of the enzyme (III,M _r 29,884) in the vectorial proton translocation reaction. The data that favor subunit III as integral in vectorial proton translocation as well as the data that support a more peripheral role for subunit III in proton translocation are reviewed. Possible experimental approaches to clarify this issue are presented and a general model discussed.     

Ferricytochromec induces monophasic kinetics of ferrocytochromec oxidation in cytochromec oxidase

The kinetics of ferrocytochromec oxidation by reconstituted cytochromec oxidase (COX) from bovine heart was followed by a spectrophotometric method, using on-line data collection and subsequent calculation of reaction rates from a function fitted to the progress curve. When reaction rates were calculated at increasing reaction times, the multiphasic kinetics of ferrocytochromec oxidation gradually changed into monophasic Michaelis-Menten kinetics. The same phenomenon was observed when ferrocytochromec oxidation was followed in the presence of increasing amounts of ferricytochromec. From these results we conclude that ferricytochromec shifts the multiphasic kinetics of ferrocytochromec oxidation by COX into monophasic kinetics, comparable to high ionic strength conditions. Furthermore, we show that ferricytochromec inhibits the high affinity phase of ferrocytochromec oxidation in an apparently competitive way, while inhibition of the low affinity phase is noncompetitive. These findings are consistent with a regulatory site model where both the catalytic and the regulatory site bind ferro- as well as ferricytochromec.     

Using chemical exchange to assign non-covalent protein complexes in slow exchange with the free state: Enhanced resolution and efficient signal editing

The formation of a ligand-protein complex oftentimes results in significant chemical shift changes. These changes may occur not only in the binding pocket but also in distal regions of the protein target. Therefore the reassignment of the backbone resonances in the complex is frequently a time consuming challenge. Here we present a suite of resolution-enhanced N(z)-exchange NMR experiments useful for rapidly assigning backbone (1)H and (15)N amide resonances of the ligand-bound form of a protein in slow exchange with its free state. Incorporation of semi-constant time frequency labeling periods into 3D N(z)-exchange experiments in combination with the collection of resolution-enhanced 2D N(z)-exchange difference spectra leads to a powerful set of tools for analyzing protein-ligand complexes. This allows for both the assignment of the bound state and the rapid assessment of the protein binding interface. The proposed methodology is demonstrated on the complex formed by the dimerization-docking domain of the c-AMP-dependent protein kinase and the tethering domain of the dual-binding A-kinase anchoring protein (AKAP).     

Raman signatures of ligand binding and allosteric conformation change in hexameric insulin.

Hexameric insulin is an allosteric protein that undergoes transitions between three conformational states (T(6), T(3)R(3), and R(6)). These allosteric states are stabilized by the binding of ligands to the phenolic pockets and by the coordination of anions to the His B10 metal sites. Raman difference (RD) spectroscopy is utilized to examine the binding of phenolic ligands and the binding of thiocyanate, p-aminobenzoic acid (PABA), or 4-hydroxy-3-nitrobenzoic acid (4H3N) to the allosteric sites of T(3)R(3) and R(6). The RD spectroscopic studies show changes in the amide I and III bands for the transition of residues B1-B8 from a meandering coil to an alpha helix in the T-R transitions and identify the Raman signatures of the structural differences among the T(6), T(3)R(3), and R(6) states. Evidence of the altered environment caused by the approximately 30 A displacement of phenylalanine (Phe) B1 is clearly seen from changes in the Raman bands of the Phe ring. Raman signatures arising from the coordination of PABA or 4H3N to the histidine (His) B10 Zn(II) sites show these carboxylates give distorted, asymmetric coordination to Zn(II). The RD spectra also reveal the importance of the position and the type of substituents for designing aromatic carboxylates with high affinity for the His B10 metal site.     

Hydrogen exchange and ligand binding: ligand-dependent and ligand-independent protection in the Src SH3 domain

Amide hydrogen-deuterium exchange has proven to be a powerful tool for detecting and characterizing high-energy conformations in protein ensembles. Since interactions with ligands can modulate these high-energy conformations, hydrogen exchange appears to be an ideal experimental probe of the physical mechanisms underlying processes like allosteric regulation. The chemical mechanism of hydrogen exchange, however, can complicate such studies. Here, we examine hydrogen exchange rates in a simple model system, the c-Src SH3 domain interacting with a short peptide ligand. Addition of ligand slows the rates of hydrogen exchange at nearly every amide for which we can obtain data. Careful analysis, however, reveals that this slowing is due primarily to a reduction in the population of free protein in the system, and not to any specific property of the complex. We present a method to separate the contributions of free and bound protein to the exchange kinetics that has allowed us to identify the subset of amides where exchange arises directly from the complex. These results demonstrate that the slowing of hydrogen exchange induced by ligand interactions should be interpreted with caution, and more extensive experiments are required to correlate changes in hydrogen exchange with changes in structure or internal dynamics.     

The sequence of electron carriers in the reaction of cytochromec oxidase with oxygen

Kinetic studies of the electron transfer processes performed by cytochrome oxidase have assigned rates of electron transfer between the metal centers involved in the oxidation of ferrocytochromec by molecular oxygen. Transient-state studies of the reaction with oxygen have led to the proposal of a sequence of carriers from cytochromec, to Cu_A, to cytochromea, and then to the binuclear (i.e., cytochromea ₃-Cu_B) center. Electron exchange rates between these centers agree with relative center-to-center distances as follows; cytochromec to Cu_A 5–7 Å, cytochromec to cytochromea 20–25 Å, Cu_A to cytochromea 14–16 Å and cytochromea to cytochrome a₃-Cu_B 8–10 Å. It is proposed that the step from cytochromea to the binuclear center is the key control point in the reaction and that this step is one of the major points of energy transduction in the reaction cycle.     

Studies on the molecular basis of H+ translocation by cytochromec oxidase

We report here studies which characterize further the interaction ofN,N-dicyclohexylcarbodiimide with cytochromec oxidase leading to inhibition of H⁺ translocation by the enzyme. Further evidence is presented to show that the inhibition results from a real interaction of DCCD with the enzyme and cannot be accounted for by uncoupling and, contrary to recent criticisms, this interaction occurs specifically with subunit III of the enzyme even at relatively high inhibitor-to-enzyme stoichiometries. Use of a spin-label analogue of DCCD has enabled us to demonstrate that the carbodiimide-binding site is highly apolar and may not lie on the pathway of electron transfer.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - NCCD N-(2, 2, 6, 6-tetramethylpiperidyl-1-oxyl)-N-(cyclohexyl)carbodiimide - Hepes 2-(N-2-hydroxyethylpiperazin-N-yl) ethane sulfonate - TMPD N,N,N,N-tetramethylphenylenediamine     

CuB promotes both binding and reduction of dioxygen at the heme-copper binuclear center in the Escherichia coli bo-type ubiquinol oxidase

A Cu_B-deficient mutant of the Escherichia coli bo-type ubiquinol oxidase exhibits a very low oxidase activity that is consistent with a decreased dioxygen binding rate. During the turnover, a photolabile reaction intermediate persists for a few hundred milliseconds, due to much slower heme o-to-ligand electron transfer. Thus, the lack of Cu_B seems to have endowed the mutant enzyme with myoglobin-like properties, thereby stabilizing the CO-bound form, too. Accordingly we conclude that Cu_B plays a pivotal role in preferential trapping and efficient reduction of dioxygen at the heme-copper binuclear center.     

Effect of trypsin on the kinetic properties of reconstituted beef heart cytochromec oxidase

Isolated beef heart cytochromec oxidase was reconstituted in liposomes by the cholate dialysis method with 85% of the binding site for cytochromec oriented to the outside. Trypsin cleaved specifically subunit VIa and half of subunit IV from the reconstituted enzyme. The kinetic properties of the reconstituted enzyme were changed by trypsin treatment if measured by the spectrophotometric assay but not by the polarographic assay. It is concluded that subunit VIa and/or subunit IV participate in the electron transport activity of cytochromec oxidase.     

Interaction of horse cytochromec with the photosynthetic reaction center ofRhodospirillum rubrum

Mitochondrial cytochromec (horse), which is a very efficient electron donor to bacterial photosynthetic reaction centersin vitro, binds to the reaction center ofRhodospirillum rubrum with an approximate dissociation constant of 0.3–0.5 µM at pH 8.2 and low ionic strength. The binding site for the reaction center is on the frontside of cytochromec which is the side with the exposed heme edge, as revealed by differential chemical acetylation of lysines of free and reaction-center-bound cytochromec. In contrast, bacterial cytochromec ₂ was found previously to bind to the detergent-solubilized reaction center through its backside, i.e., the side opposite to the heme cleft [Rieder, R., Wiemken, V., Bachofen, R., and Bosshard, H. R. (1985).Biochem. Biophys. Res. Commun. 128, 120–126]. Binding of mitochondrial cytochromec but not of mitochondrial cytochromec ₂ is strongly inhibited by low concentrations of poly-l-lysine. The results are difficult to reconcile with the existence of an electron transfer site on the backside of cytochromec ₂.     

Influence of 8-azido-ATP and other anions on the activity of cytochromec oxidase

The effect of ATP and other anions on the kinetics of cytochromec oxidation by reconstituted bovine heart cytochromec oxidase was investigated. The following results were obtained: (1) ATP and other polyvalent anions increase theK _m for cytochromec and theV _max (if assayed by the photometric method). The magnitude of the effect is proportional to the charge of the anion as follows from the series of increasing effectiveness: P_iii. (2) The kinetic effects are obtained in the millimolar physiological concentration range. (3) The kinetic changes are not saturated at high concentrations. (4) A specific interaction site for ATP at the cytosolic domain of the enzyme is concluded from the increase ofK _m for cytochromec after photolabelling of proteoliposomes with 8-azido-[-³²P]-ATP, which is protected by ATP but not by ADP. (5) No specific binding site for ATP could be identified by photolabelling with 8-azido-[-³²P]-ATP. The labelling is only partly protected by ATP or ADP.Abbreviations CCP carbonylcyanide-m-chlorophenylhydrazone - TMPD N,N,N,N-tetramethyl-1,4-phenylenediamine dihydrochloride - 8-N₃-ATP 8-azido-adenosine-5-triphosphate Dedicated to Professor Dr. Friedhelm Schneider on the occasion of his 60th birthday.     

Effect of ligand binding on human d-amino acid oxidase: Implications for the development of new drugs for schizophrenia treatment

In human brain the flavoprotein D ‐amino acid oxidase (hDAAO) is responsible for the degradation of the neuromodulator D ‐serine, an important effector of NMDA‐receptor mediated neurotransmission. Experimental evidence supports the concept that D ‐serine concentration increase by hDAAO inhibition may represent a valuable therapeutic approach to improve the symptoms in schizophrenia patients. This study investigated the effects on hDAAO conformation and stability of the substrate D ‐serine (or of the pseudo‐substrate trifluoro‐D ‐alanine), the FAD cofactor, and two inhibitors (benzoate, a classical substrate‐competitive inhibitor and the drug chlorpromazine (CPZ), which competes with the cofactor). We demonstrated that all these compounds do not alter the interaction of hDAAO with its physiological partner pLG72. The ligands used affect the tertiary structure of hDAAO differently: benzoate or trifluoro‐D ‐alanine binding increases the amount of the holoenzyme form in solution and stabilizes the flavoprotein, while CPZ binding favors a protein conformation resembling that of the apoprotein, which is more sensitive to degradation. Interestingly, the apoprotein form of hDAAO binds the substrate D ‐serine: this interaction increases FAD binding thus increasing the amount of active holoenzyme in solution. Benzoate and CPZ similarly modify the short‐term cellular D ‐serine concentration but affect the cellular concentration of hDAAO differently. In conclusion, the different alteration of hDAAO conformation and stability by the ligands used represents a further parameter to take into consideration during the development of new drugs to cope schizophrenia.     

Location and nature of the residues important for ligand recognition in G-protein coupled receptors

The overall structure of the biogenic amine subclass of the G-protein-coupled receptors, and of their ligand binding sites, is discussed with the aim of highlighting the major structural features of these receptors that are responsible for ligand recognition. A comparison is made between biogenic amine receptors, peptide receptors of the rhodopsin class, and the secretin receptors which all have peptide ligands. The question of where the peptide ligands bind, whether at extracellular sites or within the transmembrane helix bundle, is discussed. The suitability of the rhodopsin crystal structure as a template for construction of homology models is discussed and it is concluded that there are many reasons why a caution should be issued against using it uncritically.     

Electrostatic control of proton pumping in cytochrome c oxidase

As part of the mitochondrial respiratory chain, cytochrome c oxidase utilizes the energy produced by the reduction of O₂ to water to fuel vectorial proton transport. The mechanism coupling proton pumping to redox chemistry is unknown. Recent advances have provided evidence that each of the four observable transitions in the complex catalytic cycle consists of a similar sequence of events. However, the physico-chemical basis underlying this recurring sequence has not been identified. We identify this recurring pattern based on a comprehensive model of the catalytic cycle derived from the analysis of oxygen chemistry and available experimental evidence. The catalytic cycle involves the periodic repetition of a sequence of three states differing in the spatial distribution of charge in the active site: [0|1], [1|0], and [1|1], where the total charge of heme a and the binuclear center appears on the left and on the right, respectively. This sequence recurs four times per turnover despite differences in the redox chemistry. This model leads to a simple, robust, and reproducible sequence of electron and proton transfer steps and rationalizes the pumping mechanism in terms of electrostatic coupling of proton translocation to redox chemistry. Continuum electrostatic calculations support the proposed mechanism and suggest an electrostatic origin for the decoupled and inactive phenotypes of ionic mutants in the principal proton-uptake pathway.     

Phylogenetic analysis of the perissodactylan family Tapiridae using mitochondrial cytochromec oxidase (COII) sequences

The four extant members of the family Tapiridae have a disjunct, relictual distribution, with three species being Neotropical (Tapirus bairdii, T. terrestris, andT. pinchaque) and one found in Southeast Asia (T. indicus). Little recent work on tapir systematics have appeared, and no molecular studies of this group have been published. A phylogenetic analysis was undertaken using sequences of the mitochondrial cytochromec oxidase subunit II gene (COII) from representatives of the four species of tapirs, as well as a representative outgroup,Equus caballus. Analyses of the COII sequences indicate a close relationship between the two South American species of tapirs,T. terrestris andT. pinchaque, and estimates of divergence dates using rates of COII evolution are compatible with migration of a single tapir lineage into South America following the emergence of the isthmus of Panama, about 3 million years bp. Various methods of analysis, including maximum parsimony, maximum likelihood, and neighbor-joining, provided poorer resolution of other tapir relationship. The COII data suggest that three distinct tapir mitochondrial lineages, a South American (represented byT. terrestris andT. pinchaque), a Central American (represented byT. bairdii), and an Asian (represented byT. indicus) diverged relatively rapidly, 20–30 million years bp. Another goal of this study was to calibrate the rate of COII evolution in a eutherian mammal group which has a good fossil record, such as perissodactyls, to estimate accurately the rate of COII evolution in a nonprimate mammalian group. The rate of COII evolution in equids and tapirs has been relatively constant and, using corrected distances, calibrated to be approximately 0.22% lineage/million years. This rate is three-to fourfold lower than that of hominoid primates.     

Redesign of LAOBP to bind novel l‐amino acid ligands

Computational protein design is still a challenge for advancing structure‐function relationships. While recent advances in this field are promising, more information for genuine predictions is needed. Here, we discuss different approaches applied to install novel glutamine (Gln) binding into the Lysine/Arginine/Ornithine binding protein (LAOBP) from Salmonella typhimurium. We studied the ligand binding behavior of two mutants: a binding pocket grafting design based on a structural superposition of LAOBP to the Gln binding protein QBP from Escherichia coli and a design based on statistical coupled positions. The latter showed the ability to bind Gln even though the protein was not very stable. Comparison of both approaches highlighted a nonconservative shared point mutation between LAOBP_graft and LAOBP_sca. This context dependent L117K mutation in LAOBP turned out to be sufficient for introducing Gln binding, as confirmed by different experimental techniques. Moreover, the crystal structure of LAOBP_L117K in complex with its ligand is reported.