Inhibition of an aa3-Type Two-Subunit Cytochrome c Oxidase from Nitrobacter agilis by N,N'-Dicyclohexylcarbodiimide

The electron transfer activity of an aa₃-type two-subunit cytochromec oxidase of Nitrobacter agilis was inhibited by DCCD. Althoughthe activity of the purified cytochrome c oxidase dissolvedin 1% Triton X- 100 was not affected by DCCD even at a ratioof 1,000 mol DCCD per mol cytochrome aa₃, the activity of theenzyme dissolved in 0.02% Tween 20 or 0.02% Triton X-100 wasinhibited by 60% or more at a ratio of 1,000 mol DCCD per molcytochrome aa₃. The results of SDS polyacrylamide gel electrophoresisof the enzyme incubated with DCCD suggested that subunit IImight be a binding site for DCCD. (Received February 23, 1985; Accepted April 23, 1985)     

Sulfite Oxidation Catalyzed by aa 3-Type Cytochrome c Oxidase in Acidithiobacillus ferrooxidans

Sulfite is produced as a toxic intermediate during Acidithiobacillus ferrooxidans sulfur oxidation. A. ferrooxidans D3-2, which posseses the highest copper bioleaching activity, is more resistant to sulfite than other A. ferrooxidans strains, including ATCC 23270. When sulfite oxidase was purified homogeneously from strain D3-2, the oxidized and reduced forms of the purified sulfite oxidase absorption spectra corresponded to those of A. ferrooxidans aa ₃-type cytochrome c oxidase. The confirmed molecular weights of the α-subunit (52.5 kDa), the β-subunit (25 kDa), and the γ-subunit (20 kDa) of the purified sulfite oxidase and the N-terminal amino acid sequences of the γ-subunit of sulfite oxidase (AAKKG) corresponded to those of A. ferrooxidans ATCC 23270 cytochrome c oxidase. The sulfite oxidase activities of the iron- and sulfur-grown A. ferrooxidans D3-2 were much higher than those cytochrome c oxidases purified from A. ferrooxidans strains ATCC 23270, MON-1 and AP19-3. The activities of sulfite oxidase purified from iron- and sulfur-grown strain D3-2 were completely inhibited by an antibody raised against a purified A. ferrooxidans MON-1 aa ₃-type cytochrome c oxidase. This is the first report to indicate that aa ₃-type cytochrome c oxidase catalyzed sulfite oxidation in A. ferrooxidans.     

cbb3-Type Cytochrome c Oxidases,Aerobic Respiratory Enzymes,Impact the Anaerobic Life of Pseudomonas aeruginosa PAO1

For bacteria, many studies have focused on the role of respiratory enzymes in energy conservation; however, their effect on cell behavior is poorly understood. Pseudomonas aeruginosa can perform both aerobic respiration and denitrification. Previous studies demonstrated that cbb₃-type cytochrome c oxidases that support aerobic respiration are more highly expressed in P. aeruginosa under anoxic conditions than are other aerobic respiratory enzymes. However, little is known about their role under such conditions. In this study, it was shown that cbb₃ oxidases of P. aeruginosa PAO1 alter anaerobic growth, the denitrification process, and cell morphology under anoxic conditions. Furthermore, biofilm formation was promoted by the cbb₃ oxidases under anoxic conditions. cbb₃ oxidases led to the accumulation of nitric oxide (NO), which is produced during denitrification. Cell elongation induced by NO accumulation was reported to be required for robust biofilm formation of P. aeruginosa PAO1 under anoxic conditions. Our data show that cbb₃ oxidases promote cell elongation by inducing NO accumulation during the denitrification process, which further leads to robust biofilms. Our findings show that cbb₃ oxidases, which have been well studied as aerobic respiratory enzymes, are also involved in denitrification and influence the lifestyle of P. aeruginosa PAO1 under anoxic conditions.     

aa3-Type Cytochrome c Oxidase Occurs in Halobacterium halobium and Its Activity is Inhibited by Higher Concentrations of Salts

Cytochrome aa₃ was found to occur in Halobacterium halobiumat an early exponential phase of growth. Some of its spectralproperties were determined with a solubilized membrane fractionof the bacterium. Cytochrome c oxidizing activity of the cytochromeaa₃ was not dependent on salt concentration, but decreased steeplywith increasing buffer concentration of the reaction mixture,just as the activity of cytochrome aa₃ from non-halophilic bacteria. (Received July 4, 1986; Accepted October 17, 1986)     

Biochemical and Biophysical Characterization of the Two Isoforms of cbb3-Type Cytochrome c Oxidase from Pseudomonas stutzeri

The cbb₃-type cytochrome c oxidases (cbb₃-CcOs) are members of the heme-copper oxidase superfamily that couple the reduction of oxygen to translocation of protons across the membrane. The cbb₃-CcOs are present only in bacteria and play a primary role in microaerobic respiration, being essential for nitrogen-fixing endosymbionts and for some human pathogens. As frequently observed in Pseudomonads, Pseudomonas stutzeri contains two independent ccoNO(Q)P operons encoding the two cbb₃ isoforms, Cbb₃-1 and Cbb₃-2. While the crystal structure of Cbb₃-1 from P. stutzeri was determined recently and cbb₃-CcOs from other organisms were characterized functionally, less emphasis has been placed on the isoform-specific differences between the cbb₃-CcOs. In this work, both isoforms were homologously expressed in P. stutzeri strains from which the genomic version of the respective operon was deleted. We purified both cbb₃ isoforms separately by affinity chromatography and increased the yield of Cbb₃-2 to a similar level as Cbb₃-1 by replacing its native promoter. Mass spectrometry, UV-visible (UV-Vis) spectroscopy, differential scanning calorimetry, as well as oxygen reductase and catalase activity measurements were employed to characterize both cbb₃ isoforms. Differences were found concerning the thermal stability and the presence of subunit CcoQ. However, no significant differences between the two isoforms were observed otherwise. Interestingly, a surprisingly high turnover of at least 2,000 electrons s⁻¹ and a high Michaelis-Menten constant (K_m ∼ 3.6 mM) using ascorbate–N,N,N′,N′-tetramethyl-p-phenylenediamine dihydrochloride (TMPD) as the electron donor were characteristic for both P. stutzeri cbb₃-CcOs. Our work provides the basis for further mutagenesis studies of each of the two cbb₃ isoforms specifically.     

Macroscopic Kinetics of Pentameric Ligand Gated Ion Channels: Comparisons between Two Prokaryotic Channels and One Eukaryotic Channel

Electrochemical signaling in the brain depends on pentameric ligand-gated ion channels (pLGICs). Recently, crystal structures of prokaryotic pLGIC homologues from Erwinia chrysanthemi (ELIC) and Gloeobacter violaceus (GLIC) in presumed closed and open channel states have been solved, which provide insight into the structural mechanisms underlying channel activation. Although structural studies involving both ELIC and GLIC have become numerous, thorough functional characterizations of these channels are still needed to establish a reliable foundation for comparing kinetic properties. Here, we examined the kinetics of ELIC and GLIC current activation, desensitization, and deactivation and compared them to the GABA_A receptor, a prototypic eukaryotic pLGIC. Outside-out patch-clamp recordings were performed with HEK-293T cells expressing ELIC, GLIC, or α₁β₂γ_2L GABA_A receptors, and ultra-fast ligand application was used. In response to saturating agonist concentrations, we found both ELIC and GLIC current activation were two to three orders of magnitude slower than GABA_A receptor current activation. The prokaryotic channels also had slower current desensitization on a timescale of seconds. ELIC and GLIC current deactivation following 25 s pulses of agonist (cysteamine and pH 4.0 buffer, respectively) were relatively fast with time constants of 24.9±5.1 ms and 1.2±0.2 ms, respectively. Surprisingly, ELIC currents evoked by GABA activated very slowly with a time constant of 1.3±0.3 s and deactivated even slower with a time constant of 4.6±1.2 s. We conclude that the prokaryotic pLGICs undergo similar agonist-mediated gating transitions to open and desensitized states as eukaryotic pLGICs, supporting their use as experimental models. Their uncharacteristic slow activation, slow desensitization and rapid deactivation time courses are likely due to differences in specific structural elements, whose future identification may help uncover mechanisms underlying pLGIC gating transitions.     

Coevolutionary Patterns in Cytochrome c Oxidase Subunit I Depend on Structural and Functional Context

The strength and pattern of coevolution between amino acid residues vary depending on their structural and functional environment. This context dependence, along with differences in analytical technique, is responsible for the different results among coevolutionary analyses of different proteins. It is thus important to perform detailed study of individual proteins to gain better insight into how context dependence can affect coevolutionary patterns even within individual proteins, and to unravel the details of context dependence with respect to structure and function. Here we extend our previous study by presenting further analysis of residue coevolution in cytochrome c oxidase subunit I sequences from 231 vertebrates using a statistically robust phylogeny-based maximum likelihood ratio method. As in previous studies, a strong overall coevolutionary signal was detected, and coevolution within structural regions was significantly related to the C_α distances between residues. While the strong selection for adjacent residues among predicted coevolving pairs in the surface region indicates that the statistical method is highly selective for biologically relevant interactions, the coevolutionary signal was strongest in the transmembrane region, although the distances between coevolving residues were greater. This indicates that coevolution may act to maintain more global structural and functional constraints in the transmembrane region. In the transmembrane region, sites that coevolved according to polarity and hydrophobicity rather than volume had a greater tendency to colocalize with just one of the predicted proton channels (channel H). Thus, the details of coevolution in cytochrome c oxidase subunit I depend greatly on domain structure and residue physicochemical characteristics, but proximity to function appears to play a critical role. We hypothesize that coevolution is indicative of a more important functional role for this channel. Electronic Supplementary Material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Cytochrome a1 of Nitrosomonas europaea resembles aa3-type cytochrome c oxidase in many respects

Cytochrome c oxidase of Nitrosomonas europaea has been called cytochrome a₁ by Erickson et al. (Erickson, R.H., Hooper, A.B. and Terry, K.R. (1972) Biochim. Biophys. Acta 283, 155–166) because the reduced form of their preparation had the α peak at 595 nm. In the present studies, the enzyme was purified to an electrophoretically almost homogeneous state and some of its properties were studied. The enzyme much resembled cytochrome aa₃-type oxidase although its reduced form showed the α peak at 597 nm. (1) The absorption spectra of the CO compound of the reduced enzyme and CN⁻ compounds of the oxidized and reduced enzyme were similar to those of the respective compounds of cytochrome aa₃, as well as the absorption spectrum of the intact enzyme resembled that of the cytochrome. (2) The enzyme possessed two molecules of haem a and 1–2 atoms of copper in the molecule. (3) The enzyme molecule was composed of two kinds of subunits of M_r 50000 and 33000, respectively, as are other bacterial cytochromes aa₃. Although the enzyme resembled other bacterial cytochromes aa₃ in many properties, it differed greatly in two properties; its CO compound was easily dissociated into the oxidized enzyme and CO in air, and 50% inhibition of its activity by CN⁻ required approx. 100 μM of the reagent. The enzyme oxidized 0.57, 1.6 and 1.8 mol horse, Candida krusei and N. europaea ferrocytochromes c per s per mol haem a, respectively, in 10 mM phosphate buffer, pH 6.0. The turnover numbers with eukaryotic ferrocytochromes c were increased to 32 and 14, respectively, by addition of cardiolipin (14 μ · ml⁻¹).     

Evolutionary Conservation of Structural and Functional Coupling between the BRM AT-Hook and Bromodomain

The BAF chromatin remodeling complex is critical for genome regulation. The central ATPase of BAF is either BRM or BRG1, both of which contain a C-terminal bromodomain, known to associate with acetylated lysines. We have recently demonstrated that in addition to acetyl-lysine binding, the BRG1/BRM bromodomain can associate with DNA through a lysine/arginine rich patch that is adjacent to the acetyl-lysine binding pocket. Flanking the bromodomain is an AT-hook separated by a short, proline-rich linker. We previously found that the AT-hook and bromodomain can associate with DNA in a multivalent manner. Here, we investigate the conservation of this composite module and find that the AT-hook, linker, and lysine/arginine rich bromodomain patch are ancient, conserved over ~1 billion years. We utilize extensive mutagenesis, NMR spectroscopy, and fluorescence anisotropy to dissect the contribution of each of these conserved elements in association of this module with DNA. Our results reveal a structural and functional coupling of the AT-hook and bromodomain mediated by the linker. The lysine/arginine rich patch on the bromodomain and the conserved elements of the AT-hook are critical for robust affinity for DNA, while the conserved elements of the linker are dispensable for overall DNA affinity but critical for maintaining the relative conformation of the AT-hook and bromodomain in binding to DNA. This supports that the coupled action of the AT-hook and bromodomain are important for BAF activity.     

Potentiometric study of cytochrome c1aa3 from Thermus thermophilus

We have examined the redox behavior of the cytochrome c1aa3 complex from Thermus thermophilus. In potentiometric titrations the cytochrome c behaves as an independent center having n = 1 and E = 205 mV (NHE). Under the assumption that the individual centers equilibrate independently in this experiment, changes in the absorption band at 603 nm have been resolved into two components: cytochrome a (n = 1, Em = 270 mV, 60% spectral contribution) and cytochrome a3 (n = 2, Em = 360 mV, 40% spectral contribution). The n = 2 process was attributed to strong chemical coupling between cytochrome a3 and CuB. The enzyme was also titrated with a mixture of NADH and PMS, and the results are shown not to conform to a model of intramolecular equilibrium according to the equilibrium constants obtained from the potentiometric titration. It is suggested that a conformational equilibrium within the complex may control electron transfer between cytochromes a and a3.     

Cytochrome c Oxidase (Heme aa 3) from Paracoccus denitrificans: Analysis of Mutations in Putative Proton Channels of Subunit I

One of the challenging features of energy-transducing terminal oxidases, like the aa ₃ cytochrome c oxidase of Paracoccus denitrificans, is the translocation of protons across the cytoplasmic membrane, which is coupled to the transfer of electrons to oxygen. As a prerequisite for a more advanced examination of the enzymatic properties, several amino acid residues, selected on the basis of recent three-dimensional structure determinations, were exchanged in subunit I of the Paracoccus enzyme by site-directed mutagenesis. The properties of the mutated oxidases were analyzed by different methods to elucidate whether they are involved in the coupled and coordinated transfer of protons via two different pathways either to the site of oxygen reduction or through the enzyme from the cytoplasm to the periplasmic side.     

Kinetic and Structural Characterization of the Interaction between the FMN Binding Domain of Cytochrome P450 Reductase and Cytochrome c

Cytochrome P450 reductase (CPR) is a diflavin enzyme that transfers electrons to many protein partners. Electron transfer from CPR to cyt c has been extensively used as a model reaction to assess the redox activity of CPR. CPR is composed of multiple domains, among which the FMN binding domain (FBD) is the direct electron donor to cyt c. Here, electron transfer and complex formation between FBD and cyt c are investigated. Electron transfer from FBD to cyt c occurs at distinct rates that are dependent on the redox states of FBD. When compared with full-length CPR, FBD reduces cyt c at a higher rate in both the semiquinone and hydroquinone states. The NMR titration experiments reveal the formation of dynamic complexes between FBD and cyt c on a fast exchange time scale. Chemical shift mapping identified residues of FBD involved in the binding interface with cyt c, most of which are located in proximity to the solvent-exposed edge of the FMN cofactor along with other residues distributed around the surface of FBD. The structural model of the FBD-cyt c complex indicates two possible orientations of complex formation. The major complex structure shows a salt bridge formation between Glu-213/Glu-214 of FBD and Lys-87 of cyt c, which may be essential for the formation of the complex, and a predicted electron transfer pathway mediated by Lys-13 of cyt c. The findings provide insights into the function of CPR and CPR-cyt c interaction on a structural basis.     

痘苗病毒原核增强子样序列VV1的结构和功能的研究

增强子是基因转录调控的一个重要而必需的元件,其最.初发现于SV40早期基因的表达过程中[1,2].自此以后,相继发现这一远端基因调控序列广泛存在于真核细胞、原核细胞和病毒基因组中[3-7].本文选取活性较高的痘苗病毒原核增强子样序列VV1为目的片段,利用缺失和随机突变的方法对VV1功能区进行分析,阐明其结构和功能的关系,进一步丰富原核增强子的作用机理和基因转录调控方面的研究.     

Cytochrome aa3 from the aerobic photoheterotroph Erythrobacter longus: purification, and enzymatic and molecular features

Cytochrome c oxidase (cytochrome aa3-type) [EC 1.9.3.1] was purified from Erythrobacter longus to homogeneity as judged by polyacrylamide gel electrophoresis, and some of its properties were studied. The spectral properties of the oxidase closely resembled those of mitochondrial and other bacterial cytochromes aa3. The enzyme showed absorption peaks at 430 and 598 nm in the oxidized form, and at 444 and 603 nm in the reduced form. The CO compound of the reduced enzyme showed peaks at 432 and 600 nm. The enzyme oxidized eukaryotic ferrocytochromes C more rapidly than E. longus ferrocytochrome c. The reactions catalyzed by the enzyme were 50% inhibited by 0.7 microM KCN. The enzyme contained 1 g atom of copper and 1 g atom of magnesium per mol of heme a. The enzyme molecule seemed to be composed of two identical subunits, each with a molecular weight of 43,000.     

Cytochrome c as an electron shuttle between the outer and inner mitochondrial membranes

Addition of exogenous NADH to rotenone- and antimycin A-treated mitochondria, in 125 mM KCl, results in rates of oxygen uptake of 0.5-1 and 10-12 nanoatoms of oxygen X mg protein-1 X min-1 in the absence and presence of cytochrome c, respectively. During oxidation of exogenous NADH there is a fast and complete reduction of cytochrome b5 while endogenous or added exogenous cytochrome c become 10-15% and 100% reduced, respectively. The reoxidation of cytochrome b5, after exhaustion of NADH, precedes that of cytochrome c. NADH oxidation is blocked by mersalyl, an inhibitor of NADH-cytochrome b5 reductase. These observations support the view of an electron transfer from the outer to the inner membrane of intact mitochondria. Both the rate of exogenous NADH oxidation and the steady state level of cytochrome c reduction increase with the increase of ionic strength, while the rate of succinate oxidation undergoes a parallel depression. These observations suggest that the functions of cytochrome c as an electron carrier in the inner membrane and as an electron shuttle in the intermembrane space are alternative. It is concluded that aerobic oxidation of exogenous NADH involves the following pathway: NADH leads to NADH-cytochrome b5 reductase leads to cytochrome b5 leads to intermembrane cytochrome c leads to cytochrome oxidase leads to oxygen. It is suggested that the communication between the outer and inner membranes mediated by cytochrome c may affect the oxidation-reduction level of cytosolic NADH and the related oxidation-reduction reactions.     

Structural Changes and Proapoptotic Peroxidase Activity of Cardiolipin-Bound Mitochondrial Cytochrome c

The cellular process of intrinsic apoptosis relies on the peroxidation of mitochondrial lipids as a critical molecular signal. Lipid peroxidation is connected to increases in mitochondrial reactive oxygen species, but there is also a required role for mitochondrial cytochrome c (cyt-c). In apoptotic mitochondria, cyt-c gains a new function as a lipid peroxidase that catalyzes the reactive oxygen species-mediated chemical modification of the mitochondrial lipid cardiolipin (CL). This peroxidase activity is caused by a conformational change in the protein, resulting from interactions between cyt-c and CL. The nature of the conformational change and how it causes this gain-of-function remain uncertain. Via a combination of functional, structural, and biophysical experiments we investigate the structure and peroxidase activity of cyt-c in its membrane-bound state. We reconstituted cyt-c with CL-containing lipid vesicles, and determined the increase in peroxidase activity resulting from membrane binding. We combined these assays of CL-induced proapoptotic activity with structural and dynamic studies of the membrane-bound protein via solid-state NMR and optical spectroscopy. Multidimensional magic angle spinning (MAS) solid-state NMR of uniformly ¹³C,¹⁵N-labeled protein was used to detect site-specific conformational changes in oxidized and reduced horse heart cyt-c bound to CL-containing lipid bilayers. MAS NMR and Fourier transform infrared measurements show that the peripherally membrane-bound cyt-c experiences significant dynamics, but also retains most or all of its secondary structure. Moreover, in two-dimensional and three-dimensional MAS NMR spectra the CL-bound cyt-c displays a spectral resolution, and thus structural homogeneity, that is inconsistent with extensive membrane-induced unfolding. Cyt-c is found to interact primarily with the membrane interface, without significantly disrupting the lipid bilayer. Thus, membrane binding results in cyt-c gaining the increased peroxidase activity that represents its pivotal proapoptotic function, but we do not observe evidence for large-scale unfolding or penetration into the membrane core.     

The Structure of the Herpes Simplex Virus DNA-Packaging Terminase pUL15 Nuclease Domain Suggests an Evolutionary Lineage among Eukaryotic and Prokaryotic Viruses

Herpes simplex virus 1 (HSV-1), the prototypic member of herpesviruses, employs a virally encoded molecular machine called terminase to package the viral double-stranded DNA (dsDNA) genome into a preformed protein shell. The terminase contains a large subunit that is thought to cleave concatemeric viral DNA during the packaging initiation and completion of each packaging cycle and supply energy to the packaging process via ATP hydrolysis. We have determined the X-ray structure of the C-terminal domain of the terminase large-subunit pUL15 (pUL15C) from HSV-1. The structure shows a fold resembling those of bacteriophage terminases, RNase H, integrases, DNA polymerases, and topoisomerases, with an active site clustered with acidic residues. Docking analysis reveals a DNA-binding surface surrounded by flexible loops, indicating considerable conformational changes upon DNA binding. In vitro assay shows that pUL15C possesses non-sequence-specific, Mg²⁺-dependent nuclease activity. These results suggest that pUL15 uses an RNase H-like, metal ion-mediated catalysis mechanism for cleavage of viral concatemeric DNA. The structure reveals extra structural elements in addition to the RNase H-like fold core and variations in local architecture of the nuclease active site, which are conserved in herpesvirus terminases and bear great similarity to the phage T4 gp17 but are distinct from podovirus and siphovirus orthologs and cellular RNase H, delineating a new evolutionary lineage among a large family of eukaryotic viruses and simple and complex prokaryotic viruses.