心磷脂引起细胞色素C的氧化

心磷脂—细胞色素C—细胞色素C氧化酶体系吸收光谱的研究发现:心磷脂与氧化态细胞色素C结合产生230nm吸收峰;心磷脂与还原态细胞色素C作用,230nm吸收值上升,550nm吸收值下降,表明心磷脂可以引起细胞色素C的氧化。     

心磷脂电化学行为的研究

对心磷脂及其与细胞色素C复合物的研究表明,心磷脂具有电化学活性;它与细胞色素C的结合使细胞色素C的克式电位下降、表观电子转移数减少、电极反应变慢。说明心磷脂和细胞色素C之间可能发生了电子转移。     

心磷脂对细胞色素C氧化酶质子泵功能的影响

 用胆酸盐透析法将猪心线粒体细胞色素C氧化酶重组在含心磷脂和二肉豆寇磷脂酰胆碱的脂质体上,以还原态细胞色素C作为酶反应底物,记录脂酶体囊泡外介质液pH的变化,pH下降幅度可以反映细胞色素C氧化酶质子泵的功能。 心磷脂含量不同的细胞色素C氧化酶脂酶体质子泵功能不同。心磷脂含量在10％—40％(w/w)范围内,随心磷脂含量增高,该酶质子泵功能增强;当心磷艏含量超过50％时,该酶质子泵功能却随心磷脂含量的增加表现出下降的趋势。阿霉素可以与心磷脂紧密结合,抑制细胞色素C氧化酶的质子泵功能。然而,少量阿霉素却能增强含70％心磷脂的脂酶体的质子泵功能。     

细胞色素C和含心磷脂的人工脂膜相互作用

 本文报告以芘为荧光探剂,研究细胞色素C和含心磷脂的人工脂膜的相互作用。1.由于芘和细胞色素C的血红素团之间的能量转移,细胞色素C与心磷脂结合引起芘的单体荧光发射峰(395nm)强度下降。这种淬灭效应受脂膜的相行为影响,在液晶相时淬灭效应小于凝胶相;2.氧化态细胞色素C与还原态相比,对心磷脂结合的视和度稍高;3.在以芘的激发二聚体荧光峰(475nm)强度与单体荧光峰强度之比做为脂膜流动性的指标,发现还原态细胞色素C与含心磷脂脂膜结合后引起流动性增加的效应高于氧化态的结合。     

运动性内源自由基对大鼠肝线粒体的影响

采用大鼠耗竭游泳作为动物运动模型,用戊巴比妥酸(TBA)法测定脂质过氧化水平,薄层色谱—定磷法测定心磷脂含量,细胞色素C还原法测定细胞色素C氧化酶活性。结果如下:耗竭运动时,肝线粒体脂质过氧化水平升高24％;心磷脂含量下降21％;细胞色素C氧化酶活性下降25％。上述结果表明:耗竭运动时,机体内源自由基的产生是运动损伤和整体疲劳的原因之一。     

细胞色素C引起心磷脂的还原

本工作采用FT-IR和NMR技术,研究了心磷脂(CL)与还原态细胞色素C作用后其脂肪酸链中双键数目的变化。发现伴随细胞色素C的氧化,CL双键被部分还原为单键,提示CL可能直接参与吸呼链的电子传递。     

心磷脂对细胞凋亡作用的研究进展

心磷脂(cardiolipin, CL)是线粒体特异的一类磷脂,它不仅可以维持线粒体的结构,还对电子传递链复合体有影响。在细胞凋亡时,心磷脂会发生一些重分布,比如线粒体内膜外小叶中心磷脂含量的增加及细胞表面心磷脂的出现。同时,凋亡刺激还可以加速心磷脂的代谢循环,使心磷脂在线粒体内的含量降低。在细胞凋亡发生时,心磷脂作为一个信号整合体,对细胞色素c (cytochrome c, CytC)、胱天蛋白酶-8 (caspase-8)和促凋亡蛋白Bid发挥着重要的协调作用。本文主要就心磷脂在细胞凋亡过程中的重要作用及其在癌症中的研究进展进行综述。     

磷脂对琥珀酸-细胞色素c还原酶的作用

琥珀酸细胞色素c还原酶除去90％以上的磷脂后活力丧失约95％。将去脂琥珀酸细胞色素c还原酶与磷脂和辅酶Q_2保温,可恢复其活性。活力恢复程度依赖于磷脂的组成。当磷脂酰胆碱(PC):心磷脂(CL):磷脂酰乙醇胺(PE)=2:2:1时活力恢复最高,比大豆磷脂的效果更为明显,单组分PC,PE或CL恢复活力较差。与酶蛋白紧密结合的CL和PC在活力可逆恢复中有重要作用。     

DMPC单分子层膜及细胞色素C氧化酶重组脂质体表面的扫描隧道显微镜观察

本文报导了扫描隧道显微镜对固相磷脂单分子层膜以及重组了细胞色素C氧化酶后的脂质体表面结构的观察.对DMPC单分子层著,得到了有关磷脂头部形态,大小及排态状况等结构信息,达到分子水平分辨;对重组酶后的脂质体表面,也得到了氧化酶分子在膜上的结构信息.     

DMPC单分子层膜及细胞色素C氧化酶重组脂质体表面的扫描隧道显微镜观察

本文报导了扫描隧道显微镜对固相磷脂单分子层膜以及重组了细胞色素C氧化酶后的脂质体表面结构的观察.对DMPC单分子层著,得到了有关磷脂头部形态,大小及排态状况等结构信息,达到分子水平分辨;对重组酶后的脂质体表面,也得到了氧化酶分子在膜上的结构信息.     

Antimicrobial activity and membrane selective interactions of a synthetic lipopeptide MSI-843

The method of fluorescence resonance energy transfer (FRET) has been employed to monitor cytochrome c interaction with bilayer phospholipid membranes. Liposomes composed of phosphatidylcholine and varying amounts of anionic lipid cardiolipin (CL) were used as model membranes. Trace amount of fluorescent lipid derivative, anthrylvinyl-phosphatidylcholine was incorporated into the membranes to serve energy donor for heme moiety of cytochrome c. Energy transfer efficiency was measured at different lipid and protein concentrations to obtain extensive set of data, which were further analyzed globally in terms of adequate models of protein adsorption and energy transfer on the membrane surface. It has been found that the cytochrome c association with membranes containing 10 mol% CL can be described in terms of equilibrium binding model (yielding dissociation constant Kd = 0.2-0.4 microM and stoichiometry n = 11-13 lipid molecules per protein binding site) combined with FRET model assuming uniform acceptor distribution with the distance of 3.5-3.6 nm between the bilayer midplane and heme moiety of cytochrome c. However, increasing the CL content to 20 or 40 mol% (at low ionic strength) resulted in a different behavior of FRET profiles, inconsistent with the concepts of equilibrium adsorption of cytochrome c at the membrane surface and/or uniform acceptor distribution. To explain this fact, several possibilities are analyzed, including cytochrome c-induced formation of non-bilayer structures and clusters of charged lipids, or changes in the depth of cytochrome c penetration into the bilayer depending on the protein surface density. Additional control experiments have shown that only the latter process can explain the peculiar concentration dependences of FRET at high CL content.     

Loss of molecular interaction between cytochrome c and cardiolipin due to lipid peroxidation.

To explore the molecular mechanism underlying the translocation of cytochrome c from the mitochondrial inner membrane to the cytosol during apoptosis, we analyzed the molecular interaction between cytochrome c and cardiolipin (CL) by (1)H NMR spectroscopy. Bovine heart CL induced a drastic broadening of the linewidth of the downfield signals at 31.4 and 34.2 ppm assigned to the heme methyl group-3 and -8, respectively, of horse heart cytochrome c. In contrast, CL mono- and dihydroperoxides were less active in broadening the signals than CL, and CL trihydroperoxides induced almost no broadening of their linewidth. This finding suggests that the peroxidation of CL induces a release of cytochrome c from mitochondria into the cytosol, which release induces apoptosis in the cells.     

Cytochrome C interaction with cardiolipin/phosphatidylcholine model membranes: effect of cardiolipin protonation

Resonance energy transfer between anthrylvinyl-labeled phosphatidylcholine as a donor and heme moiety of cytochrome c (cyt c) as an acceptor has been employed to explore the protein binding to model membranes, composed of phosphatidylcholine and cardiolipin (CL). The existence of two types of protein-lipid complexes has been hypothesized where either deprotonated or partially protonated CL molecules are responsible for cyt c attachment to bilayer surface. To quantitatively describe cyt c membrane binding, the adsorption model based on scaled particle and double layer theories has been employed, with potential-dependent association constants being treated as a function of acidic phospholipid mole fraction, degree of CL protonation, ionic strength, and surface coverage. Multiple arrays of resonance energy transfer data obtained under conditions of varying pH, ionic strength, CL content, and protein/lipid molar ratio have been analyzed in terms of the model of energy transfer in two-dimensional systems combined with the adsorption model allowing for area exclusion and electrostatic effects. The set of recovered model parameters included effective protein charge, intrinsic association constants, and heme distance from the bilayer midplane for both types of protein-lipid complexes. Upon increasing CL mole fraction from 10 to 20 mol % (the value close to that characteristic of the inner mitochondrial membrane), the binding equilibrium dramatically shifted toward cyt c association with partially protonated CL species. The estimates of heme distance from bilayer center suggest shallow bilayer location of cyt c at physiological pH, whereas at pH below 6.0, the protein tends to insert into membrane core.     

Cytochrome c biogenesis in mitochondria--Systems III and V

In c-type cytochromes, heme becomes covalently attached to the polypeptide chain by a reaction between the vinyl groups of the heme and cysteine thiols from the protein. There are two such cytochromes in mitochondria: cytochrome c and cytochrome c(1). The heme attachment is a post-translational modification that is catalysed by different biogenesis proteins in different organisms. Three types of biogenesis system are found or predicted in mitochondria: System I (the cytochrome c maturation system); System III (termed holocytochrome c synthase (HCCS) or heme lyase); and System V. This review focuses primarily on cytochrome c maturation in mitochondria containing HCCS (System III). It describes what is known about the enzymology and substrate specificity of HCCS; the role of HCCS in human disease; import of HCCS into mitochondria; import of apocytochromes c and c(1) into mitochondria and the close relationships with HCCS-dependent heme attachment; and the role of the fungal cytochrome c biogenesis accessory protein Cyc2. System V is also discussed; this is the postulated mitochondrial cytochrome c biogenesis system of trypanosomes and related organisms. No cytochrome c biogenesis proteins have been identified in the genomes of these organisms whose c-type cytochromes also have a unique mode of heme attachment.     

Control of the redox potential of cytochrome c and microscopic dielectric effects in proteins

X-ray structural information provides the opportunity to explore quantitatively the relation between the microenvironments of heme proteins and their redox potentials. This can be done by considering the protein as a "solvent" for its redox center and calculating the difference between the electrostatic energy of the reduced and oxidized heme. Such calculations are presented here, applying the protein dipoles-Langevin dipoles (PDLD) model to cytochrome c. The calculations focus on an evaluation of the difference between the redox potentials of cytochrome c and the octapeptide-methionine complex formed by hydrolysis of cytochrome c. The corresponding difference (approximately 7 kcal/mol) is accounted for by the PDLD calculations. It is found that the protein provides basically a low dielectric environment for the heme, which destabilizes the oxidized heme (relative to its energy in water). The effect of the charged propionic acids on the heme is examined in a preliminary way. It is found that the negative charges of these groups are in a hydrophilic rather than a hydrophobic environment and that the protein-water system provides an effective high dielectric constant for their interaction with the heme. The dual nature of the dielectric effect of the cytochrome (a low dielectric constant for the self-energy of the heme and a high dielectric constant for charge-charge interactions) is discussed. The findings of this work are consistent with the difference between the folding energies of the reduced and oxidized cytochrome c.     

Electron transfer chain reaction of the extracellular flavocytochrome cellobiose dehydrogenase from the basidiomycete Phanerochaete chrysosporium

Cellobiose dehydrogenase (CDH) is an extracellular flavocytochrome containing flavin and b-type heme, and plays a key role in cellulose degradation by filamentous fungi. To investigate intermolecular electron transfer from CDH to cytochrome c, Phe166, which is located in the cytochrome domain and approaches one of propionates of heme, was mutated to Tyr, and the thermodynamic and kinetic properties of the mutant (F166Y) were compared with those of the wild-type (WT) enzyme. The mid-point potential of heme in F166Y was measured by cyclic voltammetry, and was estimated to be 25 mV lower than that of WT at pH 4.0. Although presteady-state reduction of flavin was not affected by the mutation, the rate of subsequent electron transfer from flavin to heme was halved in F166Y. When WT or F166Y was reduced with cellobiose and then mixed with cytochrome c, heme re-oxidation and cytochrome c reduction occurred synchronously, suggesting that the initial electron is transferred from reduced heme to cytochrome c. Moreover, in both enzymes the observed rate of the initial phase of cytochrome c reduction was concentration dependent, whereas the second phase of cytochrome c reduction was dependent on the rate of electron transfer from flavin to heme, but not on the cytochrome c concentration. In addition, the electron transfer rate from flavin to heme was identical to the steady-state reduction rate of cytochrome c in both WT and F166Y. These results clearly indicate that the first and second electrons of two-electron-reduced CDH are both transferred via heme, and that the redox reaction of CDH involves an electron-transfer chain mechanism in cytochrome c reduction.     

Mechanism of peroxynitrite interaction with cytochrome c

Kinetics of the reaction of peroxynitrite with ferric cytochrome c in the absence and presence of bicarbonate was studied. It was found that the heme iron in ferric cytochrome c does not react directly with peroxynitrite. The rates of the absorbance changes in the Soret region of cytochrome c spectrum caused by peroxynitrite or peroxynitrite/bicarbonate were the same as the rate of spontaneous isomerization of peroxynitrite or as the rate of the reaction of peroxynitrite with bicarbonate, respectively. This means that intermediate products of peroxynitrite decomposition, (.)OH/(.)NO(2) or, in the presence of bicarbonate, CO(3)(-)(.)/(.)NO(2), are the species responsible for the absorbance changes in the Soret band of cytochrome c. Modifications of the heme center of cytochrome c by radiolytically produced radicals, (.)OH, (.)NO(2) or CO(3)(-)(.), were also studied. The absorbance changes in the Soret band caused by radiolytically produced (.)OH or CO(3)(-)(.) were much more significant that those observed after peroxynitrite treatment, compared under similar concentrations of radicals. (.)NO(2) produced radiolytically did not interact with the heme center of cytochrome c. Cytochrome c exhibited an increased peroxidase-like activity after reaction with peroxynitrite as well as with radiolytically produced (.)OH, (.)NO(2) or CO(3)(-)(.) radicals. This means that modification of protein structure: oxidation of amino acids and/or tyrosine nitration, facilitates reaction of H(2)O(2) with the heme iron of cytochrome c, followed by reaction with the second substrate.     

Cytochrome c1 from Paracoccus denitrificans

Cytochrome c1 was purified from the bacterium Paracoccus denitrificans. It is an acidic, hydrophobic polypeptide with an apparent molecular weight of around 65000 and a single, covalently attached heme; it cross-reacts immunologically with cytochrome c1 from yeast mitochondria. The amino acid sequence of the tryptic heme peptide of the bacterial cytochrome c1 shows extensive homology to the corresponding region of beef heart cytochrome c1 [Wakabayashi, S. et al. (1982) J. Biol. Chem. 257, 9335-9344]. Positive evidence for a stable association of the Paracoccus cytochrome c1 with other polypeptides and b-type heme components ('bc1-complex') has not yet been obtained.     

The cytochrome c oxidase-cytochrome c complex: spectroscopic analysis of conformational changes in the protein-protein interaction domain

Binding to cytochrome c oxidase induces a conformational change in the cytochrome c molecule. This conformational change has been characterized by comparing the binding of native cytochrome c and chemically modified cytochrome c derivatives to bovine cytochrome c oxidase by using absorption, circular dichroism (CD), and magnetic circular dichroism (MCD) spectroscopy. The following derivatives were analyzed: (i) cytochrome c modified at all 19 lysine residues to yield the (N epsilon-acetimidyl)19 cytochrome c, (N epsilon-isopropyl)19 cytochrome c, and (N epsilon,N epsilon-dimethyl)19 cytochrome c; (ii) cytochrome c in which Met65 and Met80 are converted to the methionine sulfoxide; (iii) cytochrome c with a single break in the polypeptide chain at Arg38 or Gly37. The derivatives bind to cytochrome c oxidase at a ratio of one heme c per heme aa3. The association constants are similar to that of native cytochrome c except for (N epsilon-isopropyl)19 and (N epsilon,N epsilon-dimethyl)19 cytochromes c, which bind respectively four times and six times less strongly. The derivatives are good substrates for the cytochrome c oxidase reaction. The spectral changes accompanying the binding of the modified cytochromes c to cytochrome c oxidase are quite different from the spectral changes observed with native cytochrome c. The different optical absorption and MCD changes are explained by a polarity change around the exposed heme edge in the cytochrome c-cytochrome c oxidase complex. The CD changes indicate a conformational rearrangement restricted to the surface area surrounding the exposed heme edge. The rearrangement may involve a movement of the evolutionarily conserved Phe82 out of the vicinity of the heme.(ABSTRACT TRUNCATED AT 250 WORDS)