Coupling between 3-ketosteroid-delta'-dehydrogenase and the respiratory chain in the bacterium Arthrobacter globiformis

Intact bacterial cells and their cytoplasmic membranes obtained by ultrasonic desintegration are able to induce dehydration of hydrocortisone to prednisolone that is coupled with O2 uptake. This reaction is inhibited by cyanide and 2-n-nonyl-4-hydroxyquinoline-N-oxide (HOQNO). Oxidation of hydrocortisone results in cytochrome reduction both in intact cells and in cytoplasmic membranes. Aerobic dehydration of hydrocortisone is linked with transmembrane potential generation. The data obtained suggest that the electron translocation from 3-ketosteroid-delta'-dehydrogenase to O2 occurs via the respiratory chain. The enzyme donates reduced equivalents directly to the respiratory chain, presumably at the level of menaquinone.     

Kinetic model for the regulation of redox reaction in steroid transformation by Arthrobacter globiformis cells

A kinetic model of hydrocortisone transformation was developed in studies of the kinetics of biochemical systems. The regulatory bases of the model are the biosynthesis of steroid-transforming enzymes and their activity, the level of endogenous substrates, the respiratory chain activity, and the initial concentrations of reagents. When compared, the experimental data completely coincide with the results of the computer modeling, the coincidence being not only qualitative but also quantitative. It indicates that the model suggested can be used for further studies of other transformations of steroid compounds, as well as for transformation of steroid compounds under close-to-biotechnological conditions. The results obtained by means of this model permit one to trace in dynamics the behavior of a number of parameters characterizing the process which is very difficult or not feasible to do in a biochemical experiment. The following was shown: (1) the behavior of the respiratory chain (the reversible transition of its oxidized and reduced forms); (2) the change of the transmembrane potential of hydrogen ions within a far larger stretch of time than is feasible to register in a biochemical experiment; (3) the regulation of the activity of 20beta-hydroxysteroid dehydrogenase and 1, 2-reductase not only by the change in the level of endogenous substrates, but also by means of their biosynthesis; and (4) the regulatory role of 3-ketosteroid-1-en-dehydrogenase.     

Epithelial cells infected with respiratory syncytial virus are resistant to the anti-inflammatory effects of hydrocortisone

In this work we continue our study of the biochemical responses of respiratory epithelial cells to infection with human paramyxovirus pathogens. In our earlier studies, we detected elevated concentrations of the proinflammatory chemokines MIP-1alpha and IL-8 in upper and lower respiratory tract secretions from patients infected with respiratory syncytial virus (RSV). Here we demonstrate the same trend for individuals infected with parainfluenza virus (PIV), with elevated concentrations of MIP-1alpha and IL-8 (means of 309 +/- 51 and 2280 +/- 440 pg/ml/mg protein, respectively) detected in nasal wash samples from 17 patients with culture-positive PIV. Similar to our findings with RSV, cells of the HEp-2 epithelial line and primary cultures of human bronchial epithelial cells respond to PIV infection with production and release of both MIP-1alpha and IL-8. Addition of the glucocorticoid anti-inflammatory agent hydrocortisone (200-1000 ng/ml) attenuated the production of MIP-1alpha and IL-8 in PIV-infected cells while having minimal to no effect on the production of these mediators from cells infected with RSV. Neither virus infection resulted in a change in the total cellular concentration of glucocorticoid receptors, nor did hydrocortisone exert any differential effect on viral replication. As repression of chemokine production by epithelial cells is likely to result in diminished recruitment of proinflammatory leukocytes, these results may explain in part why glucocorticoid therapy reduces the symptoms associated with acute PIV infection, but have little to no effect in the overall outcome in the case of RSV.     

Competition of electrons to enter the respiratory chain: a new regulatory mechanism of oxidative metabolism in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the most important systems for conveying excess cytosolic NADH to the mitochondrial respiratory chain are the external NADH dehydrogenases (Nde1p and Nde2p) and the glycerol-3-phosphate dehydrogenase shuttle. In the latter system, NADH is oxidized to NAD+ and dihydroxyacetone phosphate is reduced to glycerol 3-phosphate by the cytosolic Gpd1p. Subsequently, glycerol 3-phosphate donates electrons to the respiratory chain via mitochondrial glycerol-3-phosphate dehydrogenase (Gut2p). At saturating concentrations of NADH, the activation of external NADH dehydrogenases completely inhibits glycerol 3-phosphate oxidation. Studies on the functionally isolated enzymes demonstrated that neither Nde1p nor Nde2p directly inhibits Gut2p. Thus, the inhibition of glycerol 3-phosphate oxidation may be caused by competition for the entrance of electrons into the respiratory chain. Using single deletion mutants of Nde1p or Nde2p, we have shown that glycerol 3-phosphate oxidation via Gut2p is inhibited fully when NADH is oxidized via Nde1p, whereas only 50% of glycerol 3-phosphate oxidation is inhibited when Nde2p is functioning. By comparing respiratory rates with different respiratory substrates, we show that electrons from Nde1p are favored over electrons coming from Ndip (internal NADH dehydrogenase) and that when electrons come from either Nde1p or Nde2p and succinodehydrogenase, their use by the respiratory chain is shared to a comparable extent. This suggests a very specific competition for electron entrance into the respiratory chain, which may be caused by the supramolecular organization of the respiratory chain. The physiological consequences of such regulation are discussed.     

Hydrocortisone inhibits the respiratory burst oxidase from human neutrophils in whole-cell and cell-free systems

The effects of hydrocortisone on the respiratory burst oxidase (NADPH oxidase, EC 1.6.99.6) from human neutrophils in both whole-cell and full soluble (cell-free) systems were investigated. In the whole-cell system, hydrocortisone inhibited the generation of superoxide by neutrophils exposed to phorbol myristate acetate, suggesting that steroids inhibit the bactericidal capacity of the body in an acute inflammatory phase. Hydrocortisone, which was added to the cuvette after the addition of NADPH and before the addition of sodium dodecyl sulfate, in a cell-free system, was found to inhibit the activation of superoxide-generating NADPH oxidase by sodium dodecyl sulfate. The concentration of hydrocortisone required for 50% inhibition of oxidase was 40 microM. Its inhibition was dose- and time-dependent in the cell-free system. However, hydrocortisone did not alter the Km of the oxidase for NADPH. These results suggest that steroids inhibit the reconstitution of NADPH oxidase by sodium dodecyl sulfate in the cell-free system, and that they do not alter the affinity to NADPH of the oxidase.     

Identification of a protein mediating respiratory supercomplex stability

The complexes of the electron transport chain associate into large macromolecular assemblies, which are believed to facilitate efficient electron flow. We have identified a conserved mitochondrial protein, named respiratory supercomplex factor 1 (Rcf1-Yml030w), that is required for the normal assembly of respiratory supercomplexes. We demonstrate that Rcf1 stably and independently associates with both Complex III and Complex IV of the electron transport chain. Deletion of the RCF1 gene caused impaired respiration, probably as a result of destabilization of respiratory supercomplexes. Consistent with the hypothetical function of these respiratory assemblies, loss of RCF1 caused elevated mitochondrial oxidative stress and damage. Finally, we show that knockdown of HIG2A, a mammalian homolog of RCF1, causes impaired supercomplex formation. We suggest that Rcf1 is a member of an evolutionarily conserved protein family that acts to promote respiratory supercomplex assembly and activity.     

Neurodevelopmental Outcomes of Extremely Preterm Infants Randomized to Stress Dose Hydrocortisone

Objective

To compare the effects of stress dose hydrocortisone therapy with placebo on survival without neurodevelopmental impairments in high-risk preterm infants.

Study Design

We recruited 64 extremely low birth weight (birth weight ≤1000g) infants between the ages of 10 and 21 postnatal days who were ventilator-dependent and at high-risk for bronchopulmonary dysplasia. Infants were randomized to a tapering 7-day course of stress dose hydrocortisone or saline placebo. The primary outcome at follow-up was a composite of death, cognitive or language delay, cerebral palsy, severe hearing loss, or bilateral blindness at a corrected age of 18–22 months. Secondary outcomes included continued use of respiratory therapies and somatic growth.

Results

Fifty-seven infants had adequate data for the primary outcome. Of the 28 infants randomized to hydrocortisone, 19 (68%) died or survived with impairment compared with 22 of the 29 infants (76%) assigned to placebo (relative risk: 0.83; 95% CI, 0.61 to 1.14). The rates of death for those in the hydrocortisone and placebo groups were 31% and 41%, respectively (P = 0.42). Randomization to hydrocortisone also did not significantly affect the frequency of supplemental oxygen use, positive airway pressure support, or need for respiratory medications.

Conclusions

In high-risk extremely low birth weight infants, stress dose hydrocortisone therapy after 10 days of age had no statistically significant effect on the incidence of death or neurodevelopmental impairment at 18–22 months. These results may inform the design and conduct of future clinical trials.

Trial Registration

ClinicalTrials.gov NCT00167544     

Functional dynamic compartmentalization of respiratory chain intermediate substrates: implications for the control of energy production and mitochondrial diseases

Activity defects in respiratory chain complexes are responsible for a large variety of pathological situations, including neuromuscular diseases and multisystemic disorders. Their impact on energy production is highly variable and disproportional. The same biochemical or genetic defect can lead to large differences in clinical symptoms and severity between tissues and patients, making the pathophysiological analysis of mitochondrial diseases difficult. The existence of compensatory mechanisms operating at the level of the respiratory chain might be an explanation for the biochemical complexity observed for respiratory defects. Here, we analyzed the role of cytochrome c and coenzyme Q in the attenuation of complex III and complex IV pharmacological inhibition on the respiratory flux. Spectrophotometry, HPLC–EC, polarography and enzymology permitted the calculation of molar ratios between respiratory chain components, giving values of 0.8:61:3:12:6.8 in muscle and 1:131:3:9:6.5 in liver, for CII:CoQ:CIII:Cyt c:CIV. The results demonstrate the dynamic functional compartmentalization of respiratory chain substrates, with the existence of a substrate pool that can be recruited to maintain energy production at normal levels when respiratory chain complexes are inhibited. The size of this reserve was different between muscle and liver, and in proportion to the magnitude of attenuation of each respiratory defect. Such functional compartmentalization could result from the recently observed physical compartmentalization of respiratory chain substrates. The dynamic nature of the mitochondrial network may modulate this compartmentalization and could play a new role in the control of mitochondrial respiration as well as apoptosis.     

Reactivity with ubiquinone of quinoprotein D-glucose dehydrogenase from Gluconobacter suboxydans

D-Glucose dehydrogenase is a pyrroloquinoline quinone-dependent oxidoreductase linked to the respiratory chain of a wide variety of bacteria. There is a controversy as to whether the glucose dehydrogenase is linked to the respiratory chain via ubiquinone or cytochrome b. In this study, it was shown that the glucose dehydrogenase of Gluconobacter suboxydans has the ability to react directly with ubiquinone. The enzyme purified from the membranes of G. suboxydans was able to react with ubiquinone homologues such as ubiquinone-1, -2, or -6 in detergent solution. Furthermore, in order to demonstrate the reactivity of the enzyme with native ubiquinone, ubiquinone-10, in the native membranous environment, the dehydrogenase was reconstituted together with cytochrome o, the terminal oxidase of the respiratory chain, into a phospholipid bilayer containing ubiquinone-10. The proteoliposomes thus reconstituted exhibited a reasonable glucose oxidase activity, the electron transfer reaction of which was able to generate a membrane potential and a pH gradient. Thus, D-glucose dehydrogenase of G. suboxydans has been demonstrated to donate electrons directly to ubiquinone in the respiratory chain.     

Steady-state kinetics of the overall oxidative phosphorylation reaction in heart mitochondria. Evidence for linkage of the energy-yielding and energy-consuming steps by freely diffusible intermediates and for an allosteric mechanism of respiratory control at coupling site 2

The three coupling segments of the respiratory chain of bovine heart mito-chondria were examined individually by steady-state kinetic methods to determine whether or not freely diffusible intermediates occur between the energy-yielding and energy-consuming steps involved in the oxidative phosphorylation of extramitochondrial ADP. The principal method employed was the dual inhibitor technique, for which an appropriate model is provided. The results indicate that in accordance with the chemiosmotic theory the intermediate reactants that link the energy-yielding rotenone-sensitive (Site 1), cytochromebc ₁ (Site 2), and cytochromeaa ₃ (Site 3) reactions of the respiratory chain to the energy-consuming ATP synthetase, AdN transport, and P_i transport reactions are freely diffusible (delocalized). Site 2 was found to differ from the others in regard to the mechanism by which the energy-linked respiratory chain reaction is controlled by the energy-consuming steps. Whereas the Site 1 and Site 3 respiratory chain reactions are controlled primarily by the thermodynamic mechanism of reaction reversal, the Site 2 respiratory reaction is controlled primarily by a kinetic mechanism in which an intermediate that links it to the energy-consuming steps inhibits it allosterically. From the effects of nigericin and valinomycin the allosteric intermediate appears to be the electrical component of the protonmotive force.     

Role of mitochondrial NADH kinase and NADPH supply in the respiratory chain activity of Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the mitochondrial nicotinamide adenine dinucleotide hydride kinase Pos5p is required for a variety of essential cellular pathways, most importantly respiration. The Pos5p knockout strain pos5Δ grows poorly in non-fermentable media. A potential relationship between this respiratory deficiency and the ability of the cells to supply nicotinamide adenine dinucleotide phosphate (NADPH) was examined by analyzing the respiratory chain activity of pos5Δ and two NADP(+)-specific dehydrogenase mutants, idp1Δ and zwf1Δ. All of the respiratory chain complexes of pos5Δ exhibited poor relative activity of <26% at the middle-log phase and 62% at the stationary phase. The respiratory chain activity levels of idp1Δ and zwf1Δ also reduced to 22%-37% and 28%-84% at the middle-log phase, and 73%-81% and 67%-88% at the stationary phase, not as robustly as those of pos5Δ. The double-mutant idp1pos5Δ exhibited even lower activities of <20% at the middle-log phase, but zwf1pos5Δ showed similar activities with pos5Δ. The complemented strain POS5/pos5Δ exhibited 1.05- to 3-fold higher activities than pos5Δ. These data showed that Pos5p contributes to the maintenance of respiratory chain complex activities, with other NADPH sources, such as Idp1p and Zwf1p, making a smaller contribution. These contributions were partly related to the ability of the cells to supply NADPH, especially in the mitochondria.     

The purification and characterization of the cytochrome d terminal oxidase complex of the Escherichia coli aerobic respiratory chain

The aerobic respiratory chain of Escherichia coli is branched. In aerobically grown cells harvested in midexponential phase, a respiratory chain containing only b-type cytochromes is predominant. This chain contains a terminal oxidase which is a b-type cytochrome, referred to as cytochrome o. However, when the bacteria are grown under conditions of oxygen limitation, additional components of the respiratory chain are induced, as evidenced by the appearance of new spectroscopic species. These include a new b-type cytochrome, cytochrome b558, as well as cytochrome a1 and cytochrome d. In this paper, a purification protocol and the initial characterization of the terminal oxidase complex containing cytochrome d are reported. Solubilization of the membrane is effected by Zwittergent 3-12, and purification is accomplished by chromatography with DEAE-Sepharose CL-6B and hydroxyapatite. The complex contains cytochrome b558, a1, and d. Analysis by sodium dodecyl sulfate-polyacrylamide gels indicates that the complex contains only two types of polypeptides with the molecular weights estimated to be 57,000 and 43,000. The purified complex has oxidase activity in the presence of detergents, utilizing substrates including ubinquinol-1, N,N,N',N'-tetramethyl-p-phenylenediamine, and 2,3,5,6-tetramethyl-p-phenylenediamine. The cytochrome d complex contains protoheme IX and iron, but does not contain nonheme iron or copper. Approximately half of the cytochromes which are thought to participate in E. coli aerobic respiration are accounted for by this single complex. These results suggest that the E. coli aerobic respiratory chain is organized around a relatively small number of cytochrome-containing complexes.     

Effect of glucocorticoids on the endocrine system of the pancreas of the pigeon and rat after a food load

The level of 35S-methionine incorporation (in 15, 30 min, 1, 2, 3, 6, 12, 24 h) has been investigated in A- and B-cells of the pigeon and rat pancreatic islets against the background of excessive injection of hydrocortisone. The pigeon and rat A- and B-endocrinocytes respond in a similar was to the excess of hydrocortisone. An accelerated elimination of the isotope from the pigeon A- and B-endocrinocytes is noted, while in the rat the effect of the excessive hydrocortisone is opposite.     

线粒体呼吸链与活性氧

已知有氧真核生物细胞吸收的氧分子绝大部分都是在线粒体呼吸链末端细胞色素氧化酶上通过四步单电子还原生成水。但同时也有1％-2％的氧可在呼吸链中途接受单电子或双电子被部分还原生成超氧（O2·^-和过氧化氢（H2O2）作为呼吸作用的正常代谢产物。此种来源于线粒体呼吸链的O2·^-和H2O2不但在多种病理的氧化损伤中起关键作用,同样它们也是正常生理条件下对多种细胞过程具有基本调控意义的氧还信号。基于Chance实验室约自20世纪70到90年代的早期研究贡献以及20世纪90年代后其他各实验室的研究新进展,我们聚焦于下述四个相关问题的评述和讨论：（1）由于线粒体内膜面积及其含有的呼吸链复合体酶活力远远高出细胞中所有膜系数量和相关酶活力之总和,因而线粒体呼吸链产生的O2·^-和H2O2构成生物体内最大数量ROS的恒定来源;（2）线粒体呼吸链复合体III的Q循环中Qo位点中半醌自由基（UQH·）已明确是O2·^-的单电子来源;还原细胞色素C-P66^SHC是生成H2O2的双电子供体。虽然复合体I也是产生线粒体基质内O2·^-的主要来源,但由于其确切生成位点尚未明确,在invivo条件下能否产生大量O2·^-也尚有争议;（3）线粒体呼吸链产生O2·^-后的分配和跨膜转移涉及其生理病理作用机制和作用靶点等复杂而重要的问题,直到目前尚未意见一致。“质子和O2·^-循环双回路解偶联模型”整合了目前提出的几种假说的联系点,指出H^＋和O2·^-相互作用生成HO2·及其跨膜很可能是这一复杂问题的中心环节,并与O2·^-对“脂肪酸shuttling model”或O2·^-对“UCPS激活”模型形成了内在的联系;（4）线粒体呼吸形成的△P（△ψ和△pH）能直接控制呼吸链的ROS生成,并以非线性（非欧姆）相关方式通过影响Q循环中的Qo半醌的氧还态和寿命来调节O2·^-生成的急速?     

Synchronization of the function of respiratory chain enzymes and ATP-synthetase in energized mitochondria

The present study revealed that the previously described effect of ATP-synthetase inhibition concomitant with inhibition of the respiratory chain functioning could be observed under different absolute values of delta phi on the mitochondrial membrane. This points out that the membrane potential is not a unique regulator in the coupling of the ATP-synthetase and respiratory chain activities. At the same time, we succeeded in obtaining some evidence testifying that under conditions of ATP-synthetase inhibition the amount of functioning respiratory chains has to be proportional the functioning of the ATP-synthetases units. The osmolarity of the incubation medium was shown to control the state of the oxidative phosphorylation system. The respiratory chain and ATP-synthetase should be considered as an enzymatic supercomplex only when the osmolarity is close to 150-300 mOsm (within the physiological range). The coupling effectivity (ADP/O) of mitochondria under these conditions is maximal. It is concluded that the respiratory chain and ATP-synthetase are tightly bound from the kinetic point of view. The ATP-synthetase inhibition induces proportional inhibition of the respiratory chain enzymes and vice versa, the respiratory chain inhibition induces proportional inhibition of ATP-synthetase.