Succinate oxidation by coupled potato tuber mitochondria followed by rapid scan spectrometry

Oxidation of succinate by potato tuber mitochondria has been investigated from aerobiosis to complete anuerobiosis. Difference spectra of the various steps were recorded by a rapid scan spectrometer delivering averaged spectra every 3 s in the range 380 to 630 mm. The transitions between state 3 and 4 resulted in large redox changes, essentially for the b cytochromes, and in significant changes in the spectral baseline (light scattering). At anaerobiosis the cytochromes c, c₁ and a were reduced while cytochrome a, remained oxidized. – Addition of uncouplers in aerobiosis induced oxidation of the b cytochromes, and when anaerobiosis occurred cytochromes c, c₁a and a₃ were reduced simultaneously. When uncouplers were added in anaerobiosis a partial oxidation of the b cytochromes and the reduction of cytochrome a₃ were observed. These results are interpreted as the building up of a membrane potential, maximal in state 4 and stable after anaerobiosis. The cytochromes buried in the membrane equilibrate with the membrane potential, and their redox states are sensitive to the changes. Variations of membrane potential also induce changes in the light scattering by the mitochondrial membrane.     

Illumination with blue light reactivates respiratory activity of mitochondria inhibited by nitric oxide, but not by glycerol trinitrate

Nitric oxide (NO) is known to inhibit mitochondrial respiration reversibly. This study aimed at clarifying whether low level illumination at specific wavelengths recovers mitochondrial respiration inhibited by NO and glycerol-trinitrate (GTN), a clinically used NO mimetic. NO fully inhibited respiration of liver mitochondria at concentrations occurring under septic shock. The respiration was completely restored by illumination at the wavelength of 430 nm while longer wavelengths were less effective. GTN inhibited mitochondrial respiration though the efficiency of GTN was lower compared to NO concentrations observed in sepsis models. However, GTN inhibition was absolutely insensitive to illumination regardless of wavelength used. Our data show that visible light of short wavelengths efficiently facilitates the recovery of mitochondria inhibited by NO-gas at the levels generated under septic conditions. The inhibition of mitochondrial respiration by GTN is not sensitive to visible light, suggesting an inhibition mechanism other that NO mediation.     

Resonance Raman quantification of the redox state of cytochromes b and c in‐vivo and in‐vitro

We observe the redox state changes with respiration of cytochromes b and c in mitochondria in a living Saccharomyces cerevisiae cell as well as in isolated mitochondria with the very use of Raman microspectroscopy. The possibility of monitoring the respiration activity of mitochondria in vivo and in vitro by Raman microspectroscopic quantification of the cytochrome redox states is suggested. It will lead to a new means to assess mitochondrial respiration activity in vivo and in vitro without using any labelling or genetic manipulation. (© 2012 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Rapid scan spectrometry: oxidation of substrates by coupled potato mitrochondria

By rapid scan spectrometry, spectral changes of redox components have been followed during the oxidation of substrates by coupled potato ( Solanum luberosum L. cv . Bintje) mitochondria under different redox conditions. The redox changes of the b cytochromes, the changes in the base line level and in the slope of the spectra during aerobiosis appear to be connected with changes of the membrane potential. As the latter does not collaps at anaerobiosis, cytochrome o₃ remains in an oxidized state. Collapse of the membrane potential by uncouplers induces partial oxidation of the b cytochromes and reduction of cytochrome a ₃, so that toe resulting redox states derive from thermodynamic equilibrium with the redox conditions of the substrates. However, in aerobiosis as well as in anaerobiosis, the amplitude changes of the b cytochromes vary with the substrate oxidized as if these components were not always completely connected with the cytochrome oxidase complex. The b cytochromes become fuliy reduced only after dithionite reduction.     

How might you compare mitochondria from different tissues and different species?

Mitochondria were isolated from the liver, kidney and mixed hindlimb skeletal muscle of three vertebrate species; the laboratory rat Rattus norvegicus, the bearded dragon lizard Pogona vitticeps, and the cane toad Bufo marinus. These vertebrate species are approximately the same body mass and have similar body temperatures. The content of cytochromes B, C, C1, and A were measured in these isolated mitochondria by oxidised–reduced difference spectra. Adenine nucleotide translocase (ANT) was measured by titration of mitochondrial respiration with carboxyactractyloside and the protein and phospholipid content of isolated mitochondria were also measured. Fatty acid composition of mitochondrial phospholipids was measured. Mitochondrial respiration was measured at 37°C under states III and IV conditions as well as during oligomycin inhibition. Species differed in the ratios of different mitochondrial cytochromes. Muscle mitochondria differed from kidney and liver mitochondria by having a higher ANT content relative to cytochrome content. Respiration rates were compared relative to a number of denominators and found to be most variable when expressed relative to mitochondrial protein content and least variable when expressed relative to mitochondrial cytochrome A and ANT content. The turnover of cytochromes was calculated and found to vary between 1 and 94 electrons s⁻¹. The molecular activity of mitochondrial cytochromes was found to be significantly positively correlated with the relative polyunsaturation of mitochondrial membrane lipids.     

Nitric oxide signalling: insect brains and photocytes

The success of insects arises partly from extraordinary biochemical and physiological specializations. For example, most species lack glutathione peroxidase, glutathione reductase and respiratory-gas transport proteins and thus allow oxygen to diffuse directly into cells. To counter the increased potential for oxidative damage, insect tissues rely on the indirect protection of the thioredoxin reductase pathway to maintain redox homoeostasis. Such specializations must impact on the control of reactive oxygen species and free radicals such as the signalling molecule NO. This chapter focuses on NO signalling in the insect central nervous system and in the light-producing lantern of the firefly. It is shown that neural NO production is coupled to both muscarinic and nicotinic acetylcholine receptors. The NO-mediated increase in cGMP evokes changes in spike activity of neurons controlling the gut and body wall musculature. In addition, maps of NO-producing and -responsive neurons make insects useful models for establishing the range and specificity of NO's actions in the central nervous system. The firefly lantern also provides insight into the interplay of tissue anatomy and cellular biochemistry in NO signalling. In the lantern, nitric oxide synthase is expressed in tracheal end cells that are interposed between neuron terminals and photocytes. Exogenous NO can activate light production and NO scavengers block evoked flashes. NO inhibits respiration in isolated lantern mitochondria and this can be reversed by bright light. It is proposed that NO controls flashes by transiently inhibiting oxygen consumption and permitting direct oxidation of activated luciferin. It is possible that light production itself contributes to the restoration of mitochondrial activity and consequent cessation of the flash.     

Effects of glucagon on the redox states of cytochromes in mitochondria in situ in perfused rat liver

The effects of glucagon on the respiratory function of mitochondria in situ were investigated in isolated perfused rat liver. Glucagon at the concentrations higher than 20 pM and cyclic AMP (75 microM) stimulated hepatic respiration, and shifted the redox state of pyridine nucleotide (NADH/NAD) in mitochondria in situ to a more reduced state as judged by organ fluorometry and beta-hydroxybutyrate/acetoacetate ratio. The organ spectrophotometric study revealed that glucagon and cyclic AMP induced the reduction of redox states of cytochromes a(a3), b and c+c1. Atractyloside (4 micrograms/ml) abolished the effects of glucagon on these parameters and gluconeogenesis from lactate. These observations suggest that glucagon increases the availability of substrates for mitochondrial respiration, and this alteration in mitochondrial function is crucial in enhancing gluconeogenesis.     

Respiration of Wild Type and Extrachromosomal Mutants of Neurospora crassa

The specific rates of respiration of cells of wild type and four extrachromosomal mutants of Neurospora crassa were measured throughout the vegetative growth cycle. Two forms of respiration were observed: (i) cyanide sensitive; and (ii) cyanide resistant, salicyl hydroxamate sensitive. These two forms are called terminal and alternate, respectively. The former proceeds by the mitochondrial electron transfer chain and involves the cytochromes; the latter apparently proceeds by the initial portion of the electron transfer chain and does not involve cytochromes. Large and rapid changes of both the terminal and alternate respiratory activities occurred during the vegetative growth cycle. The kinetics of these changes in wild type were compared under some conditions which inhibit protein synthesis and others in which the nitrogen source was varied. The kinetics of the changes of the two forms of respiration of mutants differed from those normally exhibited by wild type, but with varied experimental conditions wild type could be made to resemble the mutants. The results of these studies are discussed in terms of a dynamic model of regulation of mitochondrial biogenesis in the coordination of the synthesis of mitochondrial proteins encoded by nuclear and mitochondrial genomes.     

Fluorescent properties of c-type cytochromes reveal their potential role as an extracytoplasmic electron sink in Geobacter sulfurreducens

A novel fluorescence technique for monitoring the redox status of c-type cytochromes in Geobacter sulfurreducens was developed in order to evaluate the capacity of these extracytoplasmic cytochromes to store electrons during periods in which an external electron acceptor is not available. When intact cells in which the cytochromes were in a reduced state were excited at a wavelength of 350 nm, they fluoresced with maxima at 402 and 437 nm. Oxidation of the cytochromes resulted in a loss of fluorescence. This method was much more sensitive than the traditional approach of detecting c-type cytochromes via visible light absorbance. Furthermore, fluorescence of reduced cytochromes in individual cells could be detected via fluorescence microscopy, and the cytochromes in a G. sulfurreducens biofilm, remotely excited with an optical fibre, could be detected at distances as far as 5 cm. Fluorescence analysis of cytochrome oxidation and reduction of the external electron acceptor, anthraquinone-2,6-disulfonate, suggested that the extracytoplasmic cytochromes of G. sulfurreducens could store approximately 10(7) electrons per cell. Independent analysis of the haem content of the cells determined from analysis of incorporation of (55)Fe into cytochromes provided a similar estimate of cytochrome electron-storage capacity. This electron-storage capacity could, in the absence of an external electron acceptor, permit continued electron transfer across the inner membrane sufficient to supply the maintenance energy requirements for G. sulfurreducens for up to 8 min or enough proton motive force to power flagella motors for G. sulfurreducens motility. The fluorescence approach described here provides a sensitive method for evaluating the redox status of Geobacter species in culture and/or its environments. Furthermore, these results suggest that the periplasmic and outer-membrane cytochromes of Geobacter species act as capacitors, allowing continued electron transport, and thus viability and motility, for Geobacter species as they move between heterogeneously dispersed Fe(III) oxides during growth in the subsurface.     

Development of Respiration and Mitochondria in Mucor genevensis After Anaerobic Growth: Absence of Glucose Repression

Respiration and mitochondria in Mucor genevensis, a facultatively anaerobic dimorphic mold, have been studied in aerobically and anaerobically grown cells and in anaerobically grown cells adapting to aerobic conditions. Respiration in hyphae continues at a high level during aerobic growth but drops rapidly on exhaustion of glucose. In anaerobically grown yeastlike cells, containing no recognizable aerobic cytochromes, a small cyanide-insensitive respiration occurs. Mitochondria with well defined cristae are visible in negative contrast after KMnO(4) fixation of stringently anaerobic cells containing low amounts of fatty acid of which 10% or less are unsaturated. On aeration of anaerobically grown cells, respiratory capacity and cytochromes develop rapidly, even in the presence of 10% glucose, indicating that glucose does not repress development of respiration. However, mycelium formation by adapting yeastlike cells is repressed by high glucose concentration. In adapting cells, apparent changes in mitochondrial ultrastructure appear to be more related to changes in fixation properties of cells than to changes in the structure of mitochondria.     

Studies on the orientations of the mitochondrial redox carriers. II. Orientation of the mitochondrial chromophores with respect to the plane of the membrane in hydrated, oriented mitochondrial multilayers.

Orientations of the active site chromophores of the mitochondrial redox carriers have been investigated in hydrated, oriented multilayers of mitochondrial membranes using optical and EPR spectroscopy. The hemes of cytochrome c oxidase, cytochrome c1, and cytochromes b were found to be oriented in a similar manner, with the normal to their heme planes lying approximately in the plane of the mitochondrial membrane. The heme of cytochrome c was either less oriented in general or was oriented at an angle closer to the plane of the mitochondrial membrane than were the hemes of the "tightly bound" mitochondrial cytochromes. EPR spectra of the azide, sulfide and formate complexes of cytochrome c oxidase in mitochondria in situ obtained as a function of the orientation of the applied magnetic field relative to the planes of the membrane multilayers showed that both hemes of the oxidase were oriented in such a way that the angle between the heme normal and the membrane normal was approx. 90 degrees.     

Studies on the orientations of the mitochondrial redox carriers. I. Orientation of the hemes of cytochrome c oxidase with respect to the plane of a cytochrome oxidase-lipid model membrane.

The liganded derivatives of mitochondrial cytochrome c oxidase have been prepared in hydrated oriented multilayers of membranous cytochrome c oxidase. The optical spectra of the liganded derivatives recorded at an angle of 45 degrees between the incident light beam and the normal to the planes of the membranes in the multilayers show dichroic ratios of almost 2 in the visible region and 1.2-1.4 in the Soret region. The dichroic ratios were found to be similar for both cytochromes a and a3. Electron paramagnetic resonance spectra of the azide, sulfide, and formate complexes of cytochrome c oxidase obtained as a function of the orientation of the applied magnetic field relative to the planes of the membranes in the multilayer confirm the optical data and demonstrate that both hemes of cytochrome c oxidase are oriented such that the angle between the heme normal and the membrane normal is approximately 90 degrees.     

A rapid-scanning spectrophotometer designed for biological tissues in vitro or in vivo

Rapid and sensitive detection of optical signals from biological materials has been very useful in studies of cell physiology and biochemistry. A rapid-scanning spectrophotometer is described here that has the following advantages: (i) it can be used in transmission or reflection modes, (ii) it can rapidly accumulate spectra and simultaneous kinetic data, (iii) it has high accuracy and sensitivity, and (iv) it can analyze and store large amounts of spectral information. Evaluations described here are aimed toward the measurement of reduction/oxidation shifts of mitochondrial cytochromes in tissues, but the flexibility of the optical components makes this spectrophotometer adaptable to the study of light absorption changes of intrinsic or extrinsic optically active molecules in a variety of light scattering preparations, tissues, and organs in vitro or in vivo.     

Nitric oxide during ischemia attenuates oxidant stress and cell death during ischemia and reperfusion in cardiomyocytes

Nitric oxide (NO) has been implicated as a cardioprotective agent during ischemia/reperfusion (I/R), but the mechanism of protection is unknown. Oxidant stress contributes to cell death in I/R, so we tested whether NO protects by attenuating oxidant stress. Cardiomyocytes and murine embryonic fibroblasts were administered NO (10-1200 nM) during simulated ischemia, and cell death was assessed during reperfusion without NO. In each case, NO abrogated cell death during reperfusion. Cells overexpressing endothelial NO synthase (NOS) exhibited a similar protection, which was abolished by the NOS inhibitor N(omega)-nitro-l-arginine methyl ester. Protection was not mediated by guanylate cyclase or the mitochondrial K(ATP) channel, as inhibitors of these systems failed to abolish protection. NO did not prevent decreases in mitochondrial potential, but cells protected with NO demonstrated recovery of potential at reperfusion. Measurements using C11-BODIPY reveal that NO attenuates lipid peroxidation during ischemia and reperfusion. Measurements of oxidant stress using the ratiometric redox sensor HSP-FRET demonstrate that NO attenuates protein oxidation during ischemia. These findings reveal that physiological levels of NO during ischemia can attenuate oxidant stress both during ischemia and during reperfusion. This response is associated with a remarkable attenuation of cell death, suggesting that ischemic cell death may be a regulated event.     

Damage to mitochondrial electron transport and energy coupling by visible light

The effect of treating mitochondria with visible light above 400 nm on electron transport and coupled reactions was examined. The temporal sequence of changes was: stimulation of respiration coupled to ATP synthesis, a decline in ATP synthesis, inactivation of respiration, increased ATPase activity and, later, loss of the membrane potential. Loss of respiration was principally due to inactivation of dehydrogenases. Of the components of dehydrogenase systems, flavins and quinones were most susceptible to illumination, the iron-sulfur centers were remarkably resistant to being damaged. Succinate dehydrogenase was inactivated before choline and NADH dehydrogenase. Redox reactions of cytochromes and cytochrome c oxidase activity were unaffected.Inactivation was O₂-dependent and prevented by anaerobiosis or the presence of substrates for the dehydrogenases. Light in the range 400–500 nm was most effective and the presence of free flavins greatly enhanced inactivation of all of the above mitochondrial activities. This suggests that visible light mediates a flavin-photosensitized reaction that initiates damage involving participation of an activated species of oxygen in the damage propagation.     

Difference spectroscopy with respiratory membranes of an H2-oxidizing microorganism layered between two gas-permeable, plastic foils: a procedure that allows measurements in the ultraviolet range

A method for recording redox difference spectra of respiratory membranes which minimizes light scattering and results in increased sensitivity and spectral range when compared to the traditional technique of recording spectra of respiratory particles in suspension is described. Membranes were sandwiched between two gas-permeable, plastic foils, placed in a sealed cuvette, and gassed with H2 as reductant or O2 as oxidant. The membranes of the H2-oxidizing microorganism (Alcaligenes eutrophus H16) used in this work contain a hydrogenase which is coupled to the electron transport chain, thereby allowing H2 to serve as a source of electrons. With this procedure, spectra of both cytochromes and quinones were recorded. By using mixtures of H2 and O2, spectra of cytochromes between the fully oxidized and fully reduced states were recorded.     

Redox-linked conformational changes of a multiheme cytochrome from Geobacter sulfurreducens

Multiheme c-type cytochromes from members of the Desulfovibrionacea and Geobactereacea families play crucial roles in the bioenergetics of these microorganisms. Thermodynamic studies using NMR and visible spectroscopic techniques on tetraheme cytochromes c(3) isolated from Desulfovibrio spp. and more recently on a triheme cytochrome from Geobacter sulfurreducens showed that the properties of each redox centre are modulated by the neighbouring redox centres enabling these proteins to perform energy transduction and thus contributing to cellular energy conservation. Electron/proton transfer coupling relies on redox-linked conformational changes that were addressed for some multiheme cytochromes from the comparison of protein structure of fully reduced and fully oxidised forms. In this work, we identify for the first time in a multiheme cytochrome the simultaneous presence of two different conformations in solution. This was achieved by probing the different oxidation stages of a triheme cytochrome isolated from G. sulfurreducens using 2D-NMR techniques. The results presented here will be the foundations to evaluate the modulation of the redox centres properties by conformational changes that occur during the reoxidation of a multiheme protein.     

Optical methods for probing mitochondrial function in brain slices.

Brain slice preparations have become useful tools for studying multiple facets of normal brain function and for investigations of brain pathophysiology. Recently, a variety of neurological disorders have been linked to dysfunction of brain mitochondria. In this report we discuss optical methods for probing mitochondrial function in brain slices. Absorption spectrophotometric and spectrofluorometric techniques are described for measuring changes in the redox activity of mitochondrial cytochromes and the primary respiratory chain substrate nicotinamide adenine dinucleotide (NADH), respectively. A spectrofluorometric method is described also for measuring changes in mitochondrial membrane potential using the potential-sensitive fluorescent indicator JC-1. These methods used together have proven to be useful for studying dysfunction of mitochondria following in vitro ischemia in hippocampal slices, and might also be valuable for investigations of mitochondrial involvement in other neurological disorders.     

Redox potentials of the photosynthetic bacterial cytochromes c2 and the structural bases for variability.

The cytochromes c2 of the Rhodospirillaceae show a much greater variation in redox potential and its pH dependence than the mitochondrial cytochromes c that have been studied. It is proposed that the range of redox potential for cytochromes c2 functioning as the immediate electron donor to photo-oxidised bacteriochlorophyll may be 345-395 mV at pH 5. Closely related cytochromes c2 with different redox potentials show patterns of amino acid substitution which are consistent with changes in hydrophobicity near the haem being at least a partial determinant of redox potential. More distantly related cytochromes are difficult to compare because of the large number of amino acid substitutions and the probability that there are subtle changes in overall peptide chain folding. The redox potential versus pH curves can be analysed in terms of either one ionisation in the oxidised form or two in the oxidised form and one in the reduced. The pK in the oxidised form at higher pH values can be correlated with the pK for the disappearance or shift of the near infrared absorption band located near 695 nm. The structural bases of these ionisations are not known but the possible involvement of the haem propionate residues is discussed.     

Role of nitric oxide and mitochondria in control of firefly flash

In light-producing cells (photocytes) of the firefly light organ,mitochondria are clustered in the cell periphery, positionedbetween the tracheolar air supply and the oxygen-requiring bioluminescentreactants which are sequestered in more centrally-localizedperoxisomes. This relative positioning suggests that mitochondriacould control oxygen availability for the light reaction. Wehypothesized that active cellular respiration would make theinterior regions of the photocytes relatively hypoxic, and thatthe "on" signal for production of bioluminescence might dependon inhibition of mitochondrial oxygen consumption, which wouldallow delivered oxygen to pass through the peripheral mitochondrialzone to reach peroxisomes deep in the cell interior. We publishedrecently that exogenous NO induces bioluminescence in the intactfirefly; that NO mediates octopamine-induced bioluminescencein the dissected lantern, and that nitric oxide synthase isabundant in cells of the tracheolar system of the light organ.Additional experiments showed that nitric oxide gas (NO) inhibitsrespiration in isolated lantern mitochondria. Inhibition isreversed by bright light, and this inhibition is relieved whenthe light is turned off. Altogether, the results support theidea that NO triggers light production by reversible inhibitionof mitochondrial respiration in lantern cells, and probablyin tracheolar cells as well. The data also suggest that thelight of bioluminescence itself relieves NO inhibition thuscontributing to rapid on/off switching. While other mechanismsmay be in play, NO production that is directly related to neuralinput appears to have a key role in the oxygen gating that controlsflash communication signals.