Cytogenetic studies on natural intergeneric hybridization inAster alliances

Natural intergeneric hybrids betweenAster ageratoides subsp.ovatus (2n=36) andKalimeris incisa (2n=72) were found. All of the hybrids studied were found to have 2n=72, 18 more chromosomes than a regular F₁ hybrid. The hybrids were found to be of two types: one having 18 large chromosomes ofovatus, and the other having 9 large chromosomes of the same subspecies. In meiosis of the PMCs of the hybrid with 18 large chromosomes, a regular chromosome configuration, 36_II, was observed. In PMCs of the hybrid with 9 large chromosomes an irregularity of chromosome pairings was observed, showing varied chromosome configurations: 35_II+2_I, 34_II+4_I, 33_II+6_I, I_III+33_II+3_I, 1_IV+32_II+4_I, 32_II+8_I, 31_II+10_I, 29_II+14_I, 3_III+29_II+5_I. Most univalents were large, but a few were small. The hybrids with 18 large chromosomes were found to be partial amphidiploid and possessing double chromosome complements ofovatus. The hybrids with 9 large chromosomes were found to be the first backcrossed generation between the hybrid with 18 large chromosomes andK. incisa.     

Occurrence of two β-tubulin isoforms with different polymerizing abilities in L5178Y cells

Mouse lymphoma L5178Y cells express at least two isoforms of β-tubulin, designated Mβ_I, and Mβ_II, as revealed by isoelectrofocusing, whereas two independently isolated normal T-cell clones, 3D10 and K23, express only Mβ_I. Mβ_II-tubulin is more acidic (pI, 5.10) than Mβ_I-tubulin (pI, 5.15). L5178Y cells were disrupted under the microtubule-stabilizing conditions, followed by centrifugation to separate fractions containing polymerized and unpolymerized tubulin. We found that a proportion of Mβ_II to total β-tubulins is larger in the fraction containing unpolymerized tubulin than in that containing polymerized tubulin. In addition, when tubulin was purified from extracts of L5178Y cells by repeated cycles of polymerization-depolymerization, the Mβ_II-tubulin isoform was gradually lost during the successive purification steps. The low recovery of Mβ_II-tubulin was observed, irrespective of the presence or absence of MAPs, and even in the presence of an excess amount of essentially polymerizable porcine brain tubulin. These results indicate that Mβ_II-tubulin is less able to polymerize than is Mβ_I-tubulin, both in vivo and in vitro.     

The Intracellular Citrus Huanglongbing Bacterium, ‘Candidatus Liberibacter asiaticus’ Encodes Two Novel Autotransporters

Proteins secreted by the type V secretion system (T5SS), known as autotransporters, are large extracellular virulence proteins localized to the bacterial poles. In this study, we characterized two novel autotransporter proteins of ‘ Candidatus Liberibacter asiaticus’ (Las), and redesignated them as LasA_I and LasA_II in lieu of the previous names Hyv_I and Hyv_II. As a phloem-limited, intracellular bacterial pathogen, Las has a significantly reduced genome and causes huanglongbing (HLB), a devastating disease of citrus worldwide. Bioinformatic analyses revealed that LasA_I and LasA_II share the structural features of an autotransporter family containing large repeats of a passenger domain and a unique C-terminal translocator domain. When fused to the GFP gene and expressed in E. coli, the LasA_I C-terminus and the full length LasA_II were localized to the bacterial poles, similar to other members of autotransporter family. Despite the absence of a typical signal peptide, LasA_I was found to localize at the cell surface by immuno-dot blot using a monoclonal antibody against the partial LasA_I protein. Its surface localization was also confirmed by the removal of the LasA_I antigen using a proteinase K treatment of the intact bacterial cells. When co-inoculated with a P19 gene silencing suppressor and transiently expressed in tobacco leaves, the GFP-LasA_I translocator targeted to the mitochondria. This is the first report that Las encodes novel autotransporters that target to mitochondria when expressed in the plants. These findings may lead to a better understanding of the pathogenesis of this intracellular bacterium.     

Caloric restriction influences hydrogen peroxide generation in mitochondrial sub-populations from mouse liver

Calorie restriction (CR) has been shown to decrease H₂O₂ production in liver mitochondria, although it is not known if this is due to uniform changes in all mitochondria or changes in particular mitochondrial sub-populations. To address this issue, liver mitochondria from control and CR mice were fractionated using differential centrifugation at 1,000 g, 3,000 g and 10,000 g into distinct populations labeled as M1, M3 and M10, respectively. Mitochondrial protein levels, respiration and H₂O₂ production were measured in each fraction. CR resulted in a decrease in total protein (mg) in each fraction, although this difference disappeared when adjusted for liver weight (mg protein/g liver weight). No differences in respiration (State 3 or 4) were observed between control and CR mice in any of the mitochondrial fractions. CR decreased H₂O₂ production in all fractions when mitochondria respired on succinate (Succ), succ+antimycin A (Succ+AA) or pyruvate/malate+rotenone (P/M+ROT). Thus, CR decreased reactive oxygen species (ROS) production under conditions which stimulate mitochondrial complex I ROS production under both forward (P/M+ROT) and backward (Succ & Succ+AA) electron flow. The results indicate that CR decreases H₂O₂ production in all liver mitochondrial fractions due to a decrease in capacity for ROS production by complex I of the electron transport chain.     

Low temperature spectral properties of subchloroplast fractions purified from spinach

Spinach (Spinacia oleracea L.) chloroplasts solubilized by digitonin were separated into five fractions by sucrose density gradient centrifugation. Three of the fractions, F_I, F_II, and F_III, corresponding to photosystem I, photosystem II, and the chlorophyll a/b complex, were purified further by two steps of diethylaminoethyl-cellulose chromatography followed by electrofocusing on an Ampholine column. The polypeptide patterns of the fractions were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the spectral properties of the fractions at −196 C determined by absorption spectra, fourth derivative curves of the absorption spectra, fluorescence emission spectra, and fluorescence excitation spectra. The activity of purified F_II (photosystem II) was also assayed by the photoreduction of dichlorophenol-indophenol at room temperature using 1,5-diphenylcarbohydrazine as the electron donor and by the photoreduction of C-550 at −196 C. The different fractions showed unique polypeptide patterns and unique sets of low temperature-absorbing forms of chlorophyll. The fluorescence emission spectra of F_I, F_II, and F_III at −196 C were also unique with maxima at 734, 685 and 681 nm, respectively. F_I showed negligible emission at wavelengths shorter than 700 nm and the long wavelength tails of F_II and F_III in the 730 nm region were relatively small (approximately 10% of emission of their wavelength maxima). Addition of 0.1% Triton to F_I and F_II caused the longer wavelength absorbing forms of chlorophyll to shift to 670 nm and the fluorescence emission maxima (of both fractions) to shift to 679 nm at −196 C with an increase in the yield of fluorescence especially in the case of F_I.     

Die Lokalisation der Peroxidase-Isoenzymgruppe GI in der Zellwand von Tabak-Geweben

Summary By vacuum infiltration of intercellular spaces of tobacco tissues it is possible to extract substances from cell walls which move freely in the walls. The peroxidases (E.C. 1.11.1.7) contained in these extracts are predominantly isoenzymes of G_I (fast migrating anodic group) as was shown by discelektrophoresis of the extracts. As has been demonstrated previously G_I is not present in the protoplast; therefore G_I is the typical cell wall fraction of tobacco peroxidases. Different tissues of tobacco always differ in the isoenzyme pattern of G_I. This pattern also changes during tissue development. We can therefore say that there exists an enzymatic differentiation of plant cell walls during development. As G_I is not bound to the walls, it always appears in high amounts in crude extracts of plant material. Therefore G_I is always called the soluble cytoplasmic fraction, but our investigations clearly demonstrate that G_I is localized in cell walls only. Beside G_I there are much smaller amounts of G_III (slow migrating cathodic group) and if present in the tissue G_II (slow migrating anodic group) detectable in the infiltration fluids of intracellular spaces. G_III and G_II are localized mainly in the protoplast. But they are also bound to the walls, ionically in the case of G_III and covalently in the case of G_II.

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Abkürzungen MDH Malatdehydrogenase (E.C. 1.1.1.37) - G_I, G_II, G_III Enzymgruppen der Peroxydase - FG Frischgewicht     

New insights into the organisation of the oxidative phosphorylation system in the example of pea shoot mitochondria

The physical and functional organisation of the OXPHOS system in mitochondria in vivo remains elusive. At present, different models of OXPHOS arrangement, representing either highly ordered respiratory strings or, vice versa, a set of randomly dispersed supercomplexes and respiratory complexes, have been suggested. In the present study, we examined a supramolecular arrangement of the OXPHOS system in pea shoot mitochondria using digitonin solubilisation of its constituents, which were further analysed by classical BN-related techniques and a multidimensional gel electrophoresis system when required. As a result, in addition to supercomplexes I₁III₂, I₁III₂IV_n and III₂IV_1–2, dimer V₂, and individual complexes I-V previously detected in plant mitochondria, new OXPHOS structures were also revealed. Of them, (1) a megacomplex (II_xIII_yIV_z)n including complex II, (2) respirasomes I₂III₄IV_n with two copies of complex I and dimeric complex III₂, (3) a minor new supercomplex IV₁Va₂ comigrating with I₁III₂, and (4) a second minor form of ATP synthase, Va, were found. The activity of singular complexes I, IV, and V was higher than the activity of the associated forms. The detection of new supercomplex IV₁Va₂, along with assemblies I₁III₂ and I_1–2III_2–4IV_n, prompted us to suggest the occurrence of in vivo oxphosomes comprising complexes I, III₂, IV, and V. The putative oxphosome's stoichiometry, historical background, assumed functional significance, and subcompartmental location are discussed herein.     

Structural chemistry of lanthanidedicyclopentadienidehalides. Part 1. Two modifications of gadoliniumdicyclopentadienidebromide, [Gd(C5H5)2Br]2 and 1∞[Gd(C5H5)2Br]

The crystal structures of two modifications of gadoliniumdicyclopentadienidebromide, [Gd(C₅H₅)₂Br]₂ (I) and ¹_∞[Gd(C₅H₅)₂Br] (II) have been determined from X-ray diffraction data. I crystallizes in the [Sc(C₅H₅)₂Cl]₂-type structure, space group P2₁/c, with a=14.110(3), b=16.488(3), c= 13.765(3) Å, β=93.25(2)°, V=3197(2) ų, and D_c= 2.289 g cm⁻³ for Z=6 molecules. II crystallizes in space group P2₁/c with a=5.946(7), b=8.447(5), c=20.239(9) Å, β=90.11(4)°, V=1020(2) ų, D_c=2.392 g cm⁻³ for Z=4 formula units. The structures have been refined by full matrix least-squares techniques to conventional R factors of 0.034 for 3014 (I) and 1964 (II) reflections (with I>2σ(I)). I consists of dimers with two bromine bridges (mean GdBr 2.872 Å). II has a double chain structure with alternating juxtaposition of gadolinium and bromine atoms (GdBr 2.912 Å (once) and 3.133 Å (twice)). The arrangement of the C₅H₅ groups with regard to the metal η⁵ fashion) is nearly identical in I and II (mean GdC 2.63(1) Å (I) and 2.62(1) Å (II)). Single crystals of I and II are obtained by sublimation at different temperatures. The formation of both modifications is discussed as to its dependence on the state of the gaseous phase equilibrium [Gd(C₅H₅)₂Br]₂ ⇄ 2Gd(C₅H₅)₂Br. Obviously, I crystallizes from gaseous phase dimers while II forms from the monomers.     

Effects of <Emphasis Type="Italic">Ginkgo biloba</Emphasis> extract on heart and liver mitochondrial functions: mechanism(s) of action

Though extracts of Ginkgo biloba leaves (GBE) have a wide pharmacological application, little is known about GBE effects on mitochondria. In this work, effects of ethanolic GBE on the respiration of isolated rat heart and liver mitochondria were investigated. We found that GBE stimulates the pyruvate + malate-dependent State 2 respiration of heart mitochondria and decreases mitochondrial membrane potential. Uncoupling effect of GBE was found to be due to its protonophoric action and is likely to be mediated by the ATP/ADP-translocator and uncoupling proteins. The effect of GBE was less in liver than in heart mitochondria. State 3 respiration of heart mitochondria was slightly stimulated at low and depressed at higher GBE concentrations. Inhibition of State 3 respiration of heart mitochondria was not relieved by uncoupler indicating that GBE may inhibit the respiratory chain complexes or the substrate transport. However, Complex IV of the respiratory chain was not inhibited by GBE. H₂O₂ generation was attenuated by low concentration of GBE probably due to mild uncoupling. The data suggest that mild but not severe uncoupling activity of GBE may be important in providing pharmacological protection of cellular functions in pathological situations.     

Amino acid composition of fractions of ‘Kentucky-31’ tall fescue as affected by N fertilization and mild water stress

Summary Environmental and management factors can influence the protein concentration of forages, significantly altering specific amino acid content. Drought, high rates of fertilizer N and the presence of a fungal endophyte have been associated with significant alterations in plant N metabolites and animal performance problems on tall fescue. A controlled environment study was conducted to examine the influence of N fertilization (10 and 100 gN/g) and water regime (low and adequate soil water availability) upon the distribution and concentration of amino acids in endophyte infected tall fescue (Festuca arundinacea, Schreb.) herbage. Tall fescue tissue was collected from three replicates of each treatment, quick frozen in liquid N and lyophilized. Two insoluble (R_I, structural residue; R_II, membrane residue) and two soluble (S_I, soluble protein; S_II, low molecular weight N compounds) fractions were collected. Amino acid analyses of acid hydrolysates of fractions showed that application of 100 N significantly increased the concentration (per unit dry weight) of all amino acids in the entire plant, with an average increase of about 55%. Application of 110 N increased the concentrations of most amino acids in fractions R_I, R_II, and S_I, but only aspartate-asparagine, glutamate-glutamine, alanine, threonine, serine, valine and proline in fraction S_II. Fraction R_I contained about 65% of total amino acids under 10 N and 55% under 110 N even though N level did not alter dry matter distribution among fractions. While the amount of dry matter was least in S_I, amino acids in the fraction ranged from 8% (leucine, 10 N) to 20% (lysine, 110 N) of the total amount of specific amino acids recovered. Significant increases in proline, glutamate, aspartate, serine, valine, threonine, alanine and phenylalanine concentration occurred under low soil-water availability compared with adequate water conditions. Basic amino acids including histidine, arginine and lysine increased with increased N and with water stress at each N level. Application of N increased amounts, and water stress influenced distribution of amino acids among the fractions of tall fescue herhage. Nitrogenous components, such as non-protein amino acids which could influence plant nutritive quality, were increased in fraction S_II by increased N and water stress.     

Sites of superoxide and hydrogen peroxide production during fatty acid oxidation in rat skeletal muscle mitochondria

H₂O₂ production by skeletal muscle mitochondria oxidizing palmitoylcarnitine was examined under two conditions: the absence of respiratory chain inhibitors and the presence of myxothiazol to inhibit complex III. Without inhibitors, respiration and H₂O₂ production were low unless carnitine or malate was added to limit acetyl-CoA accumulation. With palmitoylcarnitine alone, H₂O₂ production was dominated by complex II (44% from site II_F in the forward reaction); the remainder was mostly from complex I (34%, superoxide from site I_F). With added carnitine, H₂O₂ production was about equally shared between complexes I, II, and III. With added malate, it was 75% from complex III (superoxide from site III_Qo) and 25% from site I_F. Thus complex II (site II_F in the forward reaction) is a major source of H₂O₂ production during oxidation of palmitoylcarnitine ± carnitine. Under the second condition (myxothiazol present to keep ubiquinone reduced), the rates of H₂O₂ production were highest in the presence of palmitoylcarnitine ± carnitine and were dominated by complex II (site II_F in the reverse reaction). About half the rest was from site I_F, but a significant portion, ∼40 pmol H₂O₂·min⁻¹·mg protein⁻¹, was not from complex I, II, or III and was attributed to the proteins of β-oxidation (electron-transferring flavoprotein (ETF) and ETF-ubiquinone oxidoreductase). The maximum rate from the ETF system was ∼200 pmol H₂O₂·min⁻¹·mg protein⁻¹ under conditions of compromised antioxidant defense and reduced ubiquinone pool. Thus complex II and the ETF system both contribute to H₂O₂ productionduring fatty acid oxidation under appropriate conditions.     

Respiratory control in hyperpermeable adult heart muscle cells Effects of calcium

Spontaneously beating myocardial fragments prepared by mechanical disaggregation have hyperpermeable sarcolemmae. Such preparations were used to study mitochondrial function in situ. The myocardial fragments suspended in a phosphate-buffered salt solution containing 1–3 mM MgCl₂ showed a low rate of oxygen uptake. Addition of succinate, pyruvate plus malate or glutamate was followed by an increase in the rate of O₂ uptake. Addition of ADP to fragments engaged in State 4 respiration was followed by initiation of more rapid State 3 respiration, with respiratory control ratios routinely greater than 3 for succinate and glutamate. If the fragments were suspended in the same medium containing 3 mM ATP (a medium in which contractile activity occurs), State 3 was initiated upon addition of substrate. The suspension medium used in these experiments contained about 8 μM calcium as contamination. Addition of calcium chloride to give a final concentration of 0.14 to 0.57 mM stimulated State 4 respiration of the myocardial fragments. In contrast, similar additions made during State 3 inhibited respiration. The maximum degree of inhibition brought respiration close to the State 4 rate. If calcium was added prior to ADP, respiratory stimulation by the nucleotide was diminished. Respiratory function of myocardial fragments and of mitochondria isolated from them was similar in terms of response to substrate, ADP, and calcium addition in State 4. Response to calcium in State 3 was different in that inhibition was long-lived only at low [P_i] in the case of mitochondria, but at low or high [P_i] in the case of the fragments.     

Fructose-1,6-diphosphatase from spinach leaf chloroplasts: Purification and heterogeneity

The enzyme fructose- 1,6-diphosphatase (FDPase), involved in the reductive cycle of the pentose phosphate pathway, has been purified from spinach leaves by heating (30 min at 60°), “salting out” with ammonium sulphate (between 30–70% of saturation), filtration through Sephadex G-100 and G-200, fractionation on DEAE-52 cellulose and preparative electrophoresis on polyacrylamide gel. Filtration through DEAE-cellulose led to the isolation of two active fractions (fractions I and II) with very close MWs and isoelectric points. By electrophoresis on acrylamide gel, both fractions gave two active fractions (fractions I_a-I_b and II_a-II_b). The fractions with low electrophoretic migration rate—I_b and II_b—are stable in acid and neutral pH, have a MW between 90 000 and 110 000 and constitute the native form of the photosynthetic enzyme. The fractions of faster migration rate—I_a and II_a-originate from the corresponding fractions I_b and II_b under alkaline conditions, show half the MW of the respective fractions, and behave as subunits of the original dimer form. Measured by electrofocusing, the four active fractions have isoclectric points in the range 4·10–4.30.     

Studies on essential fatty acid deficiency. Effect of the deficiency on the lipids in liver mitochondria and oxidative phosphorylation

1. Dietary deficiency of essential fatty acids results in a twofold increase in the neutral lipid content of liver mitochondria as compared with the corresponding value for stock-fed rats. 2. Deficiency produces changes in the pattern of the constituent fatty acids of the main phospholipid fractions of liver mitochondria which are similar to those previously reported for the lipids of whole liver. There is a fall in the content of C_18:2 acid and to a smaller extent of C_20:4 acid associated with a rise of C_16:1, C_18:1 and C_20:3 acids. 3. Deficiency results in small decreases in the phosphorylation quotients of liver mitochondria during oxidation of succinate and pyruvate, but the values lie within the range reported for normal mitochondria. Mitochondrial respiration with succinate is decreased as a result of deficiency but no change was observed with pyruvate as substrate.     

The properties and reactions of haemoglobin F(1) and their bearing on the dissociation equilibrium of haemoglobin

1. Hb-F_I, with the previously proposed structure α^A₂γ^Fγ^AcF, would be an exception to the general hypothesis that haemoglobins are in mobile equilibrium with their sub-units at all pH values. However, studies presented in this paper suggest that this is not so. 2. Gel-filtration and sedimentation analyses show that Hb-F_I dissociates at acid pH and gives only the usual types of hybrids in recombination experiments. When self-hybridized, Hb-F_I is the main haemoglobin species re-formed, although small but increasing amounts of Hb-F_II appear on prolonged exposure to acid. 3. Exchange experiments with isotopically labelled Hb-F_II and unlabelled Hb-F_I show no exchange of sub-units at neutral pH or after brief exposure to acid pH. Under equilibrium conditions at acid pH non-α^A-chains do not exchange, although α^A-chains equilibrate completely between the two species. 4. These results indicate that Hb-F_I does not contain γ^F-chains and its possible structure is discussed on this basis. Since the dissociation properties of Hb-F_I are not markedly different from those of Hb-A or Hb-F_II it is concluded that Hb-F_I, like other haemoglobins, is an equilibrium system.     

What are the sources of hydrogen peroxide production by heart mitochondria?

Coupled rat heart mitochondria produce externally hydrogen peroxide at the rates which correspond to about 0.8 and 0.3% of the total oxygen consumption at State 4 with succinate and glutamate plus malate as the respiratory substrates, respectively. Stimulation of the respiratory activities by ADP (State 4–State 3 transition) decreases the succinate- and glutamate plus malate-supported H₂O₂ production 8- and 1.3-times, respectively. NH₄⁺ strongly stimulates hydrogen peroxide formation with either substrate without any effect on State 4 and/or State 3 respiration. Rotenone-treated, alamethicin-permeabilized mitochondria catalyze NADH-supported H₂O₂ production at a rate about 10-fold higher than that seen in intact mitochondria under optimal (State 4 succinate-supported respiration in the presence of ammonium chloride) conditions. NADH-supported hydrogen peroxide production by the rotenone-treated mitochondria devoid of a permeability barrier for H₂O₂ diffusion by alamethicin treatment are only partially (～ 50%) sensitive to the Complex I NADH binding site-specific inhibitor, NADH-OH. The residual activity is strongly (～ 6-fold) stimulated by ammonium chloride. NAD⁺ inhibits both Complex I-mediated and ammonium-stimulated H₂O₂ production. In the absence of stimulatory ammonium about half of the total NADH-supported hydrogen peroxide production is catalyzed by Complex I. In the presence of ammonium about 90% of the total hydrogen peroxide production is catalyzed by matrix located, ammonium-dependent enzyme(s).     

Ordering selected Zn(II), Cu(II), Pd(II) and Co(III) complex compounds: their separately and combinedly antibacterial therapy and DNA-binding studies

Abstract

In this study, four Co(III)-, Cu(II)-, Zn(II)- and Pd(II)-based potent antibacterial complexes of formula K₃[Co(ox)₃]·3H₂O (I), [Cu(phen)₂Cl]Cl·6.5H₂O (II), [Zn(phen)₃]Cl₂ (III) and [Pd(phen)₂](NO₃)₂ (IV) (where ox is oxalato and phen is 1,10-phenanthroline) were synthesized. They were characterized by elemental analysis, molar conductivity measurements, UV–vis, Fourier transform infrared (FT-IR) and proton nuclear magnetic resonance (¹H-NMR) techniques. These metal complexes were ordered in three combination series of I+II, I+II+III and I+II+III+IV. Antibacterial screening for each metal complex and their combinations against Gram-positive and Gram-negative bacteria revealed that all compounds were more potent antibacterial agents against the Gram-negative than those of the Gram-positive bacteria. The four metal complexes showed antibacterial activity in the order I > II > III > IV, and the activity of their combinations followed the order of I+II+III+IV > I+II+III > I+II. The DNA-binding properties of complex (I) and its three combinations were studied using electronic absorption and fluorescence (ethidium bromide displacement assay) spectroscopy. The results obtained indicated that all series interact effectively with calf thymus DNA (CT-DNA). The binding constant (K_b), the number of binding sites (n) and the Stern–Volmer constant (K_sv) were obtained based on the results of fluorescence measurements. The calculated thermodynamic parameters supported that hydrogen bonding and van der Waals forces play a major role in the association of each series of metal complexes with CT-DNA and follow the above-binding affinity order for the series.

Communicated by Ramaswamy H. Sarma     

Stimulation of oxidative phosphorylation by calcium in cardiac mitochondria is not influenced by cAMP and PKA activity

Cardiac oxidative ATP generation is finely tuned to match several-fold increases in energy demand. Calcium has been proposed to play a role in the activation of ATP production via PKA phosphorylation in response to intramitochondrial cAMP generation. We evaluated the effect of cAMP, its membrane permeable analogs (dibutyryl-cAMP, 8-bromo-cAMP), and the PKA inhibitor H89 on respiration of isolated pig heart mitochondria. cAMP analogs did not stimulate State 3 respiration of Ca^2 +-depleted mitochondria (82.2 ± 3.6% of control), in contrast to the 2-fold activation induced by 0.95 μM free Ca^2 +, which was unaffected by H89. Using fluorescence and integrating sphere spectroscopy, we determined that Ca^2 + increased the reduction of NADH (8%), and of cytochromes b_H (3%), c₁ (3%), c (4%), and a (2%), together with a doubling of conductances for Complex I + III and Complex IV. None of these changes were induced by cAMP analogs nor abolished by H89. In Ca^2 +-undepleted mitochondria, we observed only slight changes in State 3 respiration rates upon addition of 50 μM cAMP (85 ± 9.9%), dibutyryl-cAMP (80.1 ± 5.2%), 8-bromo-cAMP (88.6 ± 3.3%), or 1 μM H89 (89.7 ± 19.9%) with respect to controls. Similar results were obtained when measuring respiration in heart homogenates. Addition of exogenous PKA with dibutyryl-cAMP or the constitutively active catalytic subunit of PKA to isolated mitochondria decreased State 3 respiration by only 5–15%. These functional studies suggest that alterations in mitochondrial cAMP and PKA activity do not contribute significantly to the acute Ca^2 + stimulation of oxidative phosphorylation.     

A carbon monoxide-releasing molecule (CORM-3) uncouples mitochondrial respiration and modulates the production of reactive oxygen species

Carbon monoxide (CO), produced during the degradation of heme by the enzyme heme oxygenase, is an important signaling mediator in mammalian cells. Here we show that precise delivery of CO to isolated heart mitochondria using a water-soluble CO-releasing molecule (CORM-3) uncouples respiration. Addition of low-micromolar concentrations of CORM-3 (1–20 μM), but not an inactive compound that does not release CO, significantly increased mitochondrial oxygen consumption rate (State 2 respiration) in a concentration-dependent manner. In contrast, higher concentrations of CORM-3 (100 μM) suppressed ADP-dependent respiration through inhibition of cytochrome c oxidase. The uncoupling effect mediated by CORM-3 was inhibited in the presence of the CO scavenger myoglobin. Moreover, this effect was associated with a gradual decrease in membrane potential (ψ) over time and was partially reversed by malonate, an inhibitor of complex II activity. Similarly, inhibition of uncoupling proteins or blockade of adenine nucleotide transporter attenuated the effect of CORM-3 on both State 2 respiration and Δψ. Hydrogen peroxide (H₂O₂) produced by mitochondria respiring from complex I-linked substrates (pyruvate/malate) was increased by CORM-3. However, respiration initiated via complex II using succinate resulted in a fivefold increase in H₂O₂ production and this effect was significantly inhibited by CORM-3. These findings disclose a counterintuitive action of CORM-3 suggesting that CO at low levels acts as an important regulator of mitochondrial respiration.     

Energy-dependent accumulation of iron by isolated rat liver mitochondria V. Effect on factors controlling respiration and oxidative phosphorylation

1. Depending on the metabolic state, the addition of iron(III)-sucrose induces an inhibition or a stimulation of the respiration rate when added to isolated rat liver mitochondria.2. Under conditions identical to those used in the accumulation studies (Romslo, I. and Flatmark, T. (1973) Biochim. Biophys. Acta 305, 29?40), the ferric complex induces a decrease in the oxygen uptake concomitant to an oxidation of cytochromes c (+c₁) and a (+a₃). These results suggest that ferric iron is reduced to ferrous iron by the respiratory chain prior to or simultaneously with its energy-dependent accumulation.3. On the other hand, the addition of iron(III)-sucrose induces a stimulation of respiration in State 4 and State 3 provided Mg²⁺ is present in the suspending medium. In contrast to Ca²⁺, iron stimulates State 4 respiration in a cyclic process only within narrow concentration limits; at concentrations of iron above 100 μM the respiration remains in the activated state until anaerobiosis. The stimulation of State 4 respiration is more pronounced with succinate than with NAD-linked substrates, a difference which partly may be attributed to a stimulation of the succinate dehydrogenase complex.4. The stimulation of respiration by iron is approx. 3 times higher in State 3 than in State 4 and this difference can be attributed to a stimulation of the adenine nucleotide exchange reaction in State 3 with a concomitant increase in the rate of oxidative phosphorylation, although the $\text{P}\text{O}$ ratio is slightly diminished.