Biosynthesis of glycoconjugates in mitochondrial outer membranes

The results reported in this paper show two distinct ways for the incorporation ofN-acetylglucosamine into mitochondrial outer membranes. The first one is the glycosylation of dolichol acceptors, which is indicated by the inhibition of the synthesis of these products by the inhibitors of the dolichol intermediates (tunicamycin and GDP). The second one is the incorporation ofN-acetylglucosamine into protein acceptors directly from UDP-N-acetylglucosamine. This second way of glycosylation is only localized in mitochondria outer membranes.The existence of a direct route forN-glycoprotein biosynthesis has been based on the following evidence. First, the synthesis of theN-acetylglucosaminylated protein acceptors was not inhibited by tunicamycin or GDP. Second, the addition of exogenous dolichol-phosphate did not change the rate of biosynthesis of glycosylated protein material. Third, the sequential incorporation ofN-acetylglucosamine and mannose from their nucleotide derivatives in the presence of GDP and tunicamycin led to the synthesis of glycosylated protein material which entirely bound to Concanavalin A-Sepharose. The oligosaccharide moiety of the glycosylated protein material resulting from the direct transfer of sugars from their nucleotide derivatives to the protein acceptor is of theN-glycan type. On sodium dodecylsulphate polyacrylamide gel electrophoresis, this glycosylated material migrated as a marker protein with a molecular weight between 45 000 and 63 000. HPLC chromatofocusing analysis revealed that the fraction studied was anionic. The oligosaccharide moiety of the glycoprotein material can only be elongated by the incorporation ofN-acetylglucosamine and galactose from their nucleotide derivatives.     

Ultrastructural transformations in bean inner mitochondrial membranes

The ultrastructure of inner membrane-matrix mitochondria isolated from bean (Phaseolus vulgaris) shoots was examined in different metabolic states. Gross ultrastructural transformations analogous to the condensed-to-orthodox configurational changes reported in mammalian mitochondria are observed on transistion from nonrespiring to respiring metabolism. With the induction of oxidative phosphorylation, the particles remain in the orthodox configurational state. The reverse orthodox-to-condensed configurational changes observed in mammalian preparations does not occur. Optically monitored absorbancy studies with bean particles show a substrate-supported P_i-induced swelling under the same conditions that induce the condensed-to-orthodox ultrastructural transformation. The swelling is associated with the net uptake of K⁺ and P_i as well as a small P_i-induced respiratory stimulation. When phosphorylation is initiated with these swollen particles, the optically monitored volume remains unchanged. Thus a positive correlation exists between the ultrastructural configuration and the osmotic volume changes, which supports the conclusion that configurational changes reflect internal osmotic adjustments.     

Proteomics of mitochondrial inner and outer membranes

For the proteomic study of mitochondrial membranes, documented high quality mitochondrial preparations are a necessity to ensure proper localization. Despite the state-of-the-art technologies currently in use, there is no single technique that can be used for all studies of mitochondrial membrane proteins. Herein, we use examples to highlight solubilization techniques, different chromatographic methods, and developments in gel electrophoresis for proteomic analysis of mitochondrial membrane proteins. Blue-native gel electrophoresis has been successful not only for dissection of the inner membrane oxidative phosphorylation system, but also for the components of the outer membrane such as those involved in protein import. Identification of PTMs such as phosphorylation, acetylation, and nitration of mitochondrial membrane proteins has been greatly improved by the use of affinity techniques. However, understanding of the biological effect of these modifications is an area for further exploration. The rapid development of proteomic methods for both identification and quantitation, especially for modifications, will greatly impact the understanding of the mitochondrial membrane proteome.     

Thryoid control over biomembranes. Rat liver mitochondrial inner membranes.

The effects of hypothyroidism and one injection of l-thyroxine on oxidative phosphorylation and the composition of proteins and phospholipids were examined in vesicles prepared from rat liver mitochondria by digitonin extractions. At 30 °C, the rates of ADP phosphorylation in sites I and II were below normal, and Mg²⁺-ATPase activity was greater than normal in vesicles from hypothyroid rats. At temperatures below 20 °C and above 30 °C, the Mg²⁺-ATPase was not accelerated above normal rates, a feature of temperature dependence shared by ADP phosphorylation (Chen, Y.-D. I., and Hoch, F. L., 1976, Arch. Biochem. Biophys.172, 741–744). Respiration at 30 °C was undiminished in hypothyroid vesicles, as were the flavin and cytochrome contents, and thyroxine administration corrected the phosphorylation rate at 30 °C in 3 days without changing either respiration or electron-carrier contents. The 30 °C phosphorylation defect comprised a decreased V and K_m for ADP and a decrease in the number of phosphorylating sites (measured with oligomycin) that accounted for most of the decreased phosphorylation rates, either dependent on or independent of the adenine nucleotide carrier. Vesicles from hypothyroid rats were not detectably depleted in major protein subunits, but were abnormal in phospholipid fatty acid contents. Thyroxine injection corrected the low unsaturation index of the fatty acids and the membrane contents of linoleic acid and its fatty acyl metabolites. Hypothyroidism appears to affect oxidative phosphorylation through the altered inner membrane lipid environment, which implies that previously reported direct, reversible effects of thyroxine may mimic repletion of the membranes with unsaturated fatty acyl groups.     

Kinetic properties of aspartate transport in rat heart mitochondrial inner membranes.

The mitochondrial glutamate-aspartate exchange carrier catalyzes the electrogenic exchange of intramitochondrial aspartate for extramitochondrial glutamate. Protons are cotransported with glutamate in a 1:1 ratio. In the present study, the effects of pH and glutamate concentration on glutamate entry into intact mitochondria were determined. Hydrogen ions were found to decrease the K_m for glutamate entry. In addition, using glutamate-loaded submitochondrial particles, aspartate transport into the particles was measured as a function of internal and external glutamate concentrations, pH, and electrical potential across the membrane. Glutamate, was a competitive inhibitor of aspartate transport when both amino acids were present on the same side of the membrane, while H⁺ was a noncompetitive inhibitor of aspartate entry into the particles. A decrease in glutamate concentration on the inside of the particles brought about a parallel decrease in V and K_m for aspartate outside of the particles, thus suggesting a ping-pong mechanism for the carrier. The uncoupling agent, carbonyl cyanide p-trifluoromethoxy-phenylhydrazone (FCCP), lowered both the K_m and V of aspartate transport, while the effect on V was somewhat larger. Data obtained in the presence of KSCN was similar to that obtained with FCCP, and therefore it is concluded that both K_m and V changes are dependent on a change of electrical potential across the membrane. A model for the carrier is proposed, which is consistent with the data presented. The model includes a single binding site specific for either glutamate or aspartate, and a separate binding site for the cotransported proton. The affinity of the binding site for protons is increased by simultaneous glutamate binding, but decreased by aspartate binding. The data suggest that an increase in the membrane potential increases the mobility of the charged carrier-aspartate complex, but also facilitates some additional step in the exchange cycle involving subsequent return of the carrier to the matrix side of the membrane. The additional membrane-potential-dependent step could be proton binding on the cytosolic side of the carrier.     

Separate fusion of outer and inner mitochondrial membranes

Mitochondria are enveloped by two closely apposed boundary membranes with different properties and functions. It is known that they undergo fusion and fission, but it has remained unclear whether outer and inner membranes fuse simultaneously, coordinately or separately. We set up assays for the study of inner and outer membrane fusion in living human cells. Inner membrane fusion was more sensitive than outer membrane fusion to inhibition of glycolysis. Fusion of the inner membrane, but not of the outer membrane, was abolished by dissipation of the inner membrane potential with K+ (valinomycin) or H+ ionophores (cccp). In addition, outer and inner membrane fusion proceeded separately in the absence of any drug. The separate fusion of outer and inner membranes and the different requirements of these fusion reactions point to the existence of fusion machineries that can function separately.     

Binding of citrate synthase to mitochondrial inner membranes

Citrate synthase and other mitochondrial matrix proteins bind to the inner surface of the mitochondrial inner membrane. No binding was observed to the outer membrane or to the outer surface of the inner membrane.     

Lipid peroxidation in mitochondrial inner membranes. I. An integrative kinetic model

An integrative mathematical model was developed to obtain an overall picture of lipid hydroperoxide metabolism in the mitochondrial inner membrane and surrounding matrix environment. The model explicitly considers an aqueous and a membrane phase, integrates a wide set of experimental data, and unsupported assumptions were minimized. The following biochemical processes were considered: the classic reactional scheme of lipid peroxidation; antioxidant and pro-oxidant effects of vitamin E; pro-oxidant effects of iron; action of phospholipase A₂, glutathione-dependent peroxidases, glutathione reductase and superoxide dismutase; production of superoxide radicals by the mitochondrial respiratory chain; oxidative damage to proteins and DNA. Steady-state fluxes and concentrations as well as half-lives and mean displacements for the main metabolites were calculated. A picture of lipid hydroperoxide physiological metabolism in mitochondria in vivo showing the main pathways is presented. The main results are:(a) perhydroxyl radical is the main initiation agent of lipid peroxidation (with a flux of 10⁻⁷Ms⁻¹); (b) vitamin E efficiently inhibits lipid peroxidation keeping the amplification (kinetic chain length) of lipid peroxidation at low values (10); (c) only a very minor fraction of lipid hydroperoxides escapes reduction via glutathione-dependent peroxidases; (d) oxidized glutathione is produced mainly from the reduction of hydrogen peroxide and not from the reduction of lipid hydroperoxides.     

Electron transfer between outer and inner membranes in plant mitochondria

Experiments on dissociation and reassociation of outer and inner membranes of cauliflower (Brassica oleracea L.) mitochondria have been carried out in order to investigate the possible occurrence of an intermembrane electron transfer. With NADH as electron donor, it has been shown that electron transfer can take place between an antimycin-insensitive NADH-cytochrome c reductase, on the outer membrane, and the cyanide-sensitive cytochrome oxidase, on the inner membrane, provided a mobile carrier such as cytochrome c is present in the intermembrane space. In intact plant mitochondria, part of the oxidation of exogenous NADH could be carried out by this pathway.     

Calcium modulation of mitochondrial inner membrane channel activity.

Protocols were defined that enable patch-clamp studies of the approximately 107 pS voltage dependent channel and a class of activity we refer to as MCC (multiconductance channel) which is characterized by multiple levels and transitions as high as 1 to 1.5 nS. If free calcium was kept at 10(-7) M or lower during mitochondrial isolation, no activity was observed at low voltage (+/- 60 mV). If free calcium levels were higher, MCC activity was observed in about 96% of the patches. The observation of approximately 107 pS channel was enhanced from 2% to 68% of patches by washing isolated mitoplasts (mitochondria stripped of outer membrane) with EGTA. Increasing matrix calcium from 10(-9) to 10(-5) M decreased the probability of opening for the MCC and approximately 107 pS activities.     

Dolichol kinase activity: a key factor in the control of N-glycosylation in inner mitochondrial membranes

Inner mitochondrial membranes from liver contain a dolichol kinase which required CTP as a phosphoryl donor. Kinase activity was linear with protein concentration and unlike other reported kinases, activated almost equally well by Mg2+, Mn2+ or Ca2+. Thin-layer chromatography showed that the reaction product co-migrated with authentic dolichyl monophosphate. The phosphorylation of dolichol did not occur in presence of ATP, GTP or UTP but required exogenous dolichol for maximal activity. Newly synthesized [3H]dolichyl monophosphate has been shown to be glycosylated in the presence of GDP[14C]mannose or UDP[14C]glucose. The double labeled lipids formed by the sugar nucleotide-dependent reactions were identified respectively as [14C]mannosylphosphoryl[3H]dolichol and [14C]glucosylphosphoryl [3H]dolichol. These results are discussed in terms of regulation of N-glycosylation processes in inner mitochondrial membranes from liver.     

Glucosyltransferase activities in liver mitochondria. I. Biosynthesis of dolichyl[14C]glucosyl phosphate and [14C]glucosylceramide

Mitochondria, and specially outer mitochondrial membranes, incorporate D-[14C]glucose from UDP-D-[14C]glucose into products extracted with organic solvents and into a residual precipitate, with a pH optimum of about 6.5 in (2-N-morpholino-ethane)-sulfonic acid (MES) buffer. The chloroform/methanol (2:1, v/v) extract contains two products. The major [14C]glucolipid is stable to mild alkali, but releases [14C]glucose upon mild acid hydrolysis. It is retained on DEAE-cellulose (acetate form) and is eluted with the same ionic strength as an hexosyldolichyl monophosphate diester. This [14C] glucolipid has the same chromatographic behaviour as dolichyl-mannosylphosphate in neutral, acidic and basic solvent systems; and its biosynthesis is greatly increased by exogenous dolichylmonophosphate. The other [14C]glucolipid is stable upon mild acid hydrolysis and is not retained on DEAE-cellulose. On silicic acid it is eluted with acetone. The biosynthesis of this compound is stimulated by exogenous ceramide. This glucolipid has the same chromatographic mobility in different solvent systems as glucosylceramide isolated from the liver of a patient with Gaucher's disease. Biosynthesis of these two glucolipids is inhibited by UDP, but only biosynthesis of dolichylglucosyl monophosphate is reversible with this nucleotide. The biosynthesis of these different glucosylated derivatives is stimulated by the addition of divalent cations (Mn2+, Mg2+). the effect of these two metal ions on dolichylglucosyl monophosphate and glucosylceramide formation is studied in different conditions.     

Rows of ATP synthase dimers in native mitochondrial inner membranes

The ATP synthase is a nanometric rotary machine that uses a transmembrane electrochemical gradient to form ATP. The structures of most components of the ATP synthase are known, and their organization has been elucidated. However, the supramolecular assembly of ATP synthases in biological membranes remains unknown. Here we show with submolecular resolution the organization of ATP synthases in the yeast mitochondrial inner membranes. The atomic force microscopy images we have obtained show how these molecules form dimers with characteristic 15 nm distance between the axes of their rotors through stereospecific interactions of the membrane embedded portions of their stators. A different interaction surface is responsible for the formation of rows of dimers. Such an organization elucidates the role of the ATP synthase in mitochondrial morphology. Some dimers have a different morphology with 10 nm stalk-to-stalk distance, in line with ATP synthases that are accessible to IF1 inhibition. Rotation torque compensation within ATP synthase dimers stabilizes the ATP synthase structure, in particular the stator-rotor interaction.