The biosynthesis of plasmalogens by rat brain: involvement of the microsomal electron transport system.

The biosynthesis of 1-alk-1'-enyl-2-acyl-sn-glycero-3-phosphoethanolamine (ethanolamine plasmalogens) was studied using 1-[1-14C]hexadecyl-sn-glycero-3-phosphoethanolamine as the substrate and EDTA-washed microsomes from brains of 14-day-old rats. It was found that the 1-E11-14C]hexadecyl-sn-glycero-3-phosphoethanolamine was first acylated to form 1-[1-14C]hexadecyl-2-acyl-sn-glycero-3-phosphoethanolamine, then was desaturated to form 1-[1-14C]hexadec-1'-enyl-2-acyl-sn-glycero-3-phosphoethanolamine. The desaturation required O2 and NADH or NADPH and was inhibited by KCN but not by CO. The data indicated that the desaturation is carried out by a mixed-function oxidase system similar to that involved in the desaturation of fatty acids and that the pathway for the biosynthesis of plasmalogens in brain is similar to that previously found in other tissues. The desaturase was not stimulated by ATP and Mg2plus nor inhibited by EDTA. The specific activity of microsomes from brains of rats of different ages was determined; the activity decreased with age until in adults the activity was only 15% that of the 12--14-day-old rats.     

The electron transport system of the anaerobic Propionibacterium shermanii

1. Electron transport particles obtained from cellfree extracts of Propionibacterium shermanii by centrifugation at 105000xg for 3 hrs oxidized NADH, d,l-lactate, l-glycerol-3-phosphate and succinate with oxygen and, except for succinate, with fumarate, too.
2. Spectral investigation of the electron transport particles revealed the presence of cytochromes b, d and o, and traces of cytochrome a ₁ and a c-type cytochrome. Cytochrome b was reduced by succinate to about 50%, and by NADH, lactate or glycerol-3-phosphate to 80–90.
3. The inhibitory effects of amytal and rotenone on NADH oxidation, but not on the oxidation of the other substrates, indicated the presence of the NADH dehydrogenase complex, or “site I region”, in the electron transport system of P. shermanii.
4. NQNO inhibited substrate oxidations by oxygen and fumarate, as well as equilibration of the flavoproteins of the substrate dehydrogenases by way of menaquinone. The inhibition occurred at low concentrations of the inhibitor, and reached 80–100%, depending on the substrate tested. The site of inhibition of the respiratory activity was located between menaquinone and cytochrome b. In addition, inhibition of flavoprotein equilibration suggested that NQNO acted upon the electron transfer directed from menaquinol towards the acceptor to be reduced, either cytochrome b or the flavoproteins, which would include fumarate reductase.
5. In NQNO-inhibited particles, cytochrome b was not oxidized by oxygen-free fumarate, but readily oxidized by oxygen. It was concluded from this and the above evidence that the branching-point of the electron transport chain towards fumarate reductase was located at the menaquinone in P. shermanii. It was further concluded that all cytochromes were situated in the oxygen-linked branch of the chain, which formed a dead end of the system under anaerobic conditions.
6. Antimycin A inhibited only oxygen-linked reactions of the particles to about 50% at high concentrations of the inhibitor. Inhibitors of terminal oxidases were inactive, except for carbon monoxide.

     

Aberrant regulation of choline metabolism by mitochondrial electron transport system inhibition in neuroblastoma cells

Anomalous choline metabolic patterns have been consistently observed in vivo using Magnetic Resonance Spectroscopy (MRS) analysis of patients with neurodegenerative diseases and tissues from cancer patient. It remains unclear; however, what signaling events may have triggered these choline metabolic aberrancies. This study investigates how changes in choline and phospholipid metabolism are regulated by distinct changes in the mitochondrial electron transport system (ETS). We used specific inhibitors to down regulate the function of individual protein complexes in the ETS of SH-SY5Y neuroblastoma cells. Interestingly, we found that dramatic elevation in the levels of phosphatidylcholine metabolites could be induced by the inhibition of individual ETS complexes, similar to in vivo observations. Such interferences produced divergent metabolic patterns, which were distinguishable via principal component analysis of the cellular metabolomes. Functional impairments in ETS components have been reported in several central nervous system (CNS) diseases, including Alzheimer’s disease (AD) and Parkinson’s disease (PD); however, it remains largely unknown how the suppression of individual ETS complex function could lead to specific dysfunction in different cell types, resulting in distinct disease phenotypes. Our results suggest that the inhibition of each of the five ETS complexes might differentially regulate phospholipase activities within choline metabolic pathways in neuronal cells, which could contribute to the overall understanding of mitochondrial diseases. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The aerobic electron transport system of Eikenella corrodens

The respiratory system of the fastidious beta-proteobacterium Eikenella corrodens grown with limited oxygen was studied. Membranes showed the highest oxidase activity with ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) or succinate and the lowest activity with NADH and formate. The presence of a bc1-type complex was suggested by the inhibition exerted by 2-heptyl-4-hydroxyquinoline-N-oxide (HOQNO), myxothiazol, and antimycin A on respiration with succinate and by the effect of the latter two inhibitors on the succinate-reduced difference spectra. Respiration with succinate or ascorbate-TMPD was abolished by low KCN concentrations, suggesting the presence of a KCN-sensitive terminal oxidase. Cytochromes b and c were spectroscopically detected after reduction with physiological or artificial electron donors, whereas type a and d cytochromes were not detected. The CO difference spectrum of membranes reduced by dithionite and its photodissociation spectrum (77 K) suggested the presence of a single CO compound that had the spectral features of a cytochrome o-like pigment. High-pressure liquid chromatography analysis of membrane haems confirmed the presence of haem B; in contrast, haems A and O were not detected. Peroxidase staining of membrane type c cytochromes using SDS-PAGE revealed the presence of five bands with apparent molecular masses of 44, 33, 30, 26, and 14 kDa. Based on our results, a tentative scheme of the respiratory chain in E. corrodens, comprising (i) dehydrogenases for succinate, NADH, and formate, (ii) a ubiquinone, (iii) a cytochrome bc1, and (iv) a type-cbb' cytochrome c oxidase, is proposed.     

Evidence for involvement of the electron transport system at a late step of anaerobic microbial heme synthesis

The penultimate step in heme biosynthesis, the oxidation of protoporphyrinogen to protoporphyrin, can be anaerobically coupled to the reduction of fumarate in extracts of anaerobically-grown Escherichia coli. This coupling is approximately 90% inhibited by 2-heptyl-4-hydroxy quinoline-N-oxide (HQNO), a known inhibitor of the electron transport chain. This observation suggests that the mechanism of the anaerobic oxidation of protoporphyrinogen in E. coli involves a coupling into the anaerobic electron transport system. In contrast, the aerobic oxidation of protoporphyrinogen, which occurs in mammalian and yeast mitochondria, is known to be linked directly to oxygen without the mediation of an electron transport system.     

The electron transport system of Alcaligenes eutrophus H16

The electron transport system of autotrophically grown Alcaligenes eutrophus H16 has been investigated by spectroscopic and thermodynamic approaches. The results have been interpreted as evidence that isolated membranes contain a branched respiratory chain composed of three c-type haems (E _m,7=+160 mV, + 170 mV, and + 335 mV), five b-type haems (E _m,7=+ 5 mV, + 75 mV, + 205 mV, + 300 mV, and + 405 mV), two (possibly three) a-type haems [E _m,7= + 255 mV, + 350 mV, (+ 420 mV)], and nne d-type haem. EPR-analysis of the signals at g=1.93, g=2.02, and g=1.90 revealed the presence of iron-sulphur centres diagnostic of complexes I (NADH dehydrogenase), II (succinate dehydrogenase), and III (ubiquinol/cytochrome c oxidoreductase). The low potential b haems (+ 5 mV and + 75 mV) plus the Rieske protein (g=1.90, E _m,7=+ 280 mV), thought to be part of an orthodox bc ₁ complex, were present in low amounts as compared to their counterparts in membranes from Paracoccus denitrificans.CO-difference spectra in the presence of either succinate, NADH, hydrogen, ascorbate/TMPD, and/or dithionite as reductants, suggested the existance of four different oxidases composed by bo-, cb-, a-, and d-type haems.It is concluded that in contrast to other chemolithotrophes, e.g. P. denitrificans, autotrophic growth of Alcaligenes eutrophus utilizes a respiratory system in which the bc ₁ complex containing pathway is only partially involved in electron transport.Abbreviations Cytochrome c-551, number wavelength in nm - Cytochrome c ₂₇₀, number mid-point potential in mV - E _m,7 mid-point potential of an oxidation-reduction couple at pH 7.0 - KP buffer, potassium phosphate-buffer - OD optical density at 436 nm, 1 cm light path - TMPD N,N,N,N-tetramethyl-p-phenylenediamine     

The respiratory electron transport system of heterotrophically-grown Rhodopseudomonas palustris

The enzymatic activities and the cytochrome components of the respiratory chain were investigated with membrane fractions from chemoheterotrophically grown Rhodopseudomonas palustris. Whereas the level of electron transfer carriers was not distinctly affected by a change of the culture conditions, the potential activities of the enzymes were clearly increased when the cells were grown aerobically. Reduced-minus oxidized difference spectra of the membrane fractions prepared from dark aerobically grown cells revealed the presence of three b-type cytochromes b ₅₆₁, b ₅₆₀ and b ₅₅₈, and at least two c-type cytochromes c ₅₅₆ and c ₂ as electron carriers in the electron transfer chain. Cytochrome of a-type could not be detected in these membranes. Reduced plus CO minus reduced difference spectra of the membrane fractions were indicative of cytochrome o, which may be equivalent to cytochrome b ₅₆₀, appearing in substrate-reduced minus oxidized difference spectra. Cytochrome o was found to be the functional terminal oxidase. CO difference spectra of the high speed supernatant fraction indicated the presence of cytochrome c′. Succinate and NADH reduced the same types of cytochromes. However, a considerable amount of cytochrome b ₅₆₁ with associated β and γ bands at 531 and 429 nm, respectively, was reducible by succinate, but not by NADH. A substantial fraction of the membrane-bound b-type cytochrome was non-substrate reducible and was found in dithionite-reduced minus substrate-reduced spectra. Cytochrome c ₂ may be localized in a branch of the electron transport system, with the branch-point at the level of ubiquinone. The separate pathways rejoined at a common terminal oxidase. Two terminal oxidases with different KCN sensitivity were present in the respiratory chain, one of which was sensitive to low concentrations of KCN and was connected with the cytochrome chain. The other terminal oxidase which was inhibited only by high concentrations of cyanide was located in a branched pathway, through which the electrons could flow from ubiquinone to oxygen bypassing the cytochrome chain.     

The electron transport system of Alcaligenes eutrophus H16

In a previous work (Kömen et al. 1991) it has been concluded that membrane fragments isolated from autotrophically grown Alcaligenes eutrophus H16 contain several iron-sulphur centres along with haems of a-, b-, c-, and d-type. These redox components have been proposed to be part of a branched respiratory chain leading to multiple membrane bound oxidases. Here, some of the respiratory activities catalyzed by membrane fragments from wild type cells of A. eutrophus (H16) and, for comparison, Paracoccus denitrificans, have been investigated through the use of electron transport inhibitors. Cyanide (CN^-) titration curves indicated that in A. eutrophus H16 oxidation of succinate and H₂ preferentially proceeds via the cytochrome c oxidase(s) branch (I ₅₀=2 · 10^-5 M) whereas the NADH dependent respiration started being inhibited at higher CN^- concentrations (I ₅₀=5 · 10^-4 M). In membranes isolated from both, cells harvested at late growth-phase (OD 12) and from a mutant deficient in cytochrome c oxidase activity (A. eutrophus RK1), respiration was insensitive to low CN^- concentrations (< 10^-4 M), and it was sustained by the high catalytic activities of two quinol oxidases. These alternative oxidases of b- (formally o-) and d-type showed different sensitivities to KCN (I ₅₀=10^-3 M and 10^-2 M, respectively). Interestingly, the cytochrome c oxidase(s) dependent respiration of H16 membranes was insensitive to antimycin A but largely inhibited by myxothiazol (10^-6 M). This, and previous work (Kömen et al. 1991), suggest that although the respiratory chain of A. eutrophus is endowed with a putative bc ₁ complex, its biochemical nature and role in respiration of this organism are apparently different from those of P. denitrificans. The peculiarity of the respiratory chain of A. eutrophus is confirmed by the rotenone insensitivity of the NADH oxidation in both protoplasts and membrane fragments from wild type and soluble hydrogenase deficient cells (HF14 and HF160). A tentative model of the respiratory chain of autotrophically grown A. eutrophus is presented.     

Evidence for involvement of the electron transport system at a late step of anaerobic microbial heme synthesis.

The penultimate step in heme biosynthesis, the oxidation of protoporphyrinogen to protoporphyrin, can be anaerobically coupled to the reduction of fumarate in extracts of anaerobically-grown Escherichia coli. This coupling is approximately 90% inhibied by 2-heptyl-4-hydroxy quinoline-N-oxide (HQNO), a known inhibitor of the electron transport chain. This observation suggests that the mechanism of the anaerobic oxidation of protoporphyrinogen in E. coli involves a coupling into the anaerobic electron transport system. In contrast, the aerobic oxidation of protoporphyrinogen, which occurs in mammalian and yeast mitochondria, is known to be linked directly to oxygen without the mediation of an electron transport system.     

Utilization and metabolism of NAD by Haemophilus parainfluenzae

The utilization of exogenous nicotinamide adenine dinucleotide (NAD) by Haemophilus parainfluenzae was studied in suspensions of whole cells using radiolabelled NAD, nicotinamide mononucleotide (NMN), and nicotinamide ribonucleoside (NR). The utilization of these compounds by H. parainfluenzae has the following characteristics. (1) NAD is not taken up intact, but rather is degraded to NMN or NR prior to internalization. (2) Uptake is carrier-mediated and energy-dependent with saturation kinetics. (3) There is specificity for the beta-configuration of the glycopyridine linkage. (4) An intact carboxamide groups is required on the pyridine ring. The intracellular metabolism of NAD was studied in crude cell extracts and in whole cells using carbonyl-14C-labelled NR, NMN, NAD, nicotinamide, and nicotinic acid as substrates in separate experiments. A synthetic pathway from NR through NMN to NAD that requires Mg2+ and ATP was demonstrated. Nicotinamide was found as an end-product of NAD degradation. Nicotinic acid mononucleotide and nicotinic acid adenine dinucleotide were not found as intermediates. The NAD synthetic pathway in H. parainfluenzae differs from the Preiss-Handler pathway and the pyridine nucleotide cycles described in other bacteria.     

The respiratory electron transport system of heterotrophically-grown Rhodopseudomonas palustris.

The enzymatic activities and the cytochrome components of the respiratory chain were investigated with membrane fractions from chemoheterotrophically growth Rhodopseudomonas palustris. Whereas the level of electron transfer carriers was not distinctly affected by a change of the culture conditions, the potential activities of the enzymes were clearly increased when the cells were grown aerobically. Reduced-minus oxidized difference spectra of the membrane fractions prepared from dark aerobically grown cells revealed the presence of three beta-types cytochromes b561, b560 and b558, and at least two c-type cytochromes c556 and c2 as electron carriers in the electron transfer chain. Cytochrome of a-type could not be detected in these membranes. Reduced plus CO minus reduced difference spectra of the membrane fractions were indicative of cytochrome o, which may be equivalent to cytochrome b560, appearing in substrate-reduced minus oxidized difference spectra. Cytochrome o was found to be the functional terminal oxidase. CO difference spectra of the high speed supernatant fraction indicated the presence of cytochrome c'. Succinate and NADH reduced the same types of cytochromes. However, a considerable amount of cytochrome b561 with associated beta and gamma bands at 531 and 429 nm, respectively, was reducible by succinate, but not by NADH. A substantial fraction of the membrane-bound b-type cytochrome was non-substrate reducible and was found in dithionite-reduced minus substrate-reduced spectra. Cytochrome c2 may be localized in a branch of the electron transport system, with the branch-point at the level of ubiquinone. The separate pathways rejoined at a common terminal oxidase. Two terminal oxidases with different KCN sensitivity were present in the respiratory chain, one of which was sensitive to low concentrations of KCN and was connected with the cytochrome chain. The other terminal oxidase which was inhibited only by high concentrations of cyanide was located in a branched pathway, through which the electrons could flow from ubiquinone to oxygen bypassing the cytochrome chain.     

Characterization of the electron transport system in Brucella abortus.

The electron transport system in Brucella abortus has been characterized. Spectral studies of membrane preparations have indicated the presence of cytochromes a + a3 (maxima at 612 nm), cytochrome b (maxima at 560, 530, and 428 nm), cytochrome c (maxima at 552 and 522 nm), cytochrome o (maxima of carbon monoxide complex at 418 nm), and flavoproteins (minimum at 582 and 450 nm). Cytochromes a + a3 appeared only after cells had reached late log phase, possibly due to lowered oxygen tension in the medium. Dehydrogenases were shown to be present for D-erythritol 1-phosphate, L-lactate, reduced nicotinamide adenine dinucleotide, and succinate. All of the above substrates reduced the electron transport chain and at least some of the flavoproteins, indicating similar pathways of electron transport. N-ethylmaleimide, p-chloromercuribenzoate, and KCN were the only electron transport inhibitors that blocked electron transport by 100%. The system seemed to be uniquely resistant to other electron transport inhibitors.