ABSTRACT
The energy coupled NADH-ubiquinone (Q) oxidoreductase segment of the respiratory chain of Escherichia coli GR19N has been studied by EPR spectroscopy. Previously Matsushita et al. [(1987) Biochemistry 26, 7732-7737] have demonstrated the presence of two distinct NADH-Q oxidoreductases in E. coli membrane particles and designated them NADH dh I and NADH dh II. Although both enzymes oxidize NADH, only NADH dh I is coupled to the formation of the H+ electrochemical gradient. In addition to NADH, NADH dh I oxidizes nicotinamide hypoxanthine dinucleotide (deamino-NADH), while NADH dh II does not. In membrane particles we have detected EPR signals arising from four low-potential iron-sulfur clusters, one binuclear, one tetranuclear, and two fast spin relaxing g perpendicular = 1.94 type clusters (whose cluster structure has not yet been assigned). The binuclear cluster, temporarily designated [N-1]E, shows an EPR spectrum with gx,y,z = 1.92, 1.935, 2.03 and the Em7.4 value of -220 mV (n = 1). The tetranuclear cluster, [N-2]E, elicits a spectrum with gx,y,z = 1.90, 1.91, 2.05 and an Em7.4 of -240 mV (n = 1). These two clusters have been shown to be part of the NADH dh I complex by stability and inhibitor studies. When stored at 4 degrees C, both clusters are extremely labile as is the deamino-NADH-Q oxidoreductase activity. Addition of deamino-NADH in the presence of piericidin A results in nearly full reduction of [N-2]E within 17 s. In membrane particles pretreated with piericidin A, the cluster [N-1]E is only partly reducible by deamino-NADH and shows an altered line shape.(ABSTRACT TRUNCATED AT 250 WORDS)
Subject(s)
Iron-Sulfur Proteins , Metalloproteins , Quinone Reductases , Bacterial Proteins , Electron Spin Resonance Spectroscopy , Electron Transport , Escherichia coli/enzymology , Membrane Proteins , NAD(P)H Dehydrogenase (Quinone) , Oxidation-Reduction , Pyridines/physiology , ThermodynamicsSubject(s)
Alzheimer Disease/metabolism , Cerebral Cortex/analysis , Hepatic Encephalopathy/cerebrospinal fluid , Pyridines/physiology , Quinolinic Acids/physiology , Tryptophan/metabolism , Aging/metabolism , Alzheimer Disease/pathology , Animals , Gas Chromatography-Mass Spectrometry , Hepatic Encephalopathy/etiology , Humans , Liver/metabolism , Liver Cirrhosis/complications , Male , Portacaval Shunt, Surgical , Quinolinic Acid , Quinolinic Acids/cerebrospinal fluid , Rats , Rats, Inbred Strains , Tryptophan/deficiencyABSTRACT
The evidence for an involvement of QUIN in human seizure disorders is clearly circumstantial. Importantly, QUIN is not a classical neurotransmitter and may thus play only a negligible or no role at all in normal brain function (Foster et al., 1984). We have yet to understand if and how such a possibly inert metabolite may turn into a pathogen. Several crucial questions remain to be addressed before a case can be made for a 'quinolinic acid hypothesis' of temporal lobe epilepsy. Among the most prominent ones figure the extracellular concentration of QUIN in the human brain under normal and pathological ('epileptic') conditions, the relationship between QUIN metabolism in the brain and its extracellular concentration and, a related issue, the regulation of cerebral QUIN metabolism (i.e., turnover). It is of equal importance to assess if NMDA-receptors, particularly those in the hippocampus and other parts of the limbic system, can exert a modulatory function upon brain QUIN. Unquestionably, future experiments with selective NMDA-antagonists will prove useful for the elucidation of such possible (feedback) interactions.
Subject(s)
Brain/metabolism , Convulsants , Epilepsy/physiopathology , Pyridines/physiology , Quinolinic Acids/physiology , Receptors, Neurotransmitter/physiology , Afferent Pathways/physiology , Animals , Brain Mapping , Cholinergic Fibers/physiology , Kainic Acid/pharmacology , Ligands , Oxidoreductases/metabolism , Pentosyltransferases/metabolism , Quinolinic Acid , Receptors, N-Methyl-D-AspartateABSTRACT
In pancreatic islets insulin secretion in response to a variety of stimulators is sensitive to the redox state of extracellular and intracellular thiols. In this connection variations of plasma glutathione (GSH) may also be of importance. In the process of stimulus-secretion coupling, membrane thiols play an important role. One major localization of critical thiols appears to be related to the influx of calcium through the voltage-dependent channel. Other transmembranal ion movements and the cAMP system seem to be less sensitive to thiol oxidation than calcium influx via voltage-dependent Ca channels.