ABSTRACT
Hepatocellular nuclei require glutathione, glutathione S-transferases (GSTs) and Se-dependent glutathione peroxidase (GPx) for intranuclear protection against damage from electrophiles or products of active oxygen. Data so far available from the literature on nuclei isolated in aqueous systems range from glutathione, GSTs and GPx either being absent altogether to being present in quantities in excess of those in the cytoplasm. This paper describes a small-scale preparation of a nuclear fraction from rat liver by a non-aqueous technique, designed to retain nuclear water-soluble molecules in situ, since low-molecular-mass compounds can diffuse freely into other compartments during aqueous separation. This non-aqueous procedure shows the nucleus to contain glutathione at 8.4 mM and soluble GSTs at 38 micrograms/mg of protein, the enrichment over the homogenate being 1.2-1.4-fold. Se-dependent GPx activity was also present in the nucleus (56 m-units/mg), although with slightly lower activity than in the homogenate (0.7-fold).
Subject(s)
Glutathione Peroxidase/metabolism , Glutathione Transferase/metabolism , Glutathione/analysis , Liver/chemistry , Animals , Cell Fractionation , Cell Nucleus/chemistry , Cell Nucleus/enzymology , Liver/enzymology , Liver/ultrastructure , Male , Microscopy, Electron , Rats , Rats, WistarABSTRACT
5-Aminolevulinic acid (ALA), the heme precursor accumulated in plasma and several organs of carriers of acute intermittent porphyria, hereditary tyrosinemia, and saturnism, was previously shown to yield reactive oxygen species upon metal-catalyzed aerobic oxidation and to cause the in vivo and in vitro impairment of rat liver mitochondrial functions. We have studied the uptake and catabolism of [5-14C]ALA to CO2 by isolated rat liver mitochondria (RLM) with the aim of determining whether possible ALA-driven oxidative injury to mitochondria can also occur into the matrix. Using silicone oil centrifugation of [5-14C]ALA-treated RLM, ALA was found to partition evenly into the intra- and extramatrix space of the mitochondrial preparations. The yield of evolved 14CO2 is very low (0.2%), responds to the concentration of added ADP, and is inhibited by malonate (75% at 2 mM), iproniazid (45% at 2 mM), beta-chloroalanine (36% at 1 mM), and aminooxyacetate (55% at 0.1 mM). With both iproniazid and aminooxyacetate, the percentage of inhibition is the same as that observed with the latter inhibitor alone. These data indicate that ALA decarboxylation by the Krebs cycle is a minor process and that it is initiated enzymically (transaminase) and not by metal-catalyzed ALA autoxidation.
Subject(s)
Aminolevulinic Acid/metabolism , Mitochondria, Liver/metabolism , Aminooxyacetic Acid/pharmacology , Animals , Carbon Dioxide/metabolism , Cell Compartmentation , Iproniazid/pharmacology , Malonates/pharmacology , Monoamine Oxidase Inhibitors/pharmacology , Quaternary Ammonium Compounds , Rats , Reactive Oxygen Species , Transaminases/antagonists & inhibitors , Valerates/metabolism , beta-Alanine/analogs & derivatives , beta-Alanine/pharmacologyABSTRACT
Glutamine is taken up by rat liver mitochondria in an electroneutral manner with a Km of 3.3 mM and a Vmax of 33 nmol x min-1 x mg-1 at 10 degrees C. The uptake is driven by the mitochondrial pH/cytosolic pH difference in isolated mitochondria, as well as in the intact rat liver. The rate of uptake is stimulated at a more alkaline matrix pH due to a stimulation of mitochondrial glutaminase. Our data confirm the notion that glutamine metabolism is regulated by pH, not only at the site of its metabolism but also through regulation of its transport systems.
Subject(s)
Glutamine/metabolism , Liver/metabolism , Mitochondria, Liver/metabolism , Animals , Biological Transport , Cytosol/metabolism , Hydrogen-Ion Concentration , Intracellular Membranes/drug effects , Intracellular Membranes/physiology , Kinetics , Membrane Potentials/drug effects , Mitochondria, Liver/drug effects , Mitochondria, Liver/physiology , Nigericin/pharmacology , Potassium/pharmacology , Rats , Succinates/pharmacologyABSTRACT
The uncoupling-like effect of fatty acids [ Scholz , R., Schwabe , U., and Soboll , S. (1984) Eur. J. Biochem. 141, 223-230] was further substantiated in experiments with perfused rat livers by two ways: firstly the kinetics of changes in metabolic rates (oxygen consumption, ketogenesis, fatty acid oxidation) were analysed; secondly subcellular contents of adenine nucleotides and pH gradients across the mitochondrial membrane were determined following fractionation of freeze-fixed and dried tissues in non-aqueous solvents. The following results were obtained. The relaxation kinetics of the increase in oxygen consumption following fatty acid infusion revealed two components, a rapid one with a half-time around 10 s and a slow one with a half-time of more than 100 s. The rapid component was similar to the kinetics of fatty acid oxidation (ketogenesis and 14CO2 production from labelled fatty acids) whereas the half-time of the slow component was in the range of half-times observed with the increase in oxygen consumption following addition of carbonylcyanide p-trifluoromethoxyphenylhydrazone. In the presence of fatty acids, the cytosolic ATP concentrations and ATP/ADP ratios decreased, whereas the corresponding parameters for the mitochondrial space were either increased (oleate) or decreased (octanoate). The effects of oleate were dependent on the albumin concentrations in the perfusate. The normally large difference between cytosolic and mitochondrial ATP/ADP ratios became smaller. Similar observations were obtained with uncoupling agents. The pH gradient across the mitochondrial membrane as calculated from the subcellular distribution of 5,5 dimethyl[2-14C]oxazolidine-2,4-dione was inversed following the addition of both carbonylcyanide p-trifluoromethoxyphenylhydrazone and fatty acids, i.e. the mitochondrial matrix became more acidic than the cytosol. The pH gradient was not affected when oleate was added in the presence of high albumin concentrations. The data support the hypothesis that the increase in hepatic oxygen consumption due to octanoate or oleate is, in part, caused by a mechanism similar to uncoupling of oxidative phosphorylation. This mechanism seems not to be an artifact of isolated systems; it may be of physiological importance for processes in which reducing equivalents are removed independently of the ATP demand of the hepatocyte.