Hypoxia is involved in many neuronal and non‐neuronal diseases, and defining the mechanisms for tissue adaptation to hypoxia is critical for the understanding and treatment of these diseases. One mechanism for tissue adaptation to hypoxia is increased glutamine and/or glutamate (Gln/Glu) utilization. To address this mechanism, we determined incorporation of Gln/Glu and other lipogenic substrates into lipids and fatty acids in both primary neurons and a neuronal cell line under normoxic and hypoxic conditions and compared this to non‐neuronal primary cells and non‐neuronal cell lines. Incorporation of Gln/Glu into total lipids was dramatically and specifically increased under hypoxia in neuronal cells including both primary (2.0‐ and 3.0‐fold for Gln and Glu, respectively) and immortalized cultures (3.5‐ and 8.0‐fold for Gln and Glu, respectively), and 90% to 97% of this increase was accounted for by incorporation into fatty acids (FA) depending upon substrate and cell type. All other non‐neuronal cells tested demonstrated decreased or unchanged FA synthesis from Gln/Glu under hypoxia. Consistent with these data, total FA mass was also increased in neuronal cells under hypoxia that was mainly accounted for by the increase in saturated and monounsaturated FA with carbon length from 14 to 24. Incorporation of FA synthesized from Gln/Glu was increased in all major lipid classes including cholesteryl esters, triacylglycerols, diacylglycerols, free FA, and phospholipids, with the highest rate of incorporation into triacylglycerols. These results indicate that increased FA biosynthesis from Gln/Glu followed by esterification may be a neuronal specific pathway for adaptation to hypoxia.
Astroglia is capable of releasing glutamate (Glu) in concentrations sufficient to activate ionotropic Glu receptors. Provided the released Glu reaches the receptors in the postsynaptic density, it can desensitize them. We have tested this possibility in the hippocampal CA1 synapses of rats either by applying exogenous Glu to the CA1 neurons or activating Glu release by astroglia. We found that Glu does not reach the synapses due to the existence of a protective uptake cap, which is sensitive to dihydrokainate, an inhibitor of GLT-type Glu transporter(s). Our results suggest that extrasynaptic and postsynaptic densities of the membranes of CA1 neurons form separate compartments differing from each other in the mechanisms and efficiency of processing external Glu. This provides additional diversity to specialized regulation of synaptic transmission and electrical excitation of pyramidal neurons. 相似文献
Rat cerebral nonsynaptic mitochondria were incubated in medium containing 2 mM glutamine (Gln) or 2 mM glutamate (Glu), in the presence of a Gln uptake inhibitor histidine (His) as well as other basic amino acids, lysine and arginine (Lys, Arg) not inhibiting Gln uptake. Subsequently, the mitochondrial contents of Glu and Gln were determined by HPLC. Incubation in the presence of Glu alone increased the Glu content from 3.5 to 15 nmol/mg protein, without affecting the Gln content. On the other hand, incubation with Gln increased the content of Gln from 1.5 to 12 nmol/mg, and that of Glu to 10 nmol/mg. As expected, addition of His did not alter the Glu and Gln content resulting from incubation with Glu. However, His significantly decreased to almost the preincubation level the content of Glu in mitochondria incubated with Gln, without affecting the content of Gln. No other amino acid had any effect on these parameters. The results point to the existence of distinct Gln pools, one of which is accessible to external Gln via a His-sensitive transporter and is accessible for deamidation in the mitochondria.Special issue dedicated to Dr. Lawrence F. Eng. 相似文献
Human serum albumin (HSA) binding with endogenous metabolites and drugs is substantially decreased in chronic renal and liver diseases. To test the hypothesis that the decreased binding ability is caused by conformational changes of the protein, we analyzed infrared and Raman spectra of HSA isolated from healthy donors and patients with chronic uremia and liver cirrhosis. Uremia did not affect the secondary structure of HSA but modified the environment of its Asp/Glu residues. Liver cirrhosis increased the amount of extended and beta-structures, modified the environment of Asp/Glu and Tyr side chains, and changed the configuration of disulfide bridges in albumin molecules. The conformational changes of "cirrhotic" albumin were not caused by reversibly bound ligands and resembled a partial unfolding of the protein induced by adsorption on the charcoal surface. The dramatic structural alterations of HSA in liver cirrhosis may be caused by its oxidative modification and might underlie the decreased binding ability and changed body distribution of albumin. 相似文献
Cholesterol oxidase is a monomeric flavoenzyme which catalyzes the oxidation and isomerization of cholesterol to cholest-4-en-3-one. ThechoR gene was cloned in pET23a and used as the starting plasmid for Glu361Asn, Glu361Gln and Glu361Asp site-directed mutagenesis. The purified mutant proteins like the wild-type have a molecular mass of 55 kD. The specific activities of Glu361Gln and Glu361Asn mutants were 28 and 35 times less than the wild-type. Glu361Asp mutant showed nearly no catalytic activity and was not purified. These experiments clearly demonstrated the importance of Glu361 for the enzymatic reactions of cholesterol oxidaseRhodococcus sp. 相似文献
Removal of L-glutamate (Glu) from the synapse is critical to maintain normal transmission and to prevent excitotoxicity, and is performed exclusively by excitatory amino acid transporters (EAATs). We investigated the effects of substrates and blockers of EAATs on extracellular Glu and cellular viability in organotypic cultures of rat hippocampus. Seven-day treatment with a range of drugs (L-trans-pyrrolidine-2,4-dicarboxylate, (2S,4R)-4-methyl-glutamate, (±)-threo-3-methylglutamate and DL-threo--benzyloxyaspartate), in the presence of 300 M added Glu, resulted in increased extracellular Glu and a significant correlation between Glu concentration and cellular injury (as indicated by lactate dehydrogenase release). In contrast, (2S,3S,4R)-2-(carboxycyclopropyl)glycine (L-CCG-III) exerted a novel neuroprotection against this toxicity, and elevations in extracellular Glu were not toxic in the presence of this compound. Similar results were obtained following two-week treatment of cultures without added Glu. Whilst blockade of GLT-1 alone was relatively ineffective in producing excitotoxic injury, heteroexchange of Glu by EAAT substrates may exacerbate excitotoxicity. 相似文献
Phenytoin was observed to inhibit competitively the sodium dependent high affinity synaptosomal transport of both glutamate (Glu) and -aminobutyric acid (GABA) withKi values of 66±10 and 185±65 M, respectively. This constrasted with a previous report that the uptakes of Glu and GABA were enhanced by phenytoin. The degree of inhibition is dependent on the concentrations of the competing drug and substrate present. Taking the therapeutic levels of phenytoin and the overall brain Glu and GABA contents, the degrees of inhibition obtainble appear to be negligible. However, as most of the high levels of Glu and GABA in the brain are intracellular, Glu, and GABA concentrations in the microenvironment of the uptake sites may be sufficiently small so that the ability of phenytoin to inhibit Glu and GABA transport may contribute significantly to the anticonvulsant property of this drug. 相似文献
The active site of mannitol 2-dehydrogenase from Pseudomonas fluorescens (PfM2DH) is connected with bulk solvent through a narrow protein channel that shows structural resemblance to proton channels utilized by redox-driven proton pumps. A key element of the PfM2DH channel is the "mobile" Glu(292), which was seen crystallographically to adopt distinct positions up and down the channel. It was suggested that the "down → up" conformational change of Glu(292) could play a proton relay function in enzymatic catalysis, through direct proton shuttling by the Glu or because the channel is opened for water molecules forming a chain along which the protons flow. We report evidence from site-directed mutagenesis (Glu(292) → Ala) substantiated by data from molecular dynamics simulations that support a role for Glu(292) as a gate in a water chain (von Grotthuss-type) mechanism of proton translocation. Occupancy of the up and down position of Glu(292) is influenced by the bonding and charge state of the catalytic acid base Lys(295), suggesting that channel opening/closing motions of the Glu are synchronized to the reaction progress. Removal of gatekeeper control in the E292A mutant resulted in a selective, up to 120-fold slowing down of microscopic steps immediately preceding catalytic oxidation of mannitol, consistent with the notion that formation of the productive enzyme-NAD(+)-mannitol complex is promoted by a corresponding position change of Glu(292), which at physiological pH is associated with obligatory deprotonation of Lys(295) to solvent. These results underscore the important role of conformational dynamics in the proton transfer steps of alcohol dehydrogenase catalysis. 相似文献
Redox-induced protonation state changes of the Glu residue in the multicopper oxidases, CueO and bilirubin oxidase (BO), were studied by attenuated total reflectance-Fourier transform infrared spectroscopy. By monitoring IR bands of the carboxylic acid CO stretch in the wild-type and Glu-to-Gln mutant enzymes the Glu506 of CueO (Glu463 of BO) was found to be unprotonated in the oxidised and protonated in the reduced forms. The results provided direct evidence for proton uptake by the Glu, suggesting it plays a key role in the proton donation to the activated oxygen species in the catalytic cycle. 相似文献
Müller glial cells from the retina "in situ" and in primary culture, mainly express the high-affinity sodium-coupled glutamate/aspartate transporter GLAST-1, which dominates total retinal glutamate (Glu) uptake, suggesting a major role for these cells in the modulation of excitatory transmission. The possible involvement of ionotropic and metabotropic Glu receptors in the regulation of Glu uptake was studied in primary cultures of Müller glia. We demonstrate that exposure to 1 mM L-Glu induces a time-dependent inhibition of D-aspartate (D-Asp) uptake in a Na+-dependent manner, as a result of a reduction in the number of transporters at the plasma membrane. The inhibition of D-Asp uptake by Glu was not mimicked by agonists or modified by antagonists of ionotropic and metabotropic Glu receptors. In contrast, transport was inhibited by GLAST-1 transportable substrates threo-hydroxyaspartate and aspartate-beta-hydroxamate, but not by the nontransportable inhibitors trans-pyrrolidine dicarboxylate or DL-threo-beta-benzyloxyaspartic acid. Under the same experimental conditions, L-Glu did not affect the sodium-dependent transport systems for glycine or GABA. The present results demonstrate that the specific downregulation of glutamate/aspartate transport by L-Glu is unrelated to Glu receptor activation, and results from the internalization of transporter proteins triggered by the transport process itself. Such negative feedback of Glu on Glu transport, could contribute to retinal toxicity under pathological conditions in which high extracellular concentrations of Glu are reached. 相似文献
