Lipid oxidation in blood plasma of patients with neurological disorders.

Nuclear magnetic resonance (NMR) spectra of blood plasma lipids from lyophilized plasma samples from patients with neurological disorders stored for several weeks in an evacuated exsiccator show characteristic differences compared to freshly lyophilized plasma samples. The main differences concern the unsaturated fatty acids, e.g., the extent of unsaturation and their structural composition. The total amount of double bond signals of unsaturated fatty acids are noticeably reduced in intensity and new signals arise from conjugated double bonds. These signals can be assigned to keto-octadecadienoic acid (KODE) or hydroxy-octadecadienoic acid (HODE). The proton and carbon NMR chemical shifts and their structural assignment to the main molecular components are given. Whereas the KODE and HODE signals occur only as storage artifacts in the spectra, we have found small amounts of 9,11-octadecadienoic acid also in fresh blood plasma of controls. Its concentration is about 60 microM. In two-dimensional H,H total correlation spectroscopy spectra also a very low amount (6-7 microM) of 13-HODE can be detected.

Rapid uptake and degradation of glycine by astroglial cells in culture: synthesis and release of serine and lactate.

Free glycine is known to have vital functions in the mammalian brain, where it serves mainly as both neurotransmitter and neuromodulator. Despite its importance, little is known about the metabolic pathways of glycine synthesis and degradation in the central nervous system. In this study, the pathway of glycine metabolism in astroglia-rich primary cultures from rat brain was examined. The cells were allowed to degrade glycine in the presence of [U-(14)C]glycine, [U-(13)C]glycine or [(15)N]glycine. The resulting intra- and extracellular metabolites were analyzed both by high-performance liquid chromatography and by (13)C/(15)N nuclear magnetic resonance spectroscopy. Glycine was rapidly consumed in a process obeying first-order kinetics. The initial glycine consumption rate was 0.47 nmol per mg protein. The half-life of glycine radiolabel in the incubation medium was shorter than that of glycine mass. This suggests that glycine is produced from endogenous sources and released simultaneously with glycine uptake and metabolism. As the main metabolites of the glycine carbon skeleton in astroglia-rich primary cultures from rat brain, serine and lactate were released during glycine consumption. The main metabolite containing the glycine amino nitrogen was glutamine. To establish a metabolic pathway from glycine to serine in neural tissue, homogenates of rat brain and of neural primary cultures were assayed for their content of serine hydroxymethyltransferase (SHMT) and glycine cleavage system (GCS). SHMT activity was present in homogenates of rat brain as well as of astroglia-rich and neuron-rich primary cultures, whereas GCS activity was detectable only in homogenates of rat brain and astroglia-rich primary culture. Of the two known SHMT isoenzymes, only the mitochondrial form was found in rat brain homogenate. It is proposed that, in neural tissue, glycine is metabolized by the combined action of SHMT and the GCS. Owing to the absence of the GCS from neurons, astrocytes appear to be the only site of this part of glycine metabolism in brain. However, neurons are able to utilize as energy source the lactate formed by astroglial cells in this metabolic pathway.

Rat brain primary neurons immobilized in basement membrane gel threads: an improved method for on-line 13C NMR spectroscopy of live cells.

In vivo MRS studies on intact brain reflect the metabolism of all cells present, but do not distinguish between different cell types. NMR studies of immobilized cultured primary cells, such as neurons and astrocytes, are a useful model to monitor the specific differences in metabolism of the various cell types in the brain. The present study shows that primary rat neuronal cells can be cultured in basement membrane gel threads. After 4 days of incubation the threads are filled with viable cells, and represent a population of morphologically differentiated neuronal cells with less than 5% of non-neuronal cells, i.e., astrocytes. These threads were placed into a NMR tube and used for on-line monitoring of neuronal metabolism. Under these conditions cells remained viable and metabolically active for several days. The energy status was monitored by using 31P NMR spectroscopy. To study neuronal glucose metabolism [1-13C]glucose was added to the perfusion medium and 30 min later 13C-labeled metabolites were detectable by 13C NMR spectroscopy. Immobilized neurons synthesized glycolytic products such as [3-13C]lactate and [3-13C]alanine, as well as several tricarboxylic acid cycle products, i.e., [2-13C]glutamate, [3-13C]glutamate, [4-13C]glutamate, [2-13C]aspartate, and [3-13C]aspartate. In summary, 31P and 13C NMR spectra can be recorded from live neuronal cells for up to 24 h using the newly designed procedure described in the present communication.

A 1H/13C inverse 2D method for the analysis of the polyamines putrescine, spermidine and spermine in cell extracts and biofluids.

The polyamines putrescine, spermidine and spermine are involved in the regulation of various metabolic processes. It is therefore desirable to detect and quantify the polyamines with NMR. We present the proton and carbon assignments for all polyamine signals obtained from PCA extracts of F98 glioma cells with high resolution using a semi-selective HSQC 2D-experiment. The biosynthesis of the polyamines in cell culture was examined using the labeled substrates [U-13C]glucose and [U-13C]glutamate. In such studies the high resolution of the semi-selective HSQC experiment at very high magnetic fields (14-19 T) allows the analysis of carbon-carbon couplings, and isotopomer patterns. The different effects of osmotic stress on the concentrations of polyamines and amino acids are also reported.

Metabolism of glycine in primary astroglial cells: synthesis of creatine, serine, and glutathione.

The metabolism of [2-13C]glycine in astroglia-rich primary cultures obtained from brains of neonatal Wistar rats was investigated using 13C NMR spectroscopy. After a 24-h incubation of the cells in a medium containing glucose, glutamate, cysteine, and [2-13C]glycine, cell extracts and incubation media were analyzed for 13C-labeled compounds. Labeled creatine, serine, and glutathione were identified in the cell extracts. If arginine and methionine were present during the incubation with [2-13C]glycine, the amount of de novo synthesized [2-13C]creatine was two-fold increased, and in addition, 13C-labeled guanidinoacetate was found in cell extracts and in the media after 24 h of incubation. A major part of the [2-13C]glycine was utilized for the synthesis of glutathione in astroglial cells. 13C-labeled glutathione was found in the cell extracts as well as in the incubation medium. The presence of newly synthesized [2-13C] serine, [3-13C]serine, and [2,3-13C]serine in the cell extracts and the incubation medium proves the capability of astroglial cells to synthesize serine out of glycine and to release serine. Therefore, astroglial cells are able to utilize glycine as a precursor for the synthesis of creatine and serine. This proves that at least one cell type of the brain is able to synthesize creatine. In addition, guanidinoacetate, the intermediate of creatine synthesis, is released by astrocytes and may be used for creatine synthesis by other cells, i.e., neurons.

Determination of de novo synthesized amino acids in cellular proteins revisited by 13C NMR spectroscopy.

13C nuclear magnetic resonance spectroscopy was used to determine the absolute amounts to de novo synthesized amino acids in both the perchloric acid extracts and the hydrolyzed protein fractions of F98 glioma cells incubated for 2 h with 5 mmol/l [U-13C]glucose. 13C NMR spectra of the hydrolyzed protein fraction revealed a marked incorporation of 13C-labelled alanine, aspartate and glutamate into the proteins of F98 cells within the incubation period. Additionally, small amounts of 13C-labelled glycine, proline and serine could unambiguously be identified in the protein fraction. Astonishingly, approximately equal amounts of 13C-labelled glutamate and aspartate were incorporated into the cellular proteins, although the cytosolic steady-state concentration of aspartate was below 13C NMR detectability. Hypertonic stress decreased the incorporation of 13C-labelled amino acids into the total protein, albeit their cytosolic concentrations were increased, which reflects an inhibition of protein synthesis under these conditions. On the other hand, hypotonic stress increased the amount of 13C-labelled proline incorporated into the cellular proteins even though the cytosolic concentration of 13C-labelled proline was largely decreased. Apparently, hypoosmotic conditions stimulate the synthesis of proteins or peptides with a high proline content. The results show that already after 2 h of incubation with [U-13C]glucose there is a pronounced flux of 13C label into the cellular proteins, which is usually disregarded if cytosolic fluids are examined only. This means that calculations of metabolic fluxes based on 13C NMR spectroscopic data obtained from perchloric acid extracts of cells or tissues and also from in vivo measurements consider only the labelled 'NMR visible' cytosolic metabolites, which may have to be corrected for fast label flowing off into other compartments.

Early stage monitoring of miltefosine induced apoptosis in KB cells by multinuclear NMR spectroscopy.

Synthetic ether lipids, like miltefosine (hexadecylphosphocholine), an alkylphosphocholine, are antineoplastic agents in vitro and in vivo. Their mode of action is mediated via the cell membrane, but the mechanism is still unclear. Miltefosine induces apoptosis in human epithelial KB cells, but slows down only proliferation in rat C6 glioma cells. NMR spectroscopy on lipid extracts reveals increased diacylglycerol and triacyglycerol biosynthesis in KB cells prior to DNA fragmentation indicating a CTP:phosphocholine-cytidylyl-transferase (CT) inhibition by the drug. Although C6 cells were morphologically affected by alterations in phospholipid composition and metabolism by a long term treatment (23 days) with the drug, no persistent diacylglycerol increase is observed.

Combined extraction techniques of tumour cells and lipid/phospholipid assignment by two dimensional NMR spectroscopy.

As the cell membranes are one of the targets of drug treatment in cancer cells, their membrane composition and variations in this composition need to be analyzed. Gradient selected 2D-NMR inverse heteronuclear chemical shift correlations are have described, which offer optimum sensitivity combined with a high reliability for unequivocal signal assignment in proton, carbon and phosphorous spectra, concerning neutral lipids and in particular phospholipids. Additionally, an extraction procedure is presented to extract subsequently the water soluble (PCA extract) and lipophilic metabolites (chloroform/methanol extract) from the same cell batch.

Adaptation of cellular metabolism to anisosmotic conditions in a glial cell line, as assessed by 13C-NMR spectroscopy.

13C-NMR spectroscopy of perchloric acid and lipid extracts of F98 glioma cells showed that volume-regulatory processes under anisosmotic conditions were accompanied by marked alterations in cellular metabolism. Production of alanine, glutamate, and glycine from [U-13C]-glucose is decreased under hypotonic stress and is oppositely increased under hypertonic stress. In contrast, degradation of these molecules is raised under hypotonic conditions and reduced under hypertonic conditions. Furthermore, phospholipid synthesis is decreased under hypertonic stress and increased under hypotonic stress. Obviously, glial metabolism is directed under hypertonic conditions to maintain a high level of small, osmotically active molecules, whereas under hypotonic conditions molecular fragments are increasingly incorporated into the phospholipids and so do not contribute to the osmotic pressure. The latter is evoked by the activation of membrane synthesis process to compensate for stretching and/or damaging of the membranes due to cell swelling.

Regulation of intracellular pH in neuronal and glial tumour cells, studied by multinuclear NMR spectroscopy.

The effect of extracellular pH (pHe) on intracellular pH (pHi) and cellular metabolism was examined by multinuclear NMR spectroscopy of cells in vivo and in vitro. A decrease in pHe from 7.4 to 6.4 led to a significant drop in pHi, in both neuronal and glial tumour cells, as detected by in vivo 31P NMR of cells embedded in basement membrane gel threads. A more than 50% decrease in both the phosphocreatine (PCr) level and derivatives of glycolysis (i.e., glycerol 3-phosphate) was observed, concomitantly to the fall in pHi. A 50% decrease in intracellular lactate levels was seen in in vivo 1H NMR spectra under these conditions. Reperfusion with fresh medium (pHe 7.4) resulted in the full recovery of pHi, simultaneously with an increase in both PCr and intracellular lactate back to their control levels. Perchloric acid and lipid extract measurements confirmed the observations made by in vivo 31P and 1H NMR spectroscopy and further showed a decrease both in tricarboxylic acid cycle activity and phospholipid synthesis. The data revealed no significant differences between the neuronal and glial tumour cells investigated. pHi measurements in the presence of inhibitors of the various pH regulatory mechanisms showed that the Na+/H+ exchanger, the carbonic anhydrase and at least one of the bicarbonate-transport systems are involved in pH regulation of both cell types. The results suggest that Na+/H+ exchange is the preferred mechanism by which both neuronal and glial cells regulate their pHi after extracellular acidification.