Modification of the blood-brain barrier through chronic intoxication by aluminum glutamate

The authors have used an experimental rat model of chronic aluminum (Al) intoxication to reproduce pathological signs analogous to those observed in humans for Alzheimer’s disease or dialysis encephalopathy. Preliminary chronic intoxication was achieved during 5 wk by daily subcutaneous injection of a suspension of glutamate and Al prior to intravenous (iv) administration of sodiuml-glutamate and Al chloride. A significant increase in Al content was observed in different areas of the brain, such as the hippocampus, the occipito-parietal cortex, the cerebellum, and the striatum. Moreover, half of the animals subcutaneously treated with Al glutamate had neurological disturbances; such as trembling, equilibrium difficulties, and convulsions leading to death about 1 h after iv administration. A significant increase in glutamic acid at the level of the occipito-parietal cortex was found in comparison with controls, which received only sodiuml-glutamate or saline solution. These results show that the Al-l-glutamate complex may well induce a modification of the blood-brain barrier.     

Effects of 6-hydroxydopamine on brain and blood catecholamines, ammonia, and amino acids in rats

The effect of 6-hydroxydopamine (6-OHDA) upon brain and blood catecholamines, ammonia, and amino acids has been studied in rats subjected to increasing doses of the drug. Time dependent effects after injection have also been studied. Systemically injected 6-OHDA significantly, acutely reduced brain adrenaline (A), noradrenaline (NA), total catecholamines (TC), gamma-aminobutyric acid (GABA), and glutamic acid (Glu); concomitantly brain ammonia (NH3) increased. In blood, NA and TC were reduced and A and NH3 increased. The changes in brain monoamines are surprising since it has been reported that 6-OHDA does not cross the blood-brain barrier. We have proposed that these changes result from a general stress response or a reflex peripheral sympathetic response to falling blood pressure which in some manner communicates to the central nervous system. As the dose of 6-OHDA increased, brain NH3 increased and Glu decreased. A similar effect was seen from a single dose as the time after injection for sampling brain and blood constituents increased. Blood ammonia increases without change in Glu, glutamine, or asparagine. The source of NH3 may be from deamination of adenine nucleotide or catechols released from nerve terminals under the abnormal stimulus of 6-OHDA.     

Aluminum transfer as glutamate complex through blood-brain barrier

In vitro distribution of aluminium between plasma and erythrocytes has been studied in the presence of variable amounts of sodium L-glutamate. With a red blood cell suspension in isotonic sodium chloride, aluminium remains confined in erythrocytes even when the sodium L-glutamate concentration increases in the medium. Aluminium initially present in plasma penetrates red blood cells when sodium L-glutamate increases in whole blood, showing that this metal is able in vitro to cross the erythrocyte membrane as glutamate complex. In vivo experiments with male Wistar rats prove that aluminium is also able to pass the blood--brain barrier as glutamate complex and deposit in the brain cortex.     

Ammonia detoxification by accelerated oxidation of branched chain amino acids in brains of acute hepatic failure rats

BCAA aminotransferase and BCKA dehydrogenase activities are increased in the mitochondrial fractions from the brains of hepatic failure rats treated with two-thirds removal of CCl4-injured liver. Cerebral leucine decarboxylation was accelerated, and it well correlated with arterial blood ammonia levels. Elevation of brain ammonia content following an intraperitoneal injection of ammonium acetate to hepatic failure rats could be prevented by intravenous infusion of BCAA. Significantly increased brain glutamic acid, glutamine, and alanine contents were noted. These results suggested that accelerated brain BCAA catabolism in acute hepatic failure rats reduce the neurotoxicity of ammonia by promoting the synthesis of glutamic acid and glutamine from BCAA.     

Effect of aluminum on the blood-brain barrier permeability during nitric oxide-blockade-induced chronic hypertension in rats

We examined the effect of aluminum on the permeability of the blood-brain barrier (BBB) during nitric oxide-blockade-induced chronic hypertension in rats. Animals were given the inhibitor of nitric oxide synthase, l-NAME (N ^ω-nitro-l-arginine methyl ester), for 4 wk to induce chronic hypertension. Two groups of rats were given an intraperitoneal injection of aluminum chloride. The integrity of the BBB was assessed by a quantitative measurement for Evans blue (EB) dye. The arterial blood pressure in l-NAME- and l-NAME plus aluminum-treated animals was significantly elevated from 115±2.8 and 110±1.7 mm Hg to 174±5.2 and 175±4.8 mm Hg, respectively (p<0.01). The EB dye content in the brain regions of the rats in the l-NAME group was increased, but there was no statistical significance compared to the saline group. The extravasation of EB dye was significantly increased in the brain regions of the animals treated with aluminum compared to the rats treated with saline (p<0.05). A significantly higher EB dye content in the brain regions was observed in the l-NAME plus aluminium group compared to l-NAME, aluminum, and saline groups (p<0.01). These findings indicate that exposure to a high level of aluminum leads to an additional increase in BBB permeability where nitric oxide-blockade-induced chronic hypertension potentiates the effect of aluminum to enhance BBB permeability to EB dye.     

Colonic luminal ammonia and portal blood l-glutamine and l-arginine concentrations: a possible link between colon mucosa and liver ureagenesis

The highest ammonia concentration in the body is found in the colon lumen and although there is evidence that this metabolite can be absorbed through the colonic epithelium, there is little information on the capacity of the colonic mucosa to transfer and metabolize this compound. In the present study, we used a model of conscious pig with a canula implanted into the proximal colon to inject endoluminally increasing amounts of ammonium chloride and to measure during 5 h the kinetics of ammonia and amino acid concentration changes in the portal and arterial blood. By injecting as a single dose from 1 to 5 g ammonia into the colonic lumen, a dose-related increase in ammonia concentration in the portal blood was recorded. Ammonia concentration remained unchanged in the arterial blood except for the highest dose tested, i.e. 5 g which thus apparently exceeds the hepatic ureagenesis capacity. By calculating the apparent net ammonia absorption, it was determined that the pig colonic epithelium has the capacity to absorb 4 g ammonia. Ammonia absorption through the colonic epithelium was concomitant with increase of l-glutamine and l-arginine concentrations in the portal blood. This coincided with the expression of both glutamate dehydrogenase and glutamine synthetase in isolated colonic epithelial cells. Since l-glutamine and l-arginine are known to represent activators for liver ureagenesis, we propose that increased portal concentrations of these amino acids following increased ammonia colonic luminal concentration represent a metabolic link between colon mucosa and liver urea biosynthesis.     

Effects of fasting and diabetes on some enzymes and transport of glutamate in cortex slices or synaptosomes from rat brain

Phosphate-activated glutaminase (PAG) and glutamic acid decarboxylase (GAD) were assayed in homogenates and synaptosomes obtained from starved (48 hr or 120 hr) and diabetic (streptozotocin) rat brain cortex. Glutamine synthetase (GS) was assayed in homogenates, microsomal and soluble fractions, from brain cortex of similarly treated rats.l-Glutamate uptake and exit rates were determined in cortex slices and synaptosomes under the same conditions. The specific activity (s.a.) of PAG, a glutamate producing enzyme, decreased (50%) in the homogenate after 120-hr starvation. In synaptosomes it decreased (25%) only after 48-hr starvation. The s.a of GAD and GS, which are glutamate-consuming enzymes, were progressively increased with time of starvation, reaching 39% and 55% respectively after 120 hr. GS in the microsomes or the soluble fraction and GAD in the synaptosomes showed no change in s.a. under these conditions. Diabetes increased (40%) microsomal GS s.a. and decreased GAD s.a. (18%) in the homogenate. Thel-glutamate uptake rate was decreased (48%) by diabetes in slices but not in synaptosomes. It is suggested that a) enzymes of the glutamate system respond differently in different subcellular fractions towards diabetes or deprivation of food and b) diabetes may affect the uptake system in glial cells but not in neurons.Abbreviations used AET 2-aminoethylisourethonium bromide - GAD glutamic acid decarboxylase - GS glutamine synthetase - GSH glutathione - PAG phosphate-activated glutaminase - PLP pyridoxal phosphate - r.c.f. relative centrifugal force - s.a. specific activity     

Evaluation of intra-blood brain barrier IgG synthesis rate and blood brain barrier function in normal rhesus monkeys

In order to evaluate blood brain barrier (BBB) integrity and intra-BBB IgG synthesis under CSF pathologic conditions, it is necessary to establish normal values in a control population. In this study an evaluation was made of the blood brain barrier (BBB) integrity and intra-BBB IgG synthesis in the central nervous system (CNS) of normal juvenile rhesus monkeys to establish these values. Parallel cisternal cerebral spinal fluid (CSF) and venous serum samples were collected from 12 healthy male rhesus monkeys. Normal values for CSF/serum ratios of IgG and of albumin were determined and incorporated in theTourtellotte formula for quantitation of intrathecally synthesized IgG per 24 hours. The effect of systemic mannitol administration on the BBB was also evaluated by the primate adapted formula and magnetic resonance imaging contrast enhanced studies.     

Glutamic Acid Signal Synchronizes Protein Synthesis Kinetics in Hepatocytes from Old Rats for the Following Several Days. Cell Metabolism Memory

The kinetics of protein synthesis was investigated in primary cultures of hepatocytes from old rats in serum–free medium. The rats were fed mixed fodder supplemented with glutamic acid and then transferred to a regular mixed fodder. The amplitude of protein synthesis rhythm in hepatocytes isolated from these rats increased on average 2–fold in comparison with the rats not receiving glutamic acid supplement. Based on this indicator reflecting the degree of cell–cell interactions, the cells from old rats were not different from those of young rats. The effect was preserved for 3–4 days. These results are discussed in connection with our previous data on preservation of the effect of single administration of gangliosides, noradrenaline, serotonin, and other synchronizers on various cell populations. In contrast to the other investigated factors, glutamic acid is capable of penetrating the blood–brain barrier, which makes its effect possible not only in the case of hepatocytes and other non–brain cells, but also in neurons.     

血脑屏障与脑血管疾病的相关研究

血脑屏障（blood brain barrier,BBB）的主要结构包括：脑毛细血管内皮细胞及其间的紧密连接（tight junction,TJ）、基底膜、基 底膜下星型胶质细胞终足。血脑屏障是存在于血液和脑组织之间的一层屏障系统,在许多大脑疾患的病理过程中,BBB 的破坏导 致通透性增高都是不可避免的一个环节。BBB是保证中枢神经系统的正常生理功能的重要屏障系统。目前已有大量关于血脑屏 障通透性在脑血管疾病中的变化研究。本文分别从血脑屏障的结构和功能,药物通过血脑屏障的方法和功能,脑缺血损伤、阿尔 茨海默病、帕金森病和多发性硬化症等不同的脑病变与血脑屏障通透性的变化及中医药应用等方面做一综述。有针对性地对 BBB和大脑疾病进行进一步的研究与探索,将会为临床治疗相关疾病带来新的视角与机遇。     

Influence of the glass packing on the contamination of pharmaceutical products by aluminium. Part II: Amino acids for parenteral nutrition

The presence of aluminium in amino acids parenteral nutrition solutions can be related to the affinity of the amino acids for aluminium present in glass containers used for storage. For this study solutions of 19 amino acids used in parenteral nutrition were stored individually in glass flasks and the aluminium measured at determined time intervals. Solutions of complexing agents for aluminium, as ethylene-diaminetetraacetic acid, nitrilotriacetic acid, citrate, oxalate and fluoride ions were also stored in the same flasks and the aluminium measured during the same time interval. The measurements were made by electrothermal atomic absorption spectrometry. The aluminium content of the glass containers was also measured. The results showed that the glasses have from 0.6% to 0.8% Al. Only solutions of cysteine, cystine, aspartic acid and glutamic acid became contaminated by aluminium. As the same occurred with the complexing agents, aluminum can be released from glass due to an affinity of the substances for aluminium. Comparing the action of complexing agents and amino acids for which the stability constants of aluminium complex are known, it is possible to relate the magnitude of the stability constant with the aluminium leached from glass, the higher the stability constant, the higher the aluminium released. The analysis of commercial formulations with and without cysteine, cystine, glutamic acid or aspartic acid stored in glass containers confirms that the presence of these amino acids combined with the age of the soLution are, at least partially, responsible for the aluminium contamination. The resuLts demonstrated that the contamination is an ongoing process due to the presence of aluminium in glass combined with the affinity of some amino acids for this element.     

Correlation between [U-14C]glucose metabolism and function in perfused cat brain

In brain perfusion experiments conducted with blood containing [U-14C]glucose the relative specific activity (RSA) of blood glucose carbon incorporated in brain intermediate metabolites was measured. It was demonstrated that the so-called metabolic pattern of Geiger is not constant, but it bears a close relation to the function of the brain. The results of the study may be summarized briefly as follows. (1) In a group (A) of cats with a high level of brain function, the RSA of lactic acid was 75 per cent; that of glutamic acid 80 per cent; aspartic acid 75 per cent; glutamine 61 per cent; GABA 43 per cent; and respiratory CO2 55 per cent. It was observed that the major part of the carbon of amino acids, such as glutamic acid and aspartic acid, which are directly associated with the tricarboxylic acid cycle are derived from blood glucose. (2) In a group (B) showing a low level of brain function, the RSA of each amino acid was considerably lowered. The RSA of glutamic acid and aspartic acid was about 50 per cent and that of respiratory CO2 was 27 per cent. (3) In a group (C) with a still lower level of brain function, each amino acid as well as the respiratory CO2 had still lower RSA values. (4) The metabolic pattern of Geiger corresponds to values obtained during low functional activity of the brain in our experiment.     

Metabolism and Brain Uptake of γ-Aminobutyric Acid in Galactosamine-Induced Hepatic Encephalopathy in Rats

Abstract: Kinetic studies of [³H]γ-aminobutyric acid ([³H]GABA) after an intravenous injection were performed in normal rats and in rats with severe degree of hepatic encephalopathy due to fulminant hepatic failure induced by galactosamine. Moreover, plasma and brain GABA levels, and GABA and glutamic acid decarboxylase activity were studied in some brain areas. After intravenous injection, [3H]GABA disappeared very rapidly in the blood of normal rats, with a prompt increase of ³H metabolites. In comatose rats, a delayed disappearance of [3H]GABA.as parallelled by a lower amount of metabolites, indirectly indicating a peripheral decrease of GABA-transaminase activity. The amount of [³H]GABA in brain was lightly but constantly lower in comatose rats than in controls, indicating that the change in permeability of the blood-brain barrier in hepatic encephalopathy does not affect the [3H]GABA uptake of the brain. Furthermore, the assay of endogenous GABA in blood, whole brain, and brain areas did not show any significant difference in any of the two groups. The finding that glutamic acid decarboxylase activity in brain was reduced, together with the indirect evidence of a reduction in GABA-transaminase, may account for the steady state of GABA in hepatic encephalopathy. However, the reduction in glutamic acid decarboxylase activity is in favor of a functional derangement at the GABA-ergic nerve terminals in this pathological condition.     

Effects of dieldrin, picrotoxin and Telodrin on the metabolism of ammonia in brain

1. Increases in the concentrations of lactic acid and pyruvic acid in rat brain during acute dieldrin poisoning are associated with hyperactivity of the brain, whereas an increase in the cerebral alanine concentration occurs before the convulsions. Throughout the dieldrin-induced seizure pattern, fluctuations in the concentration of brain ammonia are out of phase with the actual convulsions. 2. Increases in the concentrations of alanine, ammonia and lactic acid in rat brain accompany picrotoxin-induced seizures; there is no increase in the concentration of glutamine. These changes are consistent with the inhibition of glutamine synthesis. 3. In addition to previously reported changes in the concentrations of intermediary metabolites of the brain after the administration of Telodrin (Hathway & Mallinson, 1964), increases have now been found in the alanine and lactic acid concentrations. Since increases in the alanine and glutamine concentrations occur before the convulsions, liberation of ammonia also occurs before the onset of convulsions and throughout their course. Ammonia-binding mechanisms later become inadequate and free ammonia accumulates in cerebral tissues. 4. An increase in the pyruvic acid concentration of the brain after the intraperitoneal injection of either dieldrin or Telodrin is endogenous in origin. 5. The parenteral administration of a small dose of glutamine increases the cerebral concentrations of alanine and glutamic acid. Some animals previously treated with glutamine resisted Telodrin convulsions. 6. Mechanisms for the disposal of ammonia liberated in brain are discussed.     

Glutamate receptor changes in brain synaptic membranes from human alcoholics

Brains from human alcoholics and non-alcoholics were obtained shortly after death. The hippocampus was dissected, homogenized, and processed for the isolation of a synaptic membraneenriched fraction and the study ofl-[³H]glutamic acid and 3-((±)-2-carboxypiperazin-4-yl)-[1,2³H]propyl-l-phosphonic acid ([³H]CPP) binding sites. The pharmacological characteristics ofl-[³H]glutamic acid binding to synaptic membranes isolated from hippocampus corresponded to the labeling of a mixture of N-methyl-d-aspartate (NMDA), kainate and quisqualic acid receptor sites. Synaptic membranes prepared from the hippocampus of individuals classified as alcoholics had significantly higher density of glutamate binding sites than identically prepared membranes from non-alcoholic individuals. In addition, there was a clear definition of a population ofl-glutamate binding sites (approx. 10% of total) in the membranes from alcoholics that had a higher affinity for the ligand than the major set of sites labeled in membranes from both alcoholics and non-alcoholics. Neither the age of the individuals at the time of death nor the time that elapsed between death and processing of brain tissue were significant factors in determining either recovery of purified synaptic membranes from brain homogenates orl-[³H]glutamate binding to synaptic membranes. In order to determine whether some of the changes inl-[³H]glutamic acid binding were due to alterations in binding at the NMDA receptor subtype, we also measured binding of [³H]CPP to extensively washed crude synaptosomal membranes. Membranes from brains of alcoholics had higher affinity (3-fold) for [³H]CPP but lower binding capacity (3-fold) when compared with those of non-alcoholics. These observations suggest selective changes among different glutamate receptor subtypes in human brain under conditions of chronic alcohol intake.     

Glucose Transporter 1, Distribution in the Brain and in Neural Disorders: Its Relationship With Transport of Neuroactive Drugs Through the Blood-Brain Barrier

Facilitative glucose transport is mediated by one or more of the members of the closely related glucose transporter (GLUT) family. Thirteen members of the GLUT family have been described thus far. GLUT1 is a widely expressed isoform that provides many cells with their basic glucose requirement. It is also the primary transporter across the blood-brain barrier. This review describes the distribution and expression of GLUT1 in brain in different pathophysiological conditions including Alzheimers disease, epilepsy, ischemia, or traumatic brain injury. Recent investigations show that GLUT1 mediates the transport of some neuroactive drugs, such as glycosylated neuropeptides, low molecular weight heparin, and d-glucose derivatives, across the blood-brain barrier as a delivery system. By utilizing such highly specific transport mechanisms, it should be possible to establish strategies to regulate the entry of candidate drugs.     

Metabolism of hibernating reptiles. Changes of free amino acids in blood, liver and brain.

1. Glutamic acid showed a significant decrease during hibernation in brain cortex. This is attributed to: (a) Transformation to glutamine to detoxicate ammonia. (b) The synthesis of GABA from glutamic acid. (c) It is suggested that the enzyme GAD is active during hibernation. 2. GABA showed a significant increase in liver and brain cortex. It was absent in the blood serum. (a) The present results show that non-neural tissues contain lower GABA than neural tissues. (b) GABA may be formed locally in tissues by decarboxylation of glutamate as well as from pathways connected with tricarboxylic acid cycle. 3. Aspartic acid showed increased levels in blood serum, liver and brain cortex, the greatest increase was observed in liver. 4. A significant increase was recorded in the level of arginine in brain cortex and liver, whilst a smaller percentage increase was recorded in ornithine level. It is assumed that transformation of arginine to ornithine was depressed during hibernation.     

Orinithine as a constituent of the peptidoglycan of Chloroflexus aurantiacus,diaminopimelic acid in that of Chlorobium vibrioforme f. thiosulfatophilum

L-Ornithine is the only diamino acid of the peptidoglycan of the gliding phototrophic Chloroflexus aurantiacus. The other constituents are L- and D-alanine, D-glutamic acid, N-acetyl-glucosamine and N-acetyl-muramic acid (in part as muramic acid-6-phosphate), all in approximate equimolar ratios to L-ornithine, aside from small amounts of glycine and histidine. Furthermore unlike typical Gram-negative bacteria, protein is not bound to this peptidoglycan. Instead, the rigid layer (sodium dodecyl sulfate insoluble cell wall fraction) contained large amounts of a complex polysaccharide consisting of sugar O-methyl ethers, hexoses and pentoses. Its binding site is presumably muramic acid-6-phosphate of the peptidoglycan.In contrast, in Chlorobium vibrioforme f. thiosulfatophilium, meso-diaminopimelic acid was found as the only diamino acid of this peptidoglycan. As with other Gramnegative bacteria, L- and D-alanine, D-glutamic acid, N-acetyl-glucosamine and N-acetyl-muramic acid (no muramic acid-6-phosphate) were observed in approximate equimolar ratios to meso-diaminopimelic acid, except a lower D-alanine content. The rigid layer of Chlorobium vibrioforme f. thiosulfatophilum contained protein, and there were no indications for a complex polysaccharide comparable to that of Chloroflexus aurantiacus.Abbreviations Ala alanine - A₂pm diaminopimelic acid - GC/MS combined gas-liquid chromatography/mass spectrometry - GlcNAc N-acetyl-glucosamine - Glu glutamic acid - Gly glycine - HF hydrofluoric acid - Lys lysine - MurNAc N-acetyl-muramic acid - Orn ornithine - SDS sodium dodecyl sulfate     

High-affinity binding of proline to mouse brain synaptic membranes

There is evidence suggestive of the possible neuromodulatory role forl-proline in the mammalian brain. The binding of proline to whole mouse brain synaptic membranes has been partially characterized. Several binding sites for this imino acid have been identified; one in the nanomolar range and at least two in the submicromolar range. The binding of proline is inhibited by NaCl. Pipecolic acid (40 M), ornithine, aminooxyacetic acid (AOAA), glycine, GABA, and glutamate were capable of significantly inhibiting proline binding. Although detailed pharmacological and functional studies are needed, these results are consistent with a brain-specific function for this imino acid, as well as, with the presence of specific binding site(s) for proline.     

Prevention of ammonia toxicity byl-carnitine: metabolic changes in brain

l-Carnitine when injected in mice 30 min before an LD₁₀₀ of ammonium acetate (12 mmol/kg body weight, intraperitoneal) reduced mortality (100% survival with 16 mmoll-carnitine/kg) and prevented the appearance of symptoms of ammonia toxicity. Brain ammonia decreased in the animals givenl-carnitine. Ammonia decreased the levels of glutamate in brain; they were partially restored byl-carnitine, which also reduced the increase in brain glutamine in animals given only ammonia. The redox state of the brain was altered following ammonia intoxication. The ratio of lactate to pyruvate in the cytosol increased while that of glutamate to -ketoglutarate in the mitochondria decreased. These ratios were partially restored byl-carnitine. The implications of these findings are discussed relative to the mechanism of ammonia toxicity.