Determination of amino acids in different regions of the rat brain. Application to the acute effects of tetrahydrocannabinol (THC) and trimethyltin (TMT)

Efficient Fmoc-Protected Amino Ester Hydrolysis Using Green Calcium(II) Iodide as a Protective Agent

In order to modify amino acids, the C-terminus carboxylic acid usually needs to be protected, typically as a methyl ester. However, standard cleavage of methyl esters requires either highly basic or acidic conditions, which are not compatible with Fmoc or acid-labile protecting groups. This highlights the need for orthogonal conditions that permit selective deprotection of esters to create SPPS-ready amino acids. Herein, mild orthogonal ester hydrolysis conditions are systematically explored using calcium(II) iodide as a protective agent for the Fmoc protecting group and optimized for a broad scope of amino esters. Our optimized reaction improved on the already known trimethyltin hydroxide, as it produced better yields with greener, inexpensive chemicals and a less extensive energy expenditure.

Effect of cannabis on glutamate signalling in the brain: A systematic review of human and animal evidence

Use of cannabis or delta-9-tetrahydrocannabinol (Δ9-THC), its main psychoactive ingredient, is associated with psychotic symptoms or disorder. However, the neurochemical mechanism that may underlie this psychotomimetic effect is poorly understood. Although dopaminergic dysfunction is generally recognized as the final common pathway in psychosis, evidence of the effects of Δ9-THC or cannabis use on dopaminergic measures in the brain is equivocal. In fact, it is thought that cannabis or Δ9-THC may not act on dopamine firing directly but indirectly by altering glutamate neurotransmission. Here we systematically review all studies examining acute and chronic effects of cannabis or Δ9-THC on glutamate signalling in both animals and man. Limited research carried out in humans tends to support the evidence that chronic cannabis use reduces levels of glutamate-derived metabolites in both cortical and subcortical brain areas. Research in animals tends to consistently suggest that Δ9-THC depresses glutamate synaptic transmission via CB1 receptor activation, affecting glutamate release, inhibiting receptors and transporters function, reducing enzyme activity, and disrupting glutamate synaptic plasticity after prolonged exposure.

Effects of in vivo treatment of rats with trimethyltin chloride on respiratory properties of rat liver mitochondria

Liver mitochondria isolated from rats treated in vivo with trimethyltin chloride show stimulation of respiration using glutamate/malate as substrate, and a transient inhibition on rates of respiration using palmitoyl-L-carnitine as substrate. This phenomenon was observed with both ADP- and FCCP-stimulated respiration. In contrast, rates of respiration by liver mitochondria isolated from rats treated in vivo with trimethyltin chloride, following prior treatment with clofibrate, were inhibited when glutamate/malate was respiratory substrates. With palmitoyl-L-carnitine no effect of trimethyltin chloride was observed. In vitro treatment of rat liver mitochondria, or of rat liver homogenates, led to the expected, powerful inhibition of respiration. The synthesis of ATP by liver mitochondria isolated from rats treated in vivo with trimethyltin chloride was not inhibited compared to mitochondria isolated from control rats. Similarly, ATP synthesis by mitochondria isolated from rats treated with clofibrate, before treatment with trimethyltin chloride, was not inhibited. We, therefore, conclude that the powerful inhibitory effects of trimethyltin found in vitro, is not expressed in vivo during the first 36 hr following administration. In vivo treatment of rats with trimethyltin chloride caused a marked increase in hepatic levels of taurine and glycine, while levels of glutathione and glutamine were diminished. This is consistent with an enhanced oxidative stress in the liver. Our findings lead to the conclusion that increased oxidative stress, rather than inhibition of the mitochondrial ATPase, is a likely major cause of the in vivo toxic effects due to trimethyltin chloride.

Quantitating silver-stained neurodegeneration: the neurotoxicity of trimethlytin (TMT) in aged rats

This report describes the development of a histoanalytical procedure to measure the degree of neurodegeneration produced by the organometal toxicant trimethyltin (TMT). Based on a previous, non-quantitated experiment we hypothesized that the same dose of TMT would produce greater damage in animals of increasing age. Male rats aged 6, 12, 18, or 24 months at the time of dosing were given either 4.5 mg/kg TMT or saline (i.p.). One month after dosing, rats were perfused and their brains removed and processed to selectively silver-impregnate degenerating cell bodies as well as axon terminals and dendrites. Neurodegeneration was most prominent in the hippocampi (especially CA1 stratum radiatum) of TMT-treated rats, but not in the controls. Computer-assisted counting of the silver grains marking damage indicated greater neurotoxicity from the same dose of TMT when given to the older animals. Thus the grain density in the 6-month-old TMT-treated rats was not significantly elevated from the 6-month-old controls (P>0.10). The 12-month-old TMT-treated rats had significantly increased grain densities compared to their controls (P<0.05), but still larger increases of grain counts were observed in the 18- and 24-month-old rats (both P-values<0.01). Our findings with TMT are similar to previous, but nonquantitative, reports that the neurotoxic effects of kainic acid and methionine sulfoximine were also greater in older rats. An increased sensitivity to neurotoxicants might help explain the apparently spontaneous degeneration of cortical neurons in aging and in the neurological diseases of old age. The method we report here for quantitation of silver grains marking neurodegeneration should be adaptable to a wide range of histologically-based neurotoxicology investigations.

Monoamine neurotransmitters and amino acids in the cerebrum and striatum of immature rats with kaolin-induced hydrocephalus

Hydrocephalus is characterized by enlargement of the cerebral ventricles. The behavioral disturbances are, in some cases, rapidly reversible by surgical treatment suggesting that there may be a functional impairment of neurons. Hydrocephalus was induced in 3-week old rats by kaolin injection into the cisterna magna. Parietal cerebrum and striatum content of monoamine neurotransmitters and amino acids were assayed by high performance liquid chromatography (HPLC), 1, 2, or 4 weeks after induction of hydrocephalus. The ventricles exhibited progressive enlargement which was partially reversed by surgical treatment. Cerebral water content was increased at all stages. Increased levels of cerebral aspartate and glutamate suggest that there is the potential for excitatory neurotoxicity. The increase in cerebral taurine correlated negatively with the increase in water content. Cerebral concentrations of norepinephrine and serotonin, and its metabolite 5-HIAA, were increased at 1 and 2 weeks suggesting an increase in their turnover during the early stages of ventricular dilatation. Dopamine and its metabolite DOPAC were transiently diminished in the striatum at 1 and 2 weeks, respectively, suggesting that axonal projections from the brainstem may be impaired. We conclude that the effect of hydrocephalus on amino acids and monoamines varies regionally. Due to increased water content, there may be dilution effects in whole tissue, therefore, it is important to make determinations on the basis of protein content.

Comparison of glutamine-enhanced glutamate release from slices and primary cultures of rat brain

Increased extracellular glutamate has been associated with a wide range of effects including production of neurotoxicity. Glutamine has previously been shown to cause increased release of glutamate from a variety of preparations. Extracellular central nervous system (CNS) glutamine levels are known to increase with neurotoxin exposures, hepatic failure, renal failure, head trauma or stroke. However, the action of glutamine to enhance the release of glutamate under nondepolarizing conditions has not been well studied. Since glutamine-mediated increases in extracellular glutamate are potentially of significance in cellular damage as a result of CNS insult, further examination of this phenomenon is important. Striatal and hippocampal slices or virtually neuron-free primary striatal glial cultures were employed in studies to further elucidate the mechanism(s) of glutamine-enhanced glutamate release. Elevated extracellular glutamine caused increased glutamate release in all three preparations. In hippocampal and striatal slices elevated glutamine caused an enhancement of N-methyl-D-aspartate (NMDA) receptor-mediated [3H]catecholamine release equivalent to that produced by high concentrations (up to 100 microM) of exogenous glutamate. In both striatal slices and primary cultures kynurenate increased glutamate release in the presence of 500 microM glutamine, while kainate either had no effect or decreased glutamate levels in the presence of glutamine. Since several presynaptic modulators of release did not affect the glutamate release produced by glutamine in slices, vesicular release of glutamate from nerve terminals was probably not involved in the effects of the exogenous glutamine. The similarities between striatal slices and primary striatal cultures indicate that enzymatic conversion of glutamine to glutamate within glia may be an important factor in the glutamine-mediated elevation of extracellular glutamate levels.

Endogenous excitatory amino acid release from brain slices and astrocyte cultures evoked by trimethyltin and other neurotoxic agents

Trimethyltin (TMT) is a toxic alkyltin compound that is known to produce neuronal necrosis in the CNS. The present study examined the effects of TMT on the release of excitatory amino acids (EAA) from cortical slices prepared from adult and aged (24 months old) rats. The calcium dependence of TMT-induced EAA efflux was evaluated and compared to other neurotoxic agents. The actions of TMT were also evaluated in an astrocyte culture model to assess glial contributions to TMT-induced EAA efflux. TMT (10-1000 microM) evoked a dose-related increase in GLU and ASP efflux during a 30 min incubation period and this efflux was sustained or slightly higher during a 15 min recovery period. TMT-stimulated GLU efflux was not altered in aged rats. TMT-induced GLU efflux was significantly reduced by removing extracellular calcium and including 10 microM EGTA in the incubation media. Calcium channel blockers (nifedipine, verapamil, flunarizine, amiloride, neomycin) and MK-801 did not significantly attenuate TMT-induced GLU efflux. Diltiazem (25 microM) produced modest but inconsistent reductions in TMT-induced GLU efflux from brain slices, and significantly inhibited the leakage of lactate dehydrogenase (LDH) from TMT-treated astrocyte cultures. TMT did not increase GLU efflux from glial cultures during a 30 min incubation period, but did significantly elevate GLU efflux during the 15 min recovery period. TMT evoked the release of EAA by both calcium dependent and independent mechanisms in brain slices. TMT at high concentrations also produced a delayed increase in glial GLU efflux. These studies suggest that excitotoxic mechanisms may contribute to TMT-induced neurotoxicity.

Effect of methyl bromide on regional brain glutathione, glutathione-S-transferases, monoamines, and amino acids in F344 rats

Both metabolic and neurotransmitter changes have been implicated in the pathogenesis of monohalomethane neurotoxicity in rodents. This study in male and female F344 rats examined the effects of methyl bromide (MeBr) on regional brain glutathione-S-transferase (GST) activities and concentrations of glutathione (GSH), monoamines, and amino acid. Inhalation exposure to 150 ppm MeBr (6 hr/day x 5 days) yielded no histologic evidence of brain lesions but resulted in a number of biochemical changes. GSH depletion and GST inhibition were detected in the frontal cortex, caudate nucleus, hippocampus (examined for GSH only), brain stem, and cerebellum from animals of both sexes. Differences between sexes were detected for GSH depletion. Simultaneous treatment of rats with the inhibitor of monohalomethane toxicity, BW 755C (3-amino-1-[m-(trifluoromethyl)phenyl]-2-pyrazoline; 10 mg/kg bw ip, 1 hr pre- and 1 hr postexposure) completely protected against GST inhibition in all brain regions of both sexes. Partial protection by BW 755C against GSH depletion was observed in the cerebral cortex and in the cerebellum only. In males, MeBr exposure had no effect on the regional concentrations of the monoamines dopamine and serotonin and the amino acids glutamate, glutamine, taurine, and gamma-aminobutyric acid. Regional increases of brain aspartate and glycine levels were observed after exposure of males to MeBr but BW 755C had no effect on these changes induced by MeBr. Thus, of all the parameters studied, only GST, and in some brain areas GSH, correlated with inhibition of toxicity. It is concluded that, in contrast to the monoamines and the amino acids, GST and GSH are sensitive and potentially relevant indicators of MeBr neurotoxicity which could explain sex and regional differences in response to the monohalomethanes.

Effect of trimethyltin on amino acid concentrations in different regions of the mouse brain

Trimethyltin (TMT) is a neurotoxic compound known to cause marked alterations in brain chemistry. We have previously demonstrated that a single oral dose of TMT produced a dose-dependent decrease in muscarinic cholinergic receptors in mouse brain and significantly elevated glutamine in several regions of the rat brain. This study was designed to determine if TMT produced dose- and time-related alterations in amino acid concentrations in the adult male C57BL/6N mouse brain and in peripheral organs and plasma. In the dose-response study, TMT was administered orally as a single dose of 0, 0.5, 1.0, 3.0 or 5.0 mg/kg and animals were sacrificed 24 hr after treatment. In the time-course study, mice were dosed with TMT at 3.0 mg/kg and sacrificed 4, 12, 24, 48 or 96 hr after dosing. Amino acid concentrations were quantified by HPLC/EC following precolumn derivatization with o-phthalaldehyde-tert-butylthiol. TMT produced dose-dependent increases in aspartate, glutamine and glycine in the caudate nucleus (CN), frontal cortex (FC) and hippocampus (HIP) at 3.0 and 5.0 mg/kg. TMT at 3.0 mg/kg produced significant increases of aspartate in FC and HIP after 48 hr. Glutamine concentrations were significantly increased at 24 and 48 hr in HIP and at 48 hr in CN. Glycine and GABA concentrations were significantly increased at 48 and 96 hr respectively in the HIP. Glutamine was increased in plasma at 4 and 12 hr and in liver at 24 hr. Hyperammonemia occurred in plasma after 8 hr and continued through 24 hr and was accompanied by an increase in serum urea nitrogen.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct evidence for central action of PCPGABA to stimulate gastric acid secretion by intracisternal injection

PCPGABA, injected into the cisterna magna, significantly stimulated gastric acid secretion in the perfused rat stomach preparation. This secretagogue action was dose-dependent (0.5-2 micrograms/rat). The peak response occurred within 60 min and lasted up to 100 min. The secretagogue action by PCPGABA was completely reduced by truncal vagotomy. Intracisternal injection of 5-aminovaleric acid, a GABAB-receptor antagonist, did not alter basal gastric acid output, and it also failed to antagonize the acid secretory response to intracisternal PCPGABA. These results demonstrate that intracisternal PCPGABA caused hypersecretion of acid through vagal dependent mechanisms partially independent of GABAB-receptors.

High-performance liquid chromatographic determination of selected amino acids in rat brain by precolumn derivatization with phenylisothiocyanate

We describe here a simple, sensitive, selective and reproducible assay method for quantitative determination of aspartate, glutamate, serine, glutamine, glycine and gamma-aminobutyric acid in rat brain using reversed-phase high-performance liquid chromatography. The method is based upon formation of phenylthiocarbamyl derivatives of the amino acids. Good resolution of the six amino acids and the internal standard norvaline is achieved within 40 min. Other amino acids which have been reported to be present in rat brain do not interfere with the analysis. Standard curves for each of the amino acids exhibited good linearity (r greater than 0.9993) over the range 0.5-20 nmol. The coefficient of variation for the intra-day and inter-day determinations ranged from 0.4% at the highest to 11% at the lowest concentration limit. Storage of whole brains at -0 degrees C for up to 8 weeks did not affect mean concentrations of the six amino acids.

Changes with aging in the levels of amino acids in rat CNS structural elements. II. Taurine and small neutral amino acids

Taurine (Tau) and the small neutral amino acids glycine (Gly), serine (Ser), threonine (Thr), and alanine (Ala) were measured in 53 brain areas of 3- and 29-month-old male Fisher 344 rats. The ratio of highest to lowest level was 34 for Tau, 9.1 for Thr, 7.6 for Gly and Ser, and 6.5 for Ala. The heterogeneity was found in numerous areas; for example, Tau levels were more than 90 nmol/mg protein in 6 areas, and less than 20 nmol/mg protein in 10 areas. Similar heterogeneity was found with the other amino acids. The relative distribution of the small neutral amino acids showed several similarities; Tau distribution was different. With age, four amino acids decreased in 10-18 areas, and increased in only 1-3, while Thr increased in more areas than it decreased. The five amino acids of this paper, and the four of the previous paper, are among the amino acids at highest level in the brain; the sequence in their levels shows considerable regional heterogeneity.