Nobumasa Hayase

Carrier-mediated processes in blood-brain barrier penetration and neural uptake of paraquat

Due to the structural similarity to N-methyl-4-phenyl pyridinium (MPP(+)), paraquat might induce dopaminergic toxicity in the brain. However, its blood--brain barrier (BBB) penetration has not been well documented. We studied the manner of BBB penetration and neural cell uptake of paraquat using a brain microdialysis technique with HPLC/UV detection in rats. After subcutaneous administration, paraquat appeared dose-dependently in the dialysate. In contrast, MPP(+) could not penetrate the BBB in either control or paraquat pre-treated rats. These data indicated that the penetration of paraquat into the brain would be mediated by a specific carrier process, not resulting from the destruction of BBB function by paraquat itself or a paraquat radical. To examine whether paraquat was carried across the BBB by a certain amino acid transporter, L-valine or L-lysine was pre-administered as a co-substrate. The pre-treatment of L-valine, which is a high affinity substrate for the neutral amino acid transporter, markedly reduced the BBB penetration of paraquat. When paraquat was administered to the striatum through a microdialysis probe, a significant amount of paraquat was detected in the striatal cells after a sequential 180-min washout with Ringers solution. This uptake was significantly inhibited by a low Na(+) condition, but not by treatment with putrescine, a potent uptake inhibitor of paraquat into lung tissue. These findings indicated that paraquat is possibly taken up into the brain by the neutral amino acid transport system, then transported into striatal, possibly neuronal, cells in a Na(+)-dependent manner.

Nitration of manganese superoxide dismutase in cerebrospinal fluids is a marker for peroxynitrite-mediated oxidative stress in neurodegenerative diseases

Peroxynitrite can nitrate tyrosine residues of proteins. We examined nitrotyrosine‐containing proteins in cerebrospinal fluid of 66 patients with neurogenic disease by immunoblot analysis. Nitrated tyrosine residue–containing protein was observed in the cerebrospinal fluid and was concluded to be manganese superoxide dismutase (Mn‐SOD). The nitrated Mn‐SOD level was strikingly elevated in amyotrophic lateral sclerosis patients and was slightly increased in Alzheimers and Parkinsons disease patients, whereas an elevated Mn‐SOD level was observed only in progressive supranuclear palsy group. Ann Neurol 2000;47:524–527.

N-methylation ability for azaheterocyclic amines is higher in Parkinson's disease : nicotinamide loading test

Summary. The discovery of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) leads to the hypothesis that Parkinsons disease (PD) is may be initiated or precipitated by endogenous toxins by the mechanism similar to that of MPTP in genetically-predisposed individuals. The higher cerebrospinal fluid levels of N-methylated azaheterocyclic amines, such as β-carboline and tetrahydroisoquinoline, have been found in parkinsonian patients compared with age-matched controls. To estimate the N-methylation ability for azaheterocyclic amines in parkinsonian patient, nicotinamide was dosed with 100 mg to 26 parkinsonians and 20 controls consisted of 16 other neurogenic disease patients and 4 healthy volunteers. The urine was collected for 4 h, and then analyzed urinary its metabolites by an improved HPLC method. Nicotinamide has a pyridine ring in its structure and may be metabolized through the pathways similar to those for the endogenous neurotoxins. The urinary excretions of nicotinamide metabolites were significantly affected by aging. The excretion of N1-methylnicotinamide decreased along with aging both in PD patients and controls. In younger (65 years old or younger) PD patients, the excretion amount of N1-methylnicotinamide was significantly higher than that in younger controls. The decline rate of N1-methylnicotinamide excretion in parkinsonians was significantly greater than that in controls; the rate is more than 2-fold higher in parkinsonian patients. The age-associated de-crease in 1-methyl-2-pyridone-5-carboxyamide excretion was observed only in parkinsonian patients, but not in controls. The total excreted amount of N-methylated metabolites (N1-methylnicotinamide plus 1-methyl-2-pyridone-5-carboxyamide) was also observed the age-related decline in both groups. The urinary excretions of nicotinamide and nicotinamide-N-oxide were not influenced by aging. These results would indicate that the excess N-methylation ability for azaheterocyclic amines before the onset had been implicated in PD. On the other hand, the present results suggested that the contribution of aberrant cytochrome P450 or aldehyde oxidase activity acting on the pyridine ring, that could act as detoxification routes of endogenous neurotoxins, would be small in the etiology of PD.

l-Deprenyl prevents the cell hypoxia induced by dopaminergic neurotoxins, MPP+ and β-carbolinium: a microdialysis study in rats

N-Methyl-4-phenylpyridinium (MPP(+)) and 2,9-di-methyl-norharmanium (2,9-Me2NH(+)), which is a beta-carbolinium proposed as an endogenous MPP(+)-like toxin underlying Parkinsons disease, are strong mitochondrial toxins. We have measured the extracellular lactate levels as a marker for the in vivo cell hypoxia in the striatum of freely moving rats. The perfusions with MPP(+) and 2,9-Me2NH(+) increased extracellular lactate levels in a dose-dependent manner. These increases in lactate levels were significantly prevented by the co-perfusion with 10 microM L-deprenyl, a selective monoamine oxidase (MAO)-B inhibitor, but not by pargyline, a non-specific MAO inhibitor. The increase in extracellular lactate levels was considered to be the reflection of the cell damage resulted from the impairment of mitochondrial function. The present results suggested that L-deprenyl would rescue nerve cells from these toxins through the direct influence on the mitochondrial electron transport.

Structural significance of azaheterocyclic amines related to Parkinson's disease for dopamine transporter

We have evaluated the neuronal uptake of 12 neutral and quaternary azaheterocyclic amines that are possible candidates for idiopathic Parkinsons disease via dopamine transporter of striatal synaptosomes. The double-reciprocal plots for dopamine transporter obtained from Wistar rat and C57BL/6 mouse synaptosomes with N-methyl-4-phenylpyridinium cation (MPP+) as a substrate were identical to each other. Neutral beta-carbolines and tetrahydroisoquinolines were unfavorable substrates for dopamine transporter. The quarternization of these compounds strikingly increased the affinity for dopamine transporter with 2-10 times greater Km and 10 times smaller Vmax values than MPP+. Although catechol tetrahydroisoquinolines were weak substrates, their quarternization reduced their original properties as substrates for dopamine transporter. These results provide both topographic and electrogenic information of azaheterocyclic amines for the dopamine transporter-mediated influx. The intramolecular distance between the N-atom and the centroid of the benzene ring could be an important factor for the recognition of binding site of dopamine transporter, and an adequate net charge similar to dopamine would be further required for translocation into the cells.

Norharman, an indoleamine-derived β-carboline, but not Trp-P-2, a γ-carboline, induces apoptotic cell death in human neuroblastoma SH-SY5Y cells

Summary. Carbolines, azaheterocyclic amines derived from indoleamines, have various biological activities, such as neurotoxicity of β-carbolines and potent mutagenicity of γ-carbolines. In this study, structural significance among these carbolines was investigated in relation to the types of cell death, apoptosis and necrosis, using human neuroblastoma SH-SY5Y cells. DNA damage was quantitatively analyzed by a single-cell gel electrophoresis assay. DNA damage was induced by both β-carbolines, harman and norharman, and γ-carbolines, 3-amino-1,4-dimethyl-5H-pyrido[4,3-b]indole (Trp-P-1) and 3-amino-4-methyl-5H-pyrido[4,3-b]indole (Trp-P-2), in a dose dependent manner. γ-Carbolines were more potent to damage DNA than β-carbolines. Alkaline lysis of the cells prevented DNA damage induced by β-carboline, and pre-treatment of the cells with cycloheximide, an inhibitor of protein synthesis, reduced DNA damage caused by norharman. Morphological observation showed condensed and fragmented nuclei typical for apoptosis, in the cells treated with norharman. Thus, DNA damage induced by norharman was proved to be apoptotic. However, harman, which had a methyl substitution at the position 1, might induce necrosis in the cells. On the other hand, γ-carbolines, Trp-P-1 and Trp-P-2, directly damaged DNA. Thus, the nitrogen atom at the γ-position and/or an amino group in carboline structure would be required to induce the direct DNA cleavage.

Cefoselis, a β-lactam antibiotic, easily penetrates the blood-brain barrier and causes seizure independently by glutamate release

Summary.Cefoselis is a widely used β-lactam antibiotic, but occasionally induces seizures and convulsion in elder and renal failure patients. However, β-lactams are known not to pass through the blood-brain barrier (BBB). In this study, we examined the BBB penetration of cefoselis in normal and renal failure rats by means of brain microdialysis. Cefoselis was dose-dependently appeared in brain extracellular fluid in proportion to its blood level. The elimination constant from brain extracellular fluid (apparent) was slightly lower than that from blood. These results indicated that cefoselis might penetrate the BBB or be discharged by a certain transport system. In contrast to the result of cefoselis, cefazolin, a leading drug of cephalosporins, could not be detected in the brain extracellular fluid after an intravenous injection. In renal dysfunction rats, the elimination half-lives of cefoselis from both blood and brain were extensively prolonged. This would be one of responsible factors inducing seizures seen in patients. However, the additional factor, such as decrease in brain function related to aging, would be involved in seizures in patient received cefoselis, because an extremely high dose was required to induce seizures even in renal failure rats. A local administration of cefoselis into the hippocampus through the microdialysis probe caused a striking elevation of extracellular glutamate, with a minimum increase in γ-aminobutyric acid (GABA). However, a systematic cefoselis administration via the tail vein did not elevate extracellular glutamate and GABA concentrations in the hippocampus of renal failure rats that exhibited marked seizures. These results suggested that not the stimulation of glutamate release, but the blockade of GABA receptors might be responsible for the seizure induced by cefoselis.

Effects of tilisolol on ischemic myocardial metabolism in dogs

The effects of tilisolol on ischemic myocardial energy and carbohydrate metabolism were examined, and compared with those of propranolol. Ischemia was induced by ligating the left anterior descending coronary artery for 3 or 30 min in anesthetized open-chest dogs, 5 min after saline, tilisolol (0.2 mg.kg-1, i.v.), or propranolol (1 mg.kg-1, i.v.) injection. During ischemia, the myocardial energy stores were depleted, and the levels of glycolytic intermediates were altered, associated with ST segment elevation and TQ segment depression of the epicardial electrocardiogram. Tilisolol prevented the myocardial energy depletion and alterations of carbohydrate metabolism caused by 3 min of ischemia, to the same extent as did propranolol. Even 30 min after ischemia, the prevention of these ischemic changes was sustained by tilisolol, but not by propranolol. Tilisolol briefly reduced the ST segment elevation and TQ segment depression induced by ischemia. These results suggest that the protective effects of tilisolol on the ischemic myocardium are more potent and long-lasting than those of propranolol.

Glutamate is not involved in the MPP+-induced dopamine overflow in the striatum of freely moving C57BL/6 mice.

Summary. The role of glutamate in the N-methyl-4-phenyl-dihydropyridinium (MPP+) toxicity has been argued in the past decade. However, the effects of glutamate efflux and NMDA antagonist on MPP+-induced dopamine overflow have not been documented. To clarify this, we perfused MPP+ through a microdialysis probe in the striatum of freely moving mature C57BL/6 mice. The 60-min perfusion of 10 and 100 μM MPP+ strikingly increased dopamine levels to 28- and 93-fold of the basal values, respectively. In contrast, an administration of MPP+ did not induce marked glutamate release: the MPP+-perfusion slightly increased the glutamate level at 100 μM, but not at 10 μM. The addition of 100 μM (+)-MK-801 or 200 μM (±)-AP-7 to the perfusate did not attenuate MPP+-induced dopamine overflow. The extent of dopamine release only depended on the amount of MPP+ accumulation into the cells. These results indicated that, at least in the striatum, neither glutamate release nor the NMDA antagonist, including (+)-MK-801, could regulate MPP+-evoked dopamine overflow.

Protective Effects of Dilazep and its Derivative K-7259 on the Haemolysis Induced by Amphiphiles in Rat Erythrocytes

The effects of dilazep and K‐7259, a dilazep derivative, on the haemolysis (as evidenced by release of haemoglobin) induced by palmitoyl‐l‐carnitine (PAL‐CAR) or palmitoyl 1‐α‐lysophosphatidylcholine (PAL‐LPC) have been determined in rat erythrocytes.