Loss of RAB-3/A in Caenorhabditis elegans and the mouse affects behavioral response to ethanol.

The mechanisms by which ethanol induces changes in behavior are not well understood. Here, we show that Caenorhabditis elegans loss-of-function mutations in the synaptic vesicle-associated RAB-3 protein and its guanosine triphosphate exchange factor AEX-3 confer resistance to the acute locomotor effects of ethanol. Similarly, mice lacking one or both copies of Rab3A are resistant to the ataxic and sedative effects of ethanol, and Rab3A haploinsufficiency increases voluntary ethanol consumption. These data suggest a conserved role of RAB-3-/RAB3A-regulated neurotransmitter release in ethanol-related behaviors.

Mu opiates inhibit long-term potentiation induction in the spinal cord slice.

Long-term potentiation (LTP) involves a prolonged increase in neuronal excitability following repeated afferent input. This phenomenon has been extensively studied in the hippocampus as a model of learning and memory. Similar long-term increases in neuronal responses have been reported in the dorsal horn of the spinal cord following intense primary afferent stimulation. In these studies, we utilized the spinal cord slice preparation to examine effects of the potently antinociceptive mu opioids in modulating primary afferent/dorsal horn neurotransmission as well as LTP of such transmission. Transverse slices were made from the lumbar spinal cord of 10- to 17-day-old rats, placed in a recording chamber, and perfused with artificial cerebrospinal fluid also containing bicuculline (10 microM) and strychnine (1 microM). Primary afferent activation was achieved in the spinal slice by electrical stimulation of the dorsal root (DR) or the tract of Lissauer (LT) which is known to contain a high percentage of small diameter fibers likely to transmit nociception. Consistent with this anatomy, response latencies of LT-evoked field potentials in the dorsal horn were considerably slower than the response latencies of DR-evoked potentials. Only LT-evoked field potentials were found to be reliably inhibited by the mu opioid receptor agonist [D-Ala(2), N-Me-Phe(4), Gly(5)] enkephalin-ol (DAMGO, 1 microM), although evoked potentials from both DR and LT were blocked by the AMPA/kainate glutamate receptor antagonist 6-cyano-7-nitroquinoxalene-2,3-dione. Moreover repeated stimulation of LT produced LTP of LT- but not DR-evoked potentials. In contrast, repeated stimulation of DR showed no reliable LTP. LTP of LT-evoked potentials depended on N-methyl-D-aspartate (NMDA) receptor activity, in that it was attenuated by the NMDA antagonist APV. Moreover, such LTP was inhibited by DAMGO interfering with LTP induction mechanisms. Finally, in whole cell voltage-clamp studies of Lamina I neurons, DAMGO inhibited excitatory postsynaptic current (EPSC) response amplitudes from LT stimulation-evoked excitatory amino acid release but not from glutamate puffed onto the cell and increased paired-pulse facilitation of EPSCs evoked by LT stimulation. These studies suggest that mu opioids exert their inhibitory effects presynaptically, likely through the inhibition of glutamate release from primary afferent terminals, and thereby inhibit the induction of LTP in the spinal dorsal horn.

Metabolism of [5-3H]kynurenine in the rat brain in vivo: evidence for the existence of a functional kynurenine pathway.

The incorporation of tritium-label into quinolinic acid (QUIN), kynurenic acid (KYNA), and other kynurenine (KYN) pathway metabolites was studied in normal and QUIN-lesioned rat striata after a focal injection of [5-3H]KYN in vivo. The time course of metabolite accumulation was examined 15 min to 4 h after injection of [5-3H]KYN, and the concentration dependence of KYN metabolism was studied in rats killed 2 h after injection of 1.5-1,500 microM [5-3H]KYN. Labeled QUIN, KYNA, 3-hydroxykynurenine (3-HK), 3-hydroxyanthranilic acid, and xanthurenic acid (XA) were recovered from the striatum in every experiment. Following injection of 15 microM [5-3H]KYN, a lesion-induced increase in KYN metabolism was noted. Thus, the proportional recoveries of [3H]KYNA (5.0 vs. 1.8%), [3H]3-HK (20.9 vs. 4.5%), [3H]XA (1.5 vs. 0.4%), and [3H]QUIN (3.6 vs. 0.6%) were markedly elevated in the lesioned striatum. Increases in KYN metabolism in lesioned tissue were evident at all time points and KYN concentrations used. Lesion-induced increases of the activities of kynurenine-3-hydroxylase (3.6-fold), kynureninase (7.6-fold), kynurenine aminotransferase (1.8-fold), and 3-hydroxyanthranilic acid oxygenase (4.2-fold) likely contributed to the enhanced flux through the pathway in the lesioned striatum. These data provide evidence for the existence of a functional KYN pathway in the normal rat brain and for a substantial increase in flux after neuronal ablation. This method should be of value for in vivo studies of cerebral KYN pathway function and dysfunction.

Differential expression of the astrocytic enzymes 3-hydroxyanthranilic acid oxygenase, kynurenine aminotransferase and glutamine synthetase in seizure-prone and non-epileptic mice.

Previous investigations in seizure-prone mice have suggested that an abnormally elevated production of the astrocyte-derived neuroexcitant, quinolinic acid (QUIN), plays a role in seizure susceptibility. In order to evaluate further the role of QUIN metabolism in genetic murine seizure models, the activities of its biosynthetic enzyme 3-hydroxyanthranilic acid oxygenase (3HAO), and of two other astrocytic enzymes, kynurenine aminotransferase (KAT) and glutamine synthetase (GS), were measured in the brains of seizure-prone EL and DBA/2 mice and two non-epileptic strains (BALB/c and Swiss-Webster). 3HAO activity was found to be markedly higher in both EL and DBA/2 mice than in the non-epileptic strains in all brain regions examined. The activity of 3HAO was not modified by the tossing procedure employed to promote seizures in EL mice. While some strain differences were noted in the activities of KAT and GS, these enzymes did not distinguish seizure-prone from the non-epileptic mice. In order to delineate better the relationship between glial activation and 3HAO, KAT and GS, further studies were performed in the ibotenate-lesioned hippocampus. In mice (but not in rats), the activity of 3HAO was selectively increased in gliotic tissue. These data demonstrate substantial species and strain differences in astroglial enzymes and in their response to brain injury. The observation of widespread abnormally high 3HAO activity in two distinct seizure-prone mouse strains strengthens the hypothesis that enhanced production of QUIN contributes to seizure susceptibility in mice.

Increased brain quinolinic acid production in mice infected with a hamster neurotropic measles virus.

In order to examine the status of quinolinic acid (QUIN) metabolism in a model of delayed excitotoxic neurodegeneration, the de novo production of QUIN from 3-hydroxyanthranilic acid was assessed in brain homogenates and brain slices of mice injected with hamster neurotropic measles virus. In the hippocampus, which presents exclusive nerve cell loss in this model, the activity of 3-hydroxyanthranilic acid oxygenase, an astrocytic enzyme responsible for the biosynthesis of QUIN, was increased 3.3-fold by 7 days after virus inoculation. Less dramatic increases were observed in the cerebral cortex and the striatum, while cerebellar enzyme activity was not different from control values. In the same brain homogenates, no changes occurred in the activities of kynurenine aminotransferase, the biosynthetic enzyme of the neuroprotectant kynurenic acid, and of the astrocytic marker glutamine synthetase. At 7 days postinoculation, hippocampal slices from virus-treated animals, when exposed to 3-hydroxyanthranilic acid, produced 18 times more QUIN than slices from control animals. Notably, a significant increase was also seen 3 days postinoculation, i.e., at a time when astrocytes had started to proliferate but prior to the onset of neurodegeneration (Eur. J. Neurosci. 3:66-71, 1991). These data suggest that astrocyte-derived QUIN may play a causative role in the occurrence of hippocampal nerve cell loss in measles virus-infected mice.

Uptake of 3-hydroxykynurenine measured in rat brain slices and in a neuronal cell line.

The uptake of 3-hydroxykynurenine (3HK), a tryptophan metabolite with reported convulsant and cytotoxic properties, has been investigated in a neuronally derived hybrid cell line and in tissue slices prepared from rat brain. In both systems, the observed uptake was temperature-dependent and inhibited in the presence of large neutral amino acids. The apparent Km and Vmax determined for 3HK uptake into N18-RE-105 cells were 1.65 mM and 25.5 nmol/(min x mg protein), respectively. The uptake of 3HK into rat brain slices could be resolved into two components on the basis of their requirements for sodium. Kinetic analyses performed using hippocampal slices revealed a Km of 1.1 mM and Vmax of 18.8 nmol/(h x mg protein) for the sodium-independent process and a Km of 4.8 mM and Vmax of 54.5 nmol/(h x mg protein) for the sodium-dependent process. While sodium-dependent uptake was abolished following treatment with metabolic inhibitors, sodium-independent uptake was only slightly impaired. Sodium-independent uptake was inhibited in the presence of the non-metabolizable amino acids, aminoisobutyric acid (AIB) and aminobicyclo(2,2,1)heptane-2-carboxylic acid (BCH), but not by N-methylated amino acid substrates. Sodium-dependent uptake was insensitive to AIB and was completely abolished by BCH. These results indicate that an uptake process for 3HK is present in the mammalian brain, and suggest that the sodium-dependent component of 3HK transport may be mediated by a system which has not previously been described in CNS tissue.

The role of hydrogen peroxide in the in vitro cytotoxicity of 3-hydroxykynurenine.

Previous studies have indicated that the generation of H2O2 may be a key step in the mechanism mediating the in vitro cytotoxicity of 3-hydroxykynurenine (3HK). An exposure protocol resulting in a delayed toxicity was utilized in order to further examine the role of H2O2 in the in vitro toxicity of 3HK in a neural hybrid cell line. 3HK-induced cell lysis was significantly attenuated by administration of catalase after termination of 3HK exposure and was abolished when intracellular peroxidase activity was elevated by pretreatment of cultures with horseradish peroxidase. In addition, a dose-dependent attenuation of 3HK toxicity was observed when cultures were exposed to 3HK in the presence of the iron chelator, desferrioxamine (DFO). Pretreatment with DFO also resulted in a significant attenuation of 3HK toxicity. These data suggest a direct role for H2O2 and metal ions in the cytotoxic action of 3HK and indicate that cell lysis results from the intracellular accumulation of toxic levels of H2O2.

Cytotoxicity of 3-hydroxykynurenine in a neuronal hybrid cell line.

The toxicity of 3-hydroxykynurenine (3HK), an endogenous tryptophan metabolite which is markedly elevated in rat CNS tissue as a result of neonatal vitamin B-6 deficiency, was investigated in a neuronally derived hybrid cell line (N18-RE-105). At concentrations in excess of 100 microM, 3HK was toxic to greater than 85% of cultured cells over the course of 24 h. The time course of 3HK toxicity was studied in cultures exposed to 500 microM 3HK. Cell lysis proceeded linearly to completion in 8-12 h, but the toxic effects of exposure for 2 h were irreversible. 3HK was the most potently toxic among several related kynurenine metabolites tested. The toxic effects of 3HK exposure were markedly attenuated or abolished in the presence of either catalase or glutathione, indicating, a role of oxidative stress in 3HK toxicity.

Trimethyltin ototoxicity in albino rats.

The toxicity of alkyltin compounds is of exceptional interest due to the dissimilar toxic effects of some very closely related structural analogues among this class of compounds. Since several features of the toxicity of trimethyltin appeared to be consistent with a mechanism involving accumulation of the toxicant on melanin pigments, the ototoxicity induced by TMT exposure was examined in albino rats. Hearing thresholds for tones sampling the mid- and high-frequency range of the rat's audibility function were assessed by reflex inhibition audiometry. TMT produced a frequency dependent loss of auditory sensitivity that was most severe in the high frequency range. The TMT-induced impairment of auditory function was similar to that previously observed in pigmented Long-Evans rats. These results extend the observation of TMT-induced hearing loss to a non-pigmented rodent strain and suggest that the accumulation of TMT on cochlear melanin is not critical to the production of hearing impairment by TMT.

Disposition of the aromatic amine, benzidine, in the rat: characterization of mutagenic urinary and biliary metabolites.

The mutagenic and carcinogenic aromatic amine, benzidine (BZ), underwent extensive biotransformation in the rat. Three days after po (5.0 mg/kg) or iv (2.5 mg/kg administration of [14C]BZ, 90% of the radiolabel had been excreted in the urine (25%) and feces (65%); 7% was recovered in the animal. As the dose was increased from 0.5 to 50 mg/kg, the percentage of the dose excreted in urine increased twofold. In distribution studies, a major portion of the iv dose accumulated in the intestinal tract due to the excretion of 71% of the administered radiolabel in bile. The liver, which is a primary target organ of BZ carcinogenicity in rats, contained a higher concentration of radiolabel than other tissues studied. A minimum of 17 urinary and/or biliary metabolites were separated by HPLC. The major metabolites were N-acetyl-BZ(ABZ), N,N'-diacetyl-BZ(DABZ), BZ-N-glucuronide, ABZ-glucuronide, N-OH-DABZ glucuronide, 3-OH-DABZ glucuronide, and a glutathione conjugate of DABZ (3-GSH-DABZ). At low doses (0.5 to 5 mg/kg), 3-OH-DABZ glucuronide, 3-GSH-DABZ, and DABZ were the major urinary or biliary metabolites. However, at higher doses (50 mg/kg), N-OH-DABZ glucuronide, which was a minor metabolite at low doses, became a major urinary and biliary metabolite. Several urinary and biliary metabolites displayed significant mutagenicity in the Salmonella typhimurium (strain TA98)-liver S9-beta-glucuronidase assay. However, N-OH-DABZ glucuronide exhibited a mutagenic potency 10X greater than the other urinary metabolites. Results of these studies demonstrate that BZ is rapidly metabolized via N-acetylation, N-hydroxylation, and aromatic hydroxylation to a variety of mutagenic metabolites which are excreted in urine or bile primarily as glucuronide and/or glutathione conjugates. The most potent mutagen studied was also a major urinary and biliary metabolite.

Metabolism of the human carcinogen, benzidine, in the isolated perfused rat liver.

14C-Benzidine (BZ) was added to the recirculating perfusate of the isolated perfused rat liver. The system was monitored at timed intervals for the disappearance of BZ and the appearance of metabolites. BZ was extensively metabolized by this system and after 2 hr of perfusion greater than 95% of the administered radiolabel was in the form of metabolic products. In the perfusate the concentration of BZ declined rapidly whereas the concentration of N-acetyl-BZ (ABZ) increased temporarily and then declined. The concentration of N,N'-diacetyl-BZ (DABZ) increased with time and by 1 hr DABZ had become the major metabolite in the system. In the bile, which contained 22% of the dose after 2 hr, BZ-N-glucuronide and ABZ-glucuronide were the major metabolites initially, but after 1 hr of perfusion N-hydroxy-DABZ-glucuronide had become the major biliary metabolite. Addition of BZ and 35S-Na2SO4 to the perfusate resulted in at least one 35S-containing metabolite. Other major metabolites excreted in bile included 3-hydroxy-DABZ glucuronide, ABZ, and DABZ. DABZ underwent deacetylation to ABZ and N-hydroxy-DABZ underwent rapid reduction to DABZ when added to the isolated liver system. Qualitatively similar biliary metabolite patterns at later times were observed when either BZ, DABZ, or N-hydroxy-DABZ was added to the perfusate.