Inhibition of respiratory and bioenergetic mechanisms by hydrogen sulfide in mammalian brain.

The biochemical effects of hydrogen sulfide were investigated by treating enzyme homogenates and synaptosomes prepared from mammalian brain with sodium sulfide. Brain cytochrome c oxidase activity was highly sensitive to inhibition by sodium sulfide, as demonstrated by an IC50 of 0.13 microM. Sodium sulfide was also found to inhibit carbonic anhydrase activity in cerebellum, frontal cortex, and hippocampus. Synaptosomal oxygen consumption was significantly reduced as the concentration of sodium sulfide was increased from 20 to 100 microM; this was accompanied by a concentration-dependent depolarization of the synaptosomal mitochondrial membrane in situ and a reduction in synaptosomal ATP concentration. In other experiments using synaptosomes, sodium sulfide caused a significant calcium-independent increase in the extracellular accumulation of L-glutamate, inhibited Na+-dependent uptake of [3H]glutamate, but was unable to influence intrasynaptosomal free ionic Ca2+. Parallel studies conducted in vivo showed that rats exposed over a 5-d period to hydrogen sulfide (100 ppm for 3 h/d) had significantly higher concentrations of L-glutamate in the hippocampus compared to control animals. In summary, our results indicate that sulfide causes extensive disruption to respiratory and related mitochondrial functions in mammalian brain in vitro. The reduced capacity of nerve endings to take up L-glutamate may contribute to the raised L-glutamate levels observed in vivo.

Evidence that GABA, serotonin, and norepinephrine are involved in the modulation of in vitro rhythmical activity in rat hippocampal slices.

Cholinergic agonists induce a rhythmical slow activity (RSA) in the in vitro rat hippocampus. RSA consists of bursts of activity separated by quiescent periods (interburst intervals). The activity involves activation of muscarinic receptors; however, the role of other neurotransmitter substances is still controversial. The present study demonstrates that 500 microM GABA, 15 microM serotonin (5HT), or 20 microM norepinephrine (NE) can alter the pattern of carbachol-induced RSA. Application of GABA, 5HT, or NE increases interburst interval; 5HT and NE also increase burst length. Total power of RSA is decreased by GABA and 5HT but increased by NE. None of the three receptor agonists alters RSA frequency. The pattern of RSA is also dependent upon carbachol concentration: low concentrations (0.5 and 1 microM) produce only population spikes, whereas concentrations of 3 to 100 microM produce burst activity (50 microM is optimal for the generation of RSA). Burst length and peak frequency of RSA are enhanced with increasing concentrations of carbachol, whereas interburst interval is decreased. The results illustrate that the pattern of RSA is not only dependent upon carbachol concentration but can be modulated by GABA, 5HT, and NE. This suggests that more than one neurotransmitter system contributes to the production and modulation of RSA.

Effects of repeated exposures of hydrogen sulphide on rat hippocampal EEG.

Exposure to high levels of hydrogen sulphide (H2S) in humans has been associated with a number of respiratory and neurological symptoms. Acute toxicity following exposure to high concentrations is well-documented, however, there is little scientific information concerning the effects of exposure to low concentrations. The effects of low levels of H2S on electroencephalographic (EEG) activity in the hippocampus and neocortex were investigated on the freely moving rat (Sprague-Dawley). Hippocampal electrodes were implanted in the dentate gyrus (DG) and CA1 region. Activity was recorded for 10 min just prior to H2S exposure in the presence of air (pre-exposure). Rats were exposed to H2S (25, 50, 75, or 100 ppm) for 3 h/day; data was collected during the final 10 min of each exposure. The total power of hippocampal theta activity increased in a concentration-dependent manner in both DG and CA1; repeated exposures for 5 consecutive days resulted in a cumulative effect that required 2 weeks for complete recovery. The effects were found to be highly significant at all concentrations within subjects. Neocortical EEG and LIA (Large Amplitude Irregular Activity) were unaffected. The results demonstrate that repeated exposure to low levels of H2S can produce cumulative changes in hippocampal function and suggest selectivity of action of this toxicant.

Alteration of the morphology and neurochemistry of the developing mammalian nervous system by hydrogen sulphide.

1. Hydrogen sulphide (H2S) is a broad spectrum toxicant that occurs widely in nature and is also released by a variety of industrial activities and processes. 2. The central nervous system (CNS) appears to be the major target organ. 3. There is great potential for insult or injury to the developing or immature CNS. 4. The risk of chronic or repeated exposures to low concentrations have not been well defined. 5. Exposure to low concentrations of H2S to time-pregnant rats from day 5 postcoitus until day 21 postnatal results in architectural modification of cerebellar Purkinje cells, alteration of putative amino acid neurotransmitters and changes in monoamine levels in the developing rat brain up to day 21 postnatal. 6. H2S-induced alterations in monoamine tissue levels observed in the developing rat brain return to control values if exposure is discontinued during development, that is, at day 21 postnatal.

Low concentrations of hydrogen sulphide alter monoamine levels in the developing rat central nervous system.

The central nervous system is one of the primary target organs for hydrogen sulphide (H2S) toxicity; however, there are limited data on the neurotoxic effects of low-dose chronic exposure on the developing nervous system. Levels of serotonin and norepinephrine in the developing rat cerebellum and frontal cortex were determined following chronic exposure to 20 and 75 ppm H2S during perinatal development. Both monoamines were altered in rats exposed to 75 ppm H2S compared with controls; serotonin levels were significantly increased at days 14 and 21 postnatal in both brain regions, and norepinephrine levels were significantly increased at days 7, 14, and 21 postnatal in cerebellum and at day 21 in the frontal cortex. Exposure to 20 ppm H2S significantly increased the levels of serotonin in the frontal cortex at day 21, whereas levels of norepinephrine were significantly reduced in the frontal cortex at days 14 and 21, and at day 14 in the cerebellum.