Effect of prenatal treatment with methylazoxymethanol on carbachol-, norepinephrine- and glutamate-stimulated phosphoinositide metabolism in the neonatal, young, and adult offspring

Carbachol-, norepinephrine- and glutamate-stimulated phosphoinositide metabolism was investigated in the neonatal, young and adult cerebral cortex slices of rats prenatally treated with methylazoxymethanol (MAM) on gestational day 15 (GD15) or GD19. In rat offspring treated on GD15 there was a significant reduction in the accumulation of [3H]inositol phosphates induced by carbachol and a significant increase in the accumulation of [3H]inositol phosphates induced by norepinephrine on day 7, whereas no changes were observed at the other ages. No significant changes, on the other hand, were observed for glutamate-stimulated phosphoinositide metabolism in GD15 treated rats and for carbachol-, norepinephrine- and glutamate-stimulated phosphoinositide metabolism in animals treated on GD19 at any of the different ages evaluated. These results indicate that treatment with MAM on GD15, which results in a marked microencephaly, causes a marked alteration of muscarinic and alpha 1-adrenergic receptor-stimulated phosphoinositide metabolism during brain development and that these alterations undergo adaptive changes in the adult brain.

Evidence for separate mechanisms of cytotoxicity in mammalian cells treated with hydrogen peroxide in the absence or presence of L-histidine

Treating Chinese hamster ovary cells with 1 mM L-histidine markedly increases their susceptibility to killing by H2O2. The mechanism of this effect has not been firmly established, although previous studies have shown that L-histidine in combination with H2O2, in contrast to H2O2 alone, generates DNA double-strand breaks (DSBs), albeit following supralethal concentrations of the oxidant. Using the highly sensitive pulsed field gel electrophoresis technique, we examined the ability of H2O2-L-histidine combinations to induce DSBs in cells over the same oxidant concentration range that causes cytotoxicity. Thus the correlation between DSB induction and cell killing could be investigated directly without the necessity for extrapolating effects across different concentration ranges. We used a number of treatment protocols that allowed the compartmentation of L-histidine inside or outside the cells, or both. Increased cytotoxicity was invariably associated with the appearance of DSBs, and both parameters were dependent on the intracellular fraction of the amino acid. A linear relationship was found between cytotoxicity and DSB formation when the cells were either treated with H2O2 (at > or = 20 microM) and L-histidine concurrently or were exposed to the oxidant following pre-loading with L-histidine. On the other hand, no DSBs were detected in cells treated with: (a) H2O2 alone; (b) L-histidine plus H2O2 at < or = 20 microM; or (c) H2O2 in association with both L-histidine and excess (20 mM) L-glutamine (which prevents L-histidine uptake). Thus, separate mechanisms appear to underlie the cytotoxic response in cells treated with H2O2 in the absence and presence of L-histidine, with the latter process being associated with the induction of DSBs and having a threshold at approximately 20 microM H2O2. The linear correlation between DSBs and cell killing observed in cells treated with H2O2-L-histidine at H2O2 concentrations > or = 20 microM was similar to (but not superimposable on) the correlation curve established for gamma-irradiated cells; DSBs produced by gamma-rays were associated with more cell killing than those generated by the H2O2-L-histidine combination.

A novel action for adenosine: apoptosis of astroglial cells in rat brain primary cultures

2-chloro-adenosine induced apoptosis of astroglial cells in rat brain cultures, as shown by flow cytometry and morphological analysis. The adenosine analogue was far more potent than several previously characterized sugars (including 2-deoxy-D-ribose and D-ribose, the sugar moiety of 2-chloro-adenosine), which trigger apoptosis in a variety of cell-lines [8-10], suggesting that the effects of 2-chloro-adenosine are only partially dictated by its sugar moiety. Nevertheless, 2-chloro-adenosine and 2-deoxy-D-ribose attenuated each other's cell death when used in combination, suggesting the involvement of common intracellular mechanisms. It is suggested that 2-chloro-adenosine may induce apoptosis via a yet-to-be identified adenosine receptor, which may have intriguing implications for both nervous system development and brain response to trauma and ischemia.

Selective in vitro blockade of neuroepithelial cells proliferation by methylazoxymethanol, a molecule capable of inducing long lasting functional impairments

In order to characterize the antiproliferative effect of methylazoxymethanol neuroepithelial cells derived from the rat striata primordia at embryonic day 14 have been exposed to graded doses of this compound. It was found that methylazoxymethanol application to striatal neuroblasts elicits a blockade of cell proliferation at a dose which does not interfere with cell survival. By using synchronized cells and short term exposures to this compound, we found that the antiproliferative effect of methylazoxymethanol is strikingly correlated to the number of cells actively dividing in culture, thus indicating that the cells targeted by methylazoxymethanol must be in an active mitotic phase. To test for the selectivity of action of Methylazoxymethanol for dividing neuroblasts either cultures composed of mature proliferating astrocytes or muscle cells have been subjected to the same treatment. It has been observed that astrocytes proliferation was not affected by the dose of methylazoxymethanol shown to be effective on neuroepithelial cells. Finally we demonstrated that methylazoxymethanol is able only transiently to interfere with smooth muscle cell division, further supporting its selectivity of action within the developing CNS.

Expression of neuronal acetylcholine nicotinic receptor alpha 4 and beta 2 subunits during postnatal development of the rat brain

The expression of the alpha 4 and beta 2 subunits of neuronal nicotinic acetylcholine receptors (nAChRs) was studied in developing rat brain using in situ hybridization. The levels of both transcripts were already high at birth in cerebral cortex, medial habenula, CA1/CA3 regions of the hippocampus and several thalamic nuclei. In general, the beta 2 subunit showed a higher density of hybrids than the alpha 4. Beta 2 expression did not change with age in the medial habenula, medial geniculate nucleus or in the hippocampus whereas it decreased in the cortex. The developmental pattern of the hybridization signal for alpha 4 was different according to the brain area considered. The expression of the two transcripts showed a biphasic pattern in some thalamic nuclei: the lowest levels occurring during the first and second postnatal weeks respectively, and the highest levels during the second and fourth postnatal weeks. The ontogenetic profile of the expression of the alpha 4 subunit in the thalamic nuclei coincided with that of [3H]-L-nicotine binding sites. These findings suggest that the two subunits of nAChRs are independently regulated in most of the brain areas examined, and that in some regions, such as the thalamus, the ontogenetic variations reported for the alpha 4 subunit correlate with those observed for the [3H]-L-nicotine binding sites.

Changes in protein kinase C and its presynaptic substrate B-50/GAP-43 after intrauterine exposure to methylazoxy-methanol, a treatment inducing cortical and hippocampal damage and cognitive deficit in rats

The involvement of protein kinase C (PKC)-dependent processes in adaptive and plastic changes underlying neuronal plasticity was tested in an in vivo animal model characterized by targeted cellular ablation of cortical and hippocampal neurons, cognitive impairment and lack of induction of long-term potentiation. [3H]Phorbol ester binding performed on brain slices revealed a 67.4 and 35.0% increase in membrane-bound protein kinase C in the cortex and hippocampus respectively of rats treated with methylazoxy-methanol acetate compared with saline-treated control rats, and there was no modification in the expression of mRNAs of different protein kinase C isozymes. In situ phosphorylation experiments performed with 32Pi-labelled synaptosomes from the affected areas demonstrated that the phosphorylation of the nervous tissue-specific presynaptic membrane-associated protein kinase C substrate B-50/GAP-43 was increased by 51.4 and 44.8% in cortex and hippocampus respectively. Western blot analysis of protein kinase C in synaptosomal cytosol and membrane fractions prepared from cortex and hippocampus showed an increased proportion of protein kinase C in the membrane compartment in treated animals, but no change in the total synaptosomal protein kinase C activity. Our data are consistent with increased activity of presynaptic protein kinase C and predict a sustained increase in glutamate release in methylazoxy-methanol-treated rats.

Simultaneous determination of DNA double strand breaks and DNA fragment size in cultured mammalian cells exposed to hydrogen peroxide/histidine or etoposide with CHEF electrophoresis

A CHEF (contour clamped, homogenous electric field) assay allowing the measurement of chemically-generated DNA DSBs (double strand breaks), and the simultaneous estimation of the size of the resulting double stranded DNA fragments, in a single gel run, has been developed. This method combines a very high sensitivity for detecting DNA DSBs with a very good resolution over a broad range of megabase--sized DNA. This information can be obtained in a 68 h gel run, a time which is slightly elevated as compared to the CHEF DSB assay (approximately 20 h), but dramatically reduced as compared to other CHEF protocols utilized for resolving DNA fragments of 0.2-5.7 Mb (5-14 days). Treatment with 5-10 microM etoposide or 50-100 microM hydrogen peroxide/300 microM histidine produced DNA fragments with a mean size of 7.7 x 10(5) bp (from < or = -0.2 Mb) or 4.6 x 10(6) bp (from > or = 5.7-2.2 Mb), respectively.

The biphasic response of rat vesical smooth muscle to ATP

1. Adenosine-5'-triphosphate (ATP) is known to exert a variety of biological effects via the activation of either ionotropic P2x- or G-protein coupled P2Y-purinoceptor subtypes. In this study the effects induced by ATP and ATP analogues on rat bladder strips were characterized at resting tone and in carbachol-prestimulated tissues. 2. ATP exerted a clear concentration-dependent biphasic response, which was maximal at 1 mM concentration and was characterized by an immediate and transient contraction, followed by a slower sustained relaxation. The receptor mediating contraction was susceptible to desensitization by ATP and by the ATP analogue, alpha,beta-methyleneATP (alpha,beta-meATP) showing the typical features of the P2x-purinoceptor; conversely, ATP-evoked relaxation did not undergo tachyphylaxis following either ATP or alpha,beta-meATP. 3. The slower and sustained relaxant phase seemed to be due to activation of P2Y-purinoceptors, based on responses obtained with the P2Y agonist, 2-methyl-thioATP (2-meSATP) and, more importantly, based on the clear involvement of the G-proteins. In fact, the G-protein activator, guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) significantly potentiated and the G-protein blocking agent, guanosine 5'-O-(2-thio-diphosphate) (GDP beta S) completely abolished the ATP-induced relaxation. No effects were exerted by these two G-protein modulators on the ATP-induced contraction. 4. The relaxant component of the ATP response of bladder tissue was not significantly influenced by nitro-benzyl-thioinosine (NBTI) or by 8-phenyltheophylline (8-PT), suggesting that the contribution of the ATP metabolite adenosine to this response was negligible. Moreover, relaxation evoked by ATP and by the adenosine analogue, 5'-N-ethylcarboxamidoadenosine (NECA) was additive.5. Suramin was unable to modify either the relaxant or the contractile responses of bladder strips to ATP. However, when tested on the concentration-response curve to the slowly hydrolysable P2x-agonist alpha,beta-meATP, a rightward shift was detected, suggesting that ATP contractile responses are mediated by suramine-sensitive P2x-purinoceptors.6. Uridine-5'-triphosphate (UTP) only induced a rapid and concentration-dependent contraction of the rat bladder preparation, which was not desensitized by pre-exposure to alpha,beta-meATP, suggesting that UTP responses were not mediated by the 'classical' P2X-purinoceptor.7. It is therefore concluded that both P2x- and P2y-purinoceptors, which mediate ATP-induced contraction and relaxation, respectively, are present in rat bladder. Moreover, removal of epithelium did not affect ATP-elicited contraction, whereas ATP-induced relaxation was significantly augmented. These data suggest that P2x- and P2Y- purinoceptors are localized in smooth muscle cells and that the relaxant response is probably modulated by excitatory factor(s) released by epithelial cells.

Action of cystine in the cytotoxic response of Escherichia coli cells exposed to hydrogen peroxide

Cystine markedly enhanced the cytotoxic response of Escherichia coli cells to concentrations of hydrogen peroxide resulting in mode one killing, but displayed little effect in mode two killed cells. The effect of cystine was concentration-dependent over a range of 5-50 microM and did not further increase at higher levels. Cystine had similar effects in other bacterial systems. In order to sensitize the cells to the oxidative injury, the amino acid must be present during exposure to the oxidant since no enhancement of the cytotoxic response can be observed in cystine pre-loaded cells. In addition, no further enhancement of cytotoxicity could be detected when cystine was added before and left during challenge with the oxidant. The enhancing effect of cystine on oxidative injury of E. coli cells appears to be directly mediated by the amino acid and in fact cysteic acid, the most likely oxidation product, had no effect on the killing of bacterial cells elicited by hydrogen peroxide. Other disulfide compounds such as oxidized glutathione, cystamine and dithionitrobenzoic acid only slightly increased the susceptibility of bacteria to the oxidant. The effect of the disulfides was not concentration-dependent over a range of 200-800 microM and was statistically significant only for cystamine. Taken together, these results indicate that cystine markedly increases the cytotoxic response of bacteria to hydrogen peroxide and suggest that the amino acid might impair the cellular defence machinery against hydrogen peroxide. This effect may involve a thiol-disulfide exchange reaction at the cell membrane level.

The induction/loss of the oxidant-resistant phenotype of Chinese hamster ovary (CHO) cell variants does not correlate with sensitivity to DNA single strand breakage by hydrogen peroxide

Hydrogen peroxide resistant variants of Chinese hamster ovary (CHO) cells characterized by different levels of resistance to growth inhibition induced by the oxidant displayed a decreased susceptibility to the induction of DNA single strand breakage by hydrogen peroxide. Resistance to DNA damage, however, was maximal in cells resistant to killing by low concentrations of H2O, and did not increase further in cells characterized by a much higher resistance to the toxic action of the oxidant. Different sensitivities to the induction of DNA single strand breakage observed in wild type and resistant sublines were related to a decreased susceptibility/differential depletion of H2O2, rather than being dependent on different velocities in DNA repair processes. Growth of resistant cells in the absence of H2O2 resulted in a rapid loss of resistance to induction of DNA strand scission by H2O2. Cells retained resistance to the growth-inhibitory effect of the oxidant under conditions where resistance to the production of DNA single strand breaks was lost. Experiments aimed at elucidating the molecular basis for resistance to DNA damage induction by H2O2 have demonstrated that this effect is dependent upon the catalase activity of the specific sublines as well as on their different total protein content.

The L-histidine-mediated enhancement of hydrogen peroxide-induced cytotoxicity is a general response in cultured mammalian cell lines and is always associated with the formation of DNA double strand breaks

Micromolar concentrations of L-histidine increase the cytotoxicity of hydrogen peroxide in a number of cell lines including CHO (hamster), EAHY, McCoy's, U937 and CCRF-CEM (human), Vero (monkey) and SC-1 (mouse). Importantly, these cell lines displayed different degrees of sensitivity to H2O2 alone and the extent of enhancement elicited by the amino acid was more pronounced in resistant cell lines. The increased cytotoxicity was invariably associated with the formation of DNA DSBs and a remarkable correlation was found by plotting the level of DNA DSBs against the cytotoxic response. These results strongly support the hypothesis that the mechanism whereby L-histidine increases the toxicity elicited by H2O2 involves the formation of DNA DSBs and are consistent with the possibility that the amino acid might participate in the regulation of the physio-pathological response to oxidative stress in mammals.

Hydrogen peroxide cytotoxicity under conditions of normal or reduced catalase activity in H2O2-sensitive and -resistant Chinese hamster ovary (CHO) cell variants

H2O2-sensitive and -resistant sublines of Chinese Hamster Ovary (CHO) cells were tested for their sensitivity to the growth inhibitory effect elicited by increasing concentrations of the oxidant under conditions of normal or reduced catalase activity. Experimental results have demonstrated that, under conditions of reduced catalase activity, the cytotoxic action of H2O2 was differentially regulated in resistant and sensitive cells. Indeed, the parental cell line and cells resistant to low concentrations of H2O2 (V 250 cells) depended on catalase to a lower extent than did highly resistant cells (V 850 cells). It is interesting to note that V 250 cells had more catalase, on a per million cell basis, than V 850 cells. We conclude that acquired resistance to oxidative stress is not entirely dependent on catalase and that the contribution of catalase depends on the degree of resistance to the oxidant.

Localization and age-dependent expression of hexokinase mRNA in the rat brain

Localization of mRNA encoding for the enzyme hexokinase and its regulation in aged animals was carried out in rat brain using the in situ hybridization technique. The highest levels of the hybridization signal were observed in the olfactory bulb, piriform cortex, tenia tecta, hippocampus and granular cells of the cerebellum. Other brain areas and nuclei including cerebral cortex, thalamus, hypothalamus, substantia nigra, subiculum, choroid plexus and superior colliculus displayed moderate to low density of transcripts. Correlation between relative hexokinase content and levels of its mRNA was found only for some brain regions such as caudate-putamen, geniculate nucleus, ventral and lateral thalamic nuclei, superior colliculus and granular cells of the cerebellum. In the cerebral cortex and hippocampus of old animals the expression of hexokinase was significantly increased at 18 and 24 months of age. From the present data we conclude that although hexokinase is an ubiquitous enzyme, sites of synthesis display a discrete and uneven localization in rat CNS and expression, in the aging brain, might be regulated to compensate for reduced oxidative phosphorylation in the brain tissue.

Cross-resistance to heavy metals in hydrogen peroxide-resistant CHO cell variants

Hydrogen peroxide-resistant Chinese hamster ovary (CHO) cells displayed cross-resistance to CdCl2, HgCl2 and NaAsO2 but not to Na2Cr2O7, ZnCl2, NiCl2 and CuSO4. Resistance to hydrogen peroxide and to the metals was partially retained by these cells for many generations despite growth in drug-free medium. The loss of resistance was a slow process, and was different for the various metal compounds. Cell variants had a slightly higher content of non-protein intracellular thiols (NPSH) than sensitive cells. This biochemical feature did not seem to be the cause of resistance to CdCl2 but accounted for at least part of the resistance to HgCl2 and NaAsO2. Increased metallothionein synthesis did not seem to be responsible for the metal-resistant phenotype. These results suggest that resistance to specific metal compounds in cultured mammalian cells adapted to hydrogen peroxide is dependent on a number of factors which differ for the various metal compounds and which are characterized by a different stability.

Development and characterization of hydrogen peroxide-resistant Chinese hamster ovary (CHO) cell variants--II. Relationships between non-protein sulfhydryl levels and the induction/stability of the oxidant-resistant phenotype

Hydrogen peroxide sensitive and resistant sublines of Chinese hamster ovary (CHO) cells were tested for their non-protein sulfhydryl (NPSH) content in an attempt to establish whether a relationship exists between resistance to growth inhibition elicited by the oxidant and the NPSH pool. Cell variants characterized by increasing levels of resistance to hydrogen peroxide displayed a significant increase in cellular NPSH (expressed on a per million cell basis). Growth of resistant cells for various lengths of time in the absence of H2O2 decreased resistance, whereas the NPSH content did not vary (at least up to 127 days of growth in peroxide-free medium). The NPSH pool returned to control levels after an additional 82 days. These changes, however, were probably related to differences in cell size/amount of total cell proteins in the sublines. Indeed, when NPSH levels were expressed on a per milligram protein basis, essentially no variations were observed in sensitive and resistant sublines. It is important to note that, even by expressing the NPSH content on a per million cell basis, no correlation was found with the degree of resistance to growth inhibition elicited by the oxidant. Further experiments have demonstrated that, under conditions of reduced NPSH content (obtained by growing the cells in the presence of a glutamylcysteine synthetase inhibitor), the cytotoxic action of hydrogen peroxide was very slightly, if at all, augmented in both wild type and resistant cells. We may therefore conclude that cellular NPSH do not afford significant protection against growth inhibition induced by hydrogen peroxide in wild type cells, and that the same lack of effect occurs in cells with an increased NPSH content and carrying the oxidant-resistant phenotype.

Developmental neurotoxicity of ethanol: further evidence for an involvement of muscarinic receptor-stimulated phosphoinositide hydrolysis

Various lines of evidence suggest that muscarinic receptor-stimulated phosphoinositide hydrolysis during postnatal development in the rat brain may play a relevant role in glial cell proliferation and neuronal differentiation. We have previously shown that administration of ethanol to developing rats during the brain growth spurt causes microencephaly and selectively decreases muscarinic receptor-stimulated phosphoinositide hydrolysis. In the present study we have investigated the sensitivity of the phosphoinositide system coupled to muscarinic receptors to ethanol inhibition during distinct stages of the brain growth spurt. Different groups of rats were treated for 3 days with ethanol (4 g/kg per day) on postnatal days 2-4 (initial), 6-8 or 10-12 (peak), 13-15 (final stage of the brain growth spurt). The results show that the period of maximal sensitivity to ethanol of muscarinic receptor-stimulated phosphoinositide hydrolysis coincides with the peak of the brain growth spurt and with the period of maximal efficacy of muscarinic receptor agonists to induce inositol phosphates accumulation. Interestingly, only when muscarinic receptor-stimulated phosphoinositide hydrolysis was inhibited, a significant reduction of brain weight was observed. The close parallel between inhibition of this second messenger response and reduction of brain weight suggests that the phosphoinositide system coupled to muscarinic receptors may represent a target for the neurotoxic effects of ethanol during this stage of brain development.

L-histidine-mediated enhancement of hydrogen peroxide-induced cytotoxicity: relationships between DNA single/double strand breakage and cell killing

Results presented in this study demonstrate an association between the L-Histidine-mediated enhancement of H2O2-induced cytotoxicity and the formation of DNA double strand breakage (DSB), whereas no relationship exists between the increased cytotoxic response and DNA single strand breakage (SSB). Indeed, the higher lethality and the production of DNA DSB occurred in oxidatively-injured cells regardless of whether the exposure to L-Histidine was performed before or during challenge with the oxidant. In fact, the increased level of DNA SSB detected in cells simultaneously exposed to the oxidant and the amino acid was not observed in cells pre-treated with L-Histidine and then challenged with hydrogen peroxide. Further experiments have demonstrated an association between the kinetics of DNA DSB formation and the enhancement of the cytotoxic response. In conclusion, intracellular L-Histidine seems to mediate the formation of DNA DSB and the increased growth-inhibitory response elicited by the oxidant. In addition, these results suggest that the enhancement of DNA SSB is produced by the extracellular/plasma membrane fraction of the amino acid and not causally related to the L-Histidine-mediated increase of the growth-inhibitory response to H2O2-treated cells.