Early methyl donor deficiency may induce persistent brain defects by reducing Stat3 signaling targeted by miR-124.

The methyl donors folate (vitamin B9) and vitamin B12 are centrepieces of the one-carbon metabolism that has a key role in transmethylation reactions, and thus in epigenetic and epigenomic regulations. Low dietary intakes of folate and vitamin B12 are frequent, especially in pregnant women and in the elderly, and deficiency constitutes a risk factor for various diseases, including neurological and developmental disorders. In this respect, both vitamins are essential for normal brain development, and have a role in neuroplasticity and in the maintenance of neuronal integrity. The consequences of a methyl donor deficiency (MDD) were studied both in vivo in rats exposed in utero, and in vitro in hippocampal progenitors (H19-7 cell line). Deficiency was associated with growth retardation at embryonic day 20 (E20) and postnatally with long-term brain defects in selective areas. mRNA and protein levels of the transcription factor Stat3 were found to be decreased in the brains of deprived fetuses and in differentiating progenitors (62 and 48% for total Stat3 protein, respectively), along with a strong reduction in its phosphorylation at both Tyr7°5 and Ser7²7 residues. Vitamin shortage also affected upstream kinases of Stat3 signaling pathway (phospho-Erk1/2, phospho-Src, phospho-JNK, and phospho-p38) as well as downstream target gene products (Bcl-2 and Bcl-xL), thus promoting apoptosis. Conversely, the expression of the Stat3 regulator miR-124 was upregulated in deficiency conditions (≥65%), and its silencing by using siRNA partly restored Stat3 signaling in hippocampal neurons by increasing specifically the phosphorylation of Erk1/2 and Src kinases. Furthermore, miR-124 siRNA improved the phenotype of deprived cells, with enhanced neurite outgrowth. Taken together, our data suggest that downregulation of Stat3 signaling by miR-124 would be a key factor in the deleterious effects of MDD on brain development.

Impact of folate and homocysteine metabolism on human reproductive health.

Folates belong to the vitamin B group and are involved in a large number of biochemical processes, particularly in the metabolism of homocysteine. Dietary or genetically determined folate deficiency leads to mild hyperhomocysteinemia, which has been associated with various pathologies. Molecular mechanisms of homocysteine-induced cellular dysfunction include increased inflammatory cytokine expression, altered nitric oxide bioavailability, induction of oxidative stress, activation of apoptosis and defective methylation. Whereas the involvement of folate metabolism and homocysteine in ageing-related diseases, in several developmental abnormalities and in pregnancy complications has given rise to a large amount of scientific work, the role of these biochemical factors in the earlier stages of mammalian reproduction and the possible preventive effects of folate supplementation on fertility have, until recently, been much less investigated. In the present article, the possible roles of folates and homocysteine in male and female subfertility and related diseases are systematically reviewed, with regard to the epidemiological, pathological, pharmacological and experimental data of the literature from the last 25 years.

Mild, non-lesioning transient hypoxia in the newborn rat induces delayed brain neurogenesis associated with improved memory scores.

Although neonatal hypoxia can lead to brain damage, mild hypoxic episodes may be beneficial, as illustrated by tolerance induction by preconditioning, a process that might involve neurogenesis. To examine if brief hypoxia in newborn rats could stimulate the generation of neurons, pups were exposed for 5 min to 100% N2. Cell density and apoptosis were monitored in various brain regions and cell proliferation was studied by the incorporation of bromodeoxyuridine. Hypoxia did not result in detectable cell death but promoted cell proliferation in the ensuing three weeks in the subventricular zone and hippocampal dentate gyrus, with increased cell density in hippocampus CA1 pyramidal cells and granular layer of the dentate gyrus. Newly generated cells expressed neuronal markers (NeuroD or neuronal nuclear antigen) and were able to migrate from germinative zones to specific sites, in particular from the subventricular zone to the CA1 layer along the posterior periventricle. Neurogenesis was associated with an early activation of the extracellular regulated kinase 1/2 pathway, and pre-hypoxic administration of U0126, an inhibitor of mitogen-activated protein kinase kinase, impaired hypoxia effect on cell proliferation. Neurobehavioral capacities of hypoxic rats paralleled those of controls, but early exposure to hypoxia was associated with significantly improved memory retrieval scores at 40 days. In conclusion, brief neonatal hypoxia may trigger delayed generation of potentially functional neurons without concomitant cell death. This may constitute an interesting model for studying cell key events involved in the induction of neurogenesis.

Sequential expression patterns of apoptosis- and cell cycle-related proteins in neuronal response to severe or mild transient hypoxia.

Severe hypoxia was shown to induce apoptotic death in developing brain neurons, whereas mild hypoxia was demonstrated to stimulate neurogenesis. Since the apoptotic process may share common pathways with mitosis, expression profiles of proteins involved in apoptosis or the cell cycle were analyzed by immunohistochemistry and/or western blotting, in relation with cell outcome of cultured neurons from fetal rat forebrain subjected to either lethal (6 h) or non-lethal (3 h) hypoxia (95% N(2)/5% CO(2)). Hypoxia for 6 h led to apoptosis that was inhibited by the cell cycle blocker olomoucine. Transient overexpression of proliferating cell nuclear antigen was followed by increasing expression of p53, p21, Bax and caspases, whereas Bcl-2 and heat shock proteins were progressively repressed. Conversely, a 3-h hypoxic insult initiated neuronal mitosis, with increased thymidine incorporation. In these conditions, levels of proliferating cell nuclear antigen, Rb, Bcl-2 and heat shock proteins were persistently elevated, while expression of p53, p21, Bax and caspases gradually decreased. These data confirm that hypoxia promotes cell cycle activation, whatever the stress intensity. This process is then aborted following apoptosis-inducing hypoxia, whereas sublethal insult would trigger neurogenesis, at least in developing brain neurons in vitro, by stimulating timed expression of neurogenic and survival-associated proteins.

Intracellular generation of free radicals and modifications of detoxifying enzymes in cultured neurons from the developing rat forebrain in response to transient hypoxia.

To address the influence of oxidative stress and defense capacities in the effects of transient hypoxia in the immature brain, the time course of reactive oxygen species generation was monitored by flow cytometry using dihydrorhodamine 123 and 2',7'-dichlorofluorescein-diacetate in cultured neurons issued from the fetal rat forebrain and subjected to hypoxia/reoxygenation (6 h/96 h). Parallel transcriptional and activity changes of superoxide dismutases, glutathione peroxidase and catalase were analyzed, in line with cell outcome. The study confirmed hypoxia-induced delayed apoptotic death, and depicted increased mitochondrial and cytosolic productions of free radicals (+30%) occurring over the 48-h period after the restoration of oxygen supply, with sequential stimulations of superoxide dismutases. Whereas catalase mRNA levels and activity were augmented by cell reoxygenation, glutathione peroxidase activity was transiently repressed (-24%), along with reduced glutathione reductase activity (-27%) and intracellular glutathione depletion (-19%). Coupled with the neuroprotective effects of the glutathione precursor N-acetyl-cysteine (50 microM), these data suggest that hypoxia/reoxygenation-induced production of reactive oxygen species can overwhelm glutathione-dependent antioxidant capacity, and thus may contribute to the resulting neuronal apoptosis.

Bilirubin exerts additional toxic effects in hypoxic cultured neurons from the developing rat brain by the recruitment of glutamate neurotoxicity.

Both hypoxia and bilirubin are common risk factors in newborns, which may act synergistically to produce anatomical and functional disturbances of the CNS. Using primary cultures of neurons from the fetal rat brain, it was recently reported that neuronal apoptosis accounts for the deleterious consequences of these two insults. To investigate the influence of hypoxia, bilirubin, or their combination on the outcome of neuronal cells of the immature brain, and delineate cellular mechanisms involved, 6-d-old cultured neurons were submitted to either hypoxia (6 h), unconjugated bilirubin (0.5 microM), or to combined conditions. Within 96 h, cell viability was reduced by 22.7% and 24.5% by hypoxia and bilirubin, respectively, whereas combined treatments decreased vital score by 34%. Nuclear morphology revealed 13.4% of apoptotic cells after hypoxia, 16.2% after bilirubin, and 22.6% after both treatments. Bilirubin action was specifically blocked by the glutamate receptor antagonist MK-801, which was without effect on the consequences of hypoxia. Temporal changes in [(3)H]leucine incorporation rates as well as beneficial effects of cycloheximide reflected a programmed phenomenon dependent upon synthesis of selective proteins. The presence of bilirubin reduced hypoxia-induced alterations of cell energy metabolism, as reflected by 2-D-[(3)H]deoxyglucose incorporation, raising the question of free radical scavenging. Measurements of intracellular radical generation, however, failed to confirm the antioxidant role of bilirubin. Taken together, our data suggest that low levels of bilirubin may enhance hypoxia effects in immature neurons by facilitating glutamate-mediated apoptosis through the activation of N:-methyl-D-aspartate receptors.

[Combined neuronal toxicity of bilirubin and hypoxia. Study of cultured rat neurons]. / Toxicité neuronale combinée de la bilirubine et de l'hypoxie. Etude sur des neurones de rat en culture.

UNLABELLED: Clinical observations suggest that bilirubin encephalopathy is often seen in newborn infants presenting not only with hyperbilirubinemia but also with alterations in oxygen transport like in severe anaemia. Since bilirubin and hypoxia have been shown to be detrimental to the central nervous system, the present study was designed to test the additional effects of the two insults on the outcome of cultured neurons from the forebrain of 14 day-old embryos. After 6 days in vitro, neurons were exposed either to bilirubin (0.5 microM) or to bilirubin and hypoxia for 6 hours. Thereafter, cells were reoxygenated for 96 hours in standard conditions. Control cells were kept in normoxia. Cell viability was assessed by the methyltetrazolium method. Cell death (apoptosis or necrosis) was characterized by fluorescent nuclear staining with DAPI. Rates of protein synthesis and energy metabolism in neurons were measured by [3H]leucine and [3H]2-deoxyglucose incorporation, respectively. Data are reported as percentages of change as compared to controls. Each experiment involved 5 to 10 dishes per time point and was repeated 2 to 4 times. RESULTS: Bilirubin reduced cell viability by 24.5% vs controls (p < 0.001) at 96 h while 16% of the neurons exhibited morphological features of apoptosis (p < 0.001). The combination of hypoxia with bilirubin induced a 34% decrease in cell viability (p < 0.001) and the percentage of apoptotic cells was higher than after the exposure to hypoxia or to bilirubin alone. The rate of protein synthesis increased significantly in all experimental conditions as early as 1 h after the onset of the insult and at 48 h post reoxygenation. It increased again at 72 h in the cells exposed to bilirubin or to bilirubin and hypoxia. These sequential changes in synthesis of specific proteins seem to be involved in delayed neuronal death. Bilirubin decreased significantly [3H]2-deoxyglucose incorporation at 24 h while it increased when the neurons were exposed to both bilirubin and hypoxia (+60%, p < 0.001) and decreased thereafter. These data confirm the deleterious effects of bilirubin on neuronal viability, on protein synthesis and metabolic rates. The combination of bilirubin with hypoxia resulted in stronger detrimental effects on neurons than bilirubin alone.

Free radical production and changes in superoxide dismutases associated with hypoxia/reoxygenation-induced apoptosis of embryonic rat forebrain neurons in culture.

Following hypoxia/reoxygenation (6h/96h), cultured neurons from the embryonic rat forebrain undergo delayed apoptosis. To evaluate the participation of oxidative stress and defense mechanisms, temporal evolution of intraneuronal free radical generation was monitored by flow cytometry using dihydrorhodamine 123, in parallel with the study of transcriptional, translational, and activity changes of the detoxifying enzymes Cu/Zn-SOD and Mn-SOD. Two distinct peaks of radical generation were depicted, at the time of reoxygenation (+ 27%) and 48 h later (+ 25%), respectively. Radical production was unaffected by caspase inhibitors YVAD-CHO or DEVD-CHO, which prevented neuronal damage, suggesting that caspase activation is not an upstream initiator of radicals in this model. Cell treatment by vitamin E (100 microM) displayed significant neuroprotection, whereas the superoxide generating system xanthine/xanthine oxidase induced apoptosis. Transcript and protein levels of both SODs were reduced 1 h after the onset of hypoxia, but activities were transiently stimulated. Reoxygenation was associated with an increased expression (139%), but a decreased activity (21%) of the inducible Mn-SOD, whereas Cu/Zn-SOD protein and activity were low and progressively increased until 48 h post-hypoxia, when the second rise in radicals occurred. In spite of a temporal regulation of SODs, which parallels radical formation, oxidative stress might account for neurotoxicity induced by hypoxia.

Bilirubin induces apoptosis via activation of NMDA receptors in developing rat brain neurons.

Increased amounts of bilirubin, the end product of heme degradation, are known to be detrimental to the central nervous system, especially in preterm newborns. In an attempt to delineate the cellular mechanisms by which unconjugated bilirubin exerts its toxic effects on neuronal cells in the developing brain, bilirubin (0.25-5 microM) was added to the extracellular medium of 6-day-old primary cultured neurons from the embryonic rat forebrain, and cell alterations were studied over the ensuing 96 h. Bilirubin decreased cell viability dose dependently with an ED(50) around 1 microM. At the dose of 0.5 microM, it triggered delayed cell death that affected 24% of the neurons. Nuclear incorporation of the fluorescent dye DAPI (4,6-diamidino-2-phenylindole) depicted the presence of apoptosis (16%). Apoptosis features were confirmed by DNA fragmentation reflected by a progressive loss of [(3)H]thymidine and sequential changes in macromolecular synthesis, as shown by the time course of [(3)H]leucine incorporation, as well as by the beneficial effects of cycloheximide and caspase inhibitors. In parallel, treatments with glutamate receptor antagonists showed that MK-801, but not NBQX, protected neurons against bilirubin neurotoxicity, suggesting a role for NMDA receptors in bilirubin effects. Coupled with previous work about glutamate toxicity in the same culture model, these data support the hypothesis that low levels of free bilirubin may promote programmed neuronal death corresponding to an apoptotic process which involves caspase activation and requires the participation of NMDA receptors, along with bilirubin-induced inhibition of protein kinase C activity.

Xenobiotic-mediated production of superoxide by primary cultures of rat cerebral endothelial cells, astrocytes, and neurones.

Previous works of our group demonstrated that xenobiotic metabolism by brain microsomes or cultured cerebral cells may promote the formation of reactive oxygen species. In order to characterise the risk of oxidative stress to both the central nervous system and the blood-brain barrier, we measured in the present work the release of superoxide in the culture medium of rat cerebrovascular endothelial cells during the metabolism of menadione, anthraquinone, diquat or nitrofurazone. Assays were run in the same experimental conditions on primary cultures of rat neurones and astrocytes. Quinone metabolism efficiently produced superoxide, but the production of radicals during the metabolism of diquat or nitrofurazone was very low, as a probable result of their reduced transport inside the cells. In all cell types assayed, superoxide production was time- and concentration-dependent, and cultured astrocytes always produced the highest amounts of radicals. Superoxide formation by microsomes prepared from the cultured cells was decreased by immunoinhibition of NADPH-cytochrome P450 reductase or by its irreversible inhibition by diphenyliodonium chloride, suggesting the involvement of this flavoprotein in radical production. Cerebrovascular endothelial cells cultured on collagen-coated filters produced equivalent amounts of superoxide both at their luminal side and through the artificial basement membrane, suggesting that in vivo, endothelial superoxide production may endanger adjacent astrocytes and neurones.

Effects of hypothermia on hypoxia-induced apoptosis in cultured neurons from developing rat forebrain: comparison with preconditioning.

In neuronal cultures from the forebrain of 14-d-old rat embryos, transient hypoxia (95% N2/5% CO2, 37 degrees C) for 6 h has been shown to trigger delayed apoptotic death through sequential changes in protein synthesis, whereas preconditioning by a brief episode of hypoxia can rescue neurons. Because hypothermia has been reported to be neuroprotective, the present study was designed to test the influence of reduced temperature on the consequences of lethal hypoxia in our culture model, and cellular mechanisms involved were compared with those underlying preconditioning effects. After 6 d in vitro, cultures were subjected to hypoxia for 6 h. They were either placed at 32 degrees C concomitantly with hypoxia for 6 h or preconditioned the day before by a 1-h episode of hypoxia. The hypoxic insult decreased cell viability by 38% at 96 h after reoxygenation, and 23% of the neurons showed morphologic features of apoptosis. Both hypothermia and preconditioning prevented neuronal death and reduced apoptosis. Preconditioning led to time-dependent changes in leucine incorporation, with persistent overexpression of the survival proteins Bcl-2 and heat-shock protein 70. It also increased thymidine incorporation, in line with induction of the cofactor for DNA polymerase, proliferating cell nuclear antigen. Hypothermia reduced basal apoptosis and necrosis, but did not affect thymidine incorporation, and abolished hypoxia-associated protein synthesis. Therefore, both treatments were protective against neuronal injury consecutive to hypoxia in developing brain neurons in vitro. Whereas preconditioning activated a program that stimulated the expression of anti-apoptotic gene products and regulatory components of the cell cycle, hypothermia did not trigger active processes, but depressed cell activity, which in turn may impair the apoptotic phenomenon.

Involvement of caspase-1 proteases in hypoxic brain injury. effects of their inhibitors in developing neurons.

To further explore the contribution of caspase-1/interleukin-1beta-convening enzyme in the consequences of hypoxia in developing brain neurons, its temporal expression profile was analysed by immunohistochemistry and western blotting in cultured neurons from the embryonic rat forebrain subjected to a hypoxic stress (95% N2/5% CO2 for 6 h), and proteolytic activity of caspase-1 was monitored as a function of time by measuring the degradation of a selective colorimetric substrate (N-acetyl-Tyr-Val-Ala-Asp-p-nitroanilide). In addition, the influence of pre- and posthypoxic treatments by caspase-1 inhibitors (N-acetyl-Tyr-Val-Ala-Asp-aldehyde and N-acetyl-Tyr-Val-Ala-Asp-chloromethylketone) was tested on cell outcome. Hypoxia led to delayed apoptotic neuronal death, with an elevation of the expression of both pro-caspase-1 and caspase-1 active cleavage product (ICE p20) for up to 96 h after cell reoxygenation. As reflected by cleavage of the specific substrate, caspase-1 activity progressively increased between 24 h and 96 h posthypoxia, and was blocked by inhibitors in a dose-dependent fashion. The inhibitory compounds, including when given 24 h after hypoxia, prevented neuronal death, reduced apoptosis hallmarks and also increased the number of mitotic neurons, suggesting they might promote neurogenesis. Similar observations were made when neurons were exposed to a sublethal hypoxia (i.e. 3 h). These data emphasize the participation of caspase-1 in neuronal injury consecutive to oxygen deprivation, and provide new insight into the possible cellular mechanisms by which caspase inhibitors may protect developing brain neurons.

CPP32/CASPASE-3-like proteases in hypoxia-induced apoptosis in developing brain neurons.

Since caspase members have been identified as effectors of apoptosis, the role of CPP32/caspase-3 was further explored in cultured neurons from the embryonic rat forebrain submitted to a 6-h hypoxia which has previously been shown to induce apoptotic death within four days after reoxygenation, whereas a shorter aggression (i.e., for 3 h) leads by the same time to an increased number of living neurons, suggesting that sublethal hypoxia may promote neurogenesis. Neuronal expression of the active cleavage product of CPP32 (CPP32 p20) increased specifically after hypoxia for 6 h to finally reach 985% over control normoxic values at 96 h post-insult, while a 3-h hypoxia triggered the inducible stress protein HSP70 that has been shown to inhibit caspase-3. Proteolytic activity of caspase-3 was progressively stimulated by lethal hypoxia, as reflected by the degradation of two selective substrates, including poly (ADP-ribose) polymerase (PARP). Caspase-3 activity was blocked specifically and dose-dependently by the peptide inhibitor, DEVD-CHO, that reduced the number of apoptotic cells and prevented the hypoxia-induced decrease in cell viability, including when given 24 h post-insult. Interestingly, in these conditions, the inhibitory compounds enhanced the number of mitotic neurons. These data emphasize the critical role of caspase-3 in neuronal injury consecutive to hypoxia. Whereas caspase inhibitors may provide benefit over a broad therapeutic window, they might allow developing neurons to complete their cell cycle initiated in response to stress, as it is the case for sublethal hypoxia.

Repeated seizure-associated long-lasting changes of N-methyl-D-aspartate receptor properties in the developing rat brain.

Glutamate NMDA receptor has been implicated in brain developmental processes as well as in excitotoxicity and seizure mediation. A previous study has shown that an acute episode of seizures for 30 min in rats altered NMDA receptor characteristics, mainly in the very immature animal. In order to assess whether receptor modifications may also account for long-lasting cerebral disabilities, medium- and long-term consequences of repeated seizures in developing rats on brain NMDA receptor properties were investigated. Seizures were induced once a day for 3 consecutive days, either from post-natal day 5 (P5) to P7 or from P15 to P17. NMDA receptors were then analysed at P15, P25 and P60 (adulthood) by measuring specific binding of [3H]MK-801 on brain membrane preparations. In addition, allosteric modulation of NMDA receptors by exogenous glutamate and glycine was investigated. Seizures from P5 to P7 led to a 22% increase in the density of [3H]MK-801 binding sites measured at P15, but did not affect NMDA receptor density or affinity at P25 or P60. P15-P17 seizures led to a 21% decrease in the density of binding sites and to a 33% decrease in receptor dissociation constant at P25, while they were without effect at P60. Moreover, P5-P7 and P15-P17 seizures were both associated with a suppression of the glutamate/glycine-induced receptor activation at P60. These modifications might account for long-term alterations in cerebral excitability or plasticity after early convulsive disorders, with regards to altered cognitive capacities, epileptogenesis and brain susceptibility to recurrent seizures.

Medium- and long-term alterations of brain A1 and A2A adenosine receptor characteristics following repeated seizures in developing rats.

In order to assess long-lasting consequences of recurrent seizures during development, the effects of repeated seizures in developing rats were investigated on brain adenosine A1 and A2A receptors. The characteristics of A1 and A2A receptors were analyzed by measuring the binding of the selective agonists [3H]CHA (N6-cyclohexyladenosine) and [3H]CGS 21680 (2-[p-(2-carboxyethyl)-phenethylamino]-5'-N-ethylcarboxamido adenosine), respectively, on cerebral membrane preparations, whereas receptor coupling to G-proteins was examined by using a GTP analogue (Gpp(NH)p; guanylyl-5'-imidodiphosphate). Seizures were induced by bicuculline once a day at two different developmental stages: either from postnatal day 5 to postnatal day 7 (P5-P7) or from P15 to P17. Adenosine receptors were then studied at P15, P25 and P60. P5-P7 seizures led to an increase in A1 receptor density at P60 and to a decrease in their coupling to G-proteins at P15, but they did not affect A2A receptors. P15-P17 seizures decreased the coupling of A1 receptors to G-proteins at P25 and P60, reduced the density of A2A receptors at P25 and increased their affinity at P60. These results depict a persistent sensitivity of both A1 and A2A brain adenosine receptors to repeated seizures, with selective receptor alterations according to the cerebral maturational stage when seizures occur. In respect to the neuromodulatory and anticonvulsant properties of adenosine, such changes might be implicated in long-term functional brain reorganization after early seizures and future susceptibility to convulsive disorders.

Transient hypoxia may lead to neuronal proliferation in the developing mammalian brain: from apoptosis to cell cycle completion.

Cerebral hypoxia/ischemia was shown to induce delayed, apoptotic neuronal death occurring through biochemical pathways potentially sharing common events with cell proliferation. This study was designed to test the hypothesis that a sublethal hypoxia may promote mitotic activity in developing central neurons. After six days in vitro, cultured neurons from the forebrain of 14-day-old rat embryos were exposed to hypoxia (95% N2/5% CO2) for 3 h and re-oxygenated for up to 96 h. Controls were kept in normoxia. As a function of time, cell viability was measured by diphenyltetrazolium bromide, and rates of DNA and protein synthesis were monitored using [3H]thymidine and [3H]leucine, respectively. Morphological features of apoptosis, necrosis and mitosis were scored under fluorescence microscopy after nuclear staining with 4,6-diamidino-2-phenylindole, and the expression profile of proliferating cell nuclear antigen, a cofactor for DNA polymerase, was analysed by immunohistochemistry. Data were compared to those obtained after transient hypoxia for 6 h followed by re-oxygenation for 96 h and which was shown to induce apoptosis. Whereas a 6-h insult reduced cell viability, with 23% of the neurons exhibiting apoptosis by the end of re-oxygenation, a 3-h hypoxia led to a cycloheximide-sensitive increase in the final number of living neurons compared to controls (13%, P < 0.01), with no signs of apoptosis, significantly increased thymidine incorporation into acid-precipitable fraction, and persistent over-expression of proliferating cell nuclear antigen. Accordingly, final score of mitotic nuclei was significantly enhanced. In addition, the cell cycle inhibitor olomoucine (50 microM) prevented apoptosis consecutive to a 6-h hypoxia, but impaired the stimulatory effects of a 3-h insult. These findings support the conclusion that some neurons exposed to sublethal hypoxia may dodge apoptotic death by fully achieving the cell cycle.

Sequential activation of activator protein-1-related transcription factors and JNK protein kinases may contribute to apoptotic death induced by transient hypoxia in developing brain neurons.

Previous studies have demonstrated that transient hypoxia (6 h) induces apoptotic death in cultured neurons isolated from the fetal rat forebrain. Since activation of c-Jun N-terminal kinases (JNKs) and subsequent phosphorylation of c-Jun are suspected to be involved in the apoptotic pathway in several cell types, the time course of activator protein-1 (AP-1) DNA-binding, in line with induction of the AP-1 components and JNK activation, was examined during hypoxia/reoxygenation in the same model. Gel shift analysis depicted the presence of functional AP-1 transcription factors in both control and hypoxic neurons. One hour after the onset of hypoxia, all AP-1 components were markedly overexpressed. They include c-Jun, Jun B, Jun D, c-Fos and Fos-related antigens. Whereas, only c-Jun remained elevated for up to 96 h post-reoxygenation, time at which neurons were injured, other gene products showed patterned induction/repression as hypoxia progressed and then during the post-reoxygenation period, with Fos-related antigens being finally induced at 96 h. Only JNK1 was constitutively detected in cultured neurons, and its expression was inhibited during hypoxia. Nonetheless, both JNK1 and JNK3 were markedly, but transiently, induced at 48 h post-reoxygenation, when apoptosis-related morphological features became apparent. These data support the hypothesis that transient hypoxia, independently of ischemia, may trigger apoptosis through JNK signaling pathway in developing brain neurons.

Identification of the uridine diphosphate glucuronosyltransferase isoform UGT1A6 in rat brain and in primary cultures of neurons and astrocytes.

The expression of a phenol uridine diphosphate glucuronosyltransferase (UGT) was investigated in rat brain homogenate and in primary cultures of astrocytes and neurons, by means of model substrates (1-naphthol and 4-methylumbelliferone) assays, Western blot analysis and reverse transcription-polymerase chain reaction (RT-PCR) experiments. Glucuronidation of these substances occurred in cerebral cell or brain homogenates, although to different extents. The specific activity was the highest in astrocytes, with values more than 10- and 100-fold those found in neurons or total brain, respectively. Using antibodies able to recognize several rat liver UGT isoforms, only one protein with an apparent molecular mass of 54 kDa was detected in astrocyte and neuron homogenates and brain microsomes. RT-PCR experiments run with primers specifically designed for the rat liver UGT1A6 revealed amplificons of the expected sizes in accordance with the presence of UGT1A6 mRNA. The nucleotide sequence of the 330-base pair product was 100% homologous to that of exon 1 of rat liver isoform UGT1A6. In conclusion, this work allowed us to identify for the first time a constitutive cerebral UGT isoform identical to rat liver UGT1A6, which glucuronidates planar phenolic substances in cultured astrocytes, neurons, and the entire brain.

Medium- and long-term effects of repeated bicuculline-induced seizures in developing rats on local cerebral energy metabolism.

To assess long-term metabolic consequences of recurrent ictal events arising during development, seizures were repeatedly generated in rats at different stages of cerebral maturation. Seizures were induced by i.p. injections of bicuculline for three consecutive days, starting from postnatal day 5 (P5), when the brain is very immature, or from P15, a period at which the brain is more structurally organized. Local cerebral metabolic rates for glucose were measured in 74 structures at P15, P25 and in adults (P60), by the autoradiographic method using 2-D-[14C]deoxyglucose. Repeated seizures in P5 to P7 pups led to a reduction (16-34%) of glucose consumption at P15, mainly significant in sensory, motor and functionally non-specific areas as well as in cerebellar nuclei. Selective decreases in metabolic activity were still recorded in adults, mostly in auditory system (20%) and cerebellar nuclei (27%). Seizures generated from P15 to P17 led to an overall mortality rate of 62% (versus 22% at P5 to P7). Surviving animals exhibited reduced metabolic rates for glucose (by 7-27%) at P25, significant in 23 structures, and depicting pronounced changes in limbic, hypothalamic, sensory and white matter areas, whereas brain functional activity finally returned to basal values at P60. Therefore, while younger rats seemed to better tolerate repeated bicuculline-induced seizures than older animals, the reverse was true for long-term metabolic effects, and the more immature the brain when seizures arise, the more persistent the functional consequences.

Prevention from hypoxia-induced apoptosis by pre-conditioning: a mechanistic approach in cultured neurons from fetal rat forebrain.

Molecular effects of pre-conditioning by 1-h hypoxia were investigated in cultured neurons from fetal rat forebrain, submitted the following day to a 6-h hypoxia that induces apoptosis. While preventing from apoptosis, pre-conditioning led to increased number of living neurons, DNA synthesis, with persistent overexpression of Bcl-2 and proliferating cell nuclear antigen (PCNA). Adaptative mechanisms would involve anti-apoptotic proteins and regulators of the cell cycle, to finally promote neuronal proliferation.