Induction of hemeoxygenase-1 expression after inhibition of hemeoxygenase activity promotes inflammation and worsens ischemic brain damage in mice.

Hemeoxygenase (HO) is an enzymatic system that degrades heme. HO-1 is an inducible isoform whereas HO-2 is constitutive. Stroke strongly induces HO-1 expression but the underlying mechanisms are not fully elucidated. Cytokines that are up-regulated after ischemia, like interleukin (IL)-10, can induce HO-1 gene expression, which is positively regulated by the transcriptional activator nuclear factor erythroid 2-related factor 2 (Nrf2) and negatively regulated by the transcriptional repressor breast cancer type 1 susceptibility protein (BRCA1) associated C-terminal helicase 1 (Bach-1). While Nrf2 is activated after ischemia and drugs promoting Nrf2 activation increase HO-1 and are beneficial, the involvement of Bach-1 is unknown. Here we investigated mechanisms involved in HO-1 induction and evaluated the effects of HO activity inhibition in mouse permanent middle cerebral artery occlusion (pMCAO). HO-1 was induced after ischemia in IL-10-deficient mice suggesting that post-ischemic HO-1 induction was IL-10-independent. Attenuation of Bach-1 gene repression after ischemia was associated to enhanced HO-1 induction. Administration of the HO activity inhibitor zinc proto-porphyrin IX (ZnPP) i.p. 24h before pMCAO exacerbated ischemia-induced tumor necrosis factor-α (TNF-α) and IL-1ß, nitro-oxidative stress, and the presence of neutrophils at 8h, and increased infarct volume at day 4. However, ZnPP did not worsen ischemic damage when given 30min before pMCAO. ZnPP induced HO-1 expression in the cerebral vasculature at 24h, when it was still detected by high-performance liquid chromatography (HPLC) in plasma. While ZnPP was not found in brain tissue extracts of controls, it could be detected after ischemia, supporting that a small fraction of the injected drug can reach the tissue following blood-brain barrier breakdown. The deleterious effect of inhibiting HO activity in ischemia became apparent in the presence of ZnPP-induced HO-1, which is known to exert effects independent of its enzymatic activity. In conclusion, HO-1 induction after ischemia was associated to down-regulation of transcriptional repressor Bach-1, and induction of HO-1 when HO enzymatic activity was inhibited was related to worst outcome after brain ischemia.

Chondroitin sulfate inhibits lipopolysaccharide-induced inflammation in rat astrocytes by preventing nuclear factor kappa B activation.

Chondroitin sulfate (CS) is a glucosaminoglycan (GAG) currently used for the treatment of osteoarthritis because of its antiinflammatory and antiapoptotic actions. Recent evidence has revealed that those peripheral effects of CS may also have therapeutic interest in diseases of the CNS. Since neuroinflammation has been implicated in different neuronal pathologies, this study was planned to investigate how CS could modulate the inflammatory response in the CNS by using rat astrocyte cultures stimulated with lipopolysaccharide (LPS). We have evaluated different proteins implicated in the nuclear factor kappa B (NFkappaB) and Janus kinase/signal transducer and activator of transcription (JAK/STAT) pathways employing RT-PCR, western blot and immunofluorescence techniques. At 10 microM, CS prevented translocation of p65 to the nucleus, reduced tumour necrosis factor alpha (TNF-alpha) mRNA and mitigated cyclooxygenase 2 (COX-2) and inducible nitric oxide synthase (iNOS) induction by LPS. However, it did not modify LPS-induced IP-10 and SOCS-1 mRNA, proteins that participate in the JAK/STAT pathway. The results of this study indicate that CS can potentially reduce neuroinflammation by inhibition of NFkappaB. Therefore endogenous GAGs could afford neuroimmunomodulatory actions under neurotoxic conditions.

Harms and benefits of lymphocyte subpopulations in patients with acute stroke.

UNLABELLED: Lymphocytes are major players in the development of innate and adaptive immune responses but their behavior in patients with acute stroke has received little attention. EXPERIMENTAL PROCEDURES: Using flow cytometry we identified total lymphocytes, T cells, helper T (Th) cells, cytotoxic T lymphocytes (CTL), natural killer (NK) cells, B cells, and regulatory T (Treg) cells in 46 consecutive patients with acute stroke within a median of 180 min of clinical onset, and at days 2, 7, and 90. Daily neurological score (National Institutes of Health Stroke Scale), diffusion-weighted imaging on brain magnetic resonance imaging, functional impairment, and stroke-associated infection (SAI) at day 7 were assessed. Apoptosis in lymphocyte subsets, tumor necrosis factor (TNF) -alpha/interleukin (IL) -4 production in stimulated Th and CTL, cluster of differentiation 86 (CD86) (B7-2) expression in B cells, cortisol and metanephrine in serum were measured. Multivariate analyses were used to evaluate SAI, and stroke outcome. RESULTS: Increased apoptosis and a fall of T, Th, CTL, B, and Treg cells were observed after stroke. Severer stroke on admission and SAI disclosed a greater decline of T, Th, and CTL cells. Increased cortisol and metanephrine was associated with severe stroke and SAI, and inversely correlated with T, and CTL. T cells, and CTL were correlated with infarct growth. Stroke but not SAI resulted in lower TNF-alpha production in Th cells. SAI showed the greatest fall of lymphocytes, T, Th, and CTL, but not B cells, or Treg. Poor outcome was associated with reduced levels of B cells, and increased expression of CD86 in B cells, but not with SAI. CONCLUSION: Lymphopenia and increased apoptosis of T, Th, CTL, Treg and B cells are early signatures after human stroke. A decreased cellular response after stroke is a marker of ongoing brain damage, the stress response, and a higher risk of infection. A lower humoral response is predictor of poorer long-term outcome.

Signalling pathways mediating inflammatory responses in brain ischaemia.

Stroke causes neuronal necrosis and generates inflammation. Pro-inflammatory molecules intervene in this process by triggering glial cell activation and leucocyte infiltration to the injured tissue. Cytokines are major mediators of the inflammatory response. Pro-inflammatory and anti-inflammatory cytokines are released in the ischaemic brain. Anti-inflammatory cytokines, such as interleukin-10, promote cell survival, whereas pro-inflammatory cytokines, such as TNFalpha (tumour necrosis factor alpha), can induce cell death. However, deleterious effects of certain cytokines can turn to beneficial actions, depending on particular features such as the concentration, time point and the very intricate network of intracellular signals that become activated and interact. A key player in the intracellular response to cytokines is the JAK (Janus kinase)/STAT (signal transducer and activator of transcription) pathway that induces alterations in the pattern of gene transcription. These changes are associated either with cell death or survival depending, among other things, on the specific proteins involved. STAT1 activation is related to cell death, whereas STAT3 activation is often associated with survival. Yet, it is clear that STAT activation must be tightly controlled, and for this reason the function of JAK/STAT modulators, such as SOCS (suppressors of cytokine signalling) and PIAS (protein inhibitor of activated STAT), and phosphatases is most relevant. Besides local effects in the ischaemic brain, cytokines are released to the circulation and affect the immune system. Unbalanced pro-inflammatory and anti-inflammatory plasma cytokine concentrations favouring an 'anti-inflammatory' state can decrease the immune response. Robust evidence now supports that stroke can induce an immunodepression syndrome, increasing the risk of infection. The contribution of individual cytokines and their intracellular signalling pathways to this response needs to be further investigated.

Interleukin 10, monocytes and increased risk of early infection in ischaemic stroke.

BACKGROUND AND PURPOSE: The pathophysiology of stroke-associated infection (SAI) is uncertain. The cytokine profile and peripheral white cell response were assessed in patients with or without SAI. METHODS: The incidence of SAI was assessed in 110 patients with ischaemic stroke allocated antibiotic prophylaxis or placebo within 24 h of clinical onset. Peripheral white cell counts, interleukin (IL)6, tumour necrosis factor (TNF)alpha and IL10 were measured in plasma. RESULTS: 17 (15%) patients developed infection and showed time-dependent increases of total white cell count, neutrophils, monocytes, lymphocytes, IL6 and IL10, whereas TNFalpha and the TNFalpha/IL10 ratio decreased. In logistic regression, IL10 (odds ratio (OR) 1.08, 95% confidence interval (CI) 1.01 to 1.16), monocyte count (OR 1.42, 95% CI 1.08 to 1.87) and National Institute for Health Stroke Survey score on admission (OR 1.17, 95% CI 1.05 to 1.31) were independent predictors of systemic infection. CONCLUSIONS: SAI is associated with stroke severity, excessive IL10-mediated response and an increased number of circulating monocytes. These results support the finding that acute ischaemic brain injury triggers a blood-borne anti-inflammatory response that decreases the antimicrobial drive of the immune system.

Carboxyl-terminal fragment of amyloid precursor protein and hydrogen peroxide induce neuronal cell death through different pathways.

Carboxyl-terminal fragments (CTs) of the amyloid precursor protein have been shown to be highly neurotoxic and are though to contribute to the neuropathology of Alzheimer's disease. We compared the effects of expressing CT99 in the human neuroblastoma MC65 with the effects of hydrogen peroxide on the parental SK-N-MC cells. CT99 and hydrogen peroxide generated a different pattern of free radicals and their toxic effects were differentially protected by a battery of antioxidants. Hydrogen peroxide caused a cell cycle arrest at phase S and apoptosis mediated through caspase-3 activation in a pattern similar to that described for amyloid-beta neurotoxicity. However, CT99 apoptosis appeared to be mediated through an unidentified mitochondrial pathway. Both oxidative injury types induced heme oxygenase-1 expression as a neuroprotective response. Overall we found a coincidence in the nonespecific stress oxidative effects of CT99 and hydrogen peroxide, but clear differences on their respective potencies and pathways of neurotoxicity.

The -174G/C polymorphism of the interleukin 6 gene is a hallmark of lacunar stroke and not other ischemic stroke phenotypes.

BACKGROUND AND PURPOSE: The CC genotype of the -174 G/C interleukin (IL)-6 polymorphism has been associated with lacunar stroke. However, it remains unsettled whether this polymorphism is also associated with other ischemic stroke phenotypes. METHODS: The -174 G/C IL-6 polymorphism was genotyped in patients with lacunar stroke (n = 89), stroke due to large vessel disease (n = 82), cardioembolism (n = 53), stroke of undetermined cause (n = 49) and in white controls without any history of stroke (n = 105) by PCR and restriction enzyme analysis. Independent predictors of the -174 G/C IL-6 genotypes were assessed using multivariate logistic regression models adjusted for demographics, risk factors and disease state. RESULTS: The prevalence of the CC genotype was 8.5% in large vessel disease, 7.5% in embolism, 19.1% in lacunar stroke, 14.3% in stroke of undetermined cause and 8.6% in controls. The CC genotype was independently associated with lacunar stroke only (adjusted OR 3.22, 95% CI 9.09-1.12). Contrarily, there were no significant differences in genotype and allele distribution in the remainder of ischemic stroke phenotypes. Pooling of patients with nonlacunar stroke did not show any independent association with the CC genotype as compared with controls (OR 1.01, 95% CI 2.77-0.36). CONCLUSIONS: The unique association between the CC genotype of the -174 G/C IL-6 polymorphism and lacunar stroke suggests a particular susceptibility of small deep penetrators of cerebral arteries to IL-6-mediated inflammatory damage.

Caspase-dependent and caspase-independent signalling of apoptosis in the penumbra following middle cerebral artery occlusion in the adult rat.

Transient focal ischaemia by middle cerebral artery occlusion (MCAO) may produce cell death, but the mechanisms leading to cell death differ in the infarct core and in the penumbra, the immediate zone surrounding the infarct core. In the present study, transient focal ischaemia to adult rats was produced by intraluminal occlusion of the middle cerebral artery for 1 h followed by 0 h (n=6), 1 h (n=10), 4 h (n=8), 6 h (n=2) and 12 h (n=3) of reperfusion. The present model of ischaemia causes a large cortico-striatal infarct extending through the mediolateral cortex and dorsolateral striatum at 12 h. The expression and subcellular distribution of several proteins involved in apoptosis have been examined in the penumbra and in the infarct core by using combined methods of immunohistochemistry, cell subfractionation and Western blotting. Transient focal ischaemia by MCAO results in activation of complex signal pathways for cell death in the penumbra. Increased expression of Bcl-2 and Bax, but not of Bcl-x, occurs in the penumbra at the time when Bax translocates from the cytosol to the mitochondria, cytochrome c is released to the cytoplasm and active caspase-3 is expressed. Bax translocation, cytochrome c release and active caspase-3 are observed at 4 h, but not at 1 h, following reperfusion, and together indicate activation of the caspase-dependent pathway of apoptosis in the penumbra. In contrast, reduced Bax expression but not Bax translocation and cytochrome c release occurs in the infarct core, thus suggesting apoptosis signals restricted to the penumbra. In addition, increased expression of an apoptosis-inducing factor in the cytoplasm and nuclei of selected cells shows, for the first time, activation of the caspase-independent mitochondrial pathway in the penumbra following transient focal ischaemia and reperfusion.

Early modifications in the expression of mitogen-activated protein kinase (MAPK/ERK), stress-activated kinases SAPK/JNK and p38, and their phosphorylated substrates following focal cerebral ischemia.

Focal ischemia induced by middle cerebral artery occlusion (MCAO) to adult rats results in necrosis at the infarct core and activation of complex signal pathways for cell death and cell survival in the penumbra. Upstream from the cell death promoters and executioners are several kinases that, once activated by phosphorylation, may activate several transcription factor substrates involved in cell death and cell survival. In the present study we examined, by immunohistochemistry, the expression of phosphorylated (active) mitogen-activated protein kinase, extracellular signal-regulated kinase (MAPK/ERK), stress-activated protein kinase (SAPK), c-Jun N-terminal kinase (JNK) and p-38 kinase at early stages (1-4 h) following 1 h of MCAO in the rat. The expression of phosphorylation-dependent, active transcription substrates of these kinases, including cyclic AMP-responsive element-binding protein (CREB) Alk-1, ATF-2, c-Myc and c-Jun was examined at early stages following reperfusion. Increased nuclear phosphorylated SAPK/JNK (SAPK/JNK-P) and c-Jun-PSer63, and reduced CREB-P, occurred in the infarct core at 1 h following reperfusion, suggesting increased phosphorylated SAPK/JNK and c-JunSer63, together with decreased phospho-CREB associated with cell death in the infarct core. However, increased cytoplasmic expression of MAPK/ERK-P, SAPK/JNK-P, p38-P, CREB-P, Elk-1-P, c-Myc-P, ATF-2-P and c-Jun-P occurred in the region bordering the infarct core (penumbra) at 4 h following reperfusion. This indicates that different signals converge in the cytoplasm of neurons located at the borders of the infarct at 4 h following reperfusion, revealing the struggle of death promoters and life facilitators at the penumbra. Whether phosphorylated kinases and specific substrates participate in promoting cell death or survival in the penumbra probably depends on additional factors and on the interaction with other proteins.

Focal cerebral ischemia causes two temporal waves of Akt activation.

We studied whether pro-survival Akt was activated after transient focal cerebral ischemia and whether it inhibited pro-apoptotic Bad. Phosphorylation of Akt (serine-473) was enhanced in cortex after 1-hour ischemia, and also after 1h and 6 h of reperfusion, but it returned back to that in controls by 24 h. After this first wave of Akt activation, a second increase was observed between 4 and 7 days. In striatum, only the late Akt activation was seen. In contrast to Akt, no Bad phosphorylation (serine-136) was detected after ischemia. Therefore, injury spontaneously activated Akt, but this did not suppress Bad signalling. It is proposed that further pharmacological activation of Akt shortly after ischemia might promote cell survival, whereas Akt activation at longer time points is involved with glial reactivity.

Expression and activation of matrix metalloproteinase-2 and -9 in rat brain after transient focal cerebral ischemia.

Matrix metalloproteinases (MMPs) degrade the extracellular matrix and carry out key functions during development and after injury. By means of zymography, Western blot and immunohistochemistry, we studied MMP-2 (gelatinase A) and MMP-9 (gelatinase B) in rat brain after focal cerebral ischemia. The control rat brain showed constitutive MMP-2 and, to a lesser extent, MMP-9, which were mainly present as prozymogens. MMP-2 protein was located in the cell body of neurons, glia, and endothelium, whereas MMP-9 was associated to neurons and myelinated fibre tracts. Ischemia greatly increased MMP activation in two temporal waves, in the first one, MMP-9 protein was induced from 4 h to 4 days, and also a small and short-lasting increase in MMP-2 was detected at 4 h. The second wave showed a massive increase in MMP-2 protein expression and activation by day 4, which was compatible with abundant MMP-2 in reactive microglia/macrophages. Our results are compatible with progressive induction of MMP-9 proform, likely in neurons, shortly after ischemia. For MMP-2, the results suggest a discrete production immediately after reperfusion, while a very enhanced expression and activation of MMP-2 attributable to microglia/macrophages occurs on day 4, and it might contribute to the phagocytic action of these reactive cells.

Temporospatial expression of HSP72 and c-JUN, and DNA fragmentation in goat hippocampus after global cerebral ischemia.

The role of gene induction (expression of HSP72 and c-JUN proteins) and delayed ischemic cell death (in situ labeling of DNA fragmentation) have been investigated in the goat hippocampus after transient global cerebral ischemia. The animals were subjected to 20-min ischemia (bilateral occlusion of the external carotid arteries plus bilateral jugular vein compression) and allowed to reperfuse for 2 h, and then 1, 3, and 7 days. Histological signs of cell loss were not found in the hippocampus at 2 h, 1 day, or 3 days of reperfusion. However, such an ischemic insult produced extensive, selective, and delayed degeneration in the hippocampus, as 68% of the neurons in CA1 had died at 7 days, but cell loss was not detected in CA3 and dentate gyrus fields. Concomitantly, a high percentage of TUNEL-positive CA1 neurons (60+/-9%, mean +/- SEM) was seen at 7 days, but not at the earlier time points. Mild induction of HSP72 was detected in the goat hippocampus after ischemia. The maximum percentage of HSP72-positive neurons (10-15%) was shown at 3 days of reperfusion and was concentrated mainly in the CA3 field, subiculum, and hilus, rather than in the CA1 field, whereas HSP72 expression was hardly detected at 7 days. At this later time point, scattered induction of nuclear c-JUN was found in a few neurons. The results show that: 1) postischemic delayed neuronal death selectively affects the CA1 field in the goat hippocampus, a phenomenon which seems to take longer to develop than in previously reported rodent models; and 2) postischemic expression of c-JUN does not appear to be related to cell death or survival, while the inability of most CA1 neurons to express HSP72 could contribute to neuronal death.

MPP(+) injection into rat substantia nigra causes secondary glial activation but not cell death in the ipsilateral striatum.

Injection of MPP(+) into the substantia nigra causes extensive necrosis and anterograde degeneration of pars compacta dopaminergic neurons. We studied secondary effects in the ipsilateral striatum by examining dopaminergic terminals, signs of neuronal damage, and glial reactivity at 1, 2, 3, and 7 days after injection of MPP(+) into the substantia nigra. Dopaminergic terminals and uptake sites were evaluated with [(3)H]GBR-12935 binding and tyrosine hydroxylase immunoreactivity. Glial reaction was examined with markers of astrocytes and microglia. Stereology was used to evaluate any changes in neuronal density. Tyrosine hydroxylase immunoreactivity and [(3)H]GBR-12935 binding markedly decreased (74%) from days 2 to 7. Loss of dopaminergic terminals in the ipsilateral striatum was accompanied by an intense astroglial and, to a lesser extent, microglial reaction. However, no signs of cell damage, neuronal loss, or disruption of the blood-brain barrier were found in the striatum. Resident astroglial and microglial cells showed a morphological shift and notable changes in protein expression typical of glial reactivity, yet the presence of macrophage-like cells was not detected. This study shows that injection of MPP(+) in the substantia nigra causes a secondary reaction within the ipsilateral striatum involving the transformation of quiescent glia to reactive glia. It is suggested that stimuli derived from damaged dopaminergic terminals within the striatum are able to activate resident glia and that this glial transformation may promote repair and regeneration.

Inhibitors of NO-synthase and donors of NO modulate kainic acid-induced damage in the rat hippocampus.

The effects of nitric oxide synthase (NOS) inhibitors, N(omega)-nitro-L-arginine and 7-nitroindazole, and the NOS substrate L-arginine on kainic acid (KA)-induced microglial reactivity and stress response were studied in the hippocampus 7 and 1 days after KA, respectively. Density of peripheral-type benzodiazepine receptors was measured as an index of microglial reactivity. Histological damage in hippocampus was evaluated at 7 days by neuronal counting. KA increased the maximal number of binding sites (B(max)) versus controls. Administration of either 7-nitroindazole (25 mg/kg) or N(omega)-nitro-L-arginine (20 and 50 mg/kg) 24 hr before KA, further increased B(max). This later effect was abolished by L-arginine (1 g/kg), which given 24 hr before KA decreased B(max) to control values. Also, KA-induced HSP72 stress response was attenuated by pre-treatment with L-arginine. Histological evaluation showed reduced cell numbers in the pyramidal cell layer of the hippocampus in groups receiving KA, either alone or in combination with 7-nitroindazole. Administration of L-arginine before KA attenuated neuronal loss in CA3 but not CA1. A clear protective effect was observed, however, in CA1 and CA3, in rats receiving both L-arginine plus 7-nitroindazole before KA. The results show that the combination of a NO substrate with a NOS inhibitor reduces the neurotoxic effects of KA in the rat hippocampus. This study suggests that extremely fine regulation of NO levels in the different neural cell types can modulate excitotoxicity.

Transforming growth factor-alpha acting at the epidermal growth factor receptor reduces infarct volume after permanent middle cerebral artery occlusion in rats.

Transforming growth factor-alpha (TGF-alpha) is a ligand for the epidermal growth factor (EGF) receptor (EGFR), and is more abundant than EGF in the brain. The authors studied whether administration of exogenous TGF-alpha into the brain can protect neurons against ischemia in a model of permanent middle cerebral artery (MCA) occlusion in the rat, and whether any effect of TGF-alpha was mediated by EGFR by administering 4,5-dianilinophthalimide (DAPH), a protein-tyrosine kinase inhibitor with high selectivity for EGFR. Rats received either TGF-alpha (10 or 25 ng), DAPH (100 ng), DAPH plus TGF-alpha (25 ng), or vehicle in the ipsilateral first ventricle. Drugs were administered twice: 30 minutes before and 30 minutes after MCA occlusion, and infarct volume was evaluated 24 hours later. Transforming growth factor-alpha at the dose of 25 ng caused a statistically significant reduction of infarct volume (60%) in relation to ischemic rats administered vehicle. This reduction was no longer seen when TGF-alpha was administered in combination with DAPH. The present results show that TGF-alpha can protect neurons from ischemic damage, and that this effect is mediated by EGFR. It is suggested that activation of EGFR-mediated intracellular signalling pathways contributes to the survival of neural cells susceptible to ischemic injury.

Epidermal growth factor receptor in proliferating reactive glia following transient focal ischemia in the rat brain.

Severe transient focal cerebral ischemia causes brain infarction with a strong glial reaction. We have studied whether postischemic reactive glial cells express epidermal growth factor receptor (EGFR) following middle cerebral artery occlusion in the rat. We have also looked for signs of proliferating activity, as EGFR is known to be involved in cell growth and proliferation in certain non-neural cells. EGFR was studied using three different antibodies which were found to stain for a tyrosine-phosphorylated protein (p170) corresponding to the membrane-anchored EGFR. Neurons of the control brain were strongly immunoreactive to EGFR, but a decrease of EGFR-immunoreactivity was seen in the ipsilateral brain side from 24 h postischemia due to neuronal loss. However, the presence of abundant glial cells strongly immunoreactive to EGFR became apparent in this area from 4 days postischemia onward. The use of microglial (lectin or OX-42) and astroglial (GFAP) markers showed that these postischemic EGFR-stained cells were reactive microglia/macrophages and astroglia. The subcellular localization of EGFR in reactive microglia/macrophages was compatible with the network of the Golgi apparatus, as revealed with an antibody against a peripheral membrane-bound protein of the Golgi. The presence of abundant proliferating cells in the ischemic brain was detected from 4 days postischemia with an antibody against proliferating cell nuclear antigen. Proliferating reactive microglia/macrophages were abundant within the infarcted brain side, whereas proliferating astrocytes were found mainly in the immediate periphery of the infarct limiting the necrotic area from the undamaged tissue. These proliferating cells were immunoreactive to EGFR. The results show the presence of EGFR in postischemic reactive glial cells and suggest that EGFR-dependent pathways mediate signal transduction in reactive glia following transient focal cerebral ischemia.

Differential cellular distribution and dynamics of HSP70, cyclooxygenase-2, and c-Fos in the rat brain after transient focal ischemia or kainic acid.

Cerebral ischemia and also excitotoxicity induce the expression of 72,000 mol. wt heat shock protein (Hsp70), c-Fos, and cyclooxygenase-2. In the present work we have examined whether Hsp70, c-Fos and cyclooxygenase-2 are expressed by the same cells in the rat brain at 6, 12 and 24 h following transient focal ischemia or kainic acid administration, by means of single and double immunohistochemistry. At 6 h after kainic acid, some co-localization of Hsp70 with c-Fos and cyclooxygenase-2 was seen in pyramidal hippocampal neurons and superficial cortical layers, however by 24 h such colocalization became rare within the cortex but was partially maintained in the hippocampus. Cyclooxygenase-2 was seen in many neurons that were also immunoreactive for c-Fos in superficial cortical layers, dentate gyrus and pyramidal cell layer of the hippocampus from 6 h after kainic acid. Co-localization of cyclooxygenase-2 and c-Fos was also observed in superficial cortical layers within the ipsilateral hemisphere at 6 h following focal ischemia. Also, some co-localization of Hsp70 with c-Fos and cyclooxygenase-2 was seen at this time. However, by 24 h cyclooxygenase-2 and c-Fos-immunoreactive cells were restricted to perifocal regions, and only a very limited co-localization with Hsp70 was seen in perifocal neurons located in the border of the penumbra-like area that surrounds the ischemic core and is strongly immunoreactive for Hsp70. This study shows a selective and dynamic cellular expression of inducible proteins following either ischemia or kainic acid, with a remarkable neuronal co-localization of c-Fos and cyclooxygenase-2. The results suggest that, first, stimuli underlying neuronal c-Fos expression can also lead to the induction of cyclooxygenase-2; second, transient co-localization of Hsp70 and c-Fos can take place in non-vulnerable neurons; and finally, expression of c-Fos, cyclooxygenase-2, and/or Hsp70 at a given time-point is part of the response to altered environmental conditions and can be related to the particular cellular sensitivity rather than the pathological outcome.

Radiation-induced apoptosis in developing rats and kainic acid-induced excitotoxicity in adult rats are associated with distinctive morphological and biochemical c-Jun/AP-1 (N) expression.

Ionizing radiation produces apoptosis in the developing rat brain. Strong c-Jun immunoreactivity, as revealed with the antibody c-Jun/AP-1 (N) which is raised against the amino acids 91-105 mapping with the amino terminal domain of mouse c-Jun p39, is simultaneously observed in the nucleus and cytoplasm of apoptotic cells. Western blotting of total brain homogenates, using the same antibody, shows a p39 band in control rats which is accompanied by a strong, phosphorylated p62 double-band in irradiated animals. In addition, increased c-Jun N-terminal kinase 1 expression, as found on western blots, is found in irradiated rats when compared with controls. Intraperitoneal injection of kainic acid at convulsant doses to the adult rat produces cell death with morphological features of necrosis, together with the appearance of cells with fine granular chromatin degeneration and small numbers of apoptotic-like cells, in the entorhinal and piriform cortices, basal amygdala, certain thalamic nuclei, and CA1 region of the hippocampus. c-Jun expression in kainic acid-treated rats, as revealed with the c-Jun/AP-1 (N) antibody, is found in the nuclei of a minority of cells in the same areas. The vast majority of c-Jun-immunoreactive cells have normal nuclear morphology, whereas necrotic cells are negative and only a few cells with fine granular chromatin condensation and apoptotic cells following kainic acid injection are stained with c-Jun antibodies. Western blotting, using the same antibody, shows a p39 band in control rats, which is accompanied by a band at about p26 from 6 h onwards following kainic acid injection. Decreased c-Jun N-terminal kinase 1 expression, as revealed on western blots, is observed in kainic acid-treated rats. These results show that the antibody c-Jun/AP-1 (N) recognizes three different forms of c-Jun-related immunoreactivity in normal and pathological states, which are associated with the different outcome of cells. These results stress the necessity of examining in detail the composition of c-Jun-immunoreactive bands and the metabolic state of c-Jun(s) in different paradigms of cell death and survival.

Kainic acid-induced excitotoxicity is associated with a complex c-Fos and c-Jun response which does not preclude either cell death or survival.

c-fos and c-jun mRNA induction and c-Fos and c-Jun protein expression were examined in the brains of adult rats subjected to systemic kainic acid (KA) injection at convulsant doses. Induction of c-fos and c-jun mRNA, as seen with in situ hybridization, occurred in the piriform and entorhinal cortices, neocortex, amygdala, hippocampus, dentate gyrus, and discrete thalamic nuclei. This was followed by c-Fos protein expression, as revealed with immunohistochemistry, in the same regions. However, the distribution of c-Jun protein expression differed depending on the antibody used. The distribution of cells immunostained with the antibody c-Jun (AB-1) was similar to that of c-jun mRNA, but the distribution of cells immunostained with the antibody c-Jun/AP1 (N) was restricted to a few neurons in the pyramidal cell layer of CA1 and CA3, layer II of the piriform and entorhinal cortices, basal amygdala, and discrete thalamic nuclei. Although the regional distribution of c-Fos- and c-Jun-immunoreactive cells in the hippocampus, layer II of the entorhinal and piriform cortices, basal amygdala, and discrete thalamic nuclei matched the distribution of cells committed to dying, c-Fos- and c-Jun-immunoreactive cells in the neocortex and dentate gyrus survived. Therefore, the present data show that c-fos and c-jun are not predictors of either cell death or survival, but rather, markers of cells sensitive to KA excitotoxicity. Western blots to c-Fos showed a double band at p62 in samples containing the hippocampus and entorhinal and piriform cortices (hip samples) and in samples containing the neocortex (cortex samples). The upper band was abolished following preincubation of the samples with alkaline phosphatase, thus suggesting c-Fos phosphorylation. Western blots to c-Jun (AB-1) showed a single band at about p39 in hip and cortex. However, Western blots to c-Jun/AP1 (N) identified two bands. One band at about p39 was seen in control rats and the cortex of KA-treated rats. Another band at p26 was observed only in hip samples of KA-treated rats. In addition, decreased c-Jun N-terminal kinase 1 (JNK-1) expression, as revealed on Western blots, was coincidental with the appearance of the p26 c-Jun-immunoreactive band in KA-treated rats. These results show that c-Fos and different Jun-related antigens are expressed following KA excitotoxicity, and that posttranslational modifications involving phosphorylation of c-Fos and Jun(s) may occur following KA injection. These results also stress the necessity of examining the composition of Fos and Jun-related antigens and the metabolic state of Fos and Jun(s) in different experimental models of nervous system injury.