Experimental stroke in gerbils: effect on translation and transcription

Polyadenylated mRNA staining reveals distinct neuronal phenotypes following endothelin 1, focal brain ischemia, and global brain ischemia/ reperfusion

OBJECTIVES

Most work on ischemia-induced neuronal death has revolved around the relative contributions of necrosis and apoptosis, but this work has not accounted for the role of ischemia-induced stress responses. An expanded view recognizes a competition between ischemia-induced damage mechanisms and stress responses in the genesis of ischemia-induced neuronal death. An important marker of post-ischemic stress responses is inhibition of neuronal protein synthesis, a morphological correlate of which is the compartmentalization of mRNA away from ribosomes in the form of cytoplasmic mRNA granules.

METHODS

Here we assessed the generality of this mRNA granule response following either 10 or 15 minutes global brain ischemia and 1 hour reperfusion, 4 hours focal cerebral ischemia alone, and endothelin 1 intraventricular injection.

RESULTS

Both global and focal ischemia led to prominent neuronal cytoplasmic mRNA granule formation in layer II cortical neurons. In addition, we report here new post-ischemic cellular phenotypes characterized by the loss of nuclear polyadenylated mRNA staining in cortical neurons following endothelin 1 treatment and 15 minutes global ischemia. Both mRNA granulation and loss of nuclear mRNAs occurred in non-shrunken post-ischemic neurons.

DISCUSSION

Where cytoplasmic mRNA granules generally appear to mark a protective response in surviving cells, loss of nuclear mRNAs may mark cellular damage leading to cell atrophy/death. Hence, staining for total mRNA may reveal facets of the competition between stress responses and damage mechanisms at early stages in post-ischemic neurons.

Nonhuman primate models of stroke for translational neuroprotection research

Despite the discovery of several promising neuroprotective therapies in rodent models of stroke, no therapy other than the fibrinolytics has been found to be effective in human clinical trials. To address potential discrepancies between rodent and human studies, the Stroke Therapy Academic Industry Roundtable (STAIR) committee suggested that nonhuman primates (NHPs) be used for preclinical, translational stroke studies. Due to the paucity of stroke studies in NHPs, few experimental models have been described. Critical factors in designing NHP stroke models include the choice of species, the method of inducing the stroke and the choice of outcome measures. In this review, we describe established NHP models of stroke and discuss factors that may influence model development with a focus on models that may be useful in preclinical studies for neuroprotective drug screening prior to clinical trials.

Translating promising preclinical neuroprotective therapies to human stroke trials

Stroke is the third leading cause of mortality and carries the greatest socioeconomic burden of disease in North America. Despite several promising therapies discovered in the preclinical setting, there have been no positive results in human stroke clinical trials to date. In this article, we review the potential causes for failure and discuss strategies that have been proposed to overcome the barrier to translation of stroke therapies. To improve the chance of success in future human stroke trials, we propose that therapies be tested in stroke models that closely resemble the human condition with molecular, imaging and functional outcomes that relate to outcomes utilized in clinical trials. These strategies include higher-order, old-world, nonhuman primate models of stroke with clinically relevant outcome measures. Although stroke neuroprotection has been looked upon pessimistically given the many failures in clinical trials to date, we propose that neuroprotection in humans is feasible and will be realized with rigorous translational science.

MK-801 does not prevent development of ischemic tolerance in rat brain

Tolerance against ischemia can be induced in the CA1 region of the hippocampus of the brain. In gerbils tolerance evolvement is blocked by the NMDA-antagonist MK-801. To examine this mechanism in rats, MK-801 was administered i.p. 1 h prior to tolerance inducing ischemia. Body temperature and activity were monitored before and after ischemia, and show that MK-801 results in hyperthermia immediately after the injection, the post-ischemic body temperature remain elevated until 5 h post-ischemia in spite of the animals being less active than control animals. Histology shows that pre-treatment with MK-801 does not affect the CA1 neuronal density, and we thus conclude that for the used rat model, MK-801 does not affect development of ischemic tolerance.

Protective effect of green tea polyphenol EGCG against neuronal damage and brain edema after unilateral cerebral ischemia in gerbils

Previous studies have demonstrated that a green tea polyphenol, (-)-epigallocatechine gallate (EGCG), has a potent free radical scavenging and antioxidant effect. Glutamate leads to excitotoxicity and oxidative stress, which are important pathophysiologic responses to cerebral ischemia resulting in brain edema and neuronal damage. We investigated the effect of EGCG on excitotoxic neuronal damage in a culture system and the effect on brain edema formation and lesion after unilateral cerebral ischemia in gerbils. In vitro, excitotoxicity was induced by 24-hr incubation with N-methyl-D-aspartate (NMDA; 10 microM), AMPA (10 microM), or kainate (20 microM). EGCG (5 microM) was added to the culture media alone or with excitotoxins. We examined malondialdehyde (MDA) level and neuronal viability to evaluate the effect of EGCG. In vivo, unilateral cerebral ischemia was induced by occlusion of the right common carotid artery for 30, 60, or 90 min and followed by reperfusion of 24 hr. Brain edema, MDA, and infarction were examined to evaluate the protective effect of EGCG. EGCG (25 or 50 mg/kg, intraperitoneally) was administered twice, at 30 min before and immediately after ischemia. EGCG reduced excitotoxin-induced MDA production and neuronal damage in the culture system. In the in vivo study, treatment of gerbils with the lower EGCG dose failed to show neuroprotective effects; however, the higher EGCG dose attenuated the increase in MDA level caused by cerebral ischemia. EGCG also reduced the formation of postischemic brain edema and infarct volume. These results demonstrate EGCG may have future possibilities as a neuroprotective agent against excitotoxicity-related neurologic disorders such as brain ischemia.

Deficient brain RNA polymerase and altered nucleolar structure persists until day 8 after perinatal asphyxia of the rat

RNA polymerases (POL) are integral constituents of the protein synthesis machinery, with POL I and POL III coding for ribosomal RNA and POL II coding for protein. POL I is located in the nucleolus and transcribes class I genes, those that code for large ribosomal RNA. It has been reported that the POL system is seriously affected in perinatal asphyxia (PA) immediately after birth. Because POL I is necessary for protein synthesis and brain protein synthesis was shown to be deranged after hypoxic-ischemic conditions, we aimed to study whether POL derangement persists in a simple, well-documented animal model of graded global PA at the activity, mRNA, protein, and morphologic level until 8 d after the asphyctic insult. Nuclear POL I activity was determined according to a radiochemical method; mRNA steady state and protein levels of RPA4O-an essential subunit of POL I and III-were evaluated by blotting methods; and the POL I subunit polymerase activating factor-53 was evaluated using immunohistochemistry. Silver staining and transmission electron microscopy were used to examine the nucleolus. At the eighth day after PA, nuclear POL I decreased with the length of the asphyctic period, whereas mRNA and protein levels for RPA4O were unchanged. The subunit polymerase activating factor-53, however, was unambiguously reduced in several brain regions. Dramatic changes of nucleolar morphology were observed, the main finding being nucleolar disintegration at the electron microscopy level. We suggest that severe acidosis and/or deficient protein kinase C in the brain during the asphyctic period may be responsible for disintegration of the nucleolus as well as for decreased POL activity persisting until the eighth day after PA. The biologic effect may be that PA causes impaired RNA and protein synthesis, which has been already observed in hypoxic-ischemic states.

Effect of gestational age and hypoxia on activity of ribonucleic acid polymerase in fetal guinea pig brain

OBJECTIVE

The aim of this study was to determine the effect of gestational age and hypoxia on the activity of ribonucleic acid polymerase in fetal guinea pig brain.

STUDY DESIGN

Fetal cerebral cortical neuronal nuclei were isolated at 40, 50, and 60 days (term) of gestation to determine the effect of gestational age on the activity of ribonucleic acid polymerase I, II, and III. Pregnant guinea pigs at 60 days' gestation were randomly assigned to a normoxic or hypoxic group to determine the effect of hypoxia on ribonucleic acid polymerase activity. The fetal neuronal nuclei were pooled from 6 pregnant animals in each group. In the normoxic group the pregnant guinea pigs were exposed to room air before delivery. In the hypoxic group delivery occurred after the pregnant guinea pig had been exposed to 7% oxygen for 60 minutes. The fetuses were delivered by cesarean, and the fetal cerebral cortical neuronal nuclei were isolated immediately. Ribonucleic acid polymerase activity was determined with nuclei suspended in a buffer containing adenosine triphosphate, guanosine triphosphate, cytidine triphosphate, and tritiated uridine triphosphate. Dactinomycin (actinomycin D) and polydeoxyadenylic-thymidylic acid were used to determine the activity of bound and free ribonucleic acid polymerase. alpha-Amanitin was used to determine the activity of ribonucleic acid polymerase II.

RESULTS

The activity of total (bound and free) ribonucleic acid polymerase I and III increased from 85.4 +/- 9.4 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour at 40 days' gestation to 233.3 +/- 82.1 fmol at 50 days and to 343.4 +/- 231.6 fmol at 60 days (P =.02). Total ribonucleic acid polymerase II activity increased from 19.9 +/- 6.0 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour at 40 days to 123.8 +/- 53.0 fmol at 50 days and to 200.9 +/- 77.8 fmol at 60 days (P <.01). In the term fetal guinea pig brain the activity of bound ribonucleic acid polymerase I and III decreased from 116.8 +/- 107.2 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour under normoxic conditions to 92.8 +/- 76.0 fmol in hypoxic fetal brain, a decrease of 20.5%. Free ribonucleic acid polymerase I and III activity decreased from 199.2 +/- 115.2 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour in normoxic fetal brain to 132.0 +/- 66.4 fmol in hypoxic fetal brain, a decrease of 33.8%. Free ribonucleic acid polymerase II activity decreased from 62.4 +/- 70.4 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour in normoxic fetuses to 13.6 +/- 9.6 fmol in hypoxic fetal brain, a decrease of 78.2%. In contrast, however, in term fetal guinea pig brain, bound ribonucleic acid polymerase II activity increased from 8.0 +/- 10.4 fmol of tritiated uridine triphosphate incorporated per milligram of protein per hour under normoxic conditions to 35.2 +/- 8.8 fmol in hypoxic fetal brain, an increase of 340% (P <.01).

CONCLUSION

The activity of ribonucleic acid polymerases I, II, and III increases throughout the latter half of gestation, from 40 to 60 days, in the fetal guinea pig brain. Hypoxia in utero is associated with a decrease in ribonucleic acid polymerase I and III activity. Although hypoxia is associated with a decrease in free ribonucleic acid polymerase II activity, we observed a marked increase in bound ribonucleic acid polymerase II activity, which may represent a hypoxia-induced alteration of gene expression.

Brain RNA polymerase and nucleolar structure in perinatal asphyxia of the rat

Ribosomes are integral constitutens of the protein synthesis machinery. Polymerase I (POL I) is located in the nucleolus and transcribes the large ribosomal genes. POL I activity is decreased in ischemia but nothing is known so far on POL I in perinatal asphyxia. We investigated the involvement of POL I in a well-documented model of graded systemic asphyxia at the level of activity, mRNA, protein, and morphology. Caeserean section was performed at the 21st day of gestation. Rat pups still in the uterus horns were immerged in a water bath for asphyctic periods from 5-20 min. Brain was taken for measurement of pH, nuclear POL I activity, and mRNA steady state, and protein levels of RPA40, an essential subunit of POL I and III. Silver staining and transmission electron microscopy with morphometry when appropriate were used to examine the nucleolus. Brain pH and nuclear POL I activity decreased with the length of the asphyctic period while POL-I mRNA and protein levels were unchanged. Accompanying the decrease in brain pH we found significant changes of nucleolar structure in the course of perinatal asphyxia at the light and electron microscopic level. As early as ten min following the asphyctic insult, morphological disintegration of the nucleolus was observed. The changes became more dramatic with longer duration of perinatal asphyxia. We conclude that severe acidosis may be responsible for decreased POL activity and for disintegration of nucleoli in neurons. This condition may lower the ribosome content in neonatal neurons and impair protein synthesis.

Altered expression of Bcl-2, Bcl-X, Bax, and c-Fos colocalizes with DNA fragmentation and ischemic cell damage following middle cerebral artery occlusion in rats

Permanent occlusion of the middle cerebral artery in rats was used to assess the effects of focal ischemia on the expression of members of the bcl-2 family which have been implicated in the regulation of programmed cell death. Intraluminal occlusion of one middle cerebral artery for 6 h resulted in histologically detectable brain damage within the ipsilateral caudate putamen, basolateral cortex and parts of the thalamus. In the infarcted basolateral cortex and thalamus fragmentation of DNA was detected in many nuclei using in-situ end-labeling of DNA breaks by terminal transferase, whereas only scattered labeled nuclei were visible in the infarcted caudate putamen. Immunohistochemical analysis revealed activation of c-Fos in the infarcted cortex and thalamus and in the non-infarcted cingulate cortex as has been shown by others. A decrease in immunoreactivity for Bcl-2, and Bcl-X and an increase in immunostaining for Bax was observed exclusively in neurons within the ischemic cortex and thalamus. Within the infarcted caudate putamen, however, protein levels of all bcl-2 family members declined and c-Fos remained absent. By reverse transcription and polymerase chain reaction it was demonstrated that levels of bcl-2 mRNA markedly decreased in the ipsilateral hemisphere, whereas the amount of bax mRNA was elevated. These findings suggest that a shift in the ratio of cell death repressor Bcl-2 to cell death effector Bax and a concomitant activation of c-Fos may contribute to neuronal apoptosis in the infarcted thalamus and cortex.

Heme oxygenase-1 (HO-1) protein induction in rat brain following focal ischemia

The induction of the heme oxygenase-1 (HO-1) protein, also called HSP32, was compared to HSP70 heat shock protein induction following focal ischemia. Adult Sprague-Dawley male rats (n = 14) were subjected to either 30 min or 2 h of focal cerebral ischemia using the suture, middle-cerebral-artery (MCA) occlusion model. Controls (n = 4) had sham surgery. Following 24 h of reperfusion, subjects were killed and their brains stained immunocytochemically for HO-1 and the HSP70 heat shock proteins. One day following 30 min of ischemia, HO-1 and HSP70 staining in striatum occurred mainly in endothelial cells in infarcts and in glial cells surrounding the areas of infarction. Following the 30 min ischemia HO-1 was not induced in cortex whereas HSP70 was induced in cortical neurons in the MCA distribution. One day following 2 h of MCA ischemia, both HO-1 and HSP70 were induced in neurons in cortex in the MCA distribution. HO-1, however, was induced in glial cells throughout ipsilateral cortex, inside as well as outside the MCA distribution. This suggests that translation and/or transcription of the HO-1 and HSP70 genes are blocked in neurons and glia destined to die within infarcts, whereas translation of these stress genes continues in the endothelial cells. The duration of ischemia required to induce HSP70 in cortical neurons appears to be less than that required to induce HO-1 in cortical glia. Prolonged spreading depression and/or diffuse hemispheric ischemia may induce HO-1 in glia throughout the ipsilateral cortex via immediate early gene activation of the AP-1 site in the HO-1 promoter. Since HO-1 degrades heme, a pro-oxidant, to antioxidant molecules, the induction of HO-1 may augment oxidative defense mechanisms compromised by cerebral ischemia.

Unchanged balance between levels of mRNA encoding AMPA glutamate receptor subtypes following global cerebral ischemia in the rat

Transient global ischemia leads to glutamate mediated delayed neuronal death in the CA1 but not in the CA3 region of the rat hippocampus, and changes in AMPA receptor subunit composition has been proposed to cause a difference in excitatory input to the CA1 and CA3 regions. In situ hybridization with riboprobes for AMPA receptor subtype GluR1-4 mRNA was performed on sections from the brain of sham operated and ischemic rats in two models (neck cuff and 4-vessel occlusion combined with hypotension) with identical results: the content of the GluR1-3 mRNA species was down regulated in the hippocampal regions CA1 and CA3 but only weak changes were observed in the dentate gyrus. The down regulation observed in CA1 was non-selective among GluR1-3, i.e. all GluR mRNA species showed approximately the same degree of down regulation. A change in calcium permeability of the AMPA channels mediated by a shift in channel sub-unit composition and corroborating an increased calcium influx is thus not supported by these findings.

Induction of c-fos, junB, c-jun, and hsp70 mRNA in cortex, thalamus, basal ganglia, and hippocampus following middle cerebral artery occlusion

Middle cerebral artery (MCA) occlusion in halothane-anesthetized rats induced c-fos, junB, and c-jun immediate early gene mRNAs and hsp70 heat shock gene mRNA in brain. In situ hybridization studies showed that c-fos and junB were induced throughout all of the cortex at 1 and 4 h following MCA occlusion. hsp70 was induced in the core and margins of the MCA ischemia. By 24 h, there was little expression of c-fos, junB, c-jun, and hsp70 in the core of the MCA infarct; there was modest induction of hsp70 at the margins of the infarct; and there was diffuse induction of c-fos, junB, and c-jun in all of the cortex outside the infarct. MCA occlusion also induced these genes in subcortical structures. c-fos, junB, and hsp70 were induced in ipsilateral medial striatum, most of thalamus including medial and lateral geniculate nuclei, substantia nigra, and hippocampus. Most of these structures, except for the striatum, are not supplied by the MCA. These data show that changes in gene expression can occur in regions remote from an infarction.

Immediate-early gene protein expression in neurons undergoing delayed death, but not necrosis, following hypoxic-ischaemic injury to the young rat brain

A unilateral hypoxia-ischaemia (HI) 21-day-old rat preparation was used to assess the effects of HI on the expression of the immediate-early gene proteins (IEGPs) c-Fos/FRAs, Fos B, c-Jun, Jun B, Jun D, Krox 20, Krox 24, and on the mRNA for the neurotrophic factor, brain-derived neurotrophic factor (BDNF). Moderate HI (15 min hypoxia) produced delayed, selective neuronal death and was associated with a rapid induction of c-Fos, Fos B, Jun B, Jun D, and c-Jun proteins, but not Krox 20 protein or BDNF mRNA, in neurons on the side of HI and also a delayed expression of c-Jun (and to a lesser extent c-Fos/FRA's and Fos B) 24-48 h after HI in neurons that underwent delayed neuronal death. Krox 24 showed an initial induction followed by a long-lasting suppression of its expression in regions undergoing cell loss. Severe HI (60 min hypoxia) resulted in seizures and rapid neuronal loss and infarction (necrotic cell death) on the side of HI, and was associated with early induction of c-Fos, Fos B, c-Jun, Jun B, Jun D, Krox 20 and Krox 24 protein and BDNF mRNA in neurons on the non-ligated side of the brain. Fos, c-Jun, Jun B, Jun D and Krox 24, but not Krox 20, Fos B, or BDNF mRNA, were also induced in non-nerve cells on the damaged side of the brain after both moderate and severe HI, and many of these cells appeared to be dividing. Thus, moderate HI induces IEGP's in neurons and non-nerve cells in damaged regions, whereas severe HI induces IEGP's and BDNF in non-damaged regions. c-Jun (and to a lesser extent c-Fos/FRA's) showed a prolonged expression in neurons undergoing delayed, but not necrotic, cell death suggesting that they may be involved in the biochemical cascade that causes selective delayed neuronal death. BDNF was not induced by HI, and therefore, does not appear to play an endogenous neuroprotective role in the CNS.

Induction of NGFI-A mRNA following middle cerebral artery occlusion in rats: in situ hybridization study

Middle cerebral artery (MCA) occlusion in halothane-anesthetized rats induced the zinc finger gene, NGFI-A, in brain. In situ hybridization studies showed that NGFI-A was induced throughout all of the cortex following MCA occlusion. By 24 h after MCA occlusion there was little expression of NGFI-A mRNA in the core of the MCA infarct, but the mRNA was still induced in all of cortex outside the infarct. MCA occlusion also induced this gene in subcortical structures: ipsilateral medial striatum; most of thalamus including medial and lateral geniculate nuclei; substantia nigra; and hippocampus at 4 h of MCA occlusion which generally disappeared by 24 h of MCA occlusion. Most of these structures, except for the striatum, are not supplied by the MCA. These data show that changes in brain gene expression can occur in many regions remote from an infarction.

MK-801, a glutamate antagonist, lowers flow threshold for inhibition of protein synthesis after middle cerebral artery occlusion of rat

The effect of the glutamate antagonist MK-801 on the ischemic threshold of energy metabolism and protein synthesis (CPS) was studied in rats submitted to 3 h occlusion of the left middle cerebral artery (MCA). Local blood flow and CPS were measured by double tracer autoradiography, and local ATP content by bioluminescence imaging. In untreated animals breakdown of energy metabolism occurred at flow values below 15 +/- 1 and CPS inhibition below 51 +/- 15 ml/100 g/min (means +/- S.D.). MK-801 treatment (3 mg/kg immediately after MCA occlusion) did not change the ischemic flow threshold of energy failure (16 +/- 3 ml/100 g/min) but lead to a highly significant decline of the perfusion threshold for the inhibition of CPS to 19 +/- 4 ml/100 g/min (P < 0.01). Our data demonstrate that MK-801 dramatically reduces the threshold for the suppression of protein synthesis which could explain previously reported therapeutical effects on the reduction of brain infarct size.

Neuronal damage after repeated 5 minutes of ischemia in the gerbil is preceded by prolonged impairment of protein metabolism

The effect of single or repeated episodes of cerebral ischemia on protein biosynthesis and neuronal injury was studied in halothane-anesthetized gerbils by autoradiography of [14C]leucine incorporation into brain proteins and light microscopy. For quantification of the protein synthesis rate, the steady-state precursor pool distribution space for labeled and unlabeled free leucine was determined by clamping the specific activity of [14C]leucine in plasma, and by measuring free tissue leucine in samples taken from various parts of the brain. Control values of protein synthesis were 14.6 +/- 2.2, 5.8 +/- 2.3, 14.2 +/- 3.1, and 10.0 +/- 3.8 nmol g-1 min-1 (means +/- SD) in the frontal cortex, striatum, CA1 sector, and thalamus, respectively. Following a single episode of 5 or 15 min of ischemia, protein synthesis recovered to normal in all brain regions except the CA1 sector, where it returned to only 50% of control after 6 h and to less than 20% after 3 days of recirculation. After three episodes of 5 min of ischemia spaced at 1 h intervals, protein synthesis remained severely suppressed in all brain regions after both 6 h and 3 days of recirculation. Inhibition of protein synthesis after 6 h predicted histological injury after 3 days of recirculation. In animals submitted to a single episode of 5 or 15 min of ischemia, histological damage was restricted to the CA1 sector but injury occurred throughout the brain after three episodes of 5 min of ischemia. These observations demonstrate that persisting inhibition of protein synthesis following cerebral ischemia is an early manifestation of neuronal injury. Prevention of neuronal injury requires restoration of a normal protein synthesis rate.

Focal ischemia in rats causes time-dependent expression of c-fos protein immunoreactivity in widespread regions of ipsilateral cortex

c-Fos protein expression was examined in brain by immunohistochemistry following permanent middle cerebral artery (MCA) occlusion above the rhinal fissure and ipsilateral common carotid artery (CCA) occlusion in Long-Evans rats. In sham-operated animals, c-fos protein-like immunoreactivity (CFPLI) was confined to neuronal nuclei of the hypothalamus and was not present in other regions including cerebral cortex. In the core territory of the MCA, CFPLI was not detected when examined at 15 and 30 min, 1, 4 and 8 h and 1, 2, 4 and 7 days after occlusion. Focal ischemia induced two temporal and spatial patterns of CFPLI. At 1 h, c-fos protein was expressed in the nuclei of many neurons in layers II-V of the ipsilateral cortex both immediately adjacent to and remote from the ischemic territory. Within regions outside the MCA territory (e.g. cingulate gyrus and piriform cortices), CFPLI in these neurons peaked at 2-4 h and was undetectable after 2 days. Neurons in the zone immediately surrounding the ischemic core within MCA territory also expressed CFPLI, but in contrast, continued to express c-fos up to 4 days after ischemia. Immunoreactivity surrounding the ischemic core was found in neuronal nuclei predominantly, although from 1 to 4 days, CFPLI was found in perikarya and dendrites as well. MK-801 (3 mg/kg, i.p., 30 min prior to occlusion) completely blocked the early c-fos protein induction in all regions but expression within neurons surrounding the ischemic core was present 1 day after a single injection.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of 70 kDa stress protein mRNA induction in gerbil brain after ischemia

Induction of mRNA encoding the 70 kDa stress/heat shock protein, hsp70, was evaluated in post-ischemic gerbil brain by in situ hybridization using an oligonucleotide probe selective for stress-inducible members of this gene family. Expression of hsp70 sequences was most pronounced in hippocampal CA1 neurons that fail to accumulate immunoreactive hsp70 protein, and that are selectively lost following ischemia. Hybridizable RNA continued to be expressed in CA1 through at least 48 h, essentially until the onset of cell death in this model. In contrast, dentate granule cells and CA2 neurons destined to survive the insult showed transient induction of hsp70 mRNA during the first 24 h of recirculation that disappeared prior to the detection of maximal hsp70 immunoreactivity in these cell populations. Pretreatment with a single injection of MK-801 (10 mg/kg) considerably attenuated the induction of hsp70 mRNA in hippocampus at 6 h of recirculation, an effect apparently mediated by persistent drug-induced hypothermia. The drug did not prevent the later, selective appearance of hsp70 hybridization in CA1 neurons at 24 h, nor did it protect against the subsequent loss of these cells. These results demonstrate a prolonged postischemic stress response at the transcriptional level in vulnerable hippocampal neurons, and suggest its utility as a marker for neuronal pathophysiology associated with mechanisms mediating delayed neuronal death.

Thymine glycols and pyrimidine dimers in brain DNA during post-ischemic reperfusion

Free-radical reactions, known to occur in the reperfused brain, damage DNA in vitro. We therefore examined the hypothesis that thymine glycols and thymine dimers, which are known to block transcription and are formed by free radical mechanisms, are formed in brain DNA during reoxygenation following ischemia. Such biochemical lesions could account for the failure of protein synthesis that occurs following an ischemic insult. Large dogs were anesthetized, instrumented, and divided into four groups: (1) non-ischemic controls; (2) 20-min cardiac arrest without resuscitation; (3) 20-min cardiac arrest, resuscitation and 2 h reperfusion; and (4) 20-min cardiac arrest, resuscitation and 8 h reperfusion. Genomic DNA was isolated from the cerebral cortex. Thymine glycols were labeled by reduction with [3H]NaBH4. Pyrimidine dimers were determined by ELISA using antibody prepared against ultraviolet irradiated DNA. The data was evaluated by Kruskal-Wallis ANOVA with alpha = 0.05. The rabbit antibodies detected the thymine dimer content in 10 pg UV irradiated DNA but did not react with normal DNA. Borohydride labeling qualitatively detected thymine glycols generated by treatment of DNA with osmium tetroxide. There was no difference between the DNAs from the experimental groups in the content of thymine glycols or pyrimidine dimers (P = 0.608 and P = 0.219, respectively). We conclude that significant quantities of thymine glycols and thymine dimers are not formed in brain DNA during post-ischemic reperfusion. Therefore, the inhibition of brain protein synthesis during reperfusion, observed by other investigators, is unlikely to be caused by interruption of transcription by these species.

Determination of RNA content in postischemic gerbil brain by in situ hybridization

Brief periods of cerebral ischemia result in prolonged inhibition of protein synthesis. In CA1 sector of hippocampus inhibition is irreversible, leading to delayed death of pyramidal neurons. In order to study the possible role of gene transcription in this process, expression of four individual RNAs was investigated in the gerbil brain after 5 min of global cerebral ischemia by in situ hybridization with the following nucleic acid probes: plasmid pMr100 (ribosomal RNA sequences), plasma pAG82 (cytochrome c oxidase sequences), plasmid p629 (amyloid A4 precursor protein of Alzheimer's disease, pre-A4 protein), and plasmid pHF beta A-1 (beta-actin sequences). Cytochrome c oxidase mRNA and ribosomal RNA did not show any changes in expression up to 48 hr after ischemia. After longer recirculation times they gradually declined in the CA1 sector of hippocampus in parallel with the morphological manifestation of delayed neuronal death. The pre-A4 mRNA transiently decreased after 8 hr of recirculation of the CA1 sector but then recovered before it finally disappeared in parallel with delayed neuronal death. The beta-actin mRNA transiently appeared to increase after 8 hr of recirculation in the stratum radiatum of hippocampus but then also declined and disappeared when CA1 neurons began to disintegrate. The possible significance of these changes in the pathogenesis of ischemic neuronal damage is discussed.

Temporal profiles of proteins responsive to transient ischemia

The responses of long and short half-lived proteins to ischemia were measured in rat brain during 6 days of recovery from 30 min of transient forebrain ischemia produced by four-vessel occlusion. At the end of the ischemic interval, the neocortical activities of four vulnerable enzymes [ornithine (ODC) and S-adenosylmethionine (SAMDC) decarboxylases, and RNA polymerases I and II] were unchanged, but within 30 min of reperfusion, their activities dropped by 25-50%. The loss of substance P in the striatum and substantia nigra was slower, reaching about 50% by 12 h. On the other hand, the activities of 5 long half-lived enzymes did not change in the neocortex at 5 and 15 h of reperfusion and regional protein concentrations were essentially unaffected over 6 days survival. The rate and extent of normalization of the amounts or activities of the vulnerable proteins varied. RNA polymerase II and ODC activities were restored within 4 h, and ODC showed a biphasic increase in activity, with peaks at 10 h and 2-3 days. RNA polymerase I and SAMDC activities were restored by 18 h and 5 days, respectively, whereas substance P concentrations did not completely recover, even at 6-15 days. The greater the regional reduction of blood flow during ischemia, the larger the net change (gain or loss) of SAMDC or ODC activity and the longer the time required to normalize the activities of these enzymes. The average rate of proteolysis, assessed by measuring the rate of clearance of 14C from protein prelabeled with [14C]bicarbonate, was abnormal during the first 2 days of reperfusion. Postischemic changes in both protein synthesis and degradation could affect the amounts of some of the proteins responsive to transient ischemia.

Changes in brain energy metabolism and protein synthesis following transient bilateral ischemia in the gerbil

The time course of the reduction in brain protein synthesis following transient bilateral ischemia in the gerbil was characterized and compared with changes in a number of metabolites related to brain energy metabolism. The recovery of brain protein synthesis was similar following ischemic periods of 5, 10, or 20 min; in vitro incorporation activity of brain supernatants was reduced to approximately 10% of control at 10 or 30 min recirculation, showed slight recovery at 60 min, and returned to 60% of control activity by 4 h. Protein synthesis activity was indistinguishable from control at 24 h. One minute of ischemia produced no detectable effect on protein synthesis measured after 30 min reperfusion; longer periods of ischemia resulted in progressive inhibition, with 5 min producing the maximal effect. Pentobarbital (50 mg/kg) increased by 1-2 min the threshold ischemic duration required to produce a given effect. Whereas most metabolites recovered quickly following 5 min ischemia, glycogen showed a delayed recovery comparable to that seen for protein synthesis. These results are discussed in relation to possible mechanisms for the coordinate regulation of brain energy metabolism and protein synthesis. An improved method for the fluorimetric measurement of guanine nucleotides is described.

Neurotransmitter amino acids in the CNS. I. Regional changes in amino acid levels in rat brain during ischemia and reperfusion

The levels of amino acids in 6 regions of the brain (cortex, hippocampus, striatum, diencephalon, stem and cerebellum) were determined during an ischemic insult of 30 min and after recovery periods of up to 10 h. The results were analyzed in two groups: putative neurotransmitters (GABA, aspartate, glutamate, taurine, glycine and alanine) and non-neurotransmitters. In the neurotransmitter group, it was found that at the end of 30 min ischemia the levels of aspartate and glutamate slightly decreased whereas those of GABA and alanine rose substantially. The amounts of glycine and taurine remained unchanged. In 30 min after the ischemic insult, there were much larger decreases in aspartate and glutamate and increases in GABA and alanine with no change in glycine and taurine. At 2 h recovery the levels of the neurotransmitter amino acids had almost returned to control values and were fully recovered by 10 h after ischemia. It is postulated that glutamate and aspartate are released during ischemia into the extracellular space and subsequently 'washed-out' into the blood during the reperfusion. Release of GABA, if it occurs, is however, compensated by increase in its synthesis and decrease in its degradation under anaerobic conditions, both of which contribute to the rise in its steady-state level. In the non-transmitter category, increases were seen in amino acids present normally in very small concentrations; tyrosine, lysine, leucine and 3 hydrophobic amino acids: valine, methionine and phenylalanine, which were most pronounced at 2 h after ischemia. It is suggested that the rise in the levels of these molecules is the consequence of stimulation of protein breakdown caused by activation of intracellular proteases by calcium and H+ during the ischemic episode. Regional variations in the patterns of changes were small although in the ischemic models used the brainstem seemed to be least affected.

Nuclear binding sites for triiodothyronine in the gerbil brain following ischemia and recirculation

The effect of cerebral ischemia and subsequent recirculation on the nuclear thyroid hormone receptors was investigated. Ischemia was produced by occlusion of the right common carotid artery in the Mongolian gerbil. The thyroid hormone receptors were measured in vitro by a [125I]triiodothyrorine (T3) binding assay with isolated nuclei and Scatchard analysis. A rapid increase of the total number of binding sites for T3 appeared within 30 min of ischemia and reached over 40% by 3 h. During the same 3-h period, the relative binding affinity was reduced by 25%. Upon recirculation after 30 min or 3 h of ischemia, a rapid reversal of measured T3 binding sites occurred, which progressed to 20-30% below the control value by the recirculation period of 3 h. If the ischemic period was only 30 min, the nuclear T3 binding capacity recovered toward the control level and the affinity constant returned normal after recirculation for 24 h. When the ischemic period was extended to 3 h, there was progressive loss of receptor sites, and no tendency for recovery of the affinity constant was observed. These results demonstrated a prompt alteration of a specific nuclear regulatory component in cerebral ischemia, which may indicate the importance of such changes within the nuclear regulatory mechanism for reversibility of cerebral function following ischemic insult.

Ionic shift in cerebral ischemia

Electrolyte and water contents were measured in gerbil brain after unilateral cerebral ischemia. Increase of Na+ and water, and decrease of K+ occurred after an ischemic period of 30 minutes. However, these abnormalities disappeared within 3 hours. When the ischemic period was extended to 3 hours, the abnormalities observed after ischemia for 30 minutes were again encountered, but more significant alterations occurred immediately after re-establishment of blood flow. In addition to more pronounced increase of Na+ and decrease of K+, Ca2+ became significantly elevated after recirculation for 15 minutes and progressively increased during recirculation for 3 hours. The steady rise of Ca2+ appears to be related to the irreversibility of cerebral ischemia.

Alterations of nuclear thyroid hormone receptors in cerebral cortex in vivo

Investigation was conducted under in vivo conditions in the adult male rat to determine the basic characteristics of the nuclear thyroid hormone receptors in the cerebral cortex. Equilibrium with cortical nuclei of an intravenous dose of triiodothyronine (T3) occurred 3 h after injection and showed a t1/2 of 1 h for dissociation. Saturation of receptors occurred at 0.5--06. ng/mg DNA. The endogenous level of binding in the normal rat was 0.07--0.1 ng/mg DNA, representing a 15% occupancy of total receptors at a serum concentration of 66 ng/dl. These characteristics were then examined under several pathophysiological conditions. In the hypothyroid rat, an apparent 37% increase in total binding sites occurred. Under either fasting conditions or insulin or glucagon administration declines in serum T3 were noted, and the endogenous binding also decreased in parallel. Only glucagon produced a significant reduction in total binding sites. Under the hypoxic condition produced by maintenance under a 7% oxygen atmosphere, a slight increase in apparent total binding sites was found with no change in endogenous binding level. Severe narcosis resulted in no effects on T3 binding parameters. These results demonstrate specific alterations of thyroid hormone receptors that may be important physiologically.

Effect of hypoxia on nucleic acid and protein synthesis in different brain regions

The incorporation of [methyl-3H]thymidine into DNA, of [5-3H]uridine into RNA, and of [1-14C]leucine into proteins of cerebral hemispheres, cerebellum, and brainstem of guinea pigs after 80 hr of hypoxic treatment was measured. Both in vivo (intraventricular administration of labeled precursors) and in vitro (tissue slices incubation) experiments were performed. The labeling of macromolecules extracted from the various subcellular fractions of the above-mentioned brain regions was also determined. After hypoxic treatment the incorporation of the labeled precursors into DNA, RNA, and proteins was impaired to a different extent in the three brain regions and in the various subcellular fractions examined; DNA and RNA labeling in cerebellar mitochondria and protein labeling in microsomes of the three brain regions examined were particularly affected.

Cerebral ischemia in gerbils: polyribosomal function during progression and recovery

Cerebral ischemia was produced by clipping the right common carotid artery in Mongolian gerbils. Polyribosomal function in cerebral ischemia during progression and recovery was studied by investigation of morphology (electronmicroscopy), physical property (size distribution profiles) and biochemical property (polypeptide synthesis). Polyribosomes and their function were relatively well preserved during progression of ischemia. The most striking finding was an extensive disaggregation of polyribosomes and suppression of polypeptide synthesis immediately after re-establishment of cerebral circulation. These phenomena occurred not only with irreversible ischemia at 3 h but also with reversible ischemia at 30 min. In the latter, disaggregation of polyribosomes gradually recovered, but no tendency for recovery was observed after an ischemic period of 3 h. The disaggregation and delay in reaggregation of ribosomes after re-establishment of cerebral circulation may be a significant factor in the irreversibility of cerebral ischemia. The observed deterioration of cellular function during the recovery process may have an important implication not only for medical management of stroke but also for surgical recirculation during acute stroke.

Phosphorylation of chromatin proteins in cerebral anoxia and ischemia

Phosphorylation of nuclear protein was investigated in cerebral anoxia up to 30 min with rabbit brain and in cerebral ischemia up to 6 h with gerbil brain in vitro. Isolated nuclei were incubated in the presence of [gamma-32P]ATP and were then fractionated into the NaCl-soluble, HCl-soluble, and phenol-soluble protein fraction. Each protein fraction was further separated by gel electrophoresis, and profiles of 32P incorporation were evaluated in these pathophysiological conditions. 32P incorporation of the acidic phenol-soluble nonhistone chromatin protein became significantly suppressed in cerebral anoxia after 15 min, and there were decreases of 32P incorporation in protein with high molecular weight and increase in protein with low molecular weight on gel electrophoresis. With gerbil brain nuclei, 32P incorporation into the NaCl-soluble and HCl-soluble fraction was increased without significant decrease in the phenol-soluble fraction after an ischemic period of 3 h. However, further separation of the phenol-soluble fraction demonstrated decrease of 32P incorporation in protein with high molecular weight and increase in protein with low molecular weight. At present, the significance of these findings, particularly in relation to chromatin template activity or irreversibility of these pathophysiological conditions, is not clear.

Aminoacid incorporation into polyribosomes of ischaemic and reperfused gerbil brain

Aminoacid incorporation into polyribosomes from the gerbil brain in a cellfree system is strongly affected by experimental ischaemia. Progression of the impairment of the protein synthesis in vitro occurs even following early reperfusion.