Hirokazu Ueda

Microtubule-associated protein 2 as a sensitive marker for cerebral ischemic damage--immunohistochemical investigation of dendritic damage.

We investigated the neuronal distribution of microtubule-associated protein 2 in gerbil brain and monitored the progression of ischemic damage immunohistochemically by using this protein as a dendritic marker. The reaction for microtubule-associated protein 2 in normal gerbil brain clearly visualized neuronal soma and dendrites but other structures such as axonal bundles, glia and endothelial cells exhibited little immunoreactivity. In a reproducible gerbil model of unilateral cerebral ischemia, we could detect the ischemic lesions as early as 3 min after right common carotid occlusion at the subiculum-CA1 region of the ipsilateral hippocampus as faint loss of the reaction in the dendrites. After ischemia for 30 min, the ischemic lesions were clearly detected as loss of the reaction in the nerve cell bodies, dendrites and the neuropil in the hippocampus, cerebral cortex, thalamus and the caudoputamen. Although the mechanism for prompt disappearance of the immunohistochemical reaction for microtubule-associated protein 2 is not clear, the present investigation suggests that dendrites in the vulnerable regions may be quite susceptible to ischemic stress and that the immunohistochemical procedure for microtubule-associated protein 2 may be very useful for demonstration of dendritic damage in various pathophysiological states of the central nervous system.

Exposure of Astrocytes to Hypoxia/Reoxygenation Enhances Expression of Glucose-Regulated Protein 78 Facilitating Astrocyte Release of the Neuroprotective Cytokine Interleukin 6

Abstract: Astrocytes exposed to hypoxia (H) or hypoxia/reoxygenation (H/R) maintain cell viability and display changes in protein biosynthesis. Sodium dodecyl sulfate‐polyacrylamide gel electrophoresis of metabolically labeled astrocytes exposed to H showed induction of an ≈78‐kDa polypeptide that demonstrated sequence identity with glucose‐regulated protein (GRP) 78. Cell lysates from H/R astrocytes displayed induction of neuroprotective interleukin (IL) 6, which was present in a high‐molecular‐weight complex also containing GRP78, suggesting that GRP78 might be functioning as a chaperone during cellular stress consequent on H/R. Introduction of anti‐sense oligonucleotide to GRP78 into astrocytes prevented expression of the protein and suppressed H/R‐induced astrocyte release of IL‐6 by ≈50%. These data indicate that modulation of astrocyte properties during oxygen deprivation results, in part, from intracellular glucose depletion and subsequent expression of GRP78, which sustains generation of neuroprotective IL‐6 under the stress of H/R.

Metabolic and biosynthetic alterations in cultured astrocytes exposed to hypoxia/reoxygenation.

To investigate the astrocyte response to hypoxia/reoxygenation, as a model relevant to the pathogenesis of ischemic injury, cultured rat astrocytes were exposed to hypoxia. On restoration of astrocytes to normoxia, there was a dramatic increase in protein synthesis within 3 h, and sodium dodecyl sulfate‐polyacrylamide gel electrophoresis of metabolically labeled astrocyte lysates showed multiple induced bands on fluorograms. Levels of cellular ATP declined during the first 3 h of reoxygenation and the concentration of AMP increased to ± 3.6 nmol/mg of protein within 1 h of reoxygenation. Reoxygenated astrocytes generated oxygen free radicals early after replacement into ambient air, and addition of diphenyliodonium, an NADPH oxidase inhibitor, diminished the generation of free radicals as well as the induction of several bands on fluorogram. Although addition of cycloheximide on reoxygenation resulted in inhibition of both astrocyte protein synthesis and accumulation of cellular AMP, it caused cell death within 6 h, suggesting the importance of protein synthesis in adaptation of hypoxic astrocytes to reoxygenation. Potential physiologic significance of biosynthetic products of astrocytes in hypoxia/reoxygenation was suggested by the recovery of glutamate uptake. These results indicate that the astrocyte response to hypoxia/reoxygenation includes generation of oxygen free radicals and de novo synthesis of products that influence cell viability and function in ischemia.

The effect of the calcium antagonist nimodipine on the gerbil model of experimental cerebral ischemia.

The gerbil model was used to assess the therapeutic effects of the calcium antagonist nimodipine on cerebral ischemia. Transient cerebral ischemia was produced in each gerbil by bilateral common carotid occlusion of 10-, 15- or 20-min duration. Nimodipine (0.01 or 0.1 mg/kg) was administered intraperitoneally just before the carotid occlusion or 10-30 min after the removal of the arterial clips. Morbidity of each animal was evaluated using the stroke index, and the sum of stroke indices was calculated for evaluating the overall morbidity during a particular period of reperfusion. Mortality was observed for 24 hours after clip removal. Although, depending on the timing of the drug administration, the low-dose (0.01 mg/kg) nimodipine worsened the morbidity in the gerbils with 10-min ischemia, the high-dose (0.1 mg/kg) of the drug had a clear beneficial effect on the mortality associated with cerebral ischemia. These results are considered worthwhile for further trials to assess the usefulness of nimodipine as a therapeutic agent in the management of the acute ischemic stroke.

Induced resistance and susceptibility to cerebral ischemia in gerbil hippocampal neurons by prolonged but mild hypoperfusion

Brief periods of non-lethal cerebral ischemia can induce resistance against subsequent lethal ischemia. In this study, asymptomatic gerbils after unilateral carotid artery ligation were subjected to 5 min of forebrain ischemia. The prolonged but mild hypoperfusion, by carotid occlusion, induced susceptibility at 1 day and tolerance at 30 days to lethal ischemia in the hippocampal neurons. The neuroprotective effect correlated well with induction of heat shock protein 72 in the hippocampal neurons. These results suggested that neuronal cells possess a cellular response to sublethal hypoperfusion and can survive forthcoming ischemic stress.

Temporal profile of serum albumin extravasation following cerebral ischemia in a newly established reproducible gerbil model for vasogenic brain edema: a combined immunohistochemical and dye tracer analysis

SummaryWe investigated the temporal profile of the extravasation of serum albumin in a reproducible gerbil model of unilateral cerebral ischemia, using immunohistochemical and dye-tracer techniques to evaluate albumin accumulation and the occurrence of active extravasation, respectively. After 30 min of cerebral ischemia and subsequent reperfusion, immunostaining for albumin became visible in the lateral part of the thalamus during the first 3 h, and then expanded to other brain regions up to 24 h. At both 24 h and 3 days after reperfusion, massive extravasation of albumin was noted in the whole ischemic hemisphere, and this had decreased again by 7 days after reperfusion. The extent and the degree of albumin immunopositivity were almost the same in all animals examined at each period after reperfusion. The extravasation of Evans blue, which was allowed to circulate for 30 min before death, was limited to the lateral part of the thalamus during the first 6 h of reperfusion. In the circumscribed area of massive albumin extravasation, many neurons were immunopositive for albumin; most of these neurons appeared to be intact and also showed immunostaining for microtubule-associated protein 2. The current investigation clearly demonstrated that (1) albumin extravasation was produced with reliable reproducibility in this model, (2) the lateral part of the thalamus was the region most vulnerable to ischemic blood-brain barrier damage, and (3) many apparently intact neurons in the ischemic region were positive for albumin.

The characteristics of blood-brain barrier in three different conditions — infarction, selective neuronal death and selective loss of presynaptic terminals — following cerebral ischemia

SummaryWe investigated the extravasation of serum albumin using immunohistochemistry in three different conditions, i.e., infarction, selective neuronal death and selective loss of presynaptic terminals following cerebral ischemia in gerbils. In selective neuronal death, which is typically found in the CA1 neurons of the hippocampus after 5-min bilateral cerebral ischemia, selective damage of postsynaptic components with intact presynaptic sites was demonstrated by immunohistochemical examination for microtubule-associated protein 2 and synapsin I, and albumin extravasation did not become apparent before postsynaptic structures were destroyed. In cerebral infarction, which was consistently observed in the thalamus after 15-min forebrain ischemia, massive albumin extravasation was visible early after ischemia due probably to the ischemic endothelial necrosis. In selective loss of presynaptic terminals, which was detected at the molecular layer of the dentate gyrus in the contralateral, nonischemic hippocampus after unilateral cerebral ischemia, immunoreaction for albumin was not visualized. Since endothelium and glial cells were intact in morphological aspects in selective damage of both pre- and postsynaptic sites, it was thought that extravasation was facilitated by the stimulation of endothelial cells and glial cells with unknown factors that were induced by the destruction of post- but not presynaptic elements.

Induction of 72-kDa Inducible Heat Shock Protein (HSP72) in Cultured Rat Astrocytes After Energy Depletion

Abstract: Protein synthesis is important in the readaptive processes for cultured astrocytes after hypoxia and subsequent reoxygenation. We have identified 72‐kDa inducible heat shock protein (HSP72) as a major stress protein in reoxygenated astrocytes. To assess the mechanism for reoxygenation‐mediated induction of HSP72, a reporter gene that consists of a human HSP promoter fused to the luciferase gene was transfected into cultured astrocytes. Analysis of cellular energy nucleotides showed an increase of the ADP/ATP ratio after reoxygenation, which synchronized with activation of the HSP promoter. Activation of the HSP promoter was also observed after an addition of iodoacetic acid to hypoxic astrocytes, which reached the maximum when the ADP/ATP ratio reached 50%, but further decline in the energy profile caused inactivation of this promoter. Inhibition of protein synthesis after reoxygenation resulted in temporary restoration of the energy profile and suppression of the DNA binding activity of the heat shock factor. Addition of quercetin greatly decreased the [3H]leucine incorporation in the polysome fraction without any effect on the mature mRNA formation. These data suggest that the energy depletion in reoxygenation triggers induction of HSP72 after reoxygenation, which may act as a pivotal mediator in the stress response of reoxygenated astrocytes by facilitating protein synthesis.

N-Acetylaspartate to Total Creatine Ratio in the Hippocampal CA1 Sector after Transient Cerebral Ischemia in Gerbils: Influence of Neuronal Elements, Reactive Gliosis, and Tissue Atrophy

The authors compared temporal profiles of Nacetylaspartate (NAA) and the NAA/total creatine ratio with neuronal and astrocytic densities and with tissue atrophy in the hippocampal CA1 sector of gerbils after 5-minute bilateral forebrain ischemia and subsequent reperfusion for up to 6 months. The CA1 sector was dissected from 20-μm lyophilized sections (n = 5) for NAA, phosphocreatine, and creatine assays using high-performance liquid chromatography. Adjacent 10-μm sections were used for immunohistochemical analysis to follow neuronal and astrocytic responses. The NAA concentration was significantly (P<0.01) decreased after 7 days but leveled off thereafter. The NAA/total creatine (phosphocreatine + creatine) ratio was significantly decreased after 7 days and further decreased (P<0.05) after 6 months. Extensive neuronal damage developed beyond 7 days, while reactive astrogliosis progressed throughout the observation period. There was a good linear correlation (P<0.01) between astroglial density and the NAA/total creatine ratio beyond 7 days. The thickness of the CA1 sector was significantly reduced after 1 month and further reduced after 6 months. Although both NAA level and the NAA/total creatine ratio seemed to be indicators of neuronal damage, the latter could be influenced by reactive astrogliosis with progression of tissue atrophy.

Zinc-deficiency increases infarct size following permanent middle cerebral artery occlusion in rats

Abstract In view of the potential relationship between cerebral ischemia and zinc status, this study was designed to examine whether dietary zinc-deficiency would affect the outcome of focal cerebral ischemia in rats. Forty-five male Sprague-Dowley rats were randomly divided into five groups: (1) eight rats received a semi-purified zinc-deficient diet containing less than 0.38mg/100g of zinc for 1 week (ZD-1w); (2) eleven rats received the same diet as described as above for 2 weeks (ZD-2w); (3) ten rats, named pair-fed control group (PF-2w), received a zinc-supplemented diet and matched by the amount of diet equal to that consumed by ZD-2w group for 2 weeks; (4) ad libitum-fed control group received the same diet as taken by PF-2w animals for 1 week (AF-1w, n=6) and (5) the remaining 10 rats were named as no-fed (NF) group, in which the rats were directly subjected to cerebral ischemia without entering the feeding process. After experiencing the dieting stage for 1 or 2 weeks, or without (NF group), respectively, the animals were subjected to permanent occlusion of the middle cerebral artery (MCA). Plasma zinc concentration and the cerebral infarct volume were determined at 24 hours of ischemia. The final level of zinc in NF and AF-1w rats was 139±5 and 127±6 μg/100 ml, respectively. The zinc-deficient diet reduced the concentration by 52% in ZD-1w and by 64% in ZD-2w group. The increment in infarct size in ZD-1w group was inconspicuous. However, treatment with zinc-deficient diet for 2 weeks increased the total infarct volume by 118%, 88%, 58% and 47% as compared with NF, AF-1w, PF-2w and ZD-1w rats, respectively. Especially, the cortical infarct volume (206±35 mm 3 ) in ZD-2w group was 98–227% larger than those in the other groups (p