Exercise-induced gene expression in soleus muscle is dependent on time after spinal cord injury in rats

Cycling exercise attenuates atrophy in hindlimb muscles and causes changes in spinal cord properties after spinal cord injury in rats. We hypothesized that exercising soleus muscle expresses genes that are potentially beneficial to the injured spinal cord. Rats underwent spinal cord injury at T10 and were exercised on a motor-driven bicycle. Soleus muscle and lumbar spinal cord tissue were used for messenger RNA (mRNA) analysis. Gene expression of brain-derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF) was elevated 11- and 14-fold, respectively, in soleus muscle after one bout of exercise performed 5 days after spinal cord transection. Also, c-fos and heat shock protein-27 (HSP27) mRNA abundance were increased 11- and 7-fold, respectively. When exercise was started 2 days after the injury, the changes in gene expression were not observed. By contrast, at 2 but not at 5 days after transection, expression of the HSP27 gene was elevated sixfold in the lumbar spinal cord, independent of exercise. Electromyographic activity in soleus muscles was also decreased at 2 days, indicating that the spinal cord was less permissive to exercise at this early time. Long-term exercise for 4 weeks attenuated muscle atrophy equally well in rats started at 2 days or 5 days after injury. We conclude that BDNF and GDNF released from exercising muscle may be involved in exercise-induced plasticity of the spinal cord. Furthermore, the data suggest that the lumbar spinal cord undergoes time-dependent changes that temporarily impede the ability of the muscle to respond to exercise.     

c-Jun expression after cerebral hyperstimulation differs between rats and marmosets

Immediate early genes (IEGs) are a fundamental element in the way we respond and adapt to a variety of stimuli. We have recently reported that IEG response, as measured by c-Fos expression, is different between rodents and primates. Here, we further extend this analysis by assessing the expression of c-Jun, one of the main complements of c-Fos, under the same stimulation protocol. For this, we investigated the immunohistochemical expression of c-Jun (and compared with that previously shown for c-Fos) after stimulation with pentylenetetrazol in the cingulate gyrus, motor cortex, piriform cortex, inferior temporal cortex, and visual cortex of rats and marmosets (Callithrix jacchus), both male and female. Overall the immunohistochemical expression of c-Jun was more intense but remained elevated for a shorter duration in marmosets as compared to rats. These results are in contrast to what we had previously shown for c-Fos. Furthermore, in terms of the temporal profile, c-Fos and c-Jun expression occurred in a complementary manner in rats—the peak of c-Fos expression coincided with low levels of c-jun expression—and in a superimposed manner in marmosets—the peak of c-Fos expression coincided with the peak of c-Jun expression. Since Fos proteins may form dimers with Jun proteins and together control late gene expressions in the cell nucleus, this different expression profile between primates and rodents may bear meaningful impact for how the nervous system reacts and adapts to stimulation.     

Hypothermic prevention of nuclear DNA fragmentation in gerbil hippocampus following transient forebrain ischemia

The protective effect of hypothermia on DNA fragmentation following transient forebrain ischemia in mongolian gerbils was investigated. The DNA fragmentation demonstrated in situ in gerbil hippocampal CA1 was compared between intra- and post-ischemic hypothermia. Intra- ischemic hypothermia prevented the DNA fragmentation in hippocampal CA1 completely while severe DNA damage was observed in post-ischemic hypothermia group. The degree of DNA fragmentation of hippocampal CA1 in the post-ischemic hypothermia group was equal to that in the ischemic control group. The results suggest that hypothermia during a transient forebrain ischemia exerts a protective effect on the post-ischemic hippocampal damage by preventing the DNA fragmentation in CA1 neurons. [Neurol Res 1995; 17; 461-464]     

Induction of DNA fragmentation and HSP72 immunoreactivity by adenovirus-mediated gene transfer in normal gerbil hippocampus and ventricle

Foreign genes have been successfully transferred and expressed in experimental animal brains using adenoviral vectors. However, it is not fully understood whether adenovirus-mediated gene transfer causes stressful or cytotoxic injury in brain. A replication-defective adenoviral vector containing the Escherichia coli lacZ gene (AdCMVnLacZ) was directly injected into right hippocampus and lateral ventricle of normal gerbil brains. Temporal and spatial profiles of the expression of lacZ gene products, DNA fragmentation detected by terminal deoxynucleotidyl d-UTP nick end labeling (TUNEL) staining, and heat shock protein 72 (HSP72) immunoreactivity were examined until 21 days after the injection. In the ventricle, lacZ gene was immediately and strongly expressed at 8 hr after the injection of AdCMVnLacZ, with a peak at 1–3 days, and disappeared by 21 days. Although a small number of choroid plexus cells were TUNEL positive at 3 and 7 days, no HSP72 immunostaining was observed in the ventricle. Small-to-moderate expression of lacZ gene was found in the needle route from 8 hr to 3 days after the injection, and a small number of TUNEL-positive cells were detected at the needle track at 1–3 days. In the hippocampus, lacZ gene was markedly expressed around the dentate gyrus (DG) at 8 hr to 3 days with a peak at 1 day. Large number of TUNEL or moderate-to-dense HSP70 staining cells were also detected in the same area. CA1 neuronal cells just adjacent to the needle route showed TUNEL positivity at 1 to 3 days. However, the TUNEL staining was not associated with lacZ gene expression. The majority of lacZ-expressing cells were discriminated from the TUNEL-positive cells, whereas some were double-positive with HSP72 staining in DG. Cellular loss was observed in the CA1 layer around the needle route. An apoptotic change was morphologically observed in the marginal region of the DG at 1–3 days and in the ventricle at 3–7 days. In the sham control group, TUNEL-positive or HSP72-staining cells were only detected around the needle track including CA1 cells adjacent to the needle route. These data suggest that adenoviral gene transfer may induce direct traumatic injury in the CA1 sector near the needle route, indirect apoptotic cell loss in the DG and ventricle, and stressful effect on the dentate granule cells in association with adenovirus infection in normal gerbil brain. J. Neurosci. Res. 54:38–45, 1998. © 1998 Wiley-Liss, Inc.     

Relationship between magnitude of hypothermia during ischemia and preventive effect against post-ischemic DNA fragmentation in the gerbil hippocampus

Protective effect of hypothermia against DNA fragmentation in hippocampal CA1 field after transient forebrain ischemia in gerbils was evaluated by changing the magnitude of hypothermia. Inhibition of DNA fragmentation was proportional to the magnitude of hypothermia. The result indicates that, in terms of susceptibility to ischemia, hippocampal CA1 neurons are sensitive to a relatively small decrement of temperature, with temperatures ≤35°C being critical for the prevention of apoptotic process following transient forebrain ischemia.     

Biphasic Expression of the Fos and Jun Families of Transcription Factors Following Transient Forebrain Ischaemia in the Rat. Effect of Hypothermia

Transient global ischaemia induces the expression of immediate early genes. Using in situ hybridization, the expression of c- fos, fosB, fra-1, fra-2 , c- jun and junB was studied after 15 min of normothermic and hypothermia (33°C) transient forebrain ischaemia in the rat, induced by common carotid occlusion combined with systemic hypotension. Two phases of induction of the immediate early genes were observed. The early phase, peaking at 1–2 h of reperfusion, was dominated by marked expression in the dentate gyrus. The second phase, with maximal expression at 12–36 h of reperfusion, was observed particularly in the vulnerable CA1 and CA3 regions. Hypothermia increased the early induction of one of the genes studied, signifying a differential effect of hypothermia upon the signal transduction mechanisms activating these genes. The late induction occurred earlier after hypothermic than after normothermic ischaemia. The early expression of immediate early genes is due to the rapid activation of cytosolic response elements caused by the ischaemic insult. We suggest that the late induction is a stress signal for activation of repair processes, analogous to the cellular response seen after UV light-induced DMA damage. The relatively fast induction of the immediate early genes following hypothermic ischaemia may reflect a faster resumption of normal intracellular signalling, enhancing neuronal recovery.     

Fos induction and persistence, neurodegeneration, and interneuron activation in the hippocampus of epilepsy-resistant versus epilepsy-prone rats after pilocarpine-induced seizures

Previous studies demonstrated that the spiny rat Proechimys guyannensis exhibits resistance to experimental epilepsy. Neural activation was studied in the Proechimys hippocampus, using Fos induction, within 24 h after pilocarpine-induced seizures; neurodegenerative events were investigated in parallel, using FluoroJade B histochemistry. These parameters were selected since pilocarpine-induced limbic epilepsy is known to elicit immediate early gene expression and cell loss in the hippocampus of seizure-prone laboratory rodents. At variance with matched experiments in Wistar rats, pilocarpine injection resulted in Proechimys in seizure episodes that, as previously reported, did not develop into status epilepticus. At 3 h and 8 h after seizure onset, Fos immunoreactivity filled the dentate gyrus of both rat species, and was quite marked in pyramidal cells of the Proechimys Ammon's horn. At 24 h, Fos immunoreactivity dropped in the Wistar hippocampus and persisted in Proechimys. At 8 h and 24 h, FluoroJade-stained neurons were very few in the Proechimys hippocampus, whereas they were abundant in that of Wistar rats. Double immunohistochemistry for Fos and parvalbumin, the protein expressed by fast-spiking hippocampal interneurons, indicated that Fos was induced up to 24 h in the vast majority of parvalbumin-containing cells of the Proechimys hippocampus, and in a minority of these cells in the Wistar hippocampus. The findings demonstrate that early postepileptic neurodegeneration is very limited in the Proechimys hippocampus, in which sustained Fos induction persists for several hours. The findings also indicate that Fos induction and persistence may not correlate with seizure intensity and may not be associated with neuronal death. Finally, the data implicate differential mechanisms of interneuron activity in anti-convulsant and pro-convulsant phenomena.     

An immunohistochemical study of MAP2 and clathrin in gerbil hippocampus after cerebral ischemia

Changes in MAP2 and clathrin immunoreactivity were studied in gerbil hippocampus after transient cerebral ischemia. MAP2 immuno-reactivity decreased significantly by 1 h in the subiculum-CA1 and CA2 areas which correspond to reactive change, while no decrease was observed in CA1 until day 4. Before the initiation of delayed neuronal death, MAP2 immunoreactivity was not changed in CA1. On the other hand clathrin immunoreactivity increased in the pyramidal cell layer of CA1 by 3 h after ischemia and remained high for 2 days. Clathrin immunoreactivity in the pyramidal cell layer of CA1 diminished after delayed neuronal death. The transient change of clathrin was noted especially in CA1 in the period prior to delayed neuronal death. These results imply an abnormal change in clathrin turnover after ischemia, which may participate in the pathogenesis of delayed neuronal death.     

Hyperbaric oxygenation prevents delayed neuronal death following transient ischaemia in the gerbil hippocampus

The mechanism of the neuroprotective effect of hyperbaric oxygenation remains unclear although its clinical benefits have been well recognized for human ischaemic neuronal disease. The preventive effect of hyperbaric oxygenation against delayed neuronal death was investigated in the gerbil following transient forebrain ischaemia. Delayed neuronal death in the gerbil was produced by clips on both the common carotid arteries (10 min). Morphological examination was carried out after several protocols of hyperbaric oxygenation, modified from the protocols for human ischaemic neuronal disease. Neurons in the hippocampal CA₁ were well preserved in the gerbils treated with hyperbaric oxygenation, more so than in the gerbils with no hyperbaric oxygenation. Moreover, more neurons were preserved in the CA₁ treated with hyperbaric oxygenation within 6 h of the ischaemia, than when the hyperbaric oxygenation was started 24 h after the ischaemia. The induction of heat shock proteins (HSP72 and HSP27) became weaker in the gerbils with hyperbaric oxygenation than in those without hyperbaric oxygenation, as seen immunohistochemically. We also observed an increase in dense bodies, that were shown to be lysosomes and myelinoid structures in the cytoplasm of the neurons ultrastructurally, in the hippocampus with hyperbaric oxygenation. However, no oxygen toxicity to the neurons was detected, up to at least two atmospheres absolute. This experimental system was useful to investigate the preventive mechanism of hyperbaric oxygenation against delayed neuronal death in the gerbil, and to determine the clinical indications and the most effective protocol for hyperbaric oxygenation for ischaemic neuronal damage in the human brain.     

Synergistic induction of HSP40 and HSC70 in the mouse hippocampal neurons after cerebral ischemia and ischemic tolerance in gerbil hippocampus.

An ischemia-induced gene was screened using a differential display technique in mouse transient forebrain ischemia. One of the ischemia-responsive clones was found to encode mouse hsp40. HSP40 has a critical regulatory function in the HSC70 ATPase activity. Expression of hsp40 mRNA was low in the nonischemic mouse hippocampus, but it was significantly upregulated 4 hr after ischemia by Northern blot analysis. In situ hybridization analysis revealed hsp40 mRNA induction in the neuron. HSP40 protein expression was also enhanced in the pyramidal and dentate granular neurons from 2 to 4 days after ischemia. The temporal expression and distribution profile of HSC70 protein was similar to that of HSP40, and both proteins were colocalized in ischemic hippocampal neurons. In the gerbil transient forebrain ischemia model, both HSP40 and HSC70 proteins were expressed strongly in ischemia-resistant CA3 neurons and dentate granule cells 1 day after 5 min ischemia, but were not expressed in vulnerable CA1 neurons. However, both proteins were in parallel expressed in the tolerance-acquired CA1 neurons. Based on the current observation that both HSP40 and HSC70 proteins were synergistically expressed in the ischemia-resistant and tolerance-acquired neurons, cochaperone HSP40 may play a significant role against postischemic neuronal response and lead to cell survival through interaction with simultaneously induced HSC70.     

Ultrastructural investigation of the CA1 region of the hippocampus after transient cerebral ischemia in gerbils

Summary Ultrastructural damage leading to delayed neuronal death was investigated in the mid-CA1 region of the hippocampus from the stratum (str.) moleculare to oriens after transient bilateral forebrain ischemia in Mongolian gerbils. After ischemia for 5 min without recirculation, mild swelling of the peripheral part of the apical and basal dendrites was already apparent in the str. moleculare and str. oriens. Mitochondria in the dendrites were also swollen in the same area. During recirculation for 12 h to 3 days, swelling of the dendritic cytoplasm persisted with formation of microvacuoles, but swelling of mitochondria receded. Microvacuolation and loss of microtubules were also observed in the proximal part of the dendrites during this period, and swelling and disruption of internal cristae were observed in mitochondria after recirculation for 3 days. The dendrites became severely degenerated after recirculation for 4 days. In the pyramidal cell bodies, no abnormality was observed at the end of ischemia for 5 min, but disaggregation of polyribosomes and swelling of the endoplasmic reticulum were observed 12 h after recirculation. Proliferation of the endoplasmic reticulum in parallel arrays occurred after recirculation for 1 day and persisted. Severe degeneration of the pyramidal cell bodies was obvious after recirculation for 4 days. The findings observed in the present investigation suggested that the neuronal structure most vulnerable to ischemia was the peripheral part of the dendrites and postischemic neuronal damage occurred early in this part of the dendrites.Supported by the grant NS-06663 from the National Institutes of Health, U.S. Public Health Service     

Co-localization of somatostatin mRNA and parvalbumin in the dorsal rat hippocampus after cerebral ischemia

Following transient global ischemia most of the neurons containing somatostatin in the fascia dentata of the dorsal hippocampal formation die, while somatostatinergic neurons in the CA1 region survive. These neurons react to ischemia with a transiently reduced expression of somatostatin mRNA and peptide. We have tested the hypothesis that this selective vulnerability is solely related to those somatostatinergic neurons which do not express the calcium-binding protein parvalbumin. Postischemic changes were studied in rat dorsal hippocampus at 2 and 16 days after 10 min of global cerebral ischemia using a four-vessel occlusion model. We performed a double-staining visualizing the mRNA coding for somatostatin by non-radioactive in situ hybridization and parvalbumin protein by immunocytochemistry. Only 5% of the somatostatinergic cells in the fascia dentata contained parvalbumin. The number of somatostatinergic cells was permanently reduced following ischemia. Among surviving neurons we found cells with and without parvalbumin expression. Thus, expression of parvalbumin is not predictive for survival of somatostatinergic cells in the fascia dentata. In contrast, in CA1, 37% of the somatostatinergic cells contained parvalbumin. These cells were unaffected by the transient ischemic period. The somatostatinergic cells lacking parvalbumin showed transiently reduced mRNA levels at day 2, but recovered to control values at the 16th postischemic day. Thus, expression of the calcium-buffering protein parvalbumin coincides with resistance of somatostatinergic neurons in CA1 to transient effects of ischemia. We conclude that the calcium-buffering capacity of parvalbumin may partially contribute to the protection of somatostatinergic neurons from ischemia in the dorsal hippocampus. However, the survival of somatostatinergic cells without parvalbumin indicates the importance of other factors as well. © 1995 Wiley-Liss, Inc.     

大鼠脑缺血再灌流后海马区一氧化氮合酶活性的变化

目的 :观察鼠全脑缺血再灌流后海马区NOS活性的变化。方法 :采用大鼠 4血管关闭方法制作全脑缺血再灌流模型。实验动物分为假手术组、缺血 10min组、再灌注 1、2、3d组 ,测定脑缺血再灌流后海马区NOS活性的变化。结果 :全脑缺血再灌注后海马组织NOS活性被激活上调。结论 :NO可能参与了海马CA1区迟发性神经元死亡 (DND)的发生。     

脑缺血再灌注后海马CA1区谷氨酸的表达变化及氟桂利嗪的影响

目的　观察暂短性脑缺血再灌注后沙土鼠海马区谷氨酸的表达变化以及氟桂利嗪干预的影响。方法　按照Kirino的方法 ,制作缺血再灌注模型。于缺血再灌注后 1、2、7天采取免疫组化方法检测谷氨酸表达 ,并于 7天在电镜和光镜下观察组织学变化。结果　缺血再灌注组 1天及 2天海马CA1区谷氨酸表达增高 (P <0 .0 1) ,7天恢复正常。光镜及电镜可见给药组存活的神经元数目明显多于缺血再灌注组 (P <0 .0 1)。结论　谷氨酸表达增高可能是鼠脑海马区迟发性神经元死亡的原因之一 ,氟桂利嗪可抑制谷氨酸的表达 ,对缺血的神经元起保护作用。     

Role of HSP70 in motoneuron survival after excitotoxic stress in a rat spinal cord injury model in vitro

The outcome for gait recovery from paralysis due to spinal lesion remains uncertain even when damage is limited. One critical factor is the survival of motoneurons, which are very vulnerable cells. To clarify the early pathophysiological mechanisms of spinal damage, an in vitro injury model of the rat spinal cord caused by moderate excitotoxicity was used. With this preparation we investigated whether motoneuron survival was dependent on the expression of the neuroprotective protein HSP70. In the present study excitotoxicity evoked by kainate induced delayed (24 h) loss (35%) of motoneurons, which became pyknotic with translocation of the cell death biomarker apoptosis‐inducing factor (AIF) to the nucleus. This process was concomitant with suppression of locomotor network electrical activity. Surviving cells showed strong expression of HSP70 without nuclear AIF. The HSP70 inhibitor VER155008 per se induced neurotoxicity similar to that of kainate, while the HSP90 inhibitor geldanamycin did not damage spinal tissue. Electrophysiological recording following kainate or VER155008 indicated depression of motoneuron field potentials, with decreased excitability and impaired synaptic transmission. When these two drugs were applied together, more intense neurotoxicity emerged. Our data indicate that HSP70 was one important contributor to motoneuron survival and suggest that enhancing HSP70 activity is a potential future strategy for neuroprotecting these cells.     

Amphetamine and cocaine do not increase Narp expression in rat ventral tegmental area,nucleus accumbens or prefrontal cortex,but Narp may contribute to individual differences in responding to a novel environment

Narp is an immediate early gene product that acts extracellularly to cluster AMPA receptors at excitatory synapses. The present study tested the hypothesis that drugs of abuse alter Narp expression and thereby influence AMPA receptor transmission in addiction-related circuits. Immunohistochemical studies demonstrated the existence of Narp-positive cells in hippocampus, prefrontal cortex (PFC) and nucleus accumbens (NAc), with lower levels of staining in the ventral tegmental area (VTA). To study the effects of psychomotor stimulants, Narp levels were quantified by Western blotting and normalized to actin. There were no differences in Narp levels in any brain region between rats treated with repeated saline injections, a single amphetamine injection (5 mg/kg), repeated amphetamine injections (5 mg/kg x 5 days), or repeated cocaine injections (20 mg/kg twice daily x 7 days). We also examined the possible role of Narp in individual differences in responding to a novel environment, a predictor of behavioural responses to psychomotor stimulant drugs including the propensity to acquire drug self-administration. Narp levels in the PFC, but not other regions, were significantly correlated with locomotor activity in a novel environment. These findings suggest that differential Narp expression in the PFC may be involved in determining individual vulnerability to drugs of abuse, perhaps by influencing the activity of its excitatory projections.     

Characterization of spinal HSP72 induction and development of ischemic tolerance after spinal ischemia in rats

Induction of heat shock protein (HSP72) has been implicated in the development of ischemic tolerance in several tissue organs including brain and spinal cord. In the present study, using an aortic balloon occlusion model in rats, we characterized the effect of transient noninjurious (3 or 6 min) or injurious intervals (10 min) of spinal ischemia followed by 4-72 h of reflow on spinal expression of HSP72 and GFAP protein. In a separate group of animals, the effect of ischemic preconditioning (3 or 6 min) on the recovery of function after injurious interval of spinal ischemia (10 min) was studied. After 3 min of ischemia, there was a modest increase in HSP72 protein immunoreactivity in the dorsal horn neurons at 12 h after reperfusion. After 6 min of ischemia, a more robust and wide spread HSP72 protein expression in both dorsal and ventral horn neurons was detected. The peak of the expression was seen at 24 h after ischemia. At the same time point, a significant increase in spinal tissue GFAP expression was measured with Western blots and corresponded morphologically with the presence of activated astrocytes in spinal segments that had been treated similarly. After 10 min of ischemia and 24 h of reflow, a significant increase in spinal neuronal HSP72 expression in perinecrotic regions was seen. Behaviorally, 3 min preconditioning ischemia led to the development of a biphasic ischemic tolerance (the first at 30 min and the second at 24 h after preconditioning) and was expressed as a significantly better recovery of motor function after exposure to a second 10-min interval of spinal ischemia. After 6 min ischemic preconditioning, a more robust ischemic tolerance at 24 h after preconditioning then seen after 3-min preconditioning was detected. These data indicate that 3 min of spinal ischemia represents a threshold for spinal neuronal HSP72 induction, however, a longer sublethal interval (6 min) of preconditioning ischemia is required for a potent neuronal HSP72 induction. More robust neurological protection, seen after 6 min of preconditioning ischemia, also indicates that HSP72 expression in spinal interneurons seen at 24 h after preconditioning may represent an important variable in modulating ischemic tolerance observed during this time frame.     

大鼠脑缺血再灌注后星形胶质细胞反应性变化差异与海马CA1区的迟发性神经元死亡

BACKGROUND： Blood supply to the hippocampus is not provided by the middle cerebral artery. However, previous studies have shown that delayed neuronal death in the hippocampus may occur following focal cerebral ischemia induced by middle cerebral artery occlusion.
OBJECTIVE： To observe the relationship between reactive changes in hippocampal astrocytes and delayed neuronal death in the hippocampal CA1 region following middle cerebral artery occlusion.
DESIGN, TIME AND SETTING： The immunohistochemical, randomized, controlled animal study was performed at the Laboratory of Department of Neurology, Tongji Hospital, Tongji Medical College, Huazhong University of Science and Technology, from July to November 2007.
MATERIALS： Rabbit anti-glial fibrillary acidic protein （GFAP） （Neomarkers, USA）, goat anti-rabbit IgG （Sigma, USA） and ApoAlert apoptosis detection kit （Biosciences Clontech, USA） were used in this study. METHODS： A total of 42 healthy adult male Wistar rats, aged 3–5 months, were randomly divided into a sham operation group （n = 6） and a cerebral ischemia/reperfusion group （n = 36）. In the cerebral ischemia/reperfusion group, cerebral ischemia/reperfusion models were created by middle cerebral artery occlusion. In the sham operation group, the thread was only inserted into the initial region of the internal carotid artery, and middle cerebral artery occlusion was not induced. Rats in the cerebral ischemia/reperfusion group were assigned to a delayed neuronal death （＋） subgroup and a delayed neuronal death （–） subgroup, according to the occurrence of delayed neuronal death in the ischemic side of the hippocampal CA1 region following cerebral ischemia.
MAIN OUTCOME MEASURES： Delayed neuronal death in the hippocampal CA1 region was measured by Nissl staining. GFAP expression and delayed neuronal death changes were measured in the rat hippocampal CA1 region at the ischemic hemisphere by double staining for GFAP and TUNEL.
RESULTS： After 3 days of ischemia/reperfusion, astrocytes with abnormal morphology were detected in the rat hippocampal CA1 region in the delayed neuronal death （＋） subgroup. No significant difference in GFAP expression was found in the rat hippocampal CA1 region at the ischemic hemisphere in the sham operation group, delayed neuronal death （＋） subgroup and delayed neuronal death （–） subgroup （P 〉 0.05）. After 7 days of ischemia/reperfusion, many GFAP-positive cells, which possessed a large cell body and an increased number of processes, were activated in the rat hippocampal CA1 region at the ischemic hemisphere. GFAP expression in the hippocampal CA1 region was greater in the delayed neuronal death （＋） subgroup and delayed neuronal death （–） subgroup compared with the sham operation group （P 〈 0.01）. Moreover, GFAP expression was significantly greater in the delayed neuronal death （–） subgroup than in the delayed neuronal death （＋） subgroup （P 〈 0.01）. After 30 days of ischemia/reperfusion, GFAP-positive cells were present in scar-like structures in the rat hippocampal CA1 region at the ischemic hemisphere. GFAP expression was significantly greater in the delayed neuronal death （＋） subgroup and delayed neuronal death （–） subgroup compared with the sham operation group （P 〈 0.05）. GFAP expression was significantly lower in the delayed neuronal death （–） subgroup than in the delayed neuronal death （＋） subgroup （P 〈 0.05）. The delayed neuronal death rates were 42% （5/12）, 33% （4/12） and 33% （4/12） at 3, 7 and 30 days, respectively, followingischemia/reperfusion. No significant differences were detected at various time points （χ2 = 0.341, P 〉 0.05）.
CONCLUSION： The activation of astrocytes was poor in the hippocampal CA1 region during the early stages of ischemia, which is an important reason for delayed neuronal death. Glial scar formation aggravated delayed neuronal death during the advanced ischemic stage.     

Immunohistochemical localization of lysosomal cysteine protease cathepsins B and L in monkey hippocampal neurons after transient ischemia

The mechanism by which hippocampal neurons are selectively vulnerable to ischemic injury remains unclarified. Neuronal lysosomes are known to contain the cysteine protease cathepsins, which may be involved in the mechanism of delayed neuronal death. In this study, the expression and localization of cathepsins in the postischemic hippocampal neurons of the monkey were examined. Enzymatic activities and protein levels of cathepsins B and L were increased after ischemia in both the vulnerable CA1 sector and the remaining resistant sectors. Immunohistochemical analysis suggested that lysosomal enzymes of CA1 were localized mainly in the neuropil and not in the neuronal cell bodies, while the enzymes of CA2–4 sectors were located within the neurons and associated with the perinuclear lysosomal granules. Thus, it was concluded that distributional differences of cathepsins B and L after transient ischemia could be related to selective CA1 neuronal death in the hippocampus.     

重组人粒细胞集落刺激因子对糖尿病脑缺血大鼠神经细胞凋亡及血管内皮生长因子表达的影响

目的探讨重组人粒细胞集落刺激因子(rhG-CSF)对糖尿病脑缺血大鼠神经细胞凋亡及血管内皮生长因子(VEGF)表达的影响。方法制备糖尿病大鼠大脑中动脉栓塞模型;对模型鼠采用rhG-CSF50μg/(kg.d)皮下注射;分别于注射后7d、14d和21d采用神经功能评分(NSS)量表进行评分;对脑组织切片予以TUNEL染色,计数脑缺血周边区神经细胞凋亡数;免疫组化法检测脑组织VEGF表达。结果与对照组比较,rhG-CSF组各时间点NSS明显降低(均P<0.01);脑缺血周边区的TUNEL阳性细胞数明显减少(均P<0.01);VEGF蛋白免疫阳性细胞明显增多(均P<0.01)。结论rhG-CSF通过增加糖尿病脑组织缺血后VEGF蛋白的表达,减轻神经细胞的凋亡而发挥脑保护作用。