应激对大鼠行为和部分脑区谷氨酸含量的影响

以旷场试验法测定动物在急、慢性躯体性和心理性应激时的行为变化,以快速断头冷冻匀浆法,用ＨＩＴＡＣＨＩ－８３５氨基酸分析仪测定应激各期视皮层、海马、下丘脑、小脑谷氨酸含量。并对正常动物经侧脑室微量注射Ｌ－ＡＰ４后观察行为变化。结果显示,急性应激期动物行为活动增加,慢性应激期减少：应激时,大鼠部分脑区的谷氨酸含量与对照组相比在不同时期呈显著性差异;侧脑室微量注射Ｌ－ＡＰ４提示行为活动减弱可能与脑内Ｇｌｕ系统的活动有关。     

强迫性冷水游泳应激对大鼠行为和海马神经颗粒素的影响

为考察应激对海马神经颗粒素含量和磷酸化水平的影响,以及神经颗粒素是否涉及应激所致行为效应的脑机制,采用强迫性冷水游泳应激模型,选取40只Sprague-Dawley大鼠,随机分为应激组、装置对照组和正常对照组1和正常对照组2。以旷场试验法测定应激前后大鼠行为的变化,以Western blotting技术测定大鼠海马区域神经颗粒素的总含量和磷酸化水平,并分析两者之间的相互关系。结果表明：应激组动物活动增加,表现出焦虑行为;而海马区域神经颗粒素含量降低,与对照组相比差异具有显著性;且多项行为指标的变化与海马神经颗粒素含量的改变呈显著相关。这些结果提示神经颗粒素有可能在应激所致焦虑行为中起作用,可作为预测应激所致焦虑行为的较为敏感的指标之一。慢性应激过程中海马区域没有发现神经颗粒素的磷酸化反应。     

慢性应激对大鼠空间学习记忆及海马和前脑皮层突触体膜流动性的影响

慢性应激对学习记忆功能的影响是神经科学的热点问题, 在脑内, 海马和前额叶是与学习记忆功能密切相关的重要脑区, 也是应激易累及损伤的主要靶区。膜流动性的改变在神经细胞功能活动中起重要作用。为探讨慢性应激对大鼠空间学习记忆功能的影响及前脑皮层和海马突触体膜流动性的作用。采用多因素慢性应激动物模型, 通过开场试验和Morris水迷宫测试大鼠行为及空间学习记忆能力; 并且测定大鼠前脑皮层和海马突触体膜流动性和突触体内游离Ca2+浓度的变化。研究结果显示, 与对照组相比, 应激组大鼠在应激后即刻, 在新异环境中的自发活动和探究行为显著降低(p<0.05, p<0.01), 空间学习记忆能力明显下降(p<0.05, p <0.01); 并且应激组大鼠前脑皮层和海马突触体膜流动性显著降低(p <0.05, p <0.01); 而突触体内游离Ca2+浓度的显著增加 (p <0.05, p <0.01)。停止应激后一周, 应激大鼠的各项指标有所恢复, 但仍未达到正常水平。研究结果提示, 慢性应激引起大鼠明显的开场行为改变和空间学习记忆功能障碍, 这些变化可能与突触体膜流动性和突触体内游离Ca2+浓度的变化密切相关。     

急性生理应激对大鼠的行为及脑神经颗粒素磷酸化水平的影响

突触特异性蛋白质在应激所致行为效应的中枢机制中的可能角色日益受到关注。神经颗粒素（Neurogranin,NG）是一种新发现的突触特异性蛋白质,主要分布在前额叶、杏仁核和海马区域,参与突触结构和功能可塑性机制,可能涉及到应激所致行为效应中枢机制。但是,关于NG、应激和行为之间的关系国内外尚缺乏系统的研究报道。本研究主要是探讨急性生理应激对大鼠行为和NG的作用,以及NG的变化与应激性行为效应之间的相互关系。以急性强迫性冷水游泳应激,建立生理应激动物模型。将40只雄性SD大鼠随机分为游泳应激组1（SS1,接受游泳应激和行为测试）、游泳应激组2（SS2,接受游泳应激而不接受行为测试）、正常对照组1（C1,接受行为测试）和正常对照组（C2,不给予任何处理）（n=10）。以旷场行为和高架十字迷宫任务来评定大鼠应激后的行为变化,Western blotting方法测定海马和前脑皮层中的NG含量和磷酸化水平。结果表明：应激后SS1组的呆滞行为增加,与C1组比较,差异有显著性, P<0.01; SS1组海马的NG含量和NG磷酸化水平增高,与C1和C2组相比,差异有显著性,均为P<0.05; SS1组皮层的NG含量增高,与C1和C2组相比,差异有显著性,均为P<0.01;SS1组皮层的NG磷酸化水平增高,与C1组相比,差异具有显著性,P<0.01;前脑皮层的NG磷酸化水平与呆滞行为之间的相关达显著水平。提示该应激源能诱发动物明显的恐惧反应,呆滞行为是反映急性生理应激导致行为障碍的敏感的行为学指标,海马和前脑皮层均是对急性生理应激反应敏感的脑区。NG的磷酸化水平可能是反映急性生理应激所致行为障碍的一项新的生物学指标     

海马NMDA受体经SP-NK1受体通路参与慢性应激诱发的抑郁样行为

为探讨海马N-甲基-D-天冬氨酸(N-methyl-D-aspartic acid, NMDA)受体与P物质(Substance P, SP)及其神经激肽1 (neurokinin1, NK1)受体在慢性不可预见性温和应激(chronic unpredictable mild stress, CUMS) 中的作用及其关系, 通过建立CUMS动物模型, 大鼠海马微量注射给药, 测量大鼠体重, 并采用糖水偏爱测试、旷场实验和悬尾实验等方法对大鼠进行行为学检测, 运用高效液相色谱(HPLC)法分析大鼠海马组织中SP和谷氨酸(glutamate, Glu)的含量变化。结果显示, CUMS诱发大鼠表现出明显的抑郁样行为, 海马组织中SP和Glu水平显著增加; 海马注射NMDA, 大鼠表现出与CUMS/SAL组相似的抑郁样行为, 且海马组织中SP的含量比正常对照组显著增加; 微量注射NK1受体阻断剂CP-96345和/或NMDA受体阻断剂MK-801后, 大鼠抑郁样行为明显改善, 且MK-801使CUMS导致的大鼠海马P物质水平升高得到明显控制, 而CP-96345没有明显改变CUMS引起的海马Glu水平升高; CP-96345使NMDA引起的抑郁样行为得到极显著改善。以上结果表明, 慢性应激引起大鼠海马Glu过量释放, 通过激活NMDA受体, 促进P物质合成释放增加, 激活NK1受体, 是导致抑郁样行为发生的重要途径之一。     

慢性应激损害大鼠学习记忆且抑制海马及额叶FGF2蛋白表达

慢性应激能够影响学习和记忆等认知功能。海马和额叶是与学习和记忆联系密切的脑区, 参与信息的获得、保持及提取。碱性成纤维生长因子(FGF2)对神经元发生、存活以及损伤修复具有重要促进作用, 目前成为神经系统退行性疾病相关研究的热点。本研究旨在探索慢性应激如何影响大鼠学习和记忆能力, 以及这一过程中FGF2蛋白在海马和额叶中表达的改变。实验中将16只雄性SD大鼠随机分为对照组和慢性应激组, 采用慢性不可预见温和刺激建立大鼠慢性应激模型, 通过Morris水迷宫实验及Y迷宫实验检测学习与记忆功能的改变, 并对海马及额叶中FGF2蛋白的表达情况进行Western blot及免疫组织化学检测。结果发现, 5周慢性应激导致大鼠学习和记忆能力受损, 海马及额叶FGF2蛋白表达下调。因此认为, FGF2蛋白可能参与慢性应激损害学习记忆能力的机制, 提示FGF2可能是诊断和治疗神经系统退行性病变的分子靶目标。     

急性情绪应激对大鼠行为和脑神经颗粒素磷酸化水平的影响

为探讨急性情绪应激对大鼠旷场行为的影响,以及脑神经颗粒素（Neuroganin,NG）变化与应激性行为效应之间的相互关系。以急性不确定性空瓶刺激,建立情绪应激动物模型。将40只雄性SD大鼠随机分为情绪应激组1（ES1,接受情绪应激和旷场测试）、情绪应激组2（ES2,只接受情绪应激）、正常对照组1（C1,无情绪应激,但接受旷场测试）和正常对照组（C2,无情绪应激,也无旷场测试）（n=10）。以旷场行为和高架十字迷宫任务来评定大鼠应激后的行为变化,Western印迹杂交法（Western blotting）测定海马和前脑皮层中的NG含量和磷酸化水平。结果表明：（1） 应激后ES1组的水平活动增加,与C1组比较,差异有显著性, p<0.01;（2）ES1组海马和前脑皮层的NG磷酸化水平高于C1和C2组,差异有显著性, 均为p<0.05; ES2组的前脑皮层NG的磷酸化水平高于C1组,差异有显著性,为p<0.05;（3） 海马的NG磷酸化水平与水平活动之间的相关达显著水平。提示急性情绪应激能导致动物明显的行为改变如焦虑,这种行为改变可能与脑内NG磷酸化水平的变化有关。水平活动可能是反映急性情绪应激的较敏感行为指标,海马NG磷酸化水平可能是预测急性情绪应激所致焦虑或抑郁行为的较敏感生物学指标     

慢性应激对大鼠行为和免疫细胞热休克蛋白70表达的影响

目的：研究慢性不确定应激对大鼠急性整体热水浴后外周血和脾脏免疫细胞热休克蛋白70（Heat shock protein 70, HSP70）表达的影响。方法：随机将大鼠分成慢性应激组和控制组（每组14只）。通过4周的慢性不确定性应激诱发实验组大鼠明显的抑郁行为,此期间控制组大鼠正常饲养。随后给予大鼠42度整体热水浴刺激,维持直肠温度41度25min。热刺激后6h,采用流式细胞仪测定大鼠外周血和脾脏免疫细胞HSP70 水平。结果：与控制组大鼠相比,慢性应激大鼠在急性热刺激后HSP70合成明显减少。控制组大鼠的所有被检测的免疫细胞热应激后HSP70合成均明显增加。相反,慢性应激大鼠仅在外周血的单核细胞和粒细胞检测到HSP70合成增加,同时升高的水平明显低于控制组大鼠。结论：慢性应激降低大鼠免疫细胞HSP70的热诱导反应,提示HSP70保护性作用减弱可能参与了慢性应激损害免疫细胞功能的生物学过程     

不同应激范式对大鼠行为和脑神经颗粒素含量的影响

为探讨慢性情绪应激、生理应激对大鼠旷场行为和脑神经颗粒素（Neurogranin,NG）含量的不同作用,以及NG含量变化与应激性行为效应之间的相互关系。分别以不确定性空瓶刺激和饮水剥夺,建立情绪应激和生理应激动物模型。将40只雄性SD大鼠随机分为情绪应激组（ES）、生理应激组（PS）、定时饮水组（C1）和正常对照组（C2）（n=10）。以旷场行为任务来评定大鼠应激后的行为变化,Western blotting方法测定海马和前脑皮层中的NG含量。结果表明：应激后四组大鼠海马的NG含量差异无显著性;ES组前脑皮层的NG含量低于C2组,差异具有显著性,p<0.01;PS组的前脑皮层NG含量也下降,但与C2组相比差异无显著性; 应激后ES组、PS组修饰行为多于C2组,差异具有显著性,分别为p<0.01,p<0.05;前脑皮层NG含量与修饰行为之间的相关达显著水平。提示慢性情绪和生理应激均能导致前脑皮层NG含量下降,修饰行为增加,情绪应激作用更显著。修饰行为可能是反映情绪状态的较敏感行为指标,前脑皮层NG水平可能是预测情绪应激所致焦虑或抑郁行为的较敏感生物学指标。     

高压氧对小鼠学习记忆及脑细胞形态结构的影响

实验用两种行为模型（旷场行为模型和Ｙ－迷宫分辨学习模型）观察了幼龄小鼠在不同压力的高压氧处理后,对新异环境的探究行为和自发活动情况,以及学习记忆能力的变化;并用ＸＹ－生物医学电脑图像分析仪分析了与学习记忆相关的脑区（大脑皮层、海马）神经元密度,细胞核面积,胞核／胞浆比值的变化。结果表明：（１）与对照组相比,吸０.１ＭＰａ高压氧的幼鼠学习记忆能力明显提高,相关脑区的神经元密度、细胞核面积、胞核／浆比均显著增加。（２）吸０.２５ＭＰａ高压氧的幼鼠学习记忆能力与对照组相比无明显变化,但其在新异环境中的自发行为明显减少。提示：慢性吸入０.１ＭＰａ高压氧有利于促进幼鼠脑的生长发育,增强脑功能活动。     

Locomotor, avoidance,and maze behavior in rats with selective disruption of hippocampal output.

Behavioral correlates of selective disruption of hippocampal output were investigated in a series of five experiments. In two experiments an attempt was made through behavioral investigation to determine whether the CA1 neurons project to the fimbria or to the subiculum. The results supported recent views that the subiculum is the recipient of CA1 axons. Disruption of the CA1 output in the dorsal hippocampus of rats produced increased open-field activity, whereas passive avoidance and spontaneous alternation behaviors remained unchanged. No differentiation was obtained between CA1 damage and neocortical lesions in maze learning. Blocking of the fimbrial CA3 output from the dorsal hippocampus improved passive avoidance performance and impaired active avoidance performance, whereas open-field and spontaneous alternation behaviors were unaffected. Interruption of the CA3 output from the ventral hippocampus improved active avoidance performance and reduced spontaneous alternation behavior. Open-field behavior and passive avoidance performance remained unchanged. Total fimbrial sections increased open-field activity, improved passive and active avoidance, and reduced spontaneous alternation. The results are discussed in terms of functional differentiation between the CA1 and CA3 of the dorsal hippocampus and in terms of functional differences in the fimbrial CA3 output from the dorsal and ventral hippocampus.     

Differential effects of predator stress and the antidepressant tianeptine on physiological plasticity in the hippocampus and basolateral amygdala

Stress can profoundly affect memory and alter the functioning of the hippocampus and amygdala. Studies have also shown that the antidepressant tianeptine can block the effects of stress on hippocampal and amygdala morphology and synaptic plasticity. We examined the effects of acute predator stress and tianeptine on long-term potentiation (LTP; induced by 100 pulses in 1 s) and primed burst potentiation (PB; a low threshold form of LTP induced by only five physiologically patterned pulses) in CA1 and in the basolateral nucleus (BLA) of the amygdala in anesthetized rats. Predator stress blocked the induction of PB potentiation in CA1 and enhanced LTP in BLA. Tianeptine blocked the stress-induced suppression of PB potentiation in CA1 without affecting the stress-induced enhancement of LTP in BLA. In addition, tianeptine administered under non-stress conditions enhanced PB potentiation in the hippocampus and LTP in the amygdala. These findings support the hypothesis that acute stress impairs hippocampal functioning and enhances amygdaloid functioning. The work also provides insight into the actions of tianeptine with the finding that it enhanced electrophysiological measures of plasticity in the hippocampus and amygdala under stress, as well as non-stress, conditions.     

Electroconvulsive stimulations prevent stress-induced morphological changes in the hippocampus

Stress can precipitate major depression and other disorders linked to hippocampal shrinkage. It is hypothesized but not established that treatment of these disorders reverses and prevents the hippocampal changes. Dendritic retraction of individual neurons might in concert with other pathophysiological events contribute to the shrinkage phenomenon. Animal studies have shown that various stress paradigms can induce dendritic retraction in the CA3 pyramidal neurons of the hippocampus. Since electroconvulsive treatment is the most effective treatment in humans with major depression, we investigated whether repeated electroconvulsive stimulations (ECSs) could influence such changes in stressed rats. Furthermore, we investigated whether ECSs per se could influence neuronal branching and total length of the CA3 hippocampal neuronal dendritic tree in normal rats. Rats were stressed using the 21-day 6 h daily restraint stress paradigm. The study shows that stress caused remodelling of the pyramidal neurons by significantly reducing the number of dendritic branch points and total length of the apical dendritic tree. Concomitant administration of ECSs prevented these effects. ECSs had no effect on pyramidal neuron dendrites in normal rats.     

Loss of activity-dependent Arc gene expression in the retrosplenial cortex after hippocampal inactivation: interaction in a higher-order memory circuit

The rodent hippocampus is well known for its role in spatial navigation and memory, and recent evidence points to the retrosplenial cortex (RSC) as another element of a higher order spatial and mnemonic circuit. However, the functional interplay between hippocampus and RSC during spatial navigation remains poorly understood. To investigate this interaction, we examined cell activity in the RSC during spatial navigation in the water maze before and after acute hippocampal inactivation using expression of two immediate-early genes (IEGs), Arc and Homer 1a (H1a). Adult male rats were trained in a spatial water maze task for 4 days. On day 5, the rats received two testing/training sessions separated by 20 min. Eight minutes before the second session, different groups of rats received bilateral intrahippocampal infusion of tetrodotoxin (TTX), muscimol (MUS), or vehicle. Another group of rats (uni-TTX) received infusion of TTX in one hippocampus and vehicle in the other. Signals from Arc and H1a RNA probes correspond to the post- and pre-infusion sessions, respectively. Bilateral TTX and MUS impaired spatial memory, as expected, and decreased Arc expression in CA1 of hippocampus. Importantly, bilateral inactivation of hippocampus resulted in loss of behavior-induced Arc expression in RSC. Despite a lateralized effect in CA1, Arc expression was equivalently and bilaterally decreased in RSC of uni-TTX rats, consistent with a network level interaction between hippocampus and RSC. We conclude that the loss of hippocampal input alters activity of RSC neurons and compromises their ability to engage plastic processes dependent on IEG expression.     

记忆过程中海马CA1区神经元的集群放电特征

观察空间工作记忆过程中海马CA1区神经元群的放电特征。应用多通道神经元集群放电记录技术, 同步观察和记录清醒大鼠在执行延迟选择任务时的行为轨迹以及海马CA1区神经元的放电活动。发现：海马CA1区位置细胞的位置野是在学习过程中逐渐形成并可消退; 部分位置细胞的放电对未来目标定向性行为具有预测作用; 在空间工作记忆过程中, 神经元放电之间的相关性加强, 神经元之间以及神经元与局部场电位之间存在相位编码方式。结果提示海马CA1区神经元参与对空间信息的初级编码和加工, 并为未来行为决策提供有效信息, 而且海马对信息的加工是通过局部神经网络进行, 时间编码可能是海马信息加工的重要方式之一。     

Hippocampal associative cellular responses: dissociation with behavioral responses revealed by a transfer-of-control technique

Multiunit activity was recorded in the CA3 field of the dorsal hippocampus in freely moving rats during classical conditioning and subsequent presentation of the CS on operant baselines for food reward as well as shock avoidance. Rats were first trained in a nonsignaled bar-pressing-dependent shock omission task and in a food-motivated lever-pressing task (60-s VI). Five sessions with presentations of a previously habituated tone as a CS paired with footshock as a US were then given. Testing was carried out by presenting the CS alone while behavioral responses were maintained by reinforcement in both instrumental tasks on alternate sessions. As expected, the CS induced a marked suppression of lever pressing for food reward and a marked enhancement of bar-pressing for shock avoidance. The analysis of the frequency of multiunit discharges to the CS revealed that the hippocampal cellular responses established during classical conditioning were maintained while two different behavioral responses were exhibited to the CS. The results showed that the associative response of hippocampal neurons may be dissociated from the Pavlovian conditioned responses the CS elicits. They support the hypothesis that hippocampal cellular responses represent a neural index of the acquired CS-US associative representation.     

Open Field Motor Patterns and Object Marking, but Not Object Sniffing, Are Altered by Ibotenate Lesions of the Hippocampus

Objectmarking and object sniffing were assessed in an open field during six 5-min trials in unoperated Long-Evans rats and rats with ibotenate lesions of the hippocampus and/or neocortex. Object marking was higher in hippocampally lesioned rats than in unoperated rats. Object marking did not differ between neocortically lesioned rats and unoperated rats. Object sniffing durations and visits did not differ between unoperated and hippocampally lesioned rats nor between unoperated and neocortically lesioned rats. A new object elicited longer sniffing by both unoperated and hippocampally lesioned rats. Neocortically lesioned rats did not show this effect. There were no effects of the new object on marking. Computerized tracing of open field paths revealed a smaller perimeter track for hippocampally lesioned rats than for unoperated rats. This difference reflected distinct ambulatory patterns. Hippocampally lesioned rats made stereotyped hind-limb pivots at each corner, while normal rats used forelimb pivots or reared and reoriented adjacent to the wall. Rearing was lower in hippocampally lesioned rats, and higher in neocortically lesioned rats, than in unoperated rats. These data indicate that investigative object behavior (sniffing) is resistant to the effects of hippocampal damage, while object-elicited marking and motoric output may be profoundly altered. The data on sniffing suggest either that (1) the noticeability of the objects used elicited investigative behaviors in hippocampally damaged rats comparable to those of novelty-induced exploration in normal rats or (2) object exploration is not used to create a spatial map, and, hence, not disturbed by hippocampal loss. Object marking may require spatial locale information to be exercised normally, or may index the mediation of an olfactory-modulated behavioral pattern through the hippocampal system.     

Phase-dependent synaptic changes in the hippocampal CA1 field underlying extinction processes in freely moving rats

Recent studies focus on the functional significance of a novel form of synaptic plasticity, low-frequency stimulation (LFS)-induced synaptic potentiation in the hippocampal CA1 area. In the present study, we elucidated dynamic changes in synaptic function in the CA1 field during extinction processes associated with context-dependent fear memory in freely moving rats, with a focus on LFS-induced synaptic plasticity. Synaptic transmission in the CA1 field was transiently depressed during each extinction trial, but synaptic efficacy was gradually enhanced by repeated extinction trials, accompanied by decreases in freezing. On the day following the extinction training, synaptic transmission did not show further changes during extinction retrieval, suggesting that the hippocampal synaptic transmission that underlies extinction processes changes in a phase-dependent manner. The synaptic potentiation produced by extinction training was mimicked by synaptic changes induced by LFS (0.5 Hz) in the group that previously received footshock conditioning. Furthermore, the expression of freezing during re-exposure to footshock box was significantly reduced in the LFS application group in a manner similar to the extinction group. These results suggest that LFS-induced synaptic plasticity may be associated with the extinction processes that underlie context-dependent fear memory. This hypothesis was supported by the fact that synaptic potentiation induced by extinction training did not occur in a juvenile stress model that exhibited extinction deficits. Given the similarity between these electrophysiological and behavioral data, LFS-induced synaptic plasticity may be related to extinction learning, with some aspects of neuronal oscillations, during the acquisition and/or consolidation of extinction memory.     

Environmental enrichment protects against the effects of chronic stress on cognitive and morphological measures of hippocampal integrity

Chronic stress has detrimental effects on hippocampal integrity, while environmental enrichment (EE) has beneficial effects when initiated early in development. In this study, we investigated whether EE initiated in adulthood would mitigate chronic stress effects on cognitive function and hippocampal neuronal architecture, when EE started one week before chronic stress began, or two weeks after chronic stress onset. Adult male Sprague Dawley rats were chronically restrained (6h/d) or assigned as non-stressed controls and subdivided into EE or non-EE housing. After restraint ended, rats were tested on a radial arm water maze (RAWM) for 2-d to assess spatial learning and memory. The first study showed that when EE began prior to 3-weeks of chronic stress, EE attenuated chronic stress-induced impairments in acquisition, which corresponded with the prevention of chronic stress-induced reductions in CA3 apical dendritic length. A second study showed that when EE began 2-weeks after the onset of a 5-week stress regimen, EE blocked chronic stress-induced impairments in acquisition and retention at 1-h and 24-h delays. RAWM performance corresponded with CA3 apical dendritic complexity. Moreover, rats in EE housing (control or stress) exhibited similar corticosterone profiles across weeks, which differed from the muted corticosterone response to restraint by the chronically stressed pair-housed rats. These data support the interpretation that chronic stress and EE may act on similar mechanisms within the hippocampus, and that manipulation of these factors may yield new directions for optimizing brain integrity and resilience under chronic stress or stress related neuropsychological disorders in the adult.     

Activity-stress increases density of GFAP-immunoreactive astrocytes in the rat hippocampus

Although past research has indicated that stress and the accompanying increase in glucocorticoids compromises hippocampal neurons, little is known about the effect of stress on hippocampal glial cells. In the current study, male rats were exposed to activity-stress (A-S) for six days; this comprised housing with an activity wheel and restricted access (1h/day) to food. Physiological data (e.g., relative adrenal and thymus weights, gastric ulceration) suggested that the A-S rats experienced more stress than pair-fed (no wheel) and control (fed ad libitum, no wheel) rats. Whereas stress did not influence the quantitative morphology of glial fibrillary acidic protein (GFAP)-immunoreactive cells, a semi-quantitative analysis revealed that the A-S rats had significantly more (30%) GFAP-immunoreactive cells in the hippocampal CA3 region than the control rats. Based on the present findings, it appears that the hippocampal astrocytic response to chronic stress may be similar to the response found in endangered, or challenged hippocampal environments, such as in ischemia.