Different glial reactions to hippocampal stab wounds in young adult and aged rats

Brain injury induces reactive gliosis. To examine the activation of glial cells after brain injury in young versus aged rats, we used a brain stab-wound model and examined the expression of cells positive for ED1 (ED1(+)) and glial fibrillary acidic protein (GFAP(+)) in the hippocampus in young-mature (3 months) and aged (25 months) Wistar rats at various times following hippocampal stab injury. ED1(+) cells appeared more frequently in the aged rats than in the young-mature rats under control conditions, whereas the number of GFAP(+) cells was not different between two groups. Following the stab wound, there was an increase in ED1 expression that was delayed but stronger in the aged rats and that persisted longer; the increase of the number of GFAP(+) cells also persisted longer. We conclude that different glial reactivity in the aged brain suggests that aging is associated with increased glial responsiveness that may enhance susceptibility to injury and disease in the brain.     

Different response of senescent female Sprague-Dawley rats to gemfibrozil and rosiglitazone administration

Eighteen-month-old Sprague-Dawley rats present age-related alterations in lipid and glucose metabolism and are resistant to the effect of PPARalpha-activating hypolipidemic drugs, such as gemfibrozil. We tested if these animals were responsive to the administration of rosiglitazone, an insulin-sensitizer acting on PPARgamma. We determined in 18-month-old female Sprague-Dawley rats treated for 21 days with a daily dose of 3mg gemfibrozil/kg or 3mg rosiglitazone/kg: (i) plasma concentrations of total cholesterol (TC), triglycerides (TG), nonesterified fatty acids (NEFA), glucose, insulin and leptin, (ii) hepatic concentrations of TG, NEFA and cholesteryl esters (CE), and (iii) the liver expression and binding activity of peroxisome proliferator-activated receptor alpha (PPARalpha), and several of its target genes, hepatic nuclear factor-4 (HNF-4), and liver X receptor alpha (LXRalpha). Although gemfibrozil induced mild effects on hepatic PPARalpha, HNF-4, and LXRalpha, only rosiglitazone significantly reduced plasma TG (59%), glucose (19%), insulin (61%), and leptin (66%), and liver TG (43%), CE (49%), and NEFA (27%). These changes were associated to an increased body weight gain and a decrease in visceral fat (8.7-fold and 37% vs. control females, respectively). The beneficial effect of rosiglitazone treatment in 18-month-old female rats could be related to a direct effect on white adipose tissue.     

Maintenance by L-DOPA treatment of estrous cycles and LH response to estrogen in aging female rats

Nineteen, non-cycling female rats, 13–15 months of age, were fed 125 mg L-DOPA/15 g feed daily, and nineteen control rats of the same age were provided feed without L-DOPA. Sixteen of the L-DOPA fed rats each demonstrated 1–7 (average = 3) vaginal estrous cycles during the 75-day period of treatment, whereas no cycles were observed in the untreated controls. All animals were then ovariectomized and the post-castration rise in LH was monitored. Four weeks after ovariectomy, serum LH levels in the L-DOPA treated old female rats were significantly higher than in the non-treated old female rats. A single injection of 20μg of estradiol benzoate (EB) significantly lowered serum LH in the L-DOPA treated rats, but no effect was observed in the non-treated controls. A second injection of EB three days later produced a significantly greater LH surge in the old rats given L-DOPA than in the non-L-DOPA treated controls. These results indicate that prolonged L-DOPA administration can partially prevent the decline in function of the hypothalamo-pituitary-ovarian system in aging female rats.     

双(7)-他克林对慢性脑缺血老龄鼠海马胶质细胞可塑性及学习记忆功能的干预作用

目的探讨双(7)-他克林(B7T)对持续性低血流灌注脑缺血老年大鼠学习记忆损害及海马胶质细胞可塑性的干预作用。方法雄性SD大鼠30只,随机分为缺血组、对照组和干预组,每组10只。Morris水迷宫实验评估大鼠学习记忆功能,免疫组织化学染色及图像分析技术检测海马CA1区胶质细胞的数量、胞质突起长度等可塑性变化。结果缺血组海马CA1区锥体细胞排列稀疏紊乱,凋亡多见;对照组和干预组锥体细胞排列整齐而密集,凋亡细胞少见。缺血组海马CA1区胶质细胞酸性蛋白(GFAP)阳性细胞和胞质突起长度明显少于对照组和干预组。缺血组逃逸时间明显多于对照组和干预组;缺血组在平台象限停留时间和跨越平台区域的次数明显少于对照组和干预组(P<0.05.P<0.01)。缺血组、对照组及干预组海马CA1区GFAP阳性细胞的数量、胞质突起长度与空间记忆改善呈正相关。结论 B7T可通过促进海马胶质细胞的可塑性改变,改善慢性脑缺血所致的学习记忆认知障碍。胶质细胞的可塑性变化是学习记忆功能改善的重要病理修复机制。     

Ventilatory responses of aged male and female rats to hypercapnia and to hypoxia

Ventilatory parameters such as tidal volume, minute ventilation (VE), and inspiratory flow rate decrease in 24- vs. 12-month-old male and female rats. Differences between male and female values are maintained with age. Ventilatory response male and female rats exhibit to hypercapnia is altered by a decrease of the intercept, but not the slope value. The pattern of breathing exhibited by young females and males in response to hypercapnia (i.e. an increase of VT and f) is different than that noted in old males and females (i.e. an increase in VT only). In contrast, the ventilatory response both of slope and intercept male rats show by 24 months is decreased compared to the 12-month value; but the slope value is actually increased in the older vs. younger female rats in response to hypoxia.     

Astaxanthin supplementation modulates cognitive function and synaptic plasticity in young and aged mice

The incidence of neurodegenerative disorders and cognitive impairment is increasing. Rising prevalence of age-related medical conditions is associated with a dramatic economic burden; therefore, developing strategies to manage these health concerns is of great public health interest. Nutritionally based interventions have shown promise in treatment of these age-associated conditions. Astaxanthin is a carotenoid with reputed neuroprotective properties in the context of disease and injury, while emerging evidence suggests that astaxanthin may also have additional biological activities relating to neurogenesis and synaptic plasticity. Here, we investigate the potential for astaxanthin to modulate cognitive function and neural plasticity in young and aged mice. We show that feeding astaxanthin to aged mice for 1 month improves performance on several hippocampal-dependent cognitive tasks and increases long-term potentiation. However, we did not observe an alteration in neurogenesis, nor did we observe a change in microglial-associated IBA1 immunostaining. This demonstrates the potential for astaxanthin to modulate neural plasticity and cognitive function in aging.

     

Inhibition of dendritic spine induction on hippocampal CA1 pyramidal neurons by a nonsteroidal estrogen antagonist in female rats

Estrogens regulate the formation of excitatory synaptic connections in the hippocampus of female rats. Because the adult hippocampus has a very low concentration of intracellular estrogen receptors, it is unclear whether a conventional genomic mechanism is involved. Nonsteroidal estrogen antagonists are useful tools to study estrogen action because they can provide pharmacological data in favor of a particular pathway of estrogen action and evidence against other pathways. To investigate the role of intracellular estrogen receptors in the estrogen induction of synapse formation, we took advantage of previous studies in which we had shown that an estrogen antagonist, CI-628, enters the brain and blocks estrogen induction of progestin receptors to study whether the same antagonist would either mimic or block effects of estradiol to induce excitatory spine synapses. Using silver impregnation of neurons by the single section Golgi technique and morphometric analysis, we found that CI-628 effectively prevented estrogen induction of spines on CA1 pyramidal neurons, without having any agonist effects of its own. This result is consistent with an action of estradiol via intracellular estrogen receptors that are known to be expressed by interneurons within the hippocampus.     

Different regulation of growth hormone-releasing factor-sensitive adenylate cyclase in the anterior pituitary of young and aged rats

Low basal GH secretion and reduced GH responsiveness to different GH secretagogues, including GHRF, have been reported in aged animals and humans. Parallel to the in vivo findings, an impaired GH responsiveness to GHRF is evident in somatotropes from old rats of either sex. We report here that in anterior pituitaries (APs) from aged male and female rats GHRF-induced stimulation of adenylate cyclase (AC) activity was strikingly reduced (male rats, change from baseline 700% in young and 100% in old rats) or lacking (female rats, change from baseline 430% in young and 13% in old rats) when compared to that evoked by GHRF in the APs from young counterparts. Pretreatment with GHRH (5 micrograms/rat iv for 3 days) decreased the high basal AC activity of old male rats [from 33.38 +/- 3.60 to 15.99 +/- 5.75 (SEM) pmol cAMP/min.mg protein], did not alter the GHRF-stimulated rise in AC activity in old male rats, and induced a small but unequivocal rise in AC activity in old female rats (change from baseline 35% vs. 13%, respectively). Pretreatment with GHRF markedly reduced the acute effect of GHRF in the APs from young rats of both sexes (male rats, change from baseline 360% and 700%; female rats, change from baseline 230% and 430% in GHRF-pretreated and control rats, respectively). In parallel studies performed in female rats, it was shown that in vivo pretreatment with GHRF at the same schedule markedly reduced the effect of acute GHRF stimulation on GH secretion from cultured pituitary cells of young rats but left unchanged GHRF-induced stimulation of GH secretion from pituitary cells of old rats. In all, these data suggest that deficiency of endogenous GHRF synthesis and/or release may underlie defective GH secretion in old rats and that a GHRF replacement regimen that reduces the sensitivity of the young somatotrope cells does not alter the sensitivity of (male rats) or exerts a priming effect (female rats) on the old somatotrope cell.     

Restraint stress decreases the neurosecretory activity of tuberoinfundibular dopaminergic neurons in young but not in aged female rats

The regulation of prolactin secretion by tuberoinfundibular dopamine (DA) neurons appears to be altered in the aged rat: the concentration of prolactin in the serum increases and the activity of the tuberoinfundibular DA neurons decreases. In the young female rat a brief period of stress reduces the tuberoinfundibular DA neurosecretory activity and increases the secretion of prolactin. The purpose of the present study was to determine if the responsiveness of tuberoinfundibular DA neurons to restraint stress is altered in the aged female rat. The activity of these neurons was estimated from the rate of DA synthesis in their terminals in the median eminence, as measured by the rate of accumulation of dihydroxyphenylalanine (DOPA) after the administration of a decarboxylase inhibitor. Thirty minutes of restraint stress increased serum prolactin concentrations in both young (3 months) and aged (26 months) constant estrous rats, but reduced the rate of DOPA accumulation in the median eminence of only the young rats. Restraint also decreased the rate of DOPA accumulation in the median eminence of intermediate-aged rats (14 months) independently of whether the rats were exhibiting normal ovarian cycles (measured on the day of estrus) or were in a constant estrus. This suggests that the loss of ovarian cyclicity per se is not associated with the age-related change in the response of tuberoinfundibular DA neurons to restraint stress.(ABSTRACT TRUNCATED AT 250 WORDS)     

Learning and memory in young and aged Fischer 344 rats

Changes in learning and memory processes that occur with senescence were investigated in male and female Fischer 344 rats, 3-26 mth of age. Age-related impairments were seen in retention of inhibitory avoidance learning, acquisition of a Y-maze discrimination task, and in a swim escape task with short intertrial training intervals. In contrast, old animals performed better than the young rats in an active avoidance task. No age differences were observed in either open field activity or in flinch or jump thresholds to footshock. These results indicate that impairments in learning and memory processes of aged rats are task-specific, and that memory deficits in old rats are best seen following one-time-only events or with weak training. The behavioral baselines described will help in the design of further research to correlate memory and neurobiological changes observed during the aging process in the rat.     

Effect of ovariectomy on renal estrogen receptor-alpha and estrogen receptor-beta in young salt-sensitive and -resistant rats

This study evaluated the effect of ovariectomy on renal estrogen receptor (ER)-alpha and ERbeta expression in young female Dahl salt-sensitive and salt-resistant rats. Our hypothesis was that estrogen depletion results in an imbalance in ERalpha and ERbeta expression in salt-sensitive rats. Rats were subjected to sham surgery (intact), ovariectomy, and ovariectomy with estrogen replacement. Kidneys were harvested 8 weeks later. Western blot was used to measure ERalpha and ERbeta expression in the cortex and medulla. In intact rats, ERalpha was 2.7- and 4.3-fold higher in salt-sensitive compared with salt-resistant rats in the renal cortex and medulla, respectively. In salt-sensitive rats, ovariectomy caused 42% and 52% decreases in ERalpha and 107% and 314% increases in ERbeta in renal cortex and medulla, respectively. In salt-resistant rats, ovariectomy caused 33% and 150% increases in ERalpha and 107% and 100% increases in ERbeta in renal cortex and medulla, respectively. Estrogen replacement did not alter ERalpha but restored ERbeta expression levels similar to levels in intact rats in both salt-sensitive and salt-resistant rats. Thus, estrogen loss had opposite effects on ERalpha in salt-sensitive (downregulation) and salt-resistant rats (upregulation). We propose that the decrease in ERalpha expression in salt-sensitive rats after estrogen loss alters the balance of renal ERs and may play a role in accelerating the development of hypertension and renal damage.     

Learning and hippocampal synaptic plasticity in streptozotocin-diabetic rats: interaction of diabetes and ageing

Abstract Aims/hypothesis. Diabetes mellitus leads to functional and structural changes in the brain which appear to be most pronounced in the elderly. Because the pathogenesis of brain ageing and that of diabetic complications show close analogies, it is hypothesized that the effects of diabetes and ageing on the brain interact. Our study examined the effects of diabetes and ageing on learning and hippocampal synaptic plasticity in rats.?Methods. Young adult (5 months) and aged (2 years) rats were examined after 8 weeks of streptozotocin-diabetes. Learning was tested in a Morris water maze. Synaptic plasticity was tested ex vivo, in hippocampal slices, in response to trains of stimuli of different frequency (0.05 to 100 Hz).?Results. Statiscally significant learning impairments were observed in young adult diabetic rats compared with controls. These impairments were even greater in aged diabetic animals. In hippocampal slices from young adult diabetic animals long-term potentiation induced by 100 Hz stimulation was impaired compared with controls (138 vs 218 % of baseline). In contrast, long-term depression induced by 1 Hz stimulation was enhanced in slices from diabetic rats compared with controls (79 vs 92 %). In non-diabetic aged rats synaptic responses were 149 and 93 % of baseline in response to 100 and 1 Hz stimulation, compared with 106 and 75 % in aged diabetic rats.?Conclusion/interpretation. Both diabetes and ageing affect learning and hippocampal synaptic plasticity. The cumulative deficits in learning and synaptic plasticity in aged diabetic rats indicate that the effects of diabetes and ageing on the brain could interact. [Diabetologia (2000) 43: 500–506] Received: 18 October 1999 and in revised form: 6 December 1999     

Early and sustained exposure to high-sucrose diet triggers hippocampal ER stress in young rats

Early-life environmental insults have been shown to promote long-term development of chronic non-communicable diseases, including metabolic disturbances and mental illnesses. As such, premature consumption of high-sugar foods has been associated to early onset of detrimental outcomes, whereas underlying mechanisms are still poorly understood. In the present study, we sought to investigate whether early and sustained exposure to high-sucrose diet promotes metabolic disturbances that ultimately might anticipate neurological injuries. At postnatal day 21, weaned male rats started to be fed a standard chow (10 % sucrose, CTR) or a high-sucrose diet (25 % sucrose, HSD) for 9 weeks prior to euthanasia at postnatal day 90. HSD did not alter weight gain and feed efficiency between groups, but increased visceral, non-visceral and brown adipose tissue accumulation. HSD rats demonstrated elevated blood glucose levels in both fasting and fed states, which were associated to impaired glucose tolerance. Peripheral insulin sensitivity did not change, whereas hepatic insulin resistance was supported by increased serum triglyceride levels, as well as higher TyG index values. Assessment of hippocampal gene expression showed endoplasmic reticulum (ER) stress pathways were activated in HSD rats, as compared to CTR. HSD rats had overexpression of unfolded protein response sensors, PERK and ATF6; ER chaperone, PDIA2 and apoptosis-related genes, CHOP and Caspase 3; but decreased expression of chaperone GRP78. Finally, HSD rats demonstrated impaired neuromuscular function and anxious behavior, but preserved cognitive parameters. In conclusion, our data indicate that early exposure to HSD promote metabolic disturbances, which disrupt hippocampus homeostasis and might precociously affect its neurobehavioral functions.

     

A rich environmental experience reactivates visual cortex plasticity in aged rats

Brain aging is characterized by functional deterioration across multiple systems, associated to a progressive decay of neural plasticity. Here, we explored environmental enrichment (EE), a condition of enhanced sensory-motor and cognitive stimulation, as a strategy to restore plasticity processes in the old brain. Visual system is one of the paradigmatic models for studying experience-dependent plasticity. While reducing input from one eye through monocular deprivation induces a marked ocular dominance (OD) shift of neurons in the primary visual cortex during development, the same manipulation is totally ineffective after the closure of the critical period. We show that EE is able to reactivate OD plasticity in the visual cortex of aging rats, as assessed with both visual-evoked potentials and single-unit recordings. A marked reduction in intracortical GABAergic inhibition and a remodeling of extracellular matrix accompany this effect. The non-invasive nature of EE makes this paradigm eligible for human application.     

Hypothalamic lh-releasing activity in young and aged intact and gonadectomized rats

Hypothalamic LH-releasing activity content was measured in young (3–5 mo) and aged (22–26 mo) intact and gonadectomized male and female rats. Hypothalamic extracts (0.25, 0.5 and 1.0 hypothalamic equivalents) from young and aged rats were incubated with untreated hemisectioned rat pituitaries in medium 199. All hypothalamic extract treatments stimulated LH release from the incubated pituitaries. Increased amounts of hypothalamic extracts added to to the incubation medium proportionally increased LH release. There were no differences in LH release stimulated by young or aged hypothalamic extracts from either the intact or gonadectomized groups. In addition serum testosterone concentrations were reduced in the aged male rats and serum LH was lower in aged male and female rats than in the young groups. Although serum LH was increased after gonadectomy in all groups, the increase was of smaller magnitude in the aged rats. These data indicate significant alterations in fee responsiveness of the hypothalamus to steroid feedback in the aged rat. Although the hypothalamus contains sufficient LH-releasing activity to stimulate higher levels of pituitary and gonadal endocrine function, aging effects on the neuroendocrine control mechanisms inhibit hypothalamic hormone function.     

Serotonergic modulation of ethanol-induced electrophysiological depression in young and aged rats

BACKGROUND: Ethanol (EtOH)-induced electrophysiological depressions in cerebellar Purkinje neurons have been shown to be potentiated by exogenously applied serotonin (5HT). In this study, we determined whether this modulatory action can be activated by endogenous release from presynaptic serotonergic terminals, and whether such a response is altered by age or rat strain. METHODS: Extracellular 5HT levels in cerebellar cortex were measured in real time by in vivo chronoamperometry, by using Nafion-coated carbon fiber electrodes, in anesthetized young (3-5 months old) or aged (18-24 months old) Sprague Dawley and Fischer 344 rats. Some animals were prelesioned with 5,7 dihydroxytryptamine (5,7 DHT). Single unit electrophysiological activity was recorded from cerebellar Purkinje neurons. Serotonin or its presynaptic antagonist methiothepin was applied directly to cerebellar neurons through multibarrel pipettes. RESULTS: Local application of methiothepin dose-dependently induced 5HT overflow in young Sprague Dawley and Fisher 344 rats. Methiothepin-induced 5HT release was decreased significantly in aged or 5,7 DHT-lesioned rats. Local application of methiothepin or 5HT potentiated EtOH-induced electrophysiological depression of Purkinje neurons in young animals of both strains. Methiothepin-potentiated, EtOH-elicited neuronal inhibition was reduced greatly in aged or 5,7 DHT-lesioned rats. Serotonin-facilitated EtOH responses were reduced in the aged Sprague Dawley rats. CONCLUSIONS: EtOH-induced electrophysiological responses in cerebellum can be facilitated by endogenous 5HT release by using a 5HT autoreceptor antagonist. Such actions are attenuated in aged rats perhaps through a presynaptic serotonergic mechanism.