Impact of N-acetylcysteine and sesame oil on lipid metabolism and hypothalamic-pituitary-adrenal axis homeostasis in middle-aged hypercholesterolemic mice.

Hyperlipidemia and stress are important factors affecting cardiovascular health in middle-aged individuals. We investigated the effects of N-acetylcysteine (NAC) and sesame oil on the lipidemic status, liver architecture and the hypothalamic-pituitary-adrenal (HPA) axis of middle-aged mice fed a cholesterol-enriched diet. We randomized 36 middle-aged C57bl/6 mice into 6 groups: a control group, a cholesterol/cholic acid diet group, a cholesterol/cholic acid diet group with NAC supplementation, a cholesterol/cholic acid diet enriched with 10% sesame oil and two groups receiving a control diet enriched with NAC or sesame oil. NAC administration prevented the onset of the disturbed lipid profile, exhibiting decreased lipid peroxidation and alkaline phosphatase (ALP) levels, restored nitric oxide bioavailability and reduced hepatic damage, compared to non-supplemented groups. High-cholesterol feeding resulted in increased hypothalamic glucocorticoid receptors (GR) levels, while NAC supplementation prevented this effect. NAC supplementation presented significant antioxidant capacity by means of preventing serum lipid status alterations, hepatic damage, and HPA axis disturbance due to high-cholesterol feeding in middle-aged mice. These findings suggest a beneficial preventive action of plant-derived antioxidants, such as NAC, on lipid metabolism and on the HPA axis.

Insights into ectopic estrogen receptor expression, nucleocytoplasmic distribution and interaction with chromatin obtained with new antibodies to estrogen receptors α and ß.

Recent reports have indicated that in cells ectopically expressing only ERα or the full-length hormone-binding isoform of ERß (ERß1), the receptors interact with chromatin with different efficacies and that antibodies capable of probing such interactions by chromatin immunoprecipitation (ChIP) are scarce. We therefore produced nine subtype and isoform-specific antibodies to ERα or ERß and validated their performance in receptor probing in cell lines and tissue biopsies by various immunochemical methods, including ChIP. We also produced clones of HEK-293 cells stably transfected with an estrogen response element (ERE)-dependent luciferase reporter and ERα or ERß1, in order to comparatively study their interaction with reporter ERE. We show that ERα was located in the nucleus and ERß1 in the cytoplasm as well as the nucleus of the stably transfected cells, while both receptors were found predominantly in the nucleus in transiently transfected cells and in all estrogen target tissues examined using the same antibodies. The cells displayed wild-type transcriptional activity and canonical regulation of ERE-dependent luciferase expression by estrogen agonists and antagonists. However, unlike ERα, ERß1 recruitment to the reporter ERE could be probed only by sequential ChIP with antibodies to receptor N- and C-terminus. These data suggest that in HEK-293 cells stably expressing ERα or ERß1, ER subtype-specific constraints apply to ERß1 nuclear entry; and that in cells displaying cytoplasmic as well as nuclear localization of ERß1, sequential ChIP with different antibodies to the receptor is the method of choice for probing its interaction with chromatin.

High-fat feeding influences the endocrine responses of pubertal rats to an acute stress.

BACKGROUND/AIMS: Studies conducted in adult rats have shown that increased fat intake affects brain energy homeostasis and stress response. The neuroendocrine circuits controlling the aforementioned functions continue to mature during puberty. The aim of the present study was to investigate whether post-weaning high-fat consumption can modify the endocrine responses of pubertal rats to an acute stress. METHODS: Weaning male and female Wistar rats on postnatal day (P) 22 were fed either a high-fat (HF; 45% calories from fat) or a control (10% calories from fat) diet and were sacrificed on the individual day of puberty onset (between P35 and P42) under basal conditions or 4 h after swimming stress. Plasma insulin, leptin and corticosterone levels were determined by radioimmunoassay and the respective receptors in the hypothalamus and hippocampus were determined by Western blot analysis. RESULTS: Stressed HF-fed males showed a smaller increase in plasma insulin levels than chow-fed males. Their leptin receptor levels were reduced in the hypothalamus, but not in the hippocampus, and their glucocorticoid receptor levels were increased in the hypothalamus compared to stressed chow-fed males. HF-fed females were nonresponsive to stress-induced alterations in plasma glucose and corticosterone levels, as well as to hippocampal insulin receptors following stress. Several sex differences were also revealed in the endocrine responses of HF-fed animals following stress. CONCLUSIONS: These data show that consumption of high-fat foods during preadolescence can modify the endocrine responses to an acute stress by affecting both stress and metabolic mediators in a sexually dimorphic manner.

Fat feeding of rats during pubertal growth leads to neuroendocrine alterations in adulthood.

Juvenile obesity is a rising epidemic due largely to consumption of caloric dense, fat-enriched foods. Nevertheless, literature on fat-induced neuroendocrine and metabolic disturbances during adolescence, preceding obesity, is limited. This study aimed to examine early events induced by a fat diet (45% calories from saturated fat) in male rats fed the diet during the pre- and post-pubertal period. The neuroendocrine endpoints studied were the levels of circulating leptin, insulin and corticosterone, as well as their receptors in the hypothalamus and hippocampus. Hormonal levels were determined by radioimmunoassay and receptors' levels by western blot analysis. Leptinemia was increased in pubertal rats and in adult rats fed the fat diet from weaning to adulthood, but not in those fed from puberty to adulthood. Modifications in the developmental pattern from puberty to adulthood were observed for most of the brain receptors studied. In adult animals fed the fat diet from weaning onwards, the levels of leptin receptors in the hypothalamus and glucocorticoid receptors in the hippocampus were decreased compared to chow-fed controls. Switching from fat to normal chow at puberty onset restored the diet-induced alterations on circulating leptin, but not on its hypothalamic receptors. These data suggest that when a fat-enriched diet, resembling those consumed by many teenagers, provided in rats during pubertal growth, it can longitudinally influence the actions of leptin and corticosterone in the brain. The observed alterations at a preobese state may constitute early signs of the disturbed energy balance toward overweight and obesity.

Adult consequences of post-weaning high fat feeding on the limbic-HPA axis of female rats.

The peripubertal period is critical for the final maturation of circuits controlling energy homeostasis and stress response. However, the consequence of juvenile fat consumption on adult physiology is not clear. This study analyzed the adult consequences of post-weaning fat feeding on limbic-hypothalamic-pituitary-adrenal (HPA) axis components and on metabolic regulators of female rats. Wistar rats were fed either a high fat (HF) diet or the normal chow from weaning to puberty or to 3 months of age. Additional groups crossed their diets at puberty onset. Plasma leptin, insulin, and corticosterone levels were determined by radioimmunoassay and their brain receptors by western blot analysis. Adult HF-fed animals though not overweight, had higher corticosterone and reduced glucocorticoid receptor levels in the hypothalamus and hippocampus, compared to the controls. The alterations in HPA axis emerged already at puberty onset. Leptin receptor levels in the hypothalamus were reduced only by continuous fat feeding from weaning to adulthood. The pre-pubertal period appeared more vulnerable to diet-induced alterations in adulthood than the post-pubertal one. Switching from fat diet to normal chow at puberty onset restored most of the diet-induced alterations in the HPA axis. The corticosteroid circuit rather than the leptin or insulin system appears as the principal target for the peripubertal fat diet-induced effects in adult female rats.

Environmental and tactile stimulation modulates the neonatal handling effect on adult rat spatial memory.

Handling of rat pups promotes their adult cognitive performance. However, new data suggest that individual components of the handling procedure, like exposure to novelty or tactile stimulation, have distinct lasting effects on behaviour. In this study we examined the interaction of early novelty exposure with a varying amount of tactile stimulation on spatial recognition memory and corticosterone secretion of adult male and female rats. A split litter design was used and the experimental animals were also compared to animal facility reared controls. The experiment was conducted in two phases. In the first phase, we examined the effect of novel or home environment during the 15-min of neonatal handling, following 10 back-strokes. Tactile stimulation of 10 back-strokes combined with novelty exposure, enhanced novel arm discrimination in a Y-maze task in adult rats of both sexes compared to their siblings that stayed at home, as well as to the animal facility reared controls. In the second phase, additional back-stroking (total of 20 back-strokes) reduced the Y-maze performance of males neonatally exposed to novelty, while the same treatment enhanced the performance of their siblings that stayed at home. Basal corticosterone levels, determined 1 week post-Y-maze, were significantly increased only in the novelty exposed/10 back-stroked females compared to same sex non-handled controls. In contrast, 10 back-strokes combined with the home cage environment increased corticosterone in males. Increase to 20 back-strokes reversed the impact of neonatal environment on corticosterone levels. These data suggest that the nature and intensity of the individual components of a mild early life manipulation, like handling, are critical in modifying aspects of adult memory performance and basal adrenocortical function.

Neurofilament isoform alterations in the rat cerebellum following cytosine arabinoside administration.

A number of neurotoxic agents could potentially exert their action by degrading or modifying cytoskeleton components like neurofilaments (NF). Cytosine arabinoside (AraC) is an anticancer drug commonly used in leukemia treatment. Its side effects include neuronal cell death in the cerebellum and severe motor coordination deficits. We have previously shown that AraC administration (400mg/kg bw) in adult rats reduced NF immunostaining in cerebellar neurons. To further delineate the susceptibility of individual NF isoforms (NF-H, NF-M, NF-L) to AraC, in the present study we used Western blot analysis to quantify their level. A significant and selective reduction of NF-H isoform was observed in the cerebellum of AraC-treated animals, compared to the controls. Administration of the antioxidant N-acetylcysteine (NAC) for a period of 14 days (prior to and during AraC treatment), which was previously shown to ameliorate the AraC-induced motor deficits in these animals, largely prevented the reduction in NF-H isoform. Given the significant role of NF proteins and particularly NF-H in maintaining structural integrity and synaptic transport, the observed loss of this isoform may be a key-target of AraC action in cerebellar neurons. Moreover, this study provides further data on the neuroprophylactic role of NAC in vivo against chemotherapy-induced toxicity.

Fat diet affects leptin receptor levels in the rat cerebellum.

OBJECTIVE: The role of leptin receptors (Ob-Rs) within the hypothalamus in the control of energy expenditure has well been established. However, their role and regulation in other brain areas, including the cerebellum, is largely unexplored. In the present study we examined whether Ob-R levels in the rat cerebellum are influenced by a high-fat diet and if these changes are sexually divergent during adolescence. METHODS: The fat diet (45% energy from fat) was applied from weaning to puberty (postnatal days [P] 22-42), from weaning to adulthood (P22-90), and from puberty to adulthood (P42-90) in female and male Wistar rats. Ob-R levels were detected by western blotting and the data from pubertal and adult rats were analyzed by two-way analysis of variance for the effects of diet and sex. RESULTS: The fat diet affected Ob-R long isoform levels in a sexually dimorphic manner. In the cerebellum of all fat-fed male groups, Ob-R levels were reduced compared with their chow-fed counterparts (P < 0.05). In contrast, in female rat Ob-R levels were reduced only in the adult P22-90 group. CONCLUSION: Our data show for the first time that Ob-R levels in the rat cerebellum are subject to diet-induced alterations and that these changes are sexually dimorphic.

Effects of AraC treatment on motor coordination and cerebellar cytoarchitecture in the adult rat. A possible protective role of NAC.

Intact cerebellum cytoarchitecture and cellular communication are indispensable for successful motor coordination and certain forms of memory. Cytosine arabinoside (AraC), often used as an anti-neoplastic agent in humans, can have cerebellum-targeting adverse effects. In order to characterize the nature of AraC-induced cerebellar lesions in an adult rodent model, we have administered AraC (400 mg/kg b.w., i.p.) in adult male Wistar rats for 5 days. The animals' walking pattern, motor coordination, locomotion, spatial navigation and cognition were evaluated, along with neurofilament- and calbindin-like distribution in the cerebellum. AraC-treated rats demonstrated a disturbed walking pattern and a reduced ability of motor learning and coordination, indicative of a mild cerebellar deficit. Although the general locomotion and spatial cognition of AraC-treated rats was not significantly altered, their navigation into the water, in terms of swimming velocity, was irregular, compared to vehicle-treated animals. Neurofilament-like immunostaining was reduced in the molecular cerebellar layer, while calbindin D 28 kDa levels were increased in Purkinje neurons, following AraC treatment. Administration of the antioxidant N-acetylcysteine (NAC) (200 mg/kg b.w., p.o.), for 14 days (prior to and during AraC treatment) largely prevented the AraC-induced behavioral deficits. Our in vivo model of neurotoxicity provides data on the AraC-induced behavioral and cellular alterations concerning the adult rat cerebellum. Furthermore, it provides evidence of a possible neuroprophylactic role of the antioxidant N-acetylcysteine in this model of chemotherapy-induced toxicity.

Early neuroendocrine alterations in female rats following a diet moderately enriched in fat.

1. High-fat diets disrupt metabolic equilibrium and hypothalamic-pituitary-adrenal axis function and may lead to the development of metabolic and endocrine dysfunctions. The early neuroendocrine responses elicited by a combination of short-term metabolic and emotional stressors is not fully elucidated. 2. The purpose of the present study was to determine the impact on female rats, of a short-term enriched in fat diet, combined with an acute stressor. 3. Adult female Wistar rats were fed a fat diet for 7 days and subsequently exposed to 5 min swimming stress. Plasma leptin, insulin, glucose, luteinizing hormone (LH) and corticosterone, along with brain corticosteroid receptors' mRNAs were measured at 1 h post stress. 4. Diet, compared to chow, reduced food intake and body weight gain, increased leptin and LH, and decreased glucose in the periphery. The diet increased plasma corticosterone and reduced GR mRNA in the hippocampus, similarly to swim stress. 5. The diet significantly modified the animals' response to the subsequent swim stress, by blocking further corticosterone rise and GR mRNA reduction. In addition, exposure of diet-fed rats to stress, altered their endocrine response, in terms of leptin and LH. 6. These observations suggest that even short, moderately unbalanced diets can affect peripheral and central components of energy balance, reproduction and stress response.

Estrogens influence behavioral responses in a kainic acid model of neurotoxicity.

The behavioral and neuroprotective effects of 17beta-estradiol (E2), on ovariectomized rats treated with a subconvulsive dose (7 mg/kg bw, ip) of kainic acid (KA), were examined. Estradiol was administered either acutely (150 mug/rat, ip) along with KA, 14 days post-ovariectomy, or chronically (sc capsules providing proestrus estrogen levels in serum) starting at ovariectomy. Exploratory behavior, as deduced by sniffing in the open field test, was reduced in KA-treated rats. Both hormonal schemes partially restored sniffing behavior in KA-lesioned subjects. Moreover, acute and chronic E2 administration in KA-treated rats resulted in increased vertical and horizontal activity of these animals in the open field test. Memory for object recognition was reduced following KA and was not restored by hormonal treatments. Acute, but not chronic, E2 coadministration with KA significantly impaired spatial performance in the water maze task, while KA alone had no effect. Both acute and chronic estradiol administration rescued hilar and CA1 neurons from KA-induced cell death. Chronic, but not acute, E2 increased neurofilament immunoreactivity in the mossy fibers of the dentate gyrus neurons, similarly to KA. Our results show that although estradiol administration in KA-treated rats has beneficial effects on cell survival, it has diverse effects on exploratory behavior, object, and spatial memory. Estradiol effects on KA-lesioned animals depended on the duration and timing of exposure to the hormone, implying different mechanisms of hormone actions.

Impaired neuroendocrine response to stress following a short-term fat-enriched diet.

Unbalanced diets and stressful situations disrupt energy homeostasis and are implicated in the development of severe pathologies. The present study investigated the effects of a 7-day diet, enriched in corn oil (20%) and proportionally lower in protein and carbohydrate, on the major regulators of energy expenditure and stress response of adult male Wistar rats exposed to acute swimming stress at the end of the dietary treatment. Food intake and body weight gain were lower in diet-fed as compared with normal-chow-fed controls. The circulating leptin levels were elevated in both nonstressed and stressed diet-fed rats, while the glucose levels were significantly increased only in the diet-fed group subjected to stress. The plasma insulin levels were not affected by the diet, but were significantly reduced in acutely stressed rats. Acute swimming increased corticosterone levels both in chow-fed and diet-fed rats. No significant effect of diet was observed on corticosterone levels. Northern blot analysis showed increased glucocorticoid receptor mRNA levels in the hypothalamus of normally fed rats subjected to stress. This increase was not observed in the diet-fed stressed group, which on the contrary showed reduced glucocorticoid receptor mRNA levels following stress. The data presented indicate that even a moderately unbalanced, fat-enriched diet can within a short time disrupt the metabolic neuroendocrine balance and the stress response, rendering the organism more vulnerable to potential stressful insults.

Spatial performance and corticosteroid receptor status in the 21-day restraint stress paradigm.

Twenty-one days of restraint stress has been shown to affect hippocampal plasticity, neurogenesis, and spatial memory. Hippocampal glucocorticoid receptors (GR) and mineralocorticoid receptors (MR) are the main mediators of stress response and learning/memory processes. We studied the performance of male and female rats on a hippocampal-dependent spatial task after 21 days of restraint in relation to the stress-induced changes of GR and MR status in their hippocampi. Reduced GR immunostaining was detected in the dentate gyrus and CA1 area of stressed male rats. Stressed male rats performed worse than the male control rats on the Morris water maze. In contrast, unaltered (in the dentate gyrus) or increased (in CA1) GR immunoreactivity was seen in the hippocampus of stressed female rats. Stressed female rats had an improved memory score in the task compared with the female control rats. In addition, stressed female rats showed increased MR immunostaining in the CA3 area, which is known to be severely affected by stress. The observed sexually dimorphic effects of 21-day restraint in spatial learning and memory may be associated with the sex-dependent changes in hippocampal corticosteroid receptor status after stress.

Forced swimming differentially affects male and female brain corticosteroid receptors.

Corticosteroid receptors are key mediators of the neuroendocrine response to stress. Previously, we have determined the effects of restraint stress on the regulation of corticosteroid receptor genes in the brain and pituitary of male and female rats. Significant gender- and regional-specific regulation of receptor mRNAs was observed. To further investigate the stressor specificity in the same context, we have determined glucocorticoid receptor (GR) and mineralocorticoid receptor (MR) mRNAs following exposure to swimming stress paradigms applied alone, or in combination with restraint stress. Our data revealed stressor-specific alterations in GR or MR mRNA levels, which were more pronounced in males, the gender most affected by swimming stress. No alterations in GR or MR mRNA levels were detected in the female hippocampus and hypothalamus upon exposure to swimming paradigms, while in males the same stressors down-regulated GR mRNA in the hippocampus (chronic exposure) and up-regulated both genes in the hypothalamus (acute exposure). In the frontal cortex, acute swimming stress caused a reciprocal change in GR mRNA levels in the two sexes. The above difference is not due to circulating ovarian steroids, since ovariectomy did not change the female pattern of GR gene expression following acute stress. Our results further showed a hypothalamic-pituitary-adrenal axis facilitation to a novel superimposed stressor expressed at the level of limbic corticosteroid receptors: When chronically restrained rats of both sexes were exposed to acute swimming stress, a reduced GR/MR mRNA ratio, implying reduced feedback axis sensitivity, was detected in both the hippocampus and the hypothalamus. In conclusion, our work provides additional evidence on stressor, gender and region specificity in the regulation of brain corticosteroid receptors.