Restraint stress induced changes in rat liver and serum metallothionein and in Zn metabolism

Effects of psychogenic stress on oxidative stress and antioxidant capacity at different growth stages of rats: Experimental study

This study examined the psychogenic stress (PS) effects on changes in oxidative stress and the antioxidant capacity of an organism at different growth stages. The experimental animals were male Wistar rats of five different ages from growth periods (GPs) to old age. The growth stages were randomly classified into control (C) and experimental (PS) groups. The PS was performed using restraint and water immersion once daily for 3 h for 4 weeks. Reactive oxygen metabolites (d-ROMs) and the biological antioxidant potential (BAP) were measured before and after the experiment. In addition, the liver and adrenal glands were removed, and the wet weight was measured. The d-ROM and BAP of all growth stages given PS increased significantly. The d-ROM in the C group without PS increased significantly in GPs while decreased significantly in old-aged rats. In addition, the BAP of the C group in GP and early adulthood were all significantly elevated. There were significant differences in organ weights between the C and PS groups at all growth stages. Oxidative stress and antioxidant capacity differed depending on the organism's developmental status and growth stage, and PS also showed different effects. In particular, the variability in oxidative stress was remarkable, suggesting that the effect of PS was more significant in the organism's immature organs.

Restraint stress up-regulates expression of zinc transporter Zip14 mRNA in mouse liver

The zinc concentration in the liver was significantly higher in mice at 12 h after the onset of restraint stress than that without stress. The IL-6 protein level in the serum was transiently elevated at 3 h after the onset of restraint stress, and the IL-6-responsive zinc transporter Zip14 mRNA in the liver was expressed markedly at 6 h. These results suggest that Zip14 plays a major role in the mechanism responsible for accumulation of zinc in the liver under restraint stress.

Property of metallothionein as a Zn pool differs depending on the induced condition of metallothionein

Metallothionein (MT) is a low-molecular-weight, cysteine-rich, heavy metal-binding protein with several putative physiological functions as a radical scavenger and a regulator of metabolism of Zn. Although the induction of hepatic MT by a wide range of stressors is a well-known phenomenon, little is known about the role of MT in stressful situations. Since MT regulates Zn metabolism, we investigated the differences between affinities of MT for Zn in various stressful conditions in this study. Divalent cadmium ions are capable of displacement of Zn from MT in vitro. Therefore, we assayed the binding of Zn to MT induced by various stimuli using in vivo administration of Cd. MT was induced by paraquat (PQ), a reactive oxygen generator, fasting stress and restraint stress. Apo-MT induced by them bound to Zn in vivo. Zn, which bound to MT induced by PQ, was displaced by the administration of Cd. However, Zn that had bound to MT induced by fasting stress and restraint stress was not displaced by Cd. Moreover, we assessed the in vivo affinity of Zn to MT induced by fasting stress under the condition of subchronic Cd exposure. Cd was administered to mice by subcutaneously implanted Alzet osmotic minipumps, which released constant amounts of Cd over a 14-day period. After 4 days, mice were fasted for 24 h and hepatic MT was examined. Interestingly, it was found that Zn had displaced Cd bound to MT. These findings indicate that the affinity of MT for Zn differs depending on the stimulus by which MT was induced. This is the first report on differences in the properties of MT depending on the stimulus used to induce MT.

In vivo manipulation of endogenous metallothionein with a monoclonal antibody enhances a T-dependent humoral immune response

Metallothionein (MT) is a small stress response protein that can be induced by exposure to heavy metal cations, oxidative stressors, and acute phase cytokines that mediate inflammation. In previous experiments, we have shown that exogenous MT can affect cell proliferation, macrophage and cytotoxic T lymphocyte function, and humoral immunity to T-dependent antigens. In the studies described here, we have explored the effect of a monoclonal anti-MT antibody (clone UC1MT) on the role that endogenous MT plays in the humoral immune response. In vivo injection of UC1MT significantly increased the humoral response to simultaneous challenge with ovalbumin (OVA). In contrast, mice immunized with OVA in the presence of an isotype-matched antibody control (MOPC 21) showed no change in the anti-OVA humoral response. The predominant anti-OVA response that was enhanced by UC1MT treatment was the IgG(1) response; the IgG(2a) anti-OVA response was not altered by UC1MT treatment. UC1MT treatment increased the numbers of IgG anti-OVA secreting cells as measured by ELISPOT assay, suggesting that blocking the effects of MT synthesized during the immune response augments the differentiation of antigen-specific plasma cells. The percentages of T and B cells in the spleens of animals from each treatment group were not significantly different, suggesting that this regimen of UC1MT treatment does not significantly affect hematopoiesis, but rather alters antigen-induced differentiation of lymphocytes. These observations are compatible with previous results from our laboratory that suggest that endogenous MT synthesized during the normal immune response or as a consequence of toxicant exposure suppresses in vivo immune function. In light of the fact that significant amounts of MT can be synthesized during toxicant exposure, manipulation of MT levels with an anti-MT antibody may ultimately represent an important therapeutic approach to the treatment of immune dysfunctions that result from toxicant exposure.

Metallothionein induction in response to restraint stress. Transcriptional control, adaptation to stress, and role of glucocorticoid

Metallothioneins (MT) have been implicated in the protection of cells from oxidative stress. We studied the molecular mechanism of induction of MT-I and MT-II in response to restraint stress using a mouse model system in which the animals were restrained in well ventilated polypropylene tubes for 12 h each day (one cycle). Here, we show that MT-I and MT-II mRNA levels were elevated as much as 10-20-fold after just one cycle of this simple stress. Stress-mediated MT induction occurred at the transcriptional level. The level of MT mRNA correlated with the stress-induced increase, and not with the diurnal variation, in the level of serum glucocorticoid. Treatment of the mice with RU 486, a glucocorticoid receptor antagonist, prior to restraint stress inhibited MT induction by at least 50%. Furthermore, the glucocorticoid responsive element-binding activity in the liver nuclear extracts from the stressed mice was significantly higher than that in the control mice. The complex formations between the transcription factor Sp1, MTF1, or MLTF/ARE and the respective specific oligonucleotides were not altered in the liver from the stressed mouse. The MT mRNA levels returned to the basal level at the end of nine cycles of stress, indicating habituation of the animals to restraint stress. At this stage, exposure of the animals to another type of stress, treatment with heavy metals, resulted in further induction of MT. These data indicate that glucocorticoid is the primary physiological factor responsible for MT induction following restraint stress, and the glucocorticoid receptor is the major transcription factor involved in this process.

Chronic stress reduces serum but not liver metallothionein response to acute stress

Rats subjected to chronic immobilization stress showed a reduced serum metallothionein (MT) response to acute immobilization stress compared to nonchronically stressed rats. In contrast, liver MT response to acute immobilization stress was not influenced by previous chronic immobilization stress. These results suggest that serum MT levels are likely under endocrine regulation and that they do not reflect directly liver MT levels. Instead it appears that both MT pools are regulated differently. The fact that liver MT is resistant to adaptation to chronic stress may be related to its physiological function.

Stress-related induction of hepatic metallothionein synthesis and increase in peripheral polymorphonuclear leukocytes in mice

This experiment examined whether hepatic metallothionein (MT) synthesis induced by stressful stimuli could reinforce the peripheral leukocyte defense mechanism in mice. A 2 x 2 cm section of dorsal skin was excised from male ICR mice (7 w.o.), then the hepatic MT concentration and superoxide anion production (SOA) in peripheral leukocytes were measured at 6 and 24 hr after the excision. The 6 hr-hepatic MT level was 6 times greater in the skin-excised mice than in the controls. SOA in the skin-excised mice was 2.3 times greater at 6 hr than in the controls, then decreased to the control level by 24 hr. Food deprivation increased the hepatic MT and SOA levels at 24 and 48 hr to a remarkably greater level than in the controls. The increases in SOA, which was measured by chemiluminescence response (CL) were found to be due to an increase in the number of polymorphonuclear leukocytes (PMNs) in the peripheral leukocytes in both the skin excision and food deprivation groups. These results suggest that skin excision causes an inflammatory response in mice that results in an acute increase in the number of PMNs concomitant with the acute activation of hepatic MT synthesis. Food deprivation might result in physiologic stress 24 hr or more after food deprivation and cause "emergency" increases in MT synthesis and PMN defense mechanisms. Thus, some unknown linked mechanisms might exist between hepatic MT synthesis and increased peripheral PMNs.

Metal redistribution in largemouth bass (Micropterus salmoides) in response to restrainment stress and dietary cadmium: Role of metallothionein and other metal-binding proteins

1. Fish stressed by restrainment displayed elevated serum cortisol, copper and zinc levels; dietary cadmium had no effect. 2. Stress/dietary cadmium increased liver copper levels in a metal pool containing metallothionein and non-metallothionein proteins but decreased intestinal zinc bound as low molecular weight forms. 3. After restrainment, zinc losses occurred in dorsal skeletal muscle, ovary and spleen: copper decreased in intestine and pyloric caecum. 4. Dietary cadmium altered intestinal zinc distribution and raised hepatic Cu-binding protein levels but did not alter plasma zinc, copper or cortisol levels. 5. Alterations in zinc and copper concentrations during stress contrast with mammalian models.

Influence of thyroparathyroidectomy and thyroxine replacement on Cu and Zn cellular distribution and on the metallothionein level and induction in rats

Thyroid hormones are involved in copper and zinc distribution in rat tissues. We examined the influence of thyroparathyroidectomy (TPTY) and of a replacement therapy by T4 on Cu and Zn organ distribution. MT levels were also measured both in basal conditions and after induction by cadmium. The results confirm that a lack of T4 modified Cu and Zn in serum and tissues. In serum, TPTY increased Cu (+15%) and ceruloplasmin (+18%), and decreased Zn (-18%). In tissues, Cu was altered in liver (+13%), kidney (-24%), heart (-16%) duodenum (-18%), and Zn in liver (+25%) and kidney (-10%). The soluble fractions (100,000 g supernatant) were mainly affected in liver and kidney, and the subcellular fractions in heart and duodenum. MT levels were modified in basal conditions only in liver (+57%) and kidney (-36%). T4 administration partially prevented the effect of TPTY on both elements and MT concentrations. Therefore, no evidence is provided for a direct role of T4 in the metabolism of MT in a way comparable to the effects of glucocorticoids. However, MT could mediate the consequences of TPTY on metal distribution in certain organs, such as liver and kidney.

Metallothionein response to stress in rats: role in free radical scavenging

The possibility that liver metallothionein (MT) can function as an antioxidant in vivo has been studied in the rat. It was found that the stress of food and water deprivation with or without physical immobilization consistently increased liver lipid peroxidation (LLP), suggesting that liver MT induction by stress might be related to the stress-induced LLP. This was supported by results with the lipid peroxidation promoter dimethyl sulfoxide (DMSO) and the natural antioxidant vitamin E. Whereas DMSO administration increased LLP levels in basal and stress situations, vitamin E decreased them. Liver MT levels were increased by DMSO in basal and stress situations, whereas they were decreased by vitamin E during stress. These in vivo results are consistent with an antioxidant role of liver MT suggested by previous in vitro results. However, liver MT preinduction by Zn treatment did not result in a lower MT response to stress. Instead a positive synergistic effect between Zn and stress appeared to be present. This result indicates that the mechanism of action of MT as antioxidant remains unclear.

Structural changes in nuclear chromatin in rat pituitary after chronic stress of low intensity

Acute, intense sources of "psychogenic" stress clearly modify the structure and function of the hypophysis, and there are concomitant changes in many peripheral physiological systems. Less dramatic sources of stress yield more equivocal results. An experiment is reported in which nuclear morphology of adenohypophyseal cells from 49 male rats exposed to a chronic, low-intensity stressor was examined both by conventional histological and computer-assisted-image-processing methods. The hypothesis tested was that an unequivocal pattern of morphological changes in the nucleus and nuclear chromatin would be revealed by image processing. Rats were killed after living for a year in a relatively low-stress environment, "crowded" in groups of five animals per cage. The control condition was a minimal stress environment of two rats per cage. Results suggested few signs of pathology from peripheral measures of hypophyseal activity, and direct light microscopic examination of the gland revealed no differences between the two groups. Analysis of computer-enhanced images of the pars distalis nuclei from the adenohypophysis, on the other hand, generated findings that were statistically and biologically significant. Nuclear size increased in the stress condition, the number of chromatin and area occupied by the particles increased, and the position of chromatin shifted toward the periphery of the nucleus. Perhaps more important, optical density analysis indicated that chromatin was less tightly packed in the experimental animals. Implications are that chronic, low-intensity stress modulates nuclear structural changes from a dormant to an active state that portend changes in the peripheral systems influenced by the hypophysis.

Physiological role of glucocorticoids on rat serum and liver metallothionein in basal and stress conditions

Serious contradictions exist at present in our understanding of the physiological role of glucocorticoids on the synthesis of the metal-binding protein, metallothionein (MT). In addressing this problem, we have examined in vivo the role of glucocorticoids on liver and serum MT levels in the rat under a spectrum of experimental conditions. The experiments confirm that stress has a major positive effect on hepatic MT levels. It was found that adrenocorticotropic hormone (ACTH) administration has an inhibitory effect on hepatic MT levels in response to restraint stress and that adrenalectomy (ADX) leads to an increase in basal MT levels and in MT levels in response to acute and chronic immobilization stress. Similar results followed treatment with the glucocorticoid receptor blocker, RU 486. The effect of ADX was abolished by corticosterone replacement. The relations found among hepatic MT, serum MT, and glucocorticoid concentrations indicate that in some circumstances glucocorticoids have a permissive role in mobilizing MT from tissues to serum and that in physiological conditions corticosterone has an inhibitory role in the maintenance of hepatic MT levels.

Effect of 2-mercaptoethanol on the electrophoretic behavior of rat and dogfish metallothionein and chromatographic evidence of a naturally occurring metallothionein polymerization

1. Metallothionein behavior in SDS-PAGE has been characterized. 2. It has been found that metallothionein behavior in this electrophoretic system depends upon the reducing environment. Migration as a well-defined protein band is only achieved in the presence of 2-100 mM 2-mercaptoethanol. 3. Within those 2-mercaptoethanol levels, both rat and dogfish metallothionein migrate as a protein with a molecular weight several times higher than that expected by amino acid analyses. This is not due to molecule oxidations, since this effect is promoted by the presence of 2-mercaptoethanol. 4. No effect of 2-mercaptoethanol on metallothionein behavior is found in conventional PAGE. 5. The present results suggest that to study the effect of 2-mercaptoethanol in SDS-PAGE is a simple and accurate way to identify a protein as metallothionein. 6. It has also been found that metallothionein aggregates naturally in the absence of ionic strength.

Age-dependent effects of acute and chronic intermittent stresses on serum metallothionein

Prepuberal and adult male rats were chronically stressed for a month with several acute stressors in a random schedule. Some of the animals were killed approximately 20 hours after the last stress session without any additional stress. Other animals from both control and chronic stress groups were subjected to an acute restraint stress for 15 min before being killed. While chronic stress did not alter hepatic metallothionein (MT) either in prepuberal or in adult rats, this treatment significantly increased serum MT levels in young but not in adult rats. Likewise, 15 min of restraint stress increased serum MT levels in young rats only, regardless of whether they were control or chronically stressed rats. The present data indicate that acute and chronic stressors may alter serum MT in an age-dependent fashion.