Corticosterone Induces Dysregulation of Iron Metabolism in Hippocampal Neurons In Vitro

Iron is required for neuronal function but in excess generates neurodegeneration. Although the iron homeostasis machinery in neurons has been described extensively, little is known about the influence of corticosterone on the iron homeostasis in neurons. In this study, we characterized the response of hippocampal neurons to a model of progressive corticosterone condition. We found that increasing extracellular corticosterone-induced iron accumulation killed a large proportion of neurons. Iron concentrations were significantly increased in the corticosterone-treated cells. In the hippocampal neurons, corticosterone decreased expression of ferritin and increased expression of transferrin receptor1 (TfR1), iron regulatory protein1 (IRP1), and divalent metal transporter 1. Corticosterone-induced elevation of IRP1 expression can cause increase of TfR1 and decrease of ferritin expression, which further leads to iron accumulation in hippocampal neurons and subsequently increases the oxidative damage of the neurons; it is indicated that corticosterone might be an important reason for iron deposition-caused neurodegenerative diseases.     

Erratum to: Corticosterone Induces Dysregulation of Iron Metabolism in Hippocampal Neurons In Vitro

Iron is required for neuronal function but in excess generates neurodegeneration. Although the iron homeostasis machinery in neurons has been described extensively, little is known about the influence of corticosterone on the iron homeostasis in neurons. In this study, we characterized the response of hippocampal neurons to a model of progressive corticosterone condition. We found that increasing extracellular corticosterone-induced iron accumulation killed a large proportion of neurons. Iron concentrations were significantly increased in the corticosterone-treated cells. In the hippocampal neurons, corticosterone decreased expression of ferritin and increased expression of transferrin receptor1 (TfR1), iron regulatory protein1 (IRP1), and divalent metal transporter 1. Corticosterone-induced elevation of IRP1 expression can cause increase of TfR1 and decrease of ferritin expression, which further leads to iron accumulation in hippocampal neurons and subsequently increases the oxidative damage of the neurons; it is indicated that corticosterone might be an important reason for iron deposition-caused neurodegenerative diseases.     

Evidence for sex-dependent anabolic response to androgenic steroids mediated by muscle glucocorticoid receptors in the rat

The muscle anabolic/anti-catabolic activity of the androgenic steroids testosterone and trenbolone was studied in rats to investigate whether such steroids act as agonists via muscle androgen receptors, or as antagonists that oppose the catabolic effects of endogenous glucocorticoids via their interaction with muscle glucocorticoid receptors. For comparison, the effects of the potent glucocorticoid antagonist RU486 were also examined. The parameters measured included growth rate, muscle weight, serum growth hormone and corticosterone levels, and receptor binding parameters in muscle cytosol. Females responded better than males to anabolic treatment with the androgenic steroids. Ovariectomy or adrenalectomy abolished this response. Neither the sex difference nor the requirement for ovaries or adrenals could be explained in terms of muscle receptor parameters or serum growth hormone levels. The muscle anabolic activity of androgenic steroids was restored when castrated males were treated with oestradiol and when adrenalectomized females were treated with corticosterone. RU486 also prevented the catabolic/anti-anabolic activity of exogenous corticosterone in adrenalectomized rats. Testosterone and RU486 behaved as anti-glucocorticoids in vivo since they inhibited glucocorticoid-induced liver tyrosine aminotransferase activity. The results suggest that anabolic steroids can act via muscle glucocorticoid receptors, thereby antagonizing the catabolic activity of endogenous glucocorticoids, rather than via muscle androgen receptors.     

皮质酮对大鼠再生肝细胞鸟氨酸脱羧酶活性及其基因表达的影响

采用高效液相色谱和原位杂交技术研究了皮质酮对大鼠再生肝细胞鸟氨酸脱羧酶 (ODC)活性及ODCmRNA表达的影响。结果显示 ,大鼠完整肝脏中ODC水平较低 ,2 / 3肝切除 (PH)后 3h ,不同处理组ODC活性开始升高 ,6h达到最高值 ,其中 ,去肾上腺 NaCl组和糖皮质激素受体拮抗剂RU4 86处理组的酶活性高于对照组 (去肾上腺假手术组 ) ,而去肾上腺 皮质酮处理组的酶活性低于对照组 ,36h恢复到肝切除前水平 ;完整肝脏的ODCmRNA水平极低 ,PH后表达量迅速增加 ,5h达到最大值 ,不同处理组mRNA水平的高低顺序与酶活性一致 ,12h降至肝切除前水平 ;在PH前 12h给大鼠注射RU4 86 (10mg/kg体重 ) ,取得了与去肾上腺 NaCl处理鼠相似的结果。以上结果表明 ,在PH诱导的再生肝细胞中 ,ODCmRNA表达量的增加和 /或减少是造成ODC活性改变的原因之一 ,皮质酮对ODC活性及其mRNA的表达具有抑制作用 ,主要表现在肝再生的早期 ,该作用可能是通过受体实现的     

High Fat Diet Induces Liver Steatosis and Early Dysregulation of Iron Metabolism in Rats

This paper is dedicated to the memory of our wonderful colleague Professor Alfredo Colonna, who passed away the same day of its acceptance. Fatty liver accumulation, inflammatory process and insulin resistance appear to be crucial in non-alcoholic fatty liver disease (NAFLD), nevertheless emerging findings pointed an important role also for iron overload. Here, we investigate the molecular mechanisms of hepatic iron metabolism in the onset of steatosis to understand whether its impairment could be an early event of liver inflammatory injury. Rats were fed with control diet or high fat diet (HFD) for 5 or 8 weeks, after which liver morphology, serum lipid profile, transaminases levels and hepatic iron content (HIC), were evaluated. In liver of HFD fed animals an increased time-dependent activity of iron regulatory protein 1 (IRP1) was evidenced, associated with the increase in transferrin receptor-1 (TfR1) expression and ferritin down-regulation. Moreover, ferroportin (FPN-1), the main protein involved in iron export, was down-regulated accordingly with hepcidin increase. These findings were indicative of an increased iron content into hepatocytes, which leads to an increase of harmful free-iron also related to the reduction of hepatic ferritin content. The progressive inflammatory damage was evidenced by the increase of hepatic TNF-α, IL-6 and leptin, in parallel to increased iron content and oxidative stress. The major finding that emerged of this study is the impairment of iron homeostasis in the ongoing and sustaining of liver steatosis, suggesting a strong link between iron metabolism unbalance, inflammatory damage and progression of disease.     

Suppression of female-specific murine Cyp2b9 gene expression by growth or glucocorticoid hormones

CYP2B9 is a constitutively and female-specifically expressed P450 isoform in mouse livers. Hypophysectomy-induced CYP2B9 mRNA expression in males to a level similar to that in females, while the operation did not affect females. Twice-daily injection of growth hormone (GH), which mimics the male pattern of GH secretion, significantly repressed hypophysectomy-induced mRNA expression in males. The same treatment completely suppressed expression in intact females. Treatments with synthetic glucocorticoid dexamethasone (DEX) suppressed expression of CYP2B9 mRNA in intact females, but not in GH-treated and un-treated hypophysectomized females. In primary cultured mouse hepatocytes, CYP2B9 mRNA expression was concentration-dependently suppressed by natural glucocorticoids such as hydrocortisone and corticosterone as well as by DEX. Glucocorticoid-mediated suppression was partially inhibited by RU486, a potent antiglucocorticoid. In contrast, RU486 by itself suppressed expression of CYP2B9 mRNA. These observations suggest that the sexually dimorphic expression of CYP2B9 is partly due to suppression by the masculine plasma GH profile and by glucocorticoid hormones.     

HBx‐dependent activation of twist mediates STAT3 control of epithelium‐mesenchymal transition of liver cells

This study investigated the molecular mechanisms of liver cells with HBx expression on epithelium–mesenchymal transition (EMT) change using Western blot analysis and Transwell assay to assess EMT‐related protein expression and cell mobility. Luciferase reporter assay and chromatin immunoprecipitation (ChIP) assay were used to test the Twist promoter containing different STAT3 binding loci. Electrophoretic mobility band‐shift assay (EMSA) was used to detect Twist activity. Results showed that HBx expression affected the EMT‐related protein expression and the cell mobility of liver cancer cells (MHCC97) and liver cells (HL‐7702) in vitro or in vivo. These proteins exhibited reversed expression to a certain extent after Twist inhibition. In addition, the wound‐healing capability and the mobility of HL‐7702/HBx cells were lower than those treated with control‐siRNA. The expressions of p‐STAT3 and Twist were positively correlated with HBx expression. The second STAT‐3 binding sequence in the Twist promoter region of the HL‐7702/HBx cells was the first locus. Twist activity in the HL‐7702/HBx2 cells was higher than that in HL‐7702 cells. Moreover, the activity decreased when the cells were treated with HBx‐siRNA to inhibit HBx expression, or with STAT3 inhibitor to reduce STAT3 activation. Therefore, Twist is essential for the regulation of the mobility of liver cells with HBx expression. HBx activates the Twist promoter by activating STAT3 and promotes EMT occurrence in liver cells. J. Cell. Biochem. 114: 1097–1104, 2013. © 2012 Wiley Periodicals, Inc.     

Foot-shock Stress-Induced Regional Iron Accumulation and Altered Iron Homeostatic Mechanisms in Rat Brain

Like in other organs, iron in the brain plays an important role in various biological processes. Previous studies have shown that systemic iron homeostasis in mammalians was changed under specific stress conditions. The present study aimed to investigate effects of stress on brain iron homeostasis in rats using a foot-shock stress model. Young adult male Sprague-Dawley rats were randomly assigned to foot-shock stress group subjected to 30 min of cutaneous foot-shock (0.80 mA, 1 pulse/s, 300 ms duration) daily for 1 week or control group left undisturbed. Then, the rats were sacrificed and iron concentration in serum, liver, and some brain regions were measured using atomic absorption spectrophotometry. Expression of ferritin, Transferrin receptor (TfR), divalent metal transporter 1 (DMT1, with or without iron-responsive element), lactoferrin (Lf), and iron regulatory protein 1 (IRP1) in rat hippocampus were determined using western blot analysis. The results showed that stress induced decreased serum iron concentration, increased liver iron content, and elevated iron contents in specific brain regions including hippocampus, striatum, and frontal cortex. In the hippocampus, stress caused decreased expression of ferritin, increased expression of TfR and IRP1, and no change in expression of DMT1 or Lf. Results of this study demonstrated that foot-shock stress induced region specific iron accumulation and altered iron homeostatic mechanisms in the brain in addition to a changed systemic iron homeostasis characterized by decreased serum iron concentration and increased liver iron content. And, elevated IRP1 expression might be associated with the increased TfR and decreased ferritin expression, leading to subsequent iron accumulation and possible increased vulnerability to oxidative damage in hippocampus.     

Effects of interferon-gamma and lipopolysaccharide on macrophage iron metabolism are mediated by nitric oxide-induced degradation of iron regulatory protein 2

Iron regulatory proteins (IRP-1 and IRP-2) control the synthesis of transferrin receptors (TfR) and ferritin by binding to iron-responsive elements, which are located in the 3'-untranslated region and the 5'-untranslated region of their respective mRNAs. Cellular iron levels affect binding of IRPs to iron-responsive elements and consequently expression of TfR and ferritin. Moreover, NO(*), a redox species of nitric oxide that interacts primarily with iron, can activate IRP-1 RNA binding activity resulting in an increase in TfR mRNA levels. Recently we found that treatment of RAW 264.7 cells (a murine macrophage cell line) with NO(+) (nitrosonium ion, which causes S-nitrosylation of thiol groups) resulted in a rapid decrease in RNA binding of IRP-2 followed by IRP-2 degradation, and these changes were associated with a decrease in TfR mRNA levels (Kim, S., and Ponka, P. (1999) J. Biol. Chem. 274, 33035-33042). In this study, we demonstrated that stimulation of RAW 264.7 cells with lipopolysaccharide (LPS) and interferon-gamma (IFN-gamma) increased IRP-1 binding activity, whereas RNA binding of IRP-2 decreased and was followed by a degradation of this protein. Moreover, the decrease of IRP-2 binding/protein levels was associated with a decrease in TfR mRNA levels in LPS/IFN-gamma-treated cells, and these changes were prevented by inhibitors of inducible nitric oxide synthase. Furthermore, LPS/IFN-gamma-stimulated RAW 264.7 cells showed increased rates of ferritin synthesis. These results suggest that NO(+)-mediated degradation of IRP-2 plays a major role in iron metabolism during inflammation.     

Iron accumulation and neurotoxicity in cortical cultures treated with holotransferrin

Nonheme iron accumulates in CNS tissue after ischemic and hemorrhagic insults and may contribute to cell loss. The source of this iron has not been precisely defined. After blood-brain barrier disruption, CNS cells may be exposed to plasma concentrations of transferrin-bound iron (TBI), which exceed that in the CSF by over 50-fold. In this study, the hypothesis that these concentrations of TBI produce cell iron accumulation and neurotoxicity was tested in primary cortical cultures. Treatment with 0.5-3 mg/ml holotransferrin for 24 h resulted in the loss of 20-40% of neurons, associated with increases in malondialdehyde, ferritin, heme oxygenase-1, and iron; transferrin receptor-1 expression was reduced by about 50%. Deferoxamine, 2,2′-bipyridyl, Trolox, and ascorbate prevented all injury, but apotransferrin was ineffective. Cell TBI accumulation was significantly reduced by deferoxamine, 2,2′-bipyridyl, and apotransferrin, but not by ascorbate or Trolox. After treatment with ⁵⁵Fe-transferrin, approximately 40% of cell iron was exported within 16 h. Net export was increased by deferoxamine and 2,2′-bipyridyl, but not by apotransferrin. These results suggest that downregulation of transferrin receptor-1 expression is insufficient to prevent iron-mediated death when neurons are exposed to plasma concentrations of TBI. Chelator therapy may be beneficial for acute CNS injuries associated with loss of blood-brain barrier integrity.     

Recycling of RNA binding iron regulatory protein 1 into an aconitase after nitric oxide removal depends on mitochondrial ATP

Iron regulatory proteins (IRPs) control iron metabolism by specifically interacting with iron-responsive elements (IREs) on mRNAs. Nitric oxide (NO) converts IRP-1 from a [4Fe-4S] aconitase to a trans-regulatory protein through Fe-S cluster disassembly. Here, we have focused on the fate of IRE binding IRP1 from murine macrophages when NO flux stops. We show that virtually all IRP-1 molecules from NO-producing cells dissociated from IRE and recovered aconitase activity after re-assembling a [4Fe-4S] cluster in vitro. The reverse change in IRP-1 activities also occurred in intact cells no longer exposed to NO and did not require de novo protein synthesis. Likewise, inhibition of mitochondrial aconitase via NO-induced Fe-S cluster disassembly was also reversed independently of protein translation after NO removal. Our results provide the first evidence of Fe-S cluster repair of NO-modified aconitases in mammalian cells. Moreover, we show that reverse change in IRP-1 activities and repair of mitochondrial aconitase activity depended on energized mitochondria. Finally, we demonstrate that IRP-1 activation by NO was accompanied by both a drastic decrease in ferritin levels and an increase in transferrin receptor mRNA levels. However, although ferritin expression was recovered upon IRP-1-IRE dissociation, expression of transferrin receptor mRNA continued to rise for several hours after stopping NO flux.     

Aluminium toxicity and iron homeostasis.

In an animal model of aluminum overload, (aluminium gluconate), the increases in tissue aluminium content were paralleled by elevations of tissue iron in the kidney, liver heart and spleen as well as in various brain regions, frontal, temporal and parietal cortex and hippocampus. Despite such increases in iron content there were no significant changes in the activities of a wide range of cytoprotective enzymes apart from an increase in superoxide dismutase in the frontal cortex of the aluminium loaded rats. Such increases in tissue iron content may be attributed to the stabilisation of IRP-2 by aluminium thereby promoting transferrin receptor synthesis while blocking ferritin synthesis. Using the radioactive tracer (26)Al less than 1% of the injected dose was recovered in isolated ferritin, supporting previous studies which also found little evidence for aluminium storage within ferritin. The increases in brain iron may well be contributory to neurodegeneration, although the pathogenesis by which iron exerts such an effect is unclear.     

Sex Differences in Iron Status and Hepcidin Expression in Rats

Studies have shown that men and women exhibit significant differences regarding iron status. However, the effects of sex on iron accumulation and distribution are not well established. In this study, female and male Sprague-Dawley rats were killed at 4 months of age. Blood samples were analyzed to determine the red blood cell (RBC) count, hemoglobin (Hb) concentration, hematocrit (Hct), and mean red blood cell volume (MCV). The serum samples were analyzed to determine the concentrations of serum iron (SI), transferrin saturation (TS), ferritin, soluble transferrin receptor (sTfR), and erythropoietin (EPO). The tissue nonheme iron concentrations were measured in the liver, spleen, bone marrow, kidney, heart, gastrocnemius, duodenal epithelium, lung, pallium, cerebellum, hippocampus, and striatum. Hepatic hepcidin expression was detected by real-time PCR analysis. The synthesis of ferroportin 1 (FPN1) in the liver, spleen, kidney, and bone marrow was determined by Western blot analysis. The synthesis of duodenal cytochrome B561 (DcytB), divalent metal transporter 1 (DMT1), FPN1, hephaestin (HP) in the duodenal epithelium was also measured by Western blot analysis. The results showed that the RBC, Hb, and Hct in male rats were higher than those in female rats. The SI and plasma TS levels were lower in male rats than in female rats. The levels of serum ferritin and sTfR were higher in male rats than in female rats. The EPO levels in male rats were lower than that in female rats. The nonheme iron contents in the liver, spleen, bone marrow, and kidney in male rats were also lower (56.7, 73.2, 60.6, and 61.4 % of female rats, respectively). Nonheme iron concentrations in the heart, gastrocnemius, duodenal epithelium, lung, and brain were similar in rats of both sexes. A moderate decrease in hepatic hepcidin mRNA content was also observed in male rats (to 56.0 % of female rats). The levels of FPN1 protein in the liver, spleen, and kidney were higher in male rats than in female rats. There was no significant change in FPN1 expression in bone marrow. Significant difference was also not found in DcytB, DMT1, FPN1, and HP protein levels in the duodenal epithelium between male and female rats. These data suggest that iron is distributed differently in male and female rats. This difference in iron distribution may be associated with the difference in the hepcidin level.     

RU486 inhibits induction of aromatase by dexamethasone via glucocorticoid receptor in cultured human skin fibroblasts

Effects of RU486 on the induction of aromatase by dexamethasone via glucocorticoid receptor were determined using cultured human skin fibroblasts. Competition of [3H]dexamethasone binding to the cytosol receptor was 7 times stronger with RU486 than with dexamethasone. The order of the strength of competition was RU486 greater than dexamethasone greater than betamethasone greater than prednisolone greater than hydrocortisone. RU486 abolished a specific 8.6 S [3H]dexamethasone binding peak in the cytosol, determined using a sucrose density gradient analysis. Dexamethasone markedly induced aromatase and this event was strongly suppressed by RU486, in a dose-dependent manner, in the cultured skin fibroblasts. A linear correlation between the strength of competition and the induction of aromatase of various glucocorticoids was observed. RU486 non-competitively inhibited aromatase induction by dexamethasone determined from a double reciprocal plot of aromatase activity, with respect to [3H]androstenedione concentration in the presence of RU486. These results show that RU486 is a peripheral noncompetitive antiglucocorticoid on aromatase induction by glucocorticoid in human skin fibroblasts and that aromatase induction is a good marker for the biological function of glucocorticoid receptor in human skin fibroblasts.     

Excess capacity of the iron regulatory protein system

Iron regulatory proteins (IRP1 and IRP2) are master regulators of cellular iron metabolism. IRPs bind to iron-responsive elements (IREs) present in the untranslated regions of mRNAs encoding proteins of iron storage, uptake, transport, and export. Because simultaneous knockout of IRP1 and IRP2 is embryonically lethal, it has not been possible to use dual knockouts to explore the consequences of loss of both IRP1 and IRP2 in mammalian cells. In this report, we describe the use of small interfering RNA to assess the relative contributions of IRP1 and IRP2 in epithelial cells. Stable cell lines were created in which either IRP1, IRP2, or both were knocked down. Knockdown of IRP1 decreased IRE binding activity but did not affect ferritin H and transferrin receptor 1 (TfR1) expression, whereas knockdown of IRP2 marginally affected IRE binding activity but caused an increase in ferritin H and a decrease in TfR1. Knockdown of both IRPs resulted in a greater reduction of IRE binding activity and more severe perturbation of ferritin H and TfR1 expression compared with single IRP knockdown. Even though the knockdown of IRP-1, IRP-2, or both was efficient, resulting in nondetectable protein and under 5% of wild type levels of mRNA, all stable knockdowns retained an ability to modulate ferritin H and TfR1 appropriately in response to iron challenge. However, further knockdown of IRPs accomplished by transient transfection of small interfering RNA in stable knockdown cells completely abolished the response of ferritin H and TfR1 to iron challenge, demonstrating an extensive excess capacity of the IRP system.     

Ligand-induced structural alterations in human iron regulatory protein-1 revealed by protein footprinting.

Human iron regulatory protein-1 (IRP-1) is a bifunctional protein that regulates iron metabolism by binding to mRNAs encoding proteins involved in iron uptake, storage, and utilization. Intracellular iron accumulation regulates IRP-1 function by promoting the assembly of an iron-sulfur cluster, conferring aconitase activity to IRP-1, and hindering RNA binding. Using protein footprinting, we have studied the structure of the two functional forms of IRP-1 and have mapped the surface of the iron-responsive element (IRE) binding site. Binding of the ferritin IRE or of the minimal regulatory region of transferrin receptor mRNA induced strong protections against proteolysis in the region spanning amino acids 80 to 187, which are located in the putative cleft thought to be involved in RNA binding. In addition, IRE-induced protections were also found in the C-terminal domain at Arg-721 and Arg-728. These data implicate a bipartite IRE binding site located in the putative cleft of IRP-1. The aconitase form of IRP-1 adopts a more compact structure because strong reductions of cleavage were detected in two defined areas encompassing residues 149 to 187 and 721 to 735. Thus both ligands of apo-IRP-1, the IRE and the 4Fe-4S cluster, induce distinct but overlapping alterations in protease accessibility. These data provide evidences for structural changes in IRP-1 upon cluster formation that affect the accessibility of residues constituting the RNA binding site.