TANK-binding kinase-1 (TBK1) and the inducible IκB kinase (IKK-i) have been shown recently to activate interferon (IFN) regulatory factor-3 (IRF3), the primary transcription factor regulating induction of type I IFNs. Here, we have compared the role and specificity of TBK1 in the type I IFN response to lipopolysaccharide (LPS), polyI:C, and viral challenge by examining IRF3 nuclear translocation, signal transducer and activator of transcription 1 phosphorylation, and induction of IFN-regulated genes. The LPS and polyI:C-induced IFN responses were abolished and delayed, respectively, in macrophages from mice with a targeted disruption of the TBK1 gene. When challenged with Sendai virus, the IFN response was normal in TBK1−/− macrophages, but defective in TBK1−/− embryonic fibroblasts. Although both TBK1 and IKK-i are expressed in macrophages, only TBK1 but not IKK-i was detected in embryonic fibroblasts by Northern blotting analysis. Furthermore, the IFN response in TBK1−/− embryonic fibroblasts can be restored by reconstitution with wild-type IKK-i but not a mutant IKK-i lacking kinase activity. Thus, our studies suggest that TBK1 plays an important role in the Toll-like receptor–mediated IFN response and is redundant with IKK-i in the response of certain cell types to viral infection.
In thalassemia and other iron loading anemias, ineffective erythropoiesis and erythroid signaling molecules are thought to cause inappropriate suppression of a small peptide produced by hepatocytes named hepcidin. Previously, it was reported that the erythrokine GDF15 is expressed at very high levels in thalassemia and suppresses hepcidin expression. In this study, erythroblast expression of a second molecule named twisted gastrulation (TWSG1) was explored as a potential erythroid regulator of hepcidin. Transcriptome analyses suggest TWSG1 is produced during the earlier stages of erythropoiesis. Hepcidin suppression assays demonstrated inhibition by TWSG1 as measured by quantitative polymerase chain reaction (PCR) in dosed assays (1-1000 ng/mL TWSG1). In human cells, TWSG1 suppressed hepcidin indirectly by inhibiting the signaling effects and associated hepcidin up-regulation by bone morphogenic proteins 2 and 4 (BMP2/BMP4). In murine hepatocytes, hepcidin expression was inhibited by murine Twsg1 in the absence of additional BMP. In vivo studies of Twsg1 expression were performed in healthy and thalassemic mice. Twsg1 expression was significantly increased in the spleen, bone marrow, and liver of the thalassemic animals. These data demonstrate that twisted gastrulation protein interferes with BMPmediated hepcidin expression and may act with GDF15 to dysregulate iron homeostasis in thalassemia syndromes. IntroductionSystemic iron homeostasis in mammals is largely maintained by the effects of hepcidin, 1 a small protein produced by hepatocytes. Hepcidin is regulated at the transcriptional and posttranscriptional levels by multiple extracellular signals related to iron homeostasis and inflammation. Erythropoiesis is also thought to regulate hepcidin expression through a variety of mechanisms including anemia-related hypoxia and erythropoietin production. -Thalassemia syndromes are congenital anemias caused by mutations that reduce or abolish -globin gene expression. Despite the common feature of decreased globin chain synthesis in all patients, there are prominent phenotypic variations in the disease that are not fully understood. 2 In so-called "iron-loading" anemias like thalassemia, the diseased erythron dysregulates iron homeostasis by inhibiting hepcidin expression even in the presence of severe iron overload. Humans with thalassemia syndromes express very high levels of a cytokine named GDF15, and GDF15 present in thalassemia patients' sera inhibited hepatic hepcidin expression ex vivo. 3 However, thalassemia sera also suppressed hepcidin expression to a lesser degree after immunoprecipitation of GDF15. 3 It was therefore hypothesized that GDF15 may act with other molecules to suppress hepcidin.In addition to clinical research in humans, murine models were developed for studies of thalassemia and hepcidin regulation. Mice with deletions of both the  minor and  major genes (th3 genotype) have a -thalassemia intermedia phenotype in the heterozygous state. The homozygous deletion (th3/th3) results in death...
The peptide hormone hepcidin is the principal regulator of systemic iron homeostasis. We examined the pathway by which iron stimulates the production of hepcidin. In humans who ingested 65 mg of iron, the increase in transferrin saturation preceded by hours the increase in urinary hepcidin excretion. Increases in urinary hepcidin concentrations were proportional to the increment in transferrin saturation. Paradoxically, in previous studies in primary hepatocytes and cell lines, hepcidin response to iron or iron transferrin was not observed. We now report that freshly isolated murine primary hepatocytes responded to holotransferrin but not apotransferrin by increasing hepcidin mRNA. Hepcidin increase was not due to contamination of the transferrin preparations by endotoxin, a potent pathologic stimulus of hepcidin synthesis. Using this culture system, we showed that holotransferrin concentrations regulate hepcidin mRNA concentrations through a hemojuvelin/BMP2/4-dependent pathway. Although BMP9 is known to be expressed in the liver and potently increased the basal concentrations of hepcidin mRNA, it did not interact with hemojuvelin, and interference with its signaling pathway did not affect iron regulation. Fresh primary hepatocytes constitute a sufficient system for the regulation of hepcidin by physiologic iron stimuli and will greatly facilitate studies of major disorders of iron homeostasis. IntroductionHepcidin (HAMP) is the principal iron-regulatory hormone. 1 It is predominantly produced in the liver, circulates in blood, and is excreted in urine. Hepcidin regulates systemic iron homeostasis by inhibiting dietary iron absorption in the small intestine, recycling of iron from senescent erythrocytes by macrophages, and iron mobilization from hepatic stores.Hepcidin production is affected by dietary or parenteral iron loading, iron stores, erythropoietic activity, tissue hypoxia, and inflammation. [2][3][4][5] In healthy humans and mice, iron loading by ingestion or injection induces hepcidin synthesis. However, how iron regulates hepcidin production is still unknown. Previous in vitro studies with hepatoma cell lines and primary hepatocytes reproduced the response of hepcidin during inflammation and hypoxia but failed to demonstrate increased hepcidin synthesis in response to iron loading. It appeared that some essential regulatory components present in vivo were missing in isolated hepatocytes.In hereditary hemochromatosis, dietary iron is hyperabsorbed and accumulates in tissues, eventually causing organ damage. Hepcidin analyses in human subjects and in animal models indicate that most hereditary hemochromatosis is due to hepcidin deficiency resulting from primary mutations in human hemochromatosis gene (HFE), transferrin receptor 2 (TFR2), the juvenile hemochromatosis gene hemojuvelin (HJV), or the hepcidin gene itself. This implies that HFE, transferrin receptor 2, and hemojuvelin play important roles in the regulation of hepcidin. Mutations of hemojuvelin result in the most severe form of hereditary ...
The deficiency of hepcidin, the hormone that controls iron absorption and its tissue distribution, is the cause of iron overload in nearly all forms of hereditary hemochromatosis and in untransfused iron-loading anemias. In a recent study, we reported the development of minihepcidins, small drug-like hepcidin agonists. Here we explore the feasibility of using minihepcidins for the prevention and treatment of iron overload in hepcidindeficient mice. An optimized minihepcidin (PR65) was developed that had superior potency and duration of action compared with natural hepcidin or other minihepcidins, and favorable cost of synthesis. PR65 was administered by subcutaneous injection daily for 2 weeks to iron-depleted or iron-loaded hepcidin knockout mice. PR65 administration to iron-depleted mice prevented liver iron loading, decreased heart iron levels, and caused the expected iron retention in the spleen and duodenum. At high doses, PR65 treatment also caused anemia because of profound iron restriction. PR65 administration to hepcidin knockout mice with pre-existing iron overload had a more moderate effect and caused partial redistribution of iron from the liver to the spleen. Our study demonstrates that minihepcidins could be beneficial in iron overload disorders either used alone for prevention or possibly as adjunctive therapy with phlebotomy or chelation. IntroductionProduced by the liver, hepcidin is a 25 amino acid peptide hormone that circulates in plasma and homeostatically controls body iron balance. 1 Iron levels in turn regulate hepcidin production: in healthy individuals, hepcidin production increases when plasma or tissue iron concentrations rise and decreases after iron depletion. The hormone binds to its receptor ferroportin, the sole exporter of cellular iron into plasma. Ferroportin is prominently expressed in enterocytes, iron-recycling macrophages and hepatocytes. Hepcidin binding initiates the endocytosis and proteolysis of ferroportin and thereby decreases iron flow into plasma. 2 In hereditary hemochromatoses (HH) types I-III, mutations in genes encoding hepcidin regulators, or hepcidin itself lead to diminished production of hepcidin thus decreasing the inhibitory effect of hepcidin on duodenal iron absorption and causing clinical iron overload. 3 Hepcidin deficiency and hyperabsorption of dietary iron are major factors not only in HH but also in iron overload associated with hereditary anemias caused by ineffective erythropoiesis. 4 Hepcidin replacement therapy with pharmacologically optimized agonists would provide a rational treatment for these disorders. In HH or -thalassemia intermedia, early diagnosis may allow preventive treatment with hepcidin agonists to normalize iron regulation, and reduce the potential for iron toxicity and the need for phlebotomy or chelation. Aside from inhibiting dietary iron absorption, hepcidin or hepcidin agonists may also have a protective effect on the liver, heart, and other organs by causing redistribution of iron into macrophages of the liver and spleen...
Background/Aims-Patients with chronic hepatitis C (CHC) often have increased liver iron, a condition associated with reduced sustained response to antiviral therapy, more rapid progression to cirrhosis, and development of hepatocellular carcinoma. The hepatic hormone hepcidin is the major regulator of iron metabolism and inhibits iron absorption and recycling from erythrophagocytosis. Hepcidin decrease is a possible pathophysiological mechanism of iron overload in CHC, but studies in humans have been hampered so far by the lack of reliable quantitative assays for the 25-amino acid bioactive peptide in serum (s-hepcidin).Methods-Using a recently validated immunoassay, we measured s-hepcidin levels in 81 untreated CHC patients and 57 controls with rigorous definition of normal iron status. All CHC patients underwent liver biopsy with histological iron score.Results-S-hepcidin was significantly lower in CHC patients than in controls (geometric means with 95% confidence intervals: 33.7, 21.5-52.9 vs. 90.9, 76.1-108.4 ng/mL, respectively; p < 0.001). In CHC patients, s-hepcidin significantly correlated with serum ferritin and histological total iron score, but not with s-interleukin-6. After stratification for ferritin quartiles, s-hepcidin increased significantly across quartiles in both controls and CHC patients (chi for trend, p < 0.001). However, in CHC patients, s-hepcidin was significantly lower than in controls for each corresponding quartile (analysis of variance, p < 0.001).Conclusions-These results, together with very recent studies in animal and cellular models, indicate that although hepcidin regulation by iron stores is maintained in CHC, the suppression of
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