The Journal of biological chemistry
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Tissue needs for retinoids are believed to be satisfied through the delivery in the circulation of retinol by its specific plasma transport protein, retinol-binding protein (RBP), which circulates as a 1-to-1 protein complex with transthyretin (TTR). The binding of RBP to TTR is thought to prevent filtration of retinol-RBP in the kidney and to play a role in secretion of RBP from hepatocytes. Recently a strain of mice (TTR-) that totally lacks immunoreactive TTR was produced by targeted mutagenesis. ⋯ Kidney RBP levels were similar for the mutant and wild type mice and we were unable to detect intact RBP in urine from TTR- mice. Hepatic RBP levels in the TTR- mice were 60% higher than those of wild type mice (39.8 versus 25.0 micrograms of RBP/g of tissue). These data may suggest that there is a partial blockage in RBP secretion from TTR- hepatocytes that leads to lessened plasma levels of retinol-RBP.
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Previous studies have shown that hepsin is a putative membrane-associated serine protease that is required for cell growth (Torres-Rosado, A., O'Shea, K. S., Tsuji, A., Chou, S.-H., and Kurachi, K. (1993) Proc. Natl. ⋯ In the copresence of factor VII and factor X, hepsin-transfected BHK cells supported the formation of factor Xa. In addition, in the copresence of factor VII, factor X, and prothrombin, hepsin-transfected BHK cells supported the formation of thrombin. These results strongly suggest that membrane-associated hepsin converts zymogen factor VII to factor VIIa, which in turn, is capable of initiating a coagulation pathway on the cell surface that ultimately leads to thrombin formation.
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Several genes critical to the uptake, sequestration, and utilization of iron are regulated at the post-transcriptional level. The mRNAs encoded by these genes contain highly conserved stem-loop structures called iron-responsive elements (IREs). IREs function as the nucleic acid-binding sites for a cytosolic RNA-binding protein called the IRE-binding protein or IRE-BP. ⋯ In most cell lines tested, levels of IRP2 are inversely regulated by iron levels due to iron-dependent regulation of the half-life of the protein. In addition to changes in total amounts of IRP2, we demonstrate that the IRE binding activity of IRP2 can also vary up to 4-fold in the absence of any change in IRP2 protein levels. The possible reasons for the existence of a second IRP are discussed.
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The erythropoietin receptor (EpoR) belongs to the cytokine receptor family, members of which lack a tyrosine kinase domain. Recent studies, however, have shown that a cytoplasmic tyrosine kinase, JAK2, interacts with the cytoplasmic domain of the EpoR and becomes activated upon binding of Epo to the receptor. Epo has also been shown to stimulate activation of Ras and Raf-1. ⋯ In cells expressing a mutant EpoR that is constitutively activated by a point mutation, Arg129 to Cys, in the extracellular portion of the receptor, neither tyrosine phosphorylation of Shc nor activation of MAP kinases by phosphorylation was detectable without stimulation with Epo or IL-3. These results suggest that the carboxyl-terminal region of EpoR may play a crucial role in activation of MAP kinases through the Ras signaling pathway which may be activated by tyrosine phosphorylation of Shc and its association with Grb2. The activation of MAP kinases, however, failed to correlate with the mitogenic activity of mutant EpoRs and thus may not be required for growth signaling from the EpoR.
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Transcription of the adipocyte-specific adipsin gene is dramatically reduced in the adipose tissue of a number of genetically and chemically-induced obese rodents. To map the region of the adipsin gene that confers this response to obesity, transgenic mice were made containing -114, -250, -400, -700, and -938 base pairs (bp) to +35 bp of the promoter linked to the bacterial chloramphenicol acetyltransferase gene. Transgenic mice containing as few as 114 bp of the adipsin promoter had high levels of chloramphenicol acetyltransferase activity in adipose tissue. ⋯ Using gel retardation assays, we showed that a 56-bp fragment of DNA mapping between -687 and -743 bp upstream from the start of adipsin expression was bound by protein factors in nuclear extracts prepared from adipose tissue. There was much greater retardation of this fragment with nuclear extracts prepared from adipose tissue of lean versus obese mice. These results indicate that a tissue-specific transcription factor(s) that regulates adipsin expression is less active in the adipose tissue of obese animals.