ABSTRACT
Mammalian cells require a constant supply of oxygen to maintain adequate energy production, which is essential for maintaining normal function and for ensuring cell survival. Sustained hypoxia can result in cell death. It is, therefore, not surprising that sophisticated mechanisms have evolved that allow cells to adapt to hypoxia. "Oxygen-sensing" is a special phenotype that functions to detect changes in oxygen tension and to transduce this signal into organ system functions that enhance the delivery of oxygen to tissue in various organisms. Oxygen-sensing cells can be segregated into two distinct cell types: those that functionally depolarize (excitable) and those that do not functionally depolarize (nonexcitable) in response to reduced oxygen. Theoretically, excitable cells have all the same signaling capabilities as the nonexcitable cells, but the nonexcitable cells cannot have all the signaling capabilities as excitable cells. A number of signaling pathways have been identified that regulate gene expression during hypoxia. These include the Ca2+-calmodulin pathway, the 3'-5' adenosine monophosphate (cAMP)-protein kinase A (PKA) pathway, the p42 and p44 mitogen-activated protein kinase [(MAPK); also known as the extracellular signal-related kinase (ERK) for ERK1 and ERK2] pathway, the stress-activated protein kinase (SAPK; also known as p38 kinase) pathway, and the phosphatidylinositol 3-kinase (PI3K)-Akt pathway. In this review, we describe hypoxia-induced signaling in the model O2-sensing rat pheochromocytoma (PC12) cell line, the current level of understanding of the major signaling events that are activated by reduced O2, and how these signaling events lead to altered gene expression in both excitable and nonexcitable oxygen-sensing cells.
Subject(s)
Cell Hypoxia/physiology , PC12 Cells/physiology , Animals , Cell Hypoxia/genetics , Humans , RatsABSTRACT
Subtractive suppression hybridization was used to generate a cDNA library enriched in cDNA sequences corresponding to mRNA species that are specifically up-regulated by hypoxia (6 h, 1% O(2)) in the oxygen-responsive pheochromocytoma cell line. The dual specificity protein-tyrosine phosphatase MAPK phosphatase-1 (MKP-1) was highly represented in this library. Clones were arrayed on glass slides to create a hypoxia-specific cDNA microarray chip. Microarray, northern blot, and western blot analyses confirmed that MKP-1 mRNA and protein levels were up-regulated by hypoxia by approximately 8-fold. The magnitude of the effect of hypoxia on MKP-1 was approximately equal to that induced by KCl depolarization and much larger than the effects of either epidermal growth factor or nerve growth factor on MKP-1 mRNA levels. In contrast to the calcium-dependent induction of MKP-1 by KCl depolarization, the effect of hypoxia on MKP-1 persisted under calcium-free conditions. Cobalt and deferoxamine also increased MKP-1 mRNA levels, suggesting that hypoxia-inducible factor proteins may play a role in the regulation of MKP-1 by hypoxia. Pretreatment of cells with SB203580, which inhibits p38 kinase activity, significantly reduced the hypoxia-induced increase in MKP-1 RNA levels. Thus, hypoxia robustly increases MKP-1 levels, at least in part through a p38 kinase-mediated mechanism.
Subject(s)
Cell Cycle Proteins , Hypoxia , Immediate-Early Proteins/metabolism , Oligonucleotide Array Sequence Analysis , Phosphoprotein Phosphatases , Protein Tyrosine Phosphatases/metabolism , Animals , Blotting, Northern , Blotting, Western , Calcium/pharmacology , Cell Nucleus/metabolism , Cobalt/pharmacology , DNA, Complementary/metabolism , Deferoxamine/pharmacology , Dose-Response Relationship, Drug , Dual Specificity Phosphatase 1 , Enzyme Inhibitors/pharmacology , Flavonoids/pharmacology , Gene Library , Imidazoles/pharmacology , Mitogen-Activated Protein Kinases/metabolism , Nucleic Acid Hybridization , PC12 Cells , Polymerase Chain Reaction , Potassium Chloride/pharmacology , Protein Phosphatase 1 , Pyridines/pharmacology , RNA, Messenger/metabolism , Rats , Signal Transduction , Time Factors , Up-Regulation , p38 Mitogen-Activated Protein KinasesABSTRACT
Stress-induced analgesia is a well-documented phenomenon that occurs in all mammalian species. Forced cold water swim produces a type of stress-induced analgesia that is independent of mu opioid receptors. The neuropeptide neurotensin (NT) has been implicated in mu opioid-independent analgesia (MOIA), but the circuitry of this system is largely unknown. The medial preoptic area (MPO) and lateral hypothalamus (LH) are two regions that are known to modulate pain processing. These two regions also contain neurotensinergic projections to the periaqueductal gray, a region that has been shown to produce MOIA upon injection of NT. The goal of this study was to determine if cold water swim (CWS) stress, which produces MOIA, activates the NT-ergic systems in these two regions. In situ hybridization results indicate that CWS increases the level of NT mRNA within neurons in the MPO and LH, suggesting that these two regions are activated during this process.
Subject(s)
Cold Temperature , Hypothalamic Area, Lateral/physiology , Neurotensin/genetics , Preoptic Area/physiology , Stress, Physiological/physiopathology , Animals , Gene Expression/physiology , Hot Temperature , In Situ Hybridization , Male , Pain Threshold/physiology , RNA, Messenger/metabolism , Rats , Rats, Sprague-Dawley , Swimming/physiologyABSTRACT
Prior studies have shown that Madin-Darby canine kidney cells (MDCK) overexpressing the human insulin receptor bind and respond normally to insulin (T.C. Yeh, R.A. Roth, Diabetes 43 (1994) 1297-1303). Moreover, the insulin receptor preferentially localizes to the basolateral membrane of these cells. In the present studies, insulin was added to either the apical or the basolateral side of these cells and the extent of degradation of the insulin was assessed. Radioactive insulin added to either side was bound to its receptor and the radioactivity which reached the other side of the cell was to a large extent degraded fragments. Insulin added to the apical side was degraded to a larger extent (83%) than when added to the basolateral side (49%) although the basolateral side has much more insulin receptors than the apical side. This degradation process was not inhibitors of either lysosomal enzymes, the proteasome complex or cathepsins. The degradation process could however, be potently inhibited by the sulfhydryl alkylating agent N-ethylmaleimide. Further, cell surface biotinylation study showed that the insulin degrading enzyme was preferentially localized on the apical membranes. These results suggest that insulin added on the apical side of MDCK cells are more closely linked to the degradation process than that added on the basolateral side.
Subject(s)
Insulin/metabolism , Receptor, Insulin/metabolism , Animals , Biotransformation , Cell Line , Cell Membrane/metabolism , Dogs , Humans , Insulin/analogs & derivatives , Iodine Radioisotopes , Kidney , KineticsABSTRACT
To investigate the role of insulin degrading enzyme (insulysin, EC 3.4.24.56) in insulin signaling, Chinese hamster ovary cells overexpressing the human insulin receptor were genetically engineered to also stably overexpress the rat insulin degrading enzyme. In comparison to the parental cells, these cells expressed 2.7-fold elevated levels of enzyme and insulin degradation was also increased 2-fold. These cells also exhibited a more rapid decrease in receptor tyrosine phosphorylation after removal of insulin. Moreover, low concentrations of insulin were less effective at stimulating proliferation of the cells overexpressing the enzyme. Finally, a fraction of the overexpressed enzyme as well a fraction of the endogenous enzyme could be detected on the plasma membrane surface of these cells. These results support the hypothesis that this enzyme may function in insulin signaling by degrading the insulin molecule.
