5 results on '"Pickering, Andrew M."'
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2. Oxidative stress adaptation with acute, chronic, and repeated stress
- Author
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Pickering, Andrew M., Vojtovich, Lesya, Tower, John, and A. Davies, Kelvin J.
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OXIDATIVE stress , *BIOLOGICAL adaptation , *HORMESIS , *PHYSIOLOGICAL stress , *HEMOGLOBINS , *METHYLCOUMARINS - Abstract
Abstract: Oxidative stress adaptation, or hormesis, is an important mechanism by which cells and organisms respond to, and cope with, environmental and physiological shifts in the level of oxidative stress. Most studies of oxidative stress adaption have been limited to adaptation induced by acute stress. In contrast, many if not most environmental and physiological stresses are either repeated or chronic. In this study we find that both cultured mammalian cells and the fruit fly Drosophila melanogaster are capable of adapting to chronic or repeated stress by upregulating protective systems, such as their proteasomal proteolytic capacity to remove oxidized proteins. Repeated stress adaptation resulted in significant extension of adaptive responses. Repeated stresses must occur at sufficiently long intervals, however (12-h or more for MEF cells and 7 days or more for flies), for adaptation to be successful, and the levels of both repeated and chronic stress must be lower than is optimal for adaptation to acute stress. Regrettably, regimens of adaptation to both repeated and chronic stress that were successful for short-term survival in Drosophila nevertheless also caused significant reductions in life span for the flies. Thus, although both repeated and chronic stress can be tolerated, they may result in a shorter life. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
3. Nrf2-dependent Induction of Proteasome and Pa28αβ Regulator Are Required for Adaptation to Oxidative Stress.
- Author
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Pickering, Andrew M., Linder, Robert A., Zhang, Hongqiao, Forman, Henry J., and Davies, Kelvin J. A.
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OXIDATIVE stress , *PEROXYNITRITE , *MENADIONE , *GENE expression , *PROTEASOME regulation , *CHROMATIN - Abstract
The ability to adapt to acute oxidative stress (e.g. H2O2, peroxynitrite, menadione, and paraquat) through transient alterations in gene expression is an important component of cellular defense mechanisms. We show that such adaptation includes Nrf2-dependent increases in cellular capacity to degrade oxidized proteins that are attributable to increased expression of the 20 S proteasome and the Pa28αβ (11 S) proteasome regulator. Increased cellular levels of Nrf2, translocation of Nrf2 from the cytoplasm to the nucleus, and increased binding of Nrf2 to antioxidant response elements (AREs) or electrophile response elements (EpREs) in the 5'-untranslated region of the proteasome β5 subunit gene (demonstrated by chromatin immunoprecipitation (or ChIP) assay) are shown to be necessary requirements for increased proteasome/Pa28αβ levels, and for maximal increases in proteolytic capacity and stress resistance; Nrf2 siRNA and the Nrf2 inhibitor retinoic acid both block these adaptive changes and the Nrf2 inducers DL-sulforaphane, lipoic acid, and curcumin all replicate them without oxidant exposure. The immunoproteasome is also induced during oxidative stress adaptation, contributing to overall capacity to degrade oxidized proteins and stress resistance. Two of the three immunoproteasome subunit genes, however, contain no ARE/EpRE elements, and Nrf2 inducers, inhibitors, and siRNA all have minimal effects on immunoproteasome expression during adaptation to oxidative stress. Thus, immunoproteasome appears to be (at most) minimally regulated by the Nrf2 signal transduction pathway. [ABSTRACT FROM AUTHOR]
- Published
- 2012
- Full Text
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4. A simple fluorescence labeling method for studies of protein oxidation, protein modification, and proteolysis
- Author
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Pickering, Andrew M. and Davies, Kelvin J.A.
- Subjects
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CHEMICAL modification of proteins , *PROTEOLYSIS , *PROTEASOMES , *METHYLATION , *CARBOXYL group , *OXIDIZING agents , *PEROXYNITRITE , *TRYPSIN , *FLUORESCENCE - Abstract
Abstract: Proteins are sensitive to oxidation, and oxidized proteins are excellent substrates for degradation by proteolytic enzymes such as the proteasome and the mitochondrial Lon protease. Protein labeling is required for studies of protein turnover. Unfortunately, most labeling techniques involve 3H or 14C methylation, which is expensive, exposes researchers to radioactivity, generates large amounts of radioactive waste, and allows only single-point assays because samples require acid precipitation. Alternative labeling methods have largely proven unsuitable, either because the probe itself is modified by the oxidant(s) being studied or because the alternative labeling techniques are too complex or too costly for routine use. What is needed is a simple, quick, and cheap labeling technique that uses a non-radioactive marker, binds strongly to proteins, is resistant to oxidative modification, and emits a strong signal. We have devised a new reductive method for labeling free carboxyl groups of proteins with the small fluorophore 7-amino-4-methycoumarin (AMC). When bound to target proteins, AMC fluoresces very weakly but when AMC is released by proteinases, proteases, or peptidases, it fluoresces strongly. Thus, without acid precipitation, the proteolysis of any target protein can be studied continuously, in multiwell plates. In direct comparisons, 3H-labeled proteins and AMC-labeled proteins exhibited essentially identical degradation patterns during incubation with trypsin, cell extracts, and purified proteasome. AMC-labeled proteins are well suited to studying increased proteolytic susceptibility after protein modification, because the AMC–protein bond is resistant to oxidizing agents such as hydrogen peroxide and peroxynitrite and is stable over time and to extremes of pH, temperature (even boiling), freeze–thaw, mercaptoethanol, and methanol. [Copyright &y& Elsevier]
- Published
- 2012
- Full Text
- View/download PDF
5. HSP70 mediates dissociation and reassociation of the 26S proteasome during adaptation to oxidative stress
- Author
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Grune, Tilman, Catalgol, Betül, Licht, Anke, Ermak, Gennady, Pickering, Andrew M., Ngo, Jenny K., and Davies, Kelvin J.A.
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MOLECULAR chaperones , *MULTIENZYME complexes , *OXIDATIVE stress , *DISSOCIATION (Chemistry) , *CELLULAR signal transduction , *CELL metabolism , *FIBROBLASTS , *CHLOROACETIC acids - Abstract
Abstract: We report an entirely new role for the HSP70 chaperone in dissociating 26S proteasome complexes (into free 20S proteasomes and bound 19S regulators), preserving 19S regulators, and reconstituting 26S proteasomes in the first 1–3h after mild oxidative stress. These responses, coupled with direct 20S proteasome activation by poly(ADP ribose) polymerase in the nucleus and by PA28αβ in the cytoplasm, instantly provide cells with increased capacity to degrade oxidatively damaged proteins and to survive the initial effects of stress exposure. Subsequent adaptive (hormetic) processes (3–24h after stress exposure), mediated by several signal transduction pathways and involving increased transcription/translation of 20S proteasomes, immunoproteasomes, and PA28αβ, abrogate the need for 26S proteasome dissociation. During this adaptive period, HSP70 releases its bound 19S regulators, 26S proteasomes are reconstituted, and ATP-stimulated proteolysis is restored. The 26S proteasome-dependent, and ATP-stimulated, turnover of ubiquitinylated proteins is essential for normal cell metabolism, and its restoration is required for successful stress adaptation. [Copyright &y& Elsevier]
- Published
- 2011
- Full Text
- View/download PDF
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