Thiol-Based Redox Switches in Eukaryotic Proteins

Abstract For many years, oxidative thiol modifications in cytosolic proteins were largely disregarded as in vitro artifacts, and considered unlikely to play significant roles within the reducing environment of the cell. Recent developments in in vivo thiol trapping technology combined with mass spectrometric analysis have now provided convincing evidence that thiol-based redox switches are used as molecular tools in many proteins to regulate their activity in response to reactive oxygen and nitrogen species. Reversible oxidative thiol modifications have been found to modulate the function of proteins involved in many different pathways, starting from gene transcription, translation and protein folding, to metabolism, signal transduction, and ultimately apoptosis. This review will focus on three well-characterized eukaryotic proteins that use thiol-based redox switches to influence gene transcription, metabolism, and signal transduction. The transcription factor Yap1p is a good illustration of how oxidative modifications affect the function of a protein without changing its activity. We use glyeraldehyde-3-phosphate dehydrogenase to demonstrate how thiol modification of an active site cysteine re-routes metabolic pathways and converts a metabolic enzyme into a pro-apoptotic factor. Finally, we introduce the redox-sensitive protein tyrosine phosphatase PTP1B to illustrate that reversibility is one of the fundamental aspects of redox-regulation. Antioxid. Redox Signal. 11, 997-1014.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/78110/1/ars.2008.2285.pd

Transcriptional regulation of the bcl-x gene encoding the anti-apoptotic Bcl-xL protein by Ets, Rel/NFKB, STAT and API transcription factor families

Transcription factors play an essential role in determining the fate of a cell by affecting the expression of target genes involved in proliferation, in differentiation and in programmed cell death. Under certain conditions, some of these factors are capable of deregulating expression of genes involved in the cell cycle andlor in programmed cell death resulting in uncontrolled proliferation of the cell. The focus of this review is on the transcriptional regulation of the bcl-x gene encoding the anti-apoptotic Bcl-xL protein. Since 1999, severa1 papers have implicated members of the Ets, R~~/NFKSBT, N and AP-1 families as transcription factors regulating bcl-x expression. A specific emphasis of these different transcription factor families on bcl-x regulation in hematopoietic cells is discussed

Transcriptional regulation of the bcl-x gene encoding the anti-apoptotic Bcl-xL protein by Ets, Rel/NFKB STAT and AP1 transcription factor families

Transcription factors play an essential role in determining the fate of a cell by affecting the expression of target genes involved in proliferation, in differentiation and in programmed cell death. Under certain conditions, some of these factors are capable of deregulating expression of genes involved in the cell cycle andlor in programmed cell death resulting in uncontrolled proliferation of the cell. The focus of this review is on the transcriptional regulation of the bcl-x gene encoding the anti-apoptotic Bcl-xL protein. Since 1999, severa1 papers have implicated members of the Ets, R~~/NFKSBT, N and AP-1 families as transcription factors regulating bcl-x expression. A specific emphasis of these different transcription factor families on bcl-x regulation in hematopoietic cells is discusse