Abstract
We are using a proteomic approach that combines two-dimensional electrophoresis and tandem mass spectrometry to detect and identify proteins that are differentially expressed in a cell line that is resistant to oxidative stress. The resistant cell line (OC14 cells) was developed previously through chronic exposure of a parent cell line (HA1 cells) to increasing hydrogen peroxide concentrations. Biochemical analyses of this system by other investigators have identified elevated content and activity of several classical antioxidant proteins that have established roles in oxidative stress resistance, but do not provide a complete explanation of this resistance. The proteomics studies described here have identified the enzyme aldose reductase (AR) as 4-fold more abundant in the resistant OC14 cells than in the HA1 controls. Based on this observation, the role of AR in the resistant phenotype was investigated by using a combination of AR induction with ethoxyquin and AR inhibition with Alrestatin to test the cytotoxicity of two oxidation-derived aldehydes: acrolein and glycolaldehyde. The results show that AR induction in HA1 cells provides protection against both acrolein- and glycolaldehyde-induced cytotoxicity. Furthermore, glutathione depletion sensitizes the cells to the acrolein-induced toxicity, but not the glycolaldehyde-induced toxicity, while AR inhibition sensitizes the cells to both acrolein- and glycolaldehyde-induced. These observations are consistent with a significant role for AR in the oxidative stress-resistant phenotype. These studies also illustrate the productive use of proteomic methods to investigate the molecular mechanisms of oxidative stress.
Highlights
We are using a proteomic approach that combines twodimensional electrophoresis and tandem mass spectrometry to detect and identify proteins that are differentially expressed in a cell line that is resistant to oxidative stress
Lipid peroxidation and amino acid oxidation can result in the production of a variety of toxic aldehydes. 4-hydroxy-2-nonenol (4HNE) and acrolein are examples of ␣,unsaturated aldehydes, a highly reactive class of aldehydes that are formed as a result of the degradation of peroxidized lipids [16, 17], whereas acrolein, 2-hydroxy-propanal, and glycoladehyde are examples of aldehydes derived from amino acid oxidation [18]
Our results show that inducing a comparable overexpression in the HA1 cells provides a significant protection against both acrolein and glycolaldehyde toxicity that can be reversed by aldose reductase (AR) inhibition
Summary
We are using a proteomic approach that combines twodimensional electrophoresis and tandem mass spectrometry to detect and identify proteins that are differentially expressed in a cell line that is resistant to oxidative stress. The proteomics studies described here have identified the enzyme aldose reductase (AR) as 4-fold more abundant in the resistant OC14 cells than in the HA1 controls Based on this observation, the role of AR in the resistant phenotype was investigated by using a combination of AR induction with ethoxyquin and AR inhibition with Alrestatin to test the cytotoxicity of two oxidation-derived aldehydes: acrolein and glycolaldehyde. Our results show that inducing a comparable overexpression in the HA1 cells provides a significant protection against both acrolein and glycolaldehyde toxicity that can be reversed by AR inhibition These results provide a rational explanation for the known resistance of the OC14 cells to aldehyde-induced cytotoxicity. These results underscore the ability of 2D electrophoresis-based proteomic experiments to reveal significant, phenotype-related differences in cellular systems as leads for new studies
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
