Lipid peroxidation during oxidative stress leads to increased concentrations of thiol-reactive ␣,-unsaturated aldehyde, including 4-hydroxy-2-nonenal (4-HNE) and 4-oxo-2-nonenal (4-ONE). These aldehydes have a documented ability to disrupt protein function following adduct formation with specific residues. Therefore, to identify 4-HNE-modified proteins in a model of ethanol-induced oxidative stress, a proteomic approach was applied to liver fractions prepared from rats fed a combination high-fat/ethanol diet. The results revealed that essential 90-kDa heat shock protein (Hsp90) was consistently modified by 4-HNE in the alcohol-treated animals. In vitro chaperoning experiments using firefly luciferase as a client protein were then performed to assess the functional effect of 4-HNE modification on purified recombinant human Hsp90, modified with concentrations of this aldehyde ranging from 23 to 450 M. Modification of Hsp90 with 4-ONE also led to significant inhibition of the chaperone. Because 4-HNE and 4-ONE react selectively with Cys, a thiol-specific mechanism of inhibition was suggested by these data. Therefore, thiol sensitivity was confirmed following treatment of Hsp90 with the specific thiol modifier N-ethylmaleimide, which resulted in more than 99% inactivation of the chaperone by concentrations as low as 6 M (1:1 M ratio). Finally, tryptic digest of 4-HNE-modified Hsp90 followed by liquid chromatography/tandem mass spectrometry peptide analysis identified Cys 572 as a site for 4-HNE modification. The results presented here thus establish that 4-HNE consistently modifies Hsp90 in a rat model of alcohol-induced oxidative stress and that the chaperoning activity of this protein is subject to dysregulation through thiol modification.
A proteomic approach was applied to liver cytosol from rats fed a diet consisting of high fat and ethanol to identify 4-hydroxy-2-nonenal (4-HNE)-modified proteins in vivo. Cytosolic Hsp72, the inducible variant of the Hsp70 heat shock protein family, was consistently among the proteins modified by 4-HNE. Despite 1.3-fold induction of Hsp72 in the livers of ethanol-fed animals, no increase in Hsp70-mediated luciferase refolding in isolated heptocytes was observed, suggesting inhibition of this process by 4-HNE. A 50% and 75% reduction in luciferase refolding efficiency was observed in rabbit reticulocyte lysate (RRL) supplemented with recombinant Hsp72 which had been modified in vitro with 10 and 100 μM 4-HNE, respectively. This observation was accompanied by a 25% and 50% decrease in substrate binding by the chaperone following the same treatment; however, no effect on complex formation between Hsp72 and its co-chaperone Hsp40 was observed. Trypsin digest and mass spectral analysis of Hsp72 treated with 10 and 100 μM 4-HNE consistently identified adduct formation at Cys267 in the ATPase domain of the chaperone. The role of this residue in the observed inhibition was demonstrated through the use of DnaK, a bacterial Hsp70 variant lacking Cys267. DnaK was resistant to 4-HNE inactivation. Additionally, Hsp72 was resistant to inactivation by the thiolunreactive aldehyde malondialdehyde (MDA), further supporting a role for Cys in Hsp72 inhibition by 4-HNE. Finally, the affinity of Hsp72 for ATP was decreased 32% and 72% following treatment of the chaperone with 10 and 100 μM 4-HNE, respectively. In a model of chronic alcoholic liver injury, induction of Hsp72 was not accompanied by an increase in protein refolding ability. This is likely the result of 4-HNE modification of the Hsp72 ATPase domain.
A proteomic approach was applied to mitochondrial protein isolated from the livers of rats fed a combination high-fat and ethanol diet to identify proteins modified by 4-hydroxynonenal (4-HNE). Using this approach, the endoplasmic reticulum chaperone, protein disulfide isomerase (PDI), which participates in the maturation of newly synthesized proteins through promoting correct disulfide formation, was consistently found to be modified by 4-HNE. Further mass spectral analysis of PDI isolated from the animals revealed modification of an active site Cys residue thought to be involved in client protein binding. To test the hypothesis that 4-HNE inhibits the chaperone, purified bovine PDI was treated with concentrations of 4-HNE ranging from 20 to 200 microM (10-100-fold molar excess aldehyde), resulting in 14-56% inhibition, respectively. Similar treatments with the lipid peroxidation products acrolein (ACR) and 4-oxononenal (4-ONE) resulted in 60 and 100% inhibition, respectively, suggesting inactivation of the chaperone via Cys modification. Thiol sensitivity was confirmed through concentration-dependent inhibition of PDI by the Cys modifier N-ethylmaleimide (NEM). While some degree of sensitivity to these lipid aldehydes is suggested by the data, when compared to inactivation of other proteins by 4-HNE, PDI has demonstrated a relative resistance. It was also observed that physiologic (e.g., 4 mM) concentrations of GSH were capable of removing the 4-HNE adducts, likely serving as a protective mechanism against inactivation by 4-HNE and other lipid peroxidation products. However, because an active site Cys was found to be modified by 4-HNE on PDI in vivo, it is possible that the protective effect of GSH on the chaperone decreases under conditions of sustained oxidative stress, such as during chronic alcohol consumption, as GSH is depleted. The data presented here thus suggest potential impairment of an important molecular chaperone during oxidative stress.
Estrogen receptors regulate multiple brain functions including stress, sexual, and memory associated behaviors as well as control of neuroendocrine and autonomic function. During development, estrogen signaling is involved in programming adult sex differences in physiology and behavior. Expression of estrogen receptor alpha changes across development in a region specific fashion. By contrast, estrogen receptor beta (ERβ) is expressed in many brain regions, yet few studies have explored sex and developmental differences in its expression largely due to the absence of selective reagents for anatomical localization of the protein. In this study, we utilized bacterial artificial chromosome transgenic mice expressing ERβ identified by enhanced green fluorescent protein (EGFP) to compare expression levels and distribution of ERβ in the male and female mouse forebrain on the day of birth (P0), postnatal day 4 (P4) and P21. Using qualitative analysis, we mapped the distribution of ERβ–EGFP and found developmental alterations in ERβ expression within the cortex, hippocampus, and hypothalamic regions including the arcuate, ventromedial, and paraventricular nuclei. We also report a sex difference in ERβ in the bed nucleus of the stria terminalis with males showing greater expression at P4 and P21. Another sex difference was found in the anteroventral periventricular nucleus of P21, but not P0 or P4 mice, where ERβ-EGFP-ir cells were densely clustered near the 3rd ventricle in females but not males. These developmental changes and sex differences in ERβ indicate a mechanism through which estrogens may differentially affect brain functions or program adult physiology at select times during development.
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