Reactive oxygen species (ROS) play crucial roles in physiology and pathology. In this report, we use NMR spectroscopy and mass spectrometry (MS) to demonstrate that proteins (galectin-1, ubiquitin, RNase, cytochrome c, myoglobin, and lysozyme) under reducing conditions with dithiothreitol (DTT) become alkylated at lysine-N? groups and O-phosphorylated at serine and threonine residues. These adduction reactions only occur in the presence of monophosphate, potassium, trace metals Fe/Cu, and oxygen, and are promoted by reactive oxygen species (ROS) generated via DTT oxidation. Superoxide mediates the chemistry, because superoxide dismutase inhibits the reaction, and hydroxyl and phosphoryl radicals are also likely involved. While lysine alkylation accounts for most of the adduction, low levels of phosphorylation are also observed at some serine and threonine residues, as determined by western blotting and MS fingerprinting. The adducted alkyl group is found to be a fragment of DTT that forms a Schiff base at lysine N? groups. Although its exact chemical structure remains unknown, the DTT fragment includes a SH group and a CHOHCH2 group. Chemical adduction appears to be promoted in the context of a well-folded protein, because some adducted sites in the proteins studied are considerably more reactive than others and the reaction occurs to a lesser extent with shorter, unfolded peptides and not at all with small organic molecules. A structural signature involving clusters of positively charged and other polar groups appears to facilitate the reaction. Overall, our findings demonstrate a novel reaction for DTT-mediated ROS chemistry with proteins.
In vivo oxygen-17 NMR for imaging brain oxygen metabolism at high field
In vivo oxygen-17 NMR for imaging brain oxygen metabolism at high field
Publication year: 2011
Source:Progress in Nuclear Magnetic Resonance Spectroscopy, Volume 59, Issue 4</br>
Xiao-Hong Zhu, Wei Chen</br>
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In vivo oxygen-17 NMR for imaging brain oxygen metabolism at high field
In vivo oxygen-17 NMR for imaging brain oxygen metabolism at high field
Publication year: 2011
Source: Progress in Nuclear Magnetic Resonance Spectroscopy, In Press, Accepted Manuscript, Available online 23 April 2011</br>
Xiao-Hong, Zhu , Wei, Chen</br>
*Highlights:*? This article reviews the developments of in vivo 17O NMR imaging in brain research. ? In vivo 17O NMR imaging has improved significantly at high/ultrahigh field. ? In vivo 17O NMR can noninvasively image brain oxygen metabolism and perfusion. ? In vivo 17O NMR is useful for mapping the functional change in oxygen...
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Protein lysine-N? alkylation and O-phosphorylation mediated by DTT-generated reactive oxygen species
CHOH
Linear Mode
