Abstract
Lysine N-pyrrolation converts lysine residues to Nϵ-pyrrole-l-lysine (pyrK) in a covalent modification reaction that significantly affects the chemical properties of proteins, causing them to mimic DNA. pyrK in proteins has been detected in vivo, indicating that pyrrolation occurs as an endogenous reaction. However, the source of pyrK remains unknown. In this study, on the basis of our observation in vitro that pyrK is present in oxidized low-density lipoprotein and in modified proteins with oxidized polyunsaturated fatty acids, we used LC-electrospray ionization-MS/MS coupled with a stable isotope dilution method to perform activity-guided separation of active molecules in oxidized lipids and identified glycolaldehyde (GA) as a pyrK source. The results from mechanistic experiments to study GA-mediated lysine N-pyrrolation suggested that the reactions might include GA oxidation, generating the dialdehyde glyoxal, followed by condensation reactions of lysine amino groups with GA and glyoxal. We also studied the functional significance of GA-mediated lysine N-pyrrolation in proteins and found that GA-modified proteins are recognized by apolipoprotein E, a binding target of pyrrolated proteins. Moreover, GA-modified proteins triggered an immune response to pyrrolated proteins, and monoclonal antibodies generated from mice immunized with GA-modified proteins specifically recognized pyrrolated proteins. These findings reveal that GA is an endogenous source of DNA-mimicking pyrrolated proteins and may provide mechanistic insights relevant for innate and autoimmune responses associated with glucose metabolism and oxidative stress.
Highlights
Lysine N-pyrrolation converts lysine residues to N⑀-pyrroleL-lysine in a covalent modification reaction that significantly affects the chemical properties of proteins, causing them to mimic DNA. pyrK in proteins has been detected in vivo, indicating that pyrrolation occurs as an endogenous reaction
Several studies have shown that conversion of primary amino groups into pyrrole derivatives occurs upon reaction of lysine residues of proteins with the reactive species that originated from the lipid peroxidation reactions
Our findings uncovered a novel function of GA as an endogenous source of DNA-mimicking pyrrolated proteins and suggest that GA-derived pyrK residues generated in proteins may play a role in innate and autoimmune responses associated with glucose metabolism and oxidative stress
Summary
Lysine N-pyrrolation converts lysine residues to N⑀-pyrroleL-lysine (pyrK) in a covalent modification reaction that significantly affects the chemical properties of proteins, causing them to mimic DNA. pyrK in proteins has been detected in vivo, indicating that pyrrolation occurs as an endogenous reaction. Several studies have shown that conversion of primary amino groups into pyrrole derivatives occurs upon reaction of lysine residues of proteins with the reactive species that originated from the lipid peroxidation reactions. They are mostly aldehydes, such as 4-hydroxy-2-nonenal [4, 5], 4-oxo-2alkenals [6], 4,5-epoxy-2-alkenals [7], levuglandin E2 [8], and hydroxy--oxoalkenoic acids [9]. Our findings uncovered a novel function of GA as an endogenous source of DNA-mimicking pyrrolated proteins and suggest that GA-derived pyrK residues generated in proteins may play a role in innate and autoimmune responses associated with glucose metabolism and oxidative stress
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