Abstract
There are tens of thousands of scientific papers about flavonoids and their impacts on human health. However, despite the vast amount of energy that has been put toward studying these compounds, a unified molecular mechanism that explains their bioactivity remains elusive. One contributing factor to the absence of a general mechanistic explanation of their bioactivity is the complexity of flavonoid chemistry in aqueous solutions at neutral pH. Flavonoids have acidic protons, are redox active, and frequently auto-oxidize to produce an array of degradation products including electrophilic quinones. Flavonoids are also known to interact with specificity and high affinity with a variety of proteins, and there is evidence that some of these interactions may be covalent. This review summarizes the mechanisms of flavonoid oxidation in aqueous solutions at neutral pH and proposes the formation of protein-flavonoid adducts or flavonoid-induced protein oxidation as putative mechanisms of flavonoid bioactivity in cells. Nucleophilic residues in proteins may be able to form covalent bonds with flavonoid quinones; alternatively, specific amino acid residues such as cysteine, methionine, or tyrosine in proteins could be oxidized by flavonoids. In either case, these protein-flavonoid interactions would likely occur at specific binding sites and the formation of these types of products could effectively explain how flavonoids modify proteins in cells to induce downstream biochemical and cellular changes.
Highlights
Flavonoids are a ubiquitous and numerous group of plant secondary metabolites with hydroxylated phenyl rings that include the flavones, catechins, and anthocyanins
Flavonoids may be able to induce production of nitric oxide in endothelial tissue, causing vasodilation and indirectly improving cerebral blood flow [30,32,33]. These results demonstrate that some health benefits of dietary flavonoid consumption may arise from secondary physiological effects rather than direct interaction by flavonoids with cellular targets, which adds to the complexity of
Proving cerebral blood flow [30,32,33]. These results demonstrate that some health beneMolecules 2021, 26,f5i1t0s2of dietary flavonoid consumption may arise from secondary physiological effects ra- 3 of 20 ther than direct interaction by flavonoids with cellular targets, which adds to the complexity of investigating flavonoid bioactivity
Summary
Flavonoids are a ubiquitous and numerous group of plant secondary metabolites with hydroxylated phenyl rings that include the flavones, catechins, and anthocyanins. Flavonoids may be able to induce production of nitric oxide in endothelial tissue, causing vasodilation and indirectly improving cerebral blood flow [30,32,33] These results demonstrate that some health benefits of dietary flavonoid consumption may arise from secondary physiological effects rather than direct interaction by flavonoids with cellular targets, which adds to the complexity of. The large number of reports of protein-flavonoid interactions makes it impractical to cite all relevant examples Despite this extensive body of research, there is not a unified molecular mechanism that has yet been proposed that could explain all (or at least most) of these observed bioactivities. I will use examples from selected papers that provide useful examples of the recurring themes that occur throughout the protein-flavonoid literature
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