The conversion of sesame lignans
is of interest because the derived
products may have potential applications. Here, in investigating the
transformation of sesamin and sesamolin, main endogenous sesame lignans
in sesame seeds, in both acidic aqueous and anhydrous systems, 7R,7′S-samin was identified as one
of the major products of sesamolin in both systems catalyzed with
common inorganic acids, but sesaminol was not generated. In investigating
the effect of different oxidizing agents on the acid-catalyzed conversion
of sesame lignans, 7R,7′S-samin was still the major product of sesamolin, whereas sesamolin
as well as 7R,7′S-samin stereoselectively
rendered 7R,7′R-samin in
the presence of hydrogen peroxide. Hydrogen peroxide may play a role
in stabilizing the transitional oxonium ions, derived from acid hydrolysis
of sesamolin or 7R,7′S-samin
by forming a seven-membered ring intermediate through hydrogen bonding,
to consequently produce 7R,7′R-samin as the final product.
Luteolin (LUT), a plant-derived flavone,
exhibits various bioactivities;
however, the poor aqueous solubility hampers its applications. Here,
we revealed bioconversion of LUT by Bacillus subtilis BCRC 80517, yielding three water-soluble phosphate conjugates. These
derivatives were identified as luteolin 4′-O-phosphate (L4′P), luteolin 3′-O-phosphate (L3′P), and luteolin 7-O-phosphate (L7P) by LC-ESI-MS/MS and NMR.
Besides, we found that Bacillus subtilis BCRC 80517 was able to convert different levels of LUT but showed
a limited conversion rate. By observing bacterial morphology with
transmission electron microscopy and confocal fluorescence microscopy,
we found that LUT disrupted the bacterial membrane integrity, which
explained the incomplete conversion. Additionally, we revealed a spontaneous
intramolecular transesterification of L4′P to L3′P, the thermodynamically more stable form, under
acidic conditions and proposed the possible mechanism involving a
cyclic phosphate as the intermediate. This study provides insight
into development of a potent structural modification strategy to enhance
the solubility of LUT through biophosphorylation.
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