Plant Sunscreens
in the UV-B: Ultraviolet Spectroscopy
of Jet-Cooled Sinapoyl Malate, Sinapic Acid, and Sinapate Ester Derivatives
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Abstract
Ultraviolet
spectroscopy of sinapoyl malate, an essential UV-B
screening agent in plants, was carried out in the cold, isolated environment
of a supersonic expansion to explore its intrinsic UV spectral properties
in detail. Despite these conditions, sinapoyl malate displays anomalous
spectral broadening extending well over 1000 cm<sup>–1</sup> in the UV-B region, presenting the tantalizing prospect that nature’s
selection of UV-B sunscreen is based in part on the inherent quantum
mechanical features of its excited states. Jet-cooling provides an
ideal setting in which to explore this topic, where complications
from intermolecular interactions are eliminated. In order to better
understand the structural causes of this behavior, the UV spectroscopy
of a series of sinapate esters was undertaken and compared with <i>ab initio</i> calculations, starting with the simplest sinapate
chromophore sinapic acid, and building up the ester side chain to
sinapoyl malate. This “deconstruction” approach provided
insight into the active mechanism intrinsic to sinapoyl malate, which
is tentatively attributed to mixing of the bright V (<sup>1</sup>ππ*)
state with an adiabatically lower <sup>1</sup>nπ* state which,
according to calculations, shows unique charge-transfer characteristics
brought on by the electron-rich malate side chain. All members of
the series absorb strongly in the UV-B region, but significant differences
emerge in the appearance of the spectrum among the series, with derivatives
most closely associated with sinapoyl malate showing characteristic
broadening even under jet-cooled conditions. The long vibronic progressions,
conformational distribution, and large oscillator strength of the
V (ππ*) transition in sinapates makes them ideal candidates
for their role as UV-B screening agents in plants