Abstract
Chalcone isomerase (CHI) is an important enzyme for flavonoid biosynthesis that catalyzes the intramolecular cyclization of chalcones into (S)-flavanones. CHIs have been classified into two types based on their substrate specificity. Type I CHIs use naringenin chalcone as a substrate and are found in most of plants besides legumes, whereas type II CHIs in leguminous plants can also utilize isoliquiritigenin. In this study, we found that the CHI from the Antarctic plant Deschampsia antarctica (DaCHI1) is of type I based on sequence homology but can use type II CHI substrates. To clarify the enzymatic mechanism of DaCHI1 at the molecular level, the crystal structures of unliganded DaCHI1 and isoliquiritigenin-bound DaCHI1 were determined at 2.7 and 2.1 Å resolutions, respectively. The structures revealed that isoliquiritigenin binds to the active site of DaCHI1 and induces conformational changes. Additionally, the activity assay showed that while DaCHI1 exhibits substrate preference for naringenin chalcone, it can also utilize isoliquiritigenin although the catalytic activity was relatively low. Based on these results, we propose that DaCHI1 uses various substrates to produce antioxidant flavonoids as an adaptation to oxidative stresses associated with harsh environmental conditions.
Highlights
As antioxidant compounds, flavonoids play critical roles in the biological activities of plants, such as protection from ultraviolet (UV) radiation, pathogen resistance, plant coloration, nodulation, auxin transport, and pollen fertility [1,2,3,4]
Three Chalcone isomerase (CHI) genes have been reported in D. antarctica that are differentially expressed at high salinity [28]
A BLAST search of the three genes against the recently reported transcriptome database of D. antarctica showed that only one assembled contig was a BLAST match, with DaCHI1 showing the highest identity (100%, 696/696) [39]
Summary
Flavonoids play critical roles in the biological activities of plants, such as protection from ultraviolet (UV) radiation, pathogen resistance, plant coloration, nodulation, auxin transport, and pollen fertility [1,2,3,4]. They have beneficial effects on human health, including the prevention of cardiovascular disease, obesity, and diabetes [5,6,7]. Flavonoid biosynthesis begins with phenylpropanoid metabolism in which phenylalanine is transformed into p-coumaroyl-coenzyme (Co)A. Chalcone synthase (EC 2.3.1.74), the first enzyme responsible for generating the basic flavonoid skeleton, catalyzes the condensation of three molecules of malonyl-CoA with
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