Abstract
Benzophenone metabolism provides a number of plant natural products with fascinating chemical structures and intriguing pharmacological activities. Formation of the carbon skeleton of benzophenone derivatives from benzoyl-CoA and three molecules of malonyl-CoA is catalyzed by benzophenone synthase (BPS), a member of the superfamily of type III polyketide synthases. A point mutation in the active site cavity (T135L) transformed BPS into a functional phenylpyrone synthase (PPS). The dramatic change in both substrate and product specificities of BPS was rationalized by homology modeling. The mutation may open a new pocket that accommodates the phenyl moiety of the triketide intermediate but limits polyketide elongation to two reactions, resulting in phenylpyrone formation. 3-Hydroxybenzoyl-CoA is the second best starter molecule for BPS but a poor substrate for PPS. The aryl moiety of the triketide intermediate may be trapped in the new pocket by hydrogen bond formation with the backbone, thereby acting as an inhibitor. PPS is a promising biotechnological tool for manipulating benzoate-primed biosynthetic pathways to produce novel compounds.
Highlights
Generation of benzophenone synthase (BPS) Mutants—Based on the crystal structure of M. sativa CHS2 complexed with resveratrol (12), a homology model of BPS was generated using the Swiss-Model server
The enzymes were assayed for changes in substrate and product specificities by HPLC-DAD analysis of their products using an array of aromatic CoAlinked starter substrates and acetyl-CoA in combination with malonyl-CoA as an extender
The functional behavior of BPS was dramatically altered by a single amino acid substitution in the active site cavity, which transformed BPS into phenylpyrone synthase (PPS)
Summary
BPS from Centaurium erythraea (Gentianaceae) prefers 3-hydroxybenzoyl-CoA as a starter substrate and catalyzes the formation of 2,3Ј,4,6-tetrahydroxybenzophenone (8) These two BPS products are the precursors of all prenylated benzoylphloroglucinols and xanthones. A number of functionally divergent plant PKSs arose via gene duplication and diversification (11) They differ from CHS in their preference for starter substrates (aliphatic or aromatic units), the number of acetyl additions catalyzed (one to seven), and the mechanism of ring formation used to cyclize linear polyketide intermediates (Claisen condensation, aldol condensation, or heterocyclic lactone formation) (9). A narrow CoA-binding tunnel provides access to this large bi-lobed internal cavity termed the initiation/elongation cavity One lobe of this catalytic center forms the starter unit binding pocket and the other accommodates the growing polyketide chain (13). Derivatives of the PPS product are highly potent anti-human immunodeficiency virus agents (14)
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