Abstract
Production of ent-kaurene as a precursor for important signaling molecules such as the gibberellins seems to have arisen early in plant evolution, with corresponding cyclase(s) present in all land plants (i.e., embryophyta). The relevant enzymes seem to represent fusion of the class II diterpene cyclase that produces the intermediate ent-copalyl diphosphate (ent-CPP) and the subsequently acting class I diterpene synthase that produces ent-kaurene, although the bifunctionality of the ancestral gene is only retained in certain early diverging plants, with gene duplication and sub-functionalization leading to distinct ent-CPP synthases and ent-kaurene synthases (KSs) generally observed. This evolutionary scenario implies that plant KSs should have conserved structural features uniquely required for production of ent-kaurene relative to related enzymes that have alternative function. Notably, substitution of threonine for a conserved isoleucine has been shown to “short-circuit” the complex bicyclization and rearrangement reaction catalyzed by KSs after initial cyclization, leading to predominant production of ent-pimaradiene, at least in KSs from angiosperms. Here this effect is shown to extend to KSs from earlier diverging plants (i.e., bryophytes), including a bifunctional/KS. In addition, attribution of the dramatic effect of this single residue “switch” on product outcome to electrostatic stabilization of the ent-pimarenyl carbocation intermediate formed upon initial cyclization by the hydroxyl introduced by threonine substitution has been called into question by the observation of similar effects from substitution of alanine. Here further mutational analysis and detailed product analysis is reported that supports the importance of electrostatic stabilization by a hydroxyl or water.
Highlights
All embryophyta produce the diterpene ent-kaur-16-ene (1)
The first is catalyzed by copalyl diphosphate synthases (CPSs) that are representative of class II diterpene cyclases and produce ent-copalyl diphosphate (ent-CPP) (2). 2 is subsequently further cyclized and rearranged by kaurene synthases (KSs) that are
This Ile is further conserved in the only characterized KS from a lycophyte (i.e., Selaginella moellendorffii, SmKS) (Shimane et al, 2014), as well as the bifunctional CPS/KSs identified from other bryophytes (Hayashi et al, 2006; Kawaide et al, 2011)
Summary
All embryophyta produce the diterpene ent-kaur-16-ene (1). In vascular plants (i.e., tracheophytes) 1 serves as an intermediate in biosynthesis of the gibberellin phytohormones (Hedden and Thomas, 2012). The CPS and KS required for the production of signaling molecules derived from 1, such as the gibberellins, seem to have given rise to closely related enzymes that mediate more specialized labdane-related diterpenoid metabolism via gene duplication and neo-functionalization (Zi et al, 2014) These enzymes catalyze similar reactions, but yield different products. Many angiosperms contain small families of KS-like diterpene synthases (KSLs) that retain the multi-domain structure of KSs, but do not produce 1 These catalyze ionization of the allylic diphosphate ester bond that characterizes class I terpene synthases, and may even still react with 2. These KSLs terminate catalysis via deprotonation, either directly or following the addition of water, leading to a variety of products (see Scheme 1 for examples)
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