Insights into stereoselective ring formation in canonical strigolactone: Identification of a dirigent domain-containing enzyme catalyzing orobanchol synthesis.

Strigolactones (SLs) are plant apocarotenoids with diverse roles and structures. Canonical SLs, widespread and characterized by structural variations in their tricyclic lactone (ABC-ring), are classified into two types based on C-ring configurations. The steric C-ring configuration emerges during the BC-ring closure, downstream of the biosynthetic intermediate, carlactonoic acid (CLA). Most plants produce either type of canonical SLs stereoselectively, e.g., tomato (Solanum lycopersicum) yields orobanchol with an α-oriented C-ring. The mechanisms driving SL structural diversification are partially understood, with limited insight into functional implications. Furthermore, the exact molecular mechanism for the stereoselective BC-ring closure reaction is yet to be known. We identified an enzyme, the stereoselective BC-ring-forming factor (SRF), from the dirigent protein (DIR) family, specifically the DIR-f subfamily, whose biochemical function had not been characterized, making it a key enzyme in stereoselective canonical SL biosynthesis with the α-oriented C-ring. We first confirm the precise catalytic function of the tomato cytochrome P450 SlCYP722C, previously shown to be involved in orobanchol biosynthesis [T. Wakabayashi et al., Sci. Adv. 5, eaax9067 (2019)], to convert CLA to 18-oxocarlactonoic acid. We then show that SRF catalyzes the stereoselective BC-ring closure reaction of 18-oxocarlactonoic acid, forming orobanchol. Our methodology combines experimental and computational techniques, including SRF structure prediction and conducting molecular dynamics simulations, suggesting a catalytic mechanism based on the conrotatory 4π-electrocyclic reaction for the stereoselective BC-ring formation in orobanchol. This study sheds light on the molecular basis of how plants produce SLs with specific stereochemistry in a controlled manner.

Identification of 6-epi-heliolactone as a biosynthetic precursor of avenaol in Avena strigosa.

Strigolactones (SLs), which are known as rhizosphere signaling molecules and plant hormones regulating shoot architecture, are classified into 2 distinct groups, canonical and noncanonical SLs, based on their structures. Avenaol, a noncanonical SL found in the root exudates of black oat (Avena strigosa), has a characteristic bicyclo[4.1.0]heptane skeleton. Elucidating the biosynthetic mechanism of this peculiar structure is a challenge for further understanding of the structural diversification of noncanonical SLs. In this study, a novel noncanonical SL, 6-epi-heliolactone in black oat root exudates was identified. Feeding experiments showed that 6-epi-heliolactone was a biosynthetic intermediate between methyl carlactonoate and avenaol. Inhibitor experiments proposed the involvement of 2-oxoglutarate-dependent dioxygenase in converting 6-epi-heliolactone to avenaol. These results provide new insights into the stereochemistry diversity of noncanonical SLs and a basis to explore the biosynthetic pathway causing avenaol.

Corrigendum: Identification of novel canonical strigolactones produced by tomato.

[This corrects the article DOI: 10.3389/fpls.2022.1064378.].

Conversion of methyl carlactonoate to heliolactone in sunflower.

Heliolactone is a non-canonical strigolactone isolated from sunflower root exudates. We have previously demonstrated that exogenously administered carlactonoic acid (CLA) was converted to heliolactone in sunflower. The conversion of CLA to heliolactone requires the methyl esterification of the carboxylic acid at C-19. Also, the CLA conversion to its methyl ester, methyl carlactonoate (MeCLA), was demonstrated by feeding experiment in sunflower. However, the involvement of MeCLA in heliolactone biosynthesis remains unclear. We synthesised MeCLA in its racemic form and resolved it into its enantiomers. Feeding experiments revealed that (11R)-MeCLA was exclusively converted to heliolactone in sunflower. This result is an evidence that (11R)-MeCLA is the biosynthetic precursor of heliolactone. Further conversion of heliolactone to an unidentified metabolite with a molecular mass larger than heliolactone by 16 Da was confirmed. The conversion was inhibited by a cytochrome P450 inhibitor, suggesting the involvement of cytochrome P450-dependent monooxygenation.

Identification of novel canonical strigolactones produced by tomato.

Canonical strigolactones (SLs), such as orobanchol, consist of a tricyclic lactone ring (ABC-ring) connected to a methylbutenolide (D-ring). Tomato plants have been reported to produce not only orobanchol but also various canonical SLs related to the orobanchol structure, including orobanchyl acetate, 7-hydroxyorobanchol isomers, 7-oxoorobanchol, and solanacol. In addition to these, structurally unidentified SL-like compounds known as didehydroorobanchol isomers (DDHs), whose molecular mass is 2 Da smaller than that of orobanchol, have been found. Although the SL biosynthetic pathway in tomato is partially characterized, structural elucidation of DDHs is required for a better understanding of the entire biosynthetic pathway. In this study, three novel canonical SLs with the same molecular mass as DDHs were identified in tomato root exudates. The first was 6,7-didehydroorobanchol, while the other two were not in the DDH category. These two SLs were designated phelipanchol and epiphelipanchol because they induced the germination of Phelipanche ramosa, a noxious root parasitic weed of tomato. We also proposed a putative biosynthetic pathway incorporating these novel SLs from orobanchol to solanacol.