Gavin R Flematti1, Adrian Scaffidi1, Mark T Waters1,2, Steven M Smith3,4. 1. School of Chemistry and Biochemistry, The University of Western Australia, Western Australia, 6009, Australia. 2. Centre of Excellence in Plant Energy Biology, The University of Western Australia, Western Australia, 6009, Australia. 3. School of Biological Sciences, University of Tasmania, Hobart, TAS, 7001, Australia. steven.smith@utas.edu.au. 4. State Key Laboratory of Plant Genomics, National Center for Plant Gene Research (Beijing), Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing, 100101, China. steven.smith@utas.edu.au.
Abstract
MAIN CONCLUSION: Plants produce strigolactones with different structures and different stereospecificities which provides the potential for diversity and flexibility of function. Strigolactones (SLs) typically comprise a tricyclic ABC ring system linked through an enol-ether bridge to a butenolide D-ring. The stereochemistry of the butenolide ring is conserved but two alternative configurations of the B-C ring junction leads to two families of SLs, exemplified by strigol and orobanchol. Further modifications lead to production of many different strigolactones within each family. The D-ring structure is established by a carotenoid cleavage dioxygenase producing a single stereoisomer of carlactone, the likely precursor of all SLs. Subsequent oxidation involves cytochrome P450 enzymes of the MAX1 family. In rice, MAX1 enzymes act stereospecifically to produce 4-deoxyorobanchol and orobanchol. Strigol- and orobanchol-type SLs have different activities in the control of seed germination and shoot branching, depending on plant species. This can partly be explained by different stereospecificity of SL receptors which includes the KAI2/HTL protein family in parasitic plants and the D14 protein functioning in shoot development. Many studies use chemically synthesised SL analogues such as GR24 which is prepared as a racemic mixture of two stereoisomers, one with the same stereo-configuration as strigol, and the other its enantiomer, which does not correspond to any known SL. In Arabidopsis, these two stereoisomers are preferentially perceived by AtD14 and KAI2, respectively, which activate different developmental pathways. Thus caution should be exercised in the use of SL racemic mixtures, while conversely the use of specific stereoisomers can provide powerful tools and yield critical information about receptors and signalling pathways in operation.
MAIN CONCLUSION: Plants produce strigolactones with different structures and different stereospecificities which provides the potential for diversity and flexibility of function. Strigolactones (SLs) typically comprise a tricyclic ABC ring system linked through an enol-ether bridge to a butenolide D-ring. The stereochemistry of the butenolide ring is conserved but two alternative configurations of the B-C ring junction leads to two families of SLs, exemplified by strigol and orobanchol. Further modifications lead to production of many different strigolactones within each family. The D-ring structure is established by a carotenoid cleavage dioxygenase producing a single stereoisomer of carlactone, the likely precursor of all SLs. Subsequent oxidation involves cytochrome P450 enzymes of the MAX1 family. In rice, MAX1 enzymes act stereospecifically to produce 4-deoxyorobanchol and orobanchol. Strigol- and orobanchol-type SLs have different activities in the control of seed germination and shoot branching, depending on plant species. This can partly be explained by different stereospecificity of SL receptors which includes the KAI2/HTL protein family in parasitic plants and the D14 protein functioning in shoot development. Many studies use chemically synthesised SL analogues such as GR24 which is prepared as a racemic mixture of two stereoisomers, one with the same stereo-configuration as strigol, and the other its enantiomer, which does not correspond to any known SL. In Arabidopsis, these two stereoisomers are preferentially perceived by AtD14 and KAI2, respectively, which activate different developmental pathways. Thus caution should be exercised in the use of SL racemic mixtures, while conversely the use of specific stereoisomers can provide powerful tools and yield critical information about receptors and signalling pathways in operation.
Authors: David C Nelson; Gavin R Flematti; Emilio L Ghisalberti; Kingsley W Dixon; Steven M Smith Journal: Annu Rev Plant Biol Date: 2012-02-09 Impact factor: 26.379
Authors: David C Nelson; Adrian Scaffidi; Elizabeth A Dun; Mark T Waters; Gavin R Flematti; Kingsley W Dixon; Christine A Beveridge; Emilio L Ghisalberti; Steven M Smith Journal: Proc Natl Acad Sci U S A Date: 2011-05-09 Impact factor: 11.205
Authors: Aashima Khosla; Nicholas Morffy; Qingtian Li; Lionel Faure; Sun Hyun Chang; Jiaren Yao; Jiameng Zheng; Mei L Cai; John Stanga; Gavin R Flematti; Mark T Waters; David C Nelson Journal: Plant Cell Date: 2020-05-20 Impact factor: 11.277
Authors: Amir Arellano-Saab; Michael Bunsick; Hasan Al Galib; Wenda Zhao; Stefan Schuetz; James Michael Bradley; Zhenhua Xu; Claresta Adityani; Asrinus Subha; Hayley McKay; Alexandre de Saint Germain; François-Didier Boyer; Christopher S P McErlean; Shigeo Toh; Peter McCourt; Peter J Stogios; Shelley Lumba Journal: Proc Natl Acad Sci U S A Date: 2021-07-27 Impact factor: 11.205