Functional Characterization of Nine Norway Spruce TPS Genes and Evolution of Gymnosperm Terpene Synthases of the TPS-d Subfamily

doi:10.1104/pp.104.042028

Functional Characterization of Nine Norway Spruce TPS Genes and Evolution of Gymnosperm Terpene Synthases of the TPS-d Subfamily

Diane M. Martin , Jenny Fäldt , and Jörg Bohlmann ^*

Biotechnology Laboratory (D.M.M., J.F., J.B.), and Departments of Botany (D.M.M., J.B.) and Forest Sciences (J.B.), University of British Columbia, Vancouver V6T 1Z3, British Columbia, Canada

^* Corresponding author; email: bohlmann{at}interchange.ubc.ca.

Constitutive and induced terpenoids are important defense compoundsfor many plants against potential herbivores and pathogens.In Norway spruce (Picea abies L. Karst), treatment with methyljasmonate induces complex chemical and biochemical terpenoiddefense responses associated with traumatic resin duct developmentin stems and volatile terpenoid emissions in needles. The cloningof (+)-3-carene synthase was the first step in characterizingthis system at the molecular genetic level. Here we report theisolation and functional characterization of nine additionalterpene synthase (TPS) cDNAs from Norway spruce. These cDNAsencode four monoterpene synthases, myrcene synthase, (-)-limonenesynthase, (-)- ${alpha}$ / ${beta}$ -pinene synthase, and (-)-linalool synthase;three sesquiterpene synthases, longifolene synthase, E,E- ${alpha}$ -farnesenesynthase, and E- ${alpha}$ -bisabolene synthase; and two diterpene synthases,isopimara-7,15-diene synthase and levopimaradiene/abietadienesynthase, each with a unique product profile. To our knowledge,genes encoding isopimara-7,15-diene synthase and longifolenesynthase have not been previously described, and this linaloolsynthase is the first described from a gymnosperm. These functionallydiverse TPS account for much of the structural diversity ofconstitutive and methyl jasmonate-induced terpenoids in foliage,xylem, bark, and volatile emissions from needles of Norway spruce.Phylogenetic analyses based on the inclusion of these TPS intothe TPS-d subfamily revealed that functional specializationof conifer TPS occurred before speciation of Pinaceae. Furthermore,based on TPS enclaves created by distinct branching patterns,the TPS-d subfamily is divided into three groups according tosequence similarities and functional assessment. Similaritiesof TPS evolution in angiosperms and modeling of TPS proteinstructures are discussed.

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