Rachel Davidovich-Rikanati
Einat Bar
Gal Hivert
Xing-Qi Huang
Carolina Hoppen-Tonial
Vered Khankin
Karin Rand
Amal Abofreih
Joelle K Muhlemann
José Abramo Marchese
Yoram Shotland
Natalia Dudareva
Moshe Inbar
Efraim Lewinsohn
Galling insects gain food and shelter by inducing specialized anatomical structures in their plant hosts. Such galls often accumulate plant defensive metabolites protecting the inhabiting insects from predation. We previously found that, despite a marked natural chemopolymorphism in natural populations of Pistacia palaestina, the monoterpene levels in Baizongia pistaciae induced galls is substantially higher than in leaves of their hosts. Here we show a general upregulation of key structural genes in both the plastidial and cytosolic terpene biosynthetic pathways in galls as compared to non-colonized leaves. Novel prenyltransferases and terpene synthases were functionally expressed in E.coli to reveal their biochemical function. Individual Pistacia trees exhibiting chemopolymorphism in terpene compositions displayed differential upregulation of selected terpene synthase genes, and the metabolites generated by their gene products in vitro corresponded to the monoterpenes accumulated by each tree. Our results delineate molecular mechanisms responsible for the enhanced monoterpene formation in galls and the observed intraspecific monoterpene chemodiversity displayed in P. palaestina. We demonstrate that gall-inhabiting aphids transcriptionally reprogram their host terpene pathways by upregulating tree-specific genes boosting the accumulation of plant defensive compounds for the protection of colonizing insects.
Rachel Davidovich-Rikanati
Einat Bar
Gal Hivert
Xing-Qi Huang
Carolina Hoppen-Tonial
Vered Khankin
Karin Rand
Amal Abofreih
Joelle K Muhlemann
José Abramo Marchese
Yoram Shotland
Natalia Dudareva
Moshe Inbar
Efraim Lewinsohn
Galling insects gain food and shelter by inducing specialized anatomical structures in their plant hosts. Such galls often accumulate plant defensive metabolites protecting the inhabiting insects from predation. We previously found that, despite a marked natural chemopolymorphism in natural populations of Pistacia palaestina, the monoterpene levels in Baizongia pistaciae induced galls is substantially higher than in leaves of their hosts. Here we show a general upregulation of key structural genes in both the plastidial and cytosolic terpene biosynthetic pathways in galls as compared to non-colonized leaves. Novel prenyltransferases and terpene synthases were functionally expressed in E.coli to reveal their biochemical function. Individual Pistacia trees exhibiting chemopolymorphism in terpene compositions displayed differential upregulation of selected terpene synthase genes, and the metabolites generated by their gene products in vitro corresponded to the monoterpenes accumulated by each tree. Our results delineate molecular mechanisms responsible for the enhanced monoterpene formation in galls and the observed intraspecific monoterpene chemodiversity displayed in P. palaestina. We demonstrate that gall-inhabiting aphids transcriptionally reprogram their host terpene pathways by upregulating tree-specific genes boosting the accumulation of plant defensive compounds for the protection of colonizing insects.