A Tomato Tocopherol Binding Protein Sheds Light on Intracellular α-tocopherol Metabolism in Plants

BERMÚDEZ, LUISA; DEL POZO, TALÍA; LIRA, BRUNO SILVESTRE; DE GODOY, FABIANA; BOOS, IRENE; ROMANÓ, CECILIA; PREVITALI, VIOLA; ALMEIDA, JULIANA; BRÉHÉLIN, CLAIRE; ASIS, RAMÓN; QUADRANA, LEANDRO; DEMARCO, DIEGO; ALSEEKH, SALEH; SALINAS GAMBOA, RIGEL; PÉREZ-FLORES, LAURA; DOMINGUEZ, PIA GUADALUPE; ROTHAN, CHRISTOPHE; FERNIE, ALISDAIR ROBERT; GONZÁLEZ, MAURÍCIO; STOCKER, ACHIM; HEMMERLE, ANDREA; CLAUSEN, MADS HARTVING; CARRARI, FERNANDO; ROSSI, MAGDALENA

PLANT AND CELL PHYSIOLOGY

OXFORD UNIV PRESS

Lugar: Oxford; Año: 2018

0032-0781

Tocopherols are non-polar compounds synthesized in the plastids, which function as major antioxidants of the plant cells and are essential in the human diet. Both the intermediates and final products of the tocopherol biosynthetic pathway must cross plastid membranes to reach their sites of action. So far, no protein with tocopherol binding activity has been reported in plants. Here, we demonstrated that the tomato SlTBP protein is targeted to chloroplasts and able to bind α-tocopherol. SlTBP-knockdown tomato plants exhibited reduced levels of tocopherol in both, leaves and fruits. Several tocopherol-deficiency phenotypes were apparent in the transgenic lines, such as alterations in photosynthetic parameters, dramatic distortion of thylakoid membranes and significant variations in the lipid profile. These results, along with the altered expression of genes related to photosynthesis, tetrapyrrole, lipid, isoprenoid, inositol/phosphoinositide and redox metabolisms suggest that SlTBP may act conducting tocopherol (or its biosynthetic intermediates) between the plastid compartments and/or at the interface between chloroplast-ER membranes, affecting inter-organellar lipid metabolism.