Phylogenetically distant enzymes localized in cytosol and plastids drive citral biosynthesis in lemongrass.

Citral, a naturally occurring acyclic monoterpene aldehyde, is present in the essential oils of various plants, but only a few produce it in abundance. Despite its importance as a key aroma molecule, knowledge regarding the in-planta biosynthesis of citral and its metabolic origin remains limited. Here, we have elucidated the functions of an alcohol dehydrogenase (CfADH1) and an aldoketo-reductase (CfAKR2b) in citral biosynthesis in lemongrass (Cymbopogon flexuosus), one of the most cultivated aromatic crops for its citral-rich essential oil. Expression of both CfADH1 and CfAKR2b showed correlation with citral accumulation in different developmental stages. Recombinant CfADH1 and CfAKR2b, despite their sequence unrelatedness, catalyzed citral formation from geraniol with NADP cofactor. Virus-induced gene silencing in lemongrass and transient expression in lemon balm (Melissa officinalis) demonstrated the in-planta involvement of CfADH1 and CfAKR2b in citral biosynthesis. While CfADH1 exhibited a dual cytosolic/plastidial localization, CfAKR2b was localized to the cytosol. This was supported by higher citral-forming activity in the cytosolic fraction than in the chloroplast fraction of lemongrass leaf extract. Moreover, feeding lemongrass seedlings with inhibitors specific to the cytosolic mevalonate pathway and the plastidial methylerythritol phosphate pathway, combined with volatile profiling, supported the involvement of both pathways in citral formation. Taken together, our results indicate that high citral production has evolved in lemongrass through the recruitment of phylogenetically distant enzymes localized in both the cytosol and plastids.