Abstract
Plants are sessile organisms and, in order to defend themselves against exogenous (a)biotic constraints, they synthesize an array of secondary metabolites which have important physiological and ecological effects. Plant secondary metabolites can be classified into four major classes: terpenoids, phenolic compounds, alkaloids and sulphur-containing compounds. These phytochemicals can be antimicrobial, act as attractants/repellents, or as deterrents against herbivores. The synthesis of such a rich variety of phytochemicals is also observed in undifferentiated plant cells under laboratory conditions and can be further induced with elicitors or by feeding precursors. In this review, we discuss the recent literature on the production of representatives of three plant secondary metabolite classes: artemisinin (a sesquiterpene), lignans (phenolic compounds) and caffeine (an alkaloid). Their respective production in well-known plants, i.e., Artemisia, Coffea arabica L., as well as neglected species, like the fibre-producing plant Urtica dioica L., will be surveyed. The production of artemisinin and caffeine in heterologous hosts will also be discussed. Additionally, metabolic engineering strategies to increase the bioactivity and stability of plant secondary metabolites will be surveyed, by focusing on glycosyltransferases (GTs). We end our review by proposing strategies to enhance the production of plant secondary metabolites in cell cultures by inducing cell wall modifications with chemicals/drugs, or with altered concentrations of the micronutrient boron and the quasi-essential element silicon.
Highlights
Plants are renewable resources providing raw material and phytochemicals for different industrial applications, namely in the textile, construction, pharmaceutical, nutraceutical and cosmetic sectors
We discuss the production of secondary metabolites in response to exogenous stresses, by choosing the specific case of caffeine production in cell cultures of Coffea arabica exposed to Al
We survey the production of artemisinin and caffeine in heterologous hosts, as well as discuss some biotechnological strategies used to increase the bioactivity of plant secondary metabolites, by taking as example the use of glycosyltransferases (GTs, EC: 2.4.1.x)
Summary
Plants are renewable resources providing raw material (like lignocellulosic biomass; [1]) and phytochemicals (notably secondary metabolites) for different industrial applications, namely in the textile, construction, pharmaceutical, nutraceutical and cosmetic sectors. Transferring the β-glucosidase gene via Agrobacterium in Artemisia plants increased the density of glandular trichomes in flowers and leaves and enhanced the artemisinin content by 2.5% in flowers and 1.4% in leaves [41]. Transferred a single vector containing five different genes from the mevalonate and artemisinin pathways to N. tabacum and successfully produced artemisinin with a concentration of 0.48–6.8 μg g−1 dry weight. A. annua produces high amounts of artemisinin if compared to other Artemisia species In this plant, artemisinin is mainly synthesized in the glandular secretory trichomes on leaves and flowers [54]. A. annua plants were supplied with labelled HMG-CoA, which enhanced the artemisinin content from 7.5 to 17.3 nmol (up to 130%) and it was proven that growth regulators, such as IAA and GA3 , enhanced artemisinin biosynthesis and accumulation via an increase in HMGR activity [62]. Cloning and co-expression of cytochrome P450 reductase (CPR) with CYP71AV1 in yeast increased the concentration of artemisinic acid in the culture [66]
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