|Title||Plant surface lipid biosynthetic pathways and their utility for metabolic engineering of waxes and hydrocarbon biofuels|
|Publication Type||Journal Article|
|Year of Publication||2008|
|Authors||Jetter, R, Kunst, L|
|Type of Article||Review|
|Keywords||ARABIDOPSIS-THALIANA, BRASSICA-OLERACEA, chain lengths, CONDENSING ENZYME, CUTICULAR WAX, cuticular waxes, ECERIFERUM MUTANTS, EPICUTICULAR WAX, ESTERS, fatty acid elongation, FATTY ACYL-COENZYME, HYDROCARBONS, industrial products, LEAVES PISUM-SATIVUM, MOLECULAR CHARACTERIZATION, SACCHAROMYCES-CEREVISIAE|
Due to their unique physical properties, waxes are high-value materials that are used in a variety of industrial applications. They are generated by chemical synthesis, extracted from fossil sources, or harvested from a small number of plant and animal species. As a result, the diversity of chemical structures in commercial waxes is low and so are their yields. These limitations can be overcome by engineering of wax biosynthetic pathways in the seeds of high-yielding oil crops to produce designer waxes for specific industrial end uses. In this review, we first summarize the current knowledge regarding the genes and enzymes generating the chemical diversity of cuticular waxes that accumulate at the surfaces of primary plant organs. We then consider the potential of cuticle biosynthetic genes for biotechnological wax production, focusing on selected examples of wax ester chain lengths and isomers. Finally, we discuss the genes/enzymes of cuticular alkane biosynthesis and their potential in future metabolic engineering of plants for the production of renewable hydrocarbon fuels.
|URL||<Go to ISI>://000255755000012|