Biosynthesis of aliphatic plastic monomers with amino residues in Yarrowia lipolytica

Introduciton: The alpha,omega-diamines (NH2-(CH2)(n)-NH2) and omega -amino fatty acids (NH2-(CH2)(n)-COOH) have been widely used as building blocks in polymerindustries. Medium- to long-chain (C-8 to C-18) fatty acid monomers with amino residues are almost exclusively produced via chemical processes that generate hazardous waste and induce severe environmental problems, such as global warming and pollution. Here, we present the construction platformstrains of Yarrowia lipolytica a cheese-ripening yeast, for direct biotransformation of hydrocarbons into medium- to long-chain alpha,omega-diamines and omega amino fatty acids using metabolic engineering of endogenous fatty acid omega- and beta-oxidation pathways and introducing heterologous omega-transaminase in Y. lipolytica.Methods: We deleted six genes encoding the acyl-CoA oxidase (ACO1-6) and four fatty aldehyde dehydrogenase genes (FALDH1-4), which catalyze fatty acid beta-oxidation and downstream oxidation of fatty aldehydes in Y. lipolytica, respectively. The omega-transaminase from Chromobacterium violaceum DSM30191 was introduced into the genome of the delta POX delta FALDH strain under the control of Y. lipolytica-derived EXP1 promoters.Results and Discussion: The delta POX delta FALDH strains with omega-CvTA successfully accumulated the corresponding C12 alpha omega-diamines into a shaking culture medium with dodecane or dodecanol. In addition, these strains accumulated C-12 omega-amino fatty acids from dodecanoic acid. With the commercially available alpha,omega-diacid bioprocess, this yeast biosynthesis producing medium- and longchain alpha,omega-diamines and omega-amino fatty acids could complete the yeast platform technology generating all medium- and long-chain aliphatic polyamide monomers, alpha,omega-biofunctionalized with one or both carboxylic acid and amino residues.