Yarrowia lipolytica, a non-conventional oleaginous yeast with special traits, has attracted increasing interest for producing value-added products. Generally, the DNA fragments of these heterologous metabolic pathways are constructed via the classic restriction digestion and ligation method. In contrast, the one-step in vivo pathway assembly method has been only rarely applied to Y. lipolytica. Here, with arachidonic acid biosynthesis as a case study, a one-step in vivo pathway assembly and integration method was used for engineering Y. lipolytica. Using rDNA as integrative locus, this study showed that there was a relation between the assembly efficiency and the length of overlapping region. Especially, with an overlap up to 1 kb, the method was able to rapidly assemble the arachidonic acid biosynthesis pathway (nearly 10 kb) into the chromosome with high efficiency (nearly 23%). Meanwhile, the pathway assembled in Y. lipolytica demonstrated long-term genetic stability and the engineered strain exhibited robust growth. Furthermore, this study demonstrated that the codon-optimized genes from Mortierella alpina can function efficiently in Y. lipolytica: a high level arachidonic acid production (0.4% of total fatty acids) was produced in the engineered strain. To our knowledge, this is the first time that this method is applied to Y. lipolytica for functional polyunsaturated fatty acids production. This method represents a powerful tool with potential for facilitating engineering applications in non-conventional yeasts.
γ-linolenic acid (GLA) has various well-documented beneficial physiological effects and high biological significance. Because the natural supply of GLA is insufficient, microbial GLA production is a promising method for pharmaceutical and nutraceutical purposes. To establish and develop a biotechnological process for GLA production by Yarrowia lipolytica, the codon-optimized △6-desaturase from Mortierella alpina was introduced into this yeast under the control of the strong hp4d promoter. A recombinant Y. lipolytica strain was constructed, which produced 4.6% GLA in total fatty acids. By using a temperature-shift strategy of cultivation, consisting in preliminary growth at 28 °C followed by 6-day culture at 20 °C, optimal levels of dry cell weight (DCW), lipid content and GLA concentration were obtained from the recombinant strain: 18.55 g/L, 1.16 g/L and 71.6 mg/L, respectively. These DCW, lipid and GLA values were respectively 25.7%, 19.6% and 60.9% higher than those obtained in the control cultivation experiment at the standard constant temperature of 28 °C. This work demonstrates the excellent capacity of Y. lipolytica for GLA production, by combining metabolic engineering with a temperature-shift strategy.
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