Isolation and characterization of a Δ--desaturation-defective mutant of an arachidonic acid-producing fungus,Mortierella alpina1S-4

Harnessing the Power of Mutagenesis and Adaptive Laboratory Evolution for High Lipid Production by Oleaginous Microalgae and Yeasts

Oleaginous microalgae and yeasts represent promising candidates for large-scale production of lipids, which can be utilized for production of drop-in biofuels, nutraceuticals, pigments, and cosmetics. However, low lipid productivity and costly downstream processing continue to hamper the commercial deployment of oleaginous microorganisms. Strain improvement can play an essential role in the development of such industrial microorganisms by increasing lipid production and hence reducing production costs. The main means of strain improvement are random mutagenesis, adaptive laboratory evolution (ALE), and rational genetic engineering. Among these, random mutagenesis and ALE are straight forward, low-cost, and do not require thorough knowledge of the microorganism’s genetic composition. This paper reviews available mutagenesis and ALE techniques and screening methods to effectively select for oleaginous microalgae and yeasts with enhanced lipid yield and understand the alterations caused to metabolic pathways, which could subsequently serve as the basis for further targeted genetic engineering.

Reconstruction and analysis of a genome-scale metabolic model of the oleaginous fungus Mortierella alpina

Background

Mortierella alpina is an oleaginous fungus used in the industrial scale production of arachidonic acid (ARA). In order to investigate the metabolic characteristics at a systems level and to explore potential strategies for enhanced lipid production, a genome-scale metabolic model of M. alpina was reconstructed.

Results

This model included 1106 genes, 1854 reactions and 1732 metabolites. On minimal growth medium, 86 genes were identified as essential, whereas 49 essential genes were identified on yeast extract medium. A series of sequential desaturase and elongase catalysed steps are involved in the synthesis of polyunsaturated fatty acids (PUFAs) from acetyl-CoA precursors, with concomitant NADPH consumption, and these steps were investigated in this study. Oxygen is known to affect the degree of unsaturation of PUFAs, and robustness analysis determined that an oxygen uptake rate of 2.0 mmol gDW⁻¹ h⁻¹ was optimal for ARA accumulation. The flux of 53 reactions involving NADPH was significantly altered at different ARA levels. Of these, malic enzyme (ME) was confirmed as a key component in ARA production and NADPH generation. When using minimization of metabolic adjustment, a knock-out of ME led to a 38.28% decrease in ARA production.

Conclusions

The simulation results confirmed the model as a useful tool for future research on the metabolism of PUFAs.

Electronic supplementary material

The online version of this article (doi:10.1186/s12918-014-0137-8) contains supplementary material, which is available to authorized users.

Single cell oil production by Mortierella alpina

A filamentous fungus, Mortierella alpina 1S-4, was obtained, through extensive screening, as an potential producer of triacylglycerol containing C20 polyunsaturated fatty acids (PUFAs) such as arachidonic acid. With this discovery as a starting point, we conducted employing methods from metabolic engineering and molecular biology for controlling cultures and breeding mutant strains. These parental and mutant strains are now used for large-scale production of a variety of PUFAs.

Filamentous fungi for production of food additives and processing aids

Filamentous fungi are metabolically versatile organisms with a very wide distribution in nature. They exist in association with other species, e.g. as lichens or mycorrhiza, as pathogens of animals and plants or as free-living species. Many are regarded as nature's primary degraders because they secrete a wide variety of hydrolytic enzymes that degrade waste organic materials. Many species produce secondary metabolites such as polyketides or peptides and an increasing range of fungal species is exploited commercially as sources of enzymes and metabolites for food or pharmaceutical applications. The recent availability of fungal genome sequences has provided a major opportunity to explore and further exploit fungi as sources of enzymes and metabolites. In this review chapter we focus on the use of fungi in the production of food additives but take a largely pre-genomic, albeit a mainly molecular, view of the topic.

Functional characterization of Δ9 and ω9 desaturase genes in Mortierella alpina 1S-4 and its derivative mutants

Cloning and characterization of the Delta9 desaturase (Delta9I) gene of a fungus, Mortierella alpina 1S-4, was previously reported. In this study, two genes encoding Delta9 desaturase homologs were isolated from this fungus. One is a Delta9 desaturase (Delta9II) that exhibits 86% amino acid sequence similarity to Delta9I. Functional analysis involving expression of the encoding gene in Aspergillus oryzae revealed that Delta9II exhibits Delta9 desaturase activity, 18:0 being converted to 18:1Delta9. However, unlike Delta9I, the Delta9II transformant accumulated a low amount of 16:1Delta9. The other homolog is a omega9 desaturase (omega9) that exhibits 56 and 58% amino acid sequence similarity to Delta9I and Delta9II, respectively. On functional analysis with the Aspergillus transformant, it was found that omega9 does not convert 18:0 to 18:1Delta9, but converts 24:0 and 26:0 to 24:1omega9 and 26:1omega9, respectively. On the other hand, Delta9 desaturation-defective mutants characterized by accumulation of 18:0 were derived from M. alpina 1S-4 with a chemical mutagen, and the mutated sites of the Delta9 desaturase genes were identified. The mutation on the Delta9I gene was assumed to cause an amino acid replacement (W136Stop, G265D, and W360Stop) in the mutants (HR222, T4, and ST56), respectively. In these mutants, there was no mutated site on the Delta9II and omega9 genes. Real-time quantitative PCR (RTQ-PCR) analysis revealed that (1) the transcriptional level of the Delta9I gene in HR222 and T4 was much higher than that in the wild strain until the fifth day of the cultivation periods, (2) the Delta9II gene of the mutants was transcribed until the fourth day at the same level as the Delta9I gene of the wild strain, whereas the Delta9II gene of the wild strain was transcribed at a lower level, and (3) the transcriptional level of the omega9 gene in both the mutants and the wild strain was low, i.e., as low as that of the Delta9II gene of the wild strain. In these Delta9 desaturation-defective mutants, Delta9II is likely to play an important role in Delta9 desaturation.