In the oleaginous yeast Yarrowia lipolytica, de novo lipid synthesis and accumulation are induced under conditions of nitrogen limitation (or a high carbon-to-nitrogen ratio). The regulatory pathway responsible for this induction has not been identified. Here we report that the SNF1 pathway plays a key role in the transition from the growth phase to the oleaginous phase in Y. lipolytica. Strains with a Y. lipolytica snf1 (Ylsnf1) deletion accumulated fatty acids constitutively at levels up to 2.6-fold higher than those of the wild type. When introduced into a Y. lipolytica strain engineered to produce omega-3 eicosapentaenoic acid (EPA), Ylsnf1 deletion led to a 52% increase in EPA titers (7.6% of dry cell weight) over the control. Yarrowia lipolytica is one of the most extensively studied "nonconventional" yeasts with importance in multiple industrial applications (1) and has been engineered for the commercial production of omega-3 eicosapentaenoic acid (EPA) (2). Although Y. lipolytica is an oleaginous yeast capable of accumulating large amounts of lipid in the cell, lipid accumulation schemes using hydrophobic carbon sources as substrates have been reported in many cases (3-5). For de novo lipid synthesis using glucose as a carbon source, nitrogen limitation or a high carbon-to-nitrogen (C/N) ratio is the most commonly employed condition to increase intracellular lipid accumulation. However, in wild-type cells, lipids accumulate to Ͻ20% of dry cell weight (DCW) (6, 7), and it usually takes 3 to 10 days to accumulate the maximum level of lipids (7). Thus, an understanding of the regulation of lipid synthesis and accumulation will allow us to engineer this organism for increased rates of lipid accumulation, thereby significantly reducing the cost of manufacture for lipids and valuable lipid-derived compounds.Biochemical studies of various enzymes involved in de novo lipid synthesis have provided an explanation for how oleaginous microbes accumulate lipids under conditions of nitrogen limitation (reviewed in references 4 and 8). Briefly, nitrogen exhaustion in the medium results in stimulation of AMP deaminase, which breaks down AMP to IMP and ammonium in order to salvage nitrogen. The decrease in the AMP concentration inhibits isocitrate dehydrogenase, and accumulated isocitrate is equilibrated by aconitase with citrate, which then exits the mitochondria for acetyl coenzyme A (acetyl-CoA) generation by cytosolic ATPcitrate lyase (ACL). ACL activity is thought to be critical for lipid synthesis, and cytoplasmic malic enzyme was also shown to be important for lipid synthesis by supplying NADPH for fatty acid synthesis in certain oleaginous microorganisms. Although homologs of these enzymes were found in Y. lipolytica (9), there are not many biochemical studies of these enzymes in this yeast. It also remains to be examined if this mechanism is applicable to other nutritional limitations that induce lipid accumulation, such as phosphate, magnesium, or sulfur limitation.We are interested in discovering and controll...
Biosynthesis of the commercial carotenoids canthaxanthin and astaxanthin requires -carotene ketolase. The functional importance of the conserved amino acid residues of this enzyme from Paracoccus sp. strain N81106 (formerly classified as Agrobacterium aurantiacum) was analyzed by alanine-scanning mutagenesis. Mutations in the three highly conserved histidine motifs involved in iron coordination abolished its ability to catalyze the formation of ketocarotenoids. This supports the hypothesis that the CrtW ketolase belongs to the family of iron-dependent integral membrane proteins. Most of the mutations generated at other highly conserved residues resulted in partial activity. All partially active mutants showed a higher amount of adonixanthin accumulation than did the wild type when expressed in Escherichia coli cells harboring the zeaxanthin biosynthetic gene cluster. Some of the partially active mutants also produced a significant amount of echinenone when expressed in cells producing -carotene. In fact, expression of a mutant carrying D117A resulted in the accumulation of echinenone as the predominant carotenoid. These observations indicate that partial inactivation of the CrtW ketolase can often lead to the production of monoketolated intermediates. In order to improve the conversion rate of astaxanthin catalyzed by the CrtW ketolase, a color screening system was developed. Three randomly generated mutants, carrying L175M, M99V, and M99I, were identified to have improved activity. These mutants are potentially useful in pathway engineering for the production of astaxanthin.
ω-3 fatty acid desaturase is a key enzyme for the biosynthesis of ω-3 polyunsaturated fatty acids via the oxidative desaturase/elongase pathways. Here we report the identification of three ω-3 desaturases from oomycetes, Pythium aphanidermatum, Phytophthora sojae, and Phytophthora ramorum. These new ω-3 desaturases share 55 % identity at the amino acid level with the known Δ-17 desaturase of Saprolegnia diclina, and about 31 % identity with the bifunctional Δ-12/Δ-15 desaturase of Fusarium monoliforme. The three enzymes were expressed in either wild-type or codon optimized form in an engineered arachidonic acid producing strain of Yarrowia lipolytica to study their activity and substrate specificity. All three were able to convert the ω-6 arachidonic acid to the ω-3 eicosapentanoic acid, with a substrate conversion efficiency of 54–65 %. These enzymes have a broad ω-6 fatty acid substrate spectrum, including both C18 and C20 ω-6 fatty acids although they prefer the C20 substrates, and have strong Δ-17 desaturase activity but weaker Δ-15 desaturase activity. Thus, they belong to the Δ-17 desaturase class. Unlike the previously identified bifunctional Δ-12/Δ-15 desaturase from F. monoliforme, they lack Δ-12 desaturase activity. The newly identified Δ-17 desaturases could use fatty acids in both acyl-CoA and phospholipid fraction as substrates. The identification of these Δ-17 desaturases provides a set of powerful new tools for genetic engineering of microbes and plants to produce ω-3 fatty acids, such as eicosapentanoic acid and docosahexanoic acid, at high levels.
The RNA Abundance Database (RAD; http://www.cbil.upenn.edu/RAD) provides a comprehensive MIAME-supportive infrastructure for gene expression data management and makes extensive use of ontologies. Specific details on protocols, biomaterials, study designs, etc. are collected through a user-friendly suite of web annotation forms. Software has been developed to generate MAGE-ML documents to enable easy export of studies stored in RAD to any other database accepting data in this format (e.g. ArrayExpress). RAD is part of a more general Genomics Unified Schema (http://www.gusdb.org), which includes a richly annotated gene index (http://www.allgenes.org), thus providing a platform that integrates genomic and transcriptomic data from multiple organisms. This infrastructure enables a large variety of queries that incorporate visualization and analysis tools and have been tailored to serve the specific needs of projects focusing on particular organisms or biological systems.
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