Concerns about climate change and environmental destruction have led to interest in technologies that can replace fossil fuels and petrochemicals with compounds derived from sustainable sources that have lower environmental impact. Fatty alcohols produced by chemical synthesis from ethylene or by chemical conversion of plant oils have a large range of industrial applications. These chemicals can be synthesized through biological routes but their free forms are produced in trace amounts naturally. This review focuses on how genetic engineering of endogenous fatty acid metabolism and heterologous expression of fatty alcohol producing enzymes have come together resulting in the current state of the field for production of fatty alcohols by microbial cell factories. We provide an overview of endogenous fatty acid synthesis, enzymatic methods of conversion to fatty alcohols and review the research to date on microbial fatty alcohol production. The primary focus is on work performed in the model microorganisms, Escherichia coli and Saccharomyces cerevisiae but advances made with cyanobacteria and oleaginous yeasts are also considered. The limitations to production of fatty alcohols by microbial cell factories are detailed along with consideration to potential research directions that may aid in achieving viable commercial scale production of fatty alcohols from renewable feedstock.
Oils and oleochemicals produced by microbial cells offer an attractive alternative to petroleum and food-crop derived oils for the production of transport fuel and oleochemicals. An emerging candidate for industrial single cell oil production is the oleaginous yeast Lipomyces starkeyi. This yeast is capable of accumulating storage lipids to concentrations greater than 60% of the dry cell weight. From the perspective of industrial biotechnology L. starkeyi is an excellent chassis for single-cell oil and oleochemical production as it can use a wide variety of carbon and nitrogen sources as feedstock. The strain has been used to produce lipids from hexose and pentose sugars derived from cellulosic hydrolysates as well as crude glycerol and even sewage sludge. L. starkeyi also produces glucanhydrolases that have a variety of industrial applications and displays potential to be employed for bioremediation. Despite its excellent properties for biotechnology applications, adoption of L. starkeyi as an industrial chassis has been hindered by the difficulty of genetically manipulating the strain. This review will highlight the industrial potential of L. starkeyi as a chassis for the production of lipids, oleochemicals and other biochemicals. Additionally, we consider progress and challenges in engineering this organism for industrial applications.
The oleaginous yeast Lipomyces starkeyi was engineered for the production of long-chain fatty alcohols by expressing a fatty acyl-CoA reductase, mFAR1, from Mus musculus. The optimal conditions for production of fatty alcohols by this strain were investigated. Increased carbon-to-nitrogen ratios led to efficient C16 and C18 fatty alcohol production from glucose, xylose and glycerol. Batch cultivation resulted in a titer of 1.7 g/L fatty alcohol from glucose which represents a yield of 28 mg of fatty alcohols per gram of glucose. This relatively high level of production with minimal genetic modification indicates that L. starkeyi may be an excellent host for the bioconversion of carbon-rich waste streams, particularly lignocellulosic waste, to C16 and C18 fatty alcohols.
Background: NADPH-dependent enzymes play important roles in many anabolic reactions and the availability of redox cofactors can influence metabolic flux ultimately influencing titers of bioproducts produced by engineered microbial cells. This may be especially true of oleochemical production when carbon flux through the highly NADPH-dependent fatty acid biosynthesis pathway is increased. While pathway specific approaches are often applied to counter redox imbalance, a study evaluating generalized approaches to improved NADPH availability is lacking in Saccharomyces cerevisiae . Results: Here, we have created four unique synthetic Pyruvate-Oxaloacetate-Malate “POM” cycles consisting of either of the endogenous isoforms of pyruvate carboxylase ( PYC1 or PYC2 ), a modified version of malate dehydrogenase ( ‘MDH1 or ‘MDH2 ), and a truncated cytosolic form of the endogenous malic enzyme ( sMAE1 ). Only the POM cycle that combined expression of PYC1 , ‘MDH2 , and sMAE1 increased the titer of fatty alcohols produced; however, it did so in two unique fatty alcohol producing strains. In a FAS1 overexpression background, expression of this synthetic POM cycle increased fatty alcohol titers by 40% from 49.0 ± 2.2 mg/L to 68.6 ± 3.3 mg/L and showed similar results in a zwf1 deletion strain. The effect of overexpression of the endogenous NAD+ kinases UTR1 , YEF1 , and a cytosolic version of POS5 were also tested. We found that expression of POS5c resulted in an ~35% increase in fatty alcohol titer, while the overexpression of the UTR1 or YEF1 did not significantly influence titers. In these minimally engineered cells, combined overexpression of PYC1 , ‘ MDH2 , sMAE1 and POS5c did not further increase titers Conclusions: Overexpression of PYC1 in conjunction with ‘MDH2 and sMAE1 results in a synthetic POM cycle which can be utilized to improve fatty alcohol production in engineered strains of S. cerevisiae . Additionally, overexpression of a truncated version of POS5 ( POS5c ) results in similar increases in fatty alcohol production. These findings may serve to provide a generalized mechanism to increase NADPH production in engineered cells, resulting in increased bioproduct titers.
The goal of this project was to adapt the Yarrowia lipolytica plasmid based CRISPR/Cas9 system for usage in Lipomyces starkeyi. Lipomyces starkeyi is an oleaginous yeast, which synthesizes and stores high amounts of intracellular lipids. This specific yeast can store lipids at concentrations higher than 60% of its dry cell weight. Due to these high concentrations of lipids, L. starkeyi is a desired organism for the production of biofuels and other oleochemicals. However, there is a lack of knowledge and of genetic tools when trying to engineer the cells to produce these lipids for our use. The genome editing tool, CRISPR/Cas9 is efficient and simple, therefore desirable for the engineering of L. starkeyi. The goal was achieved by replacing the Y. lipolytica promoter with a L. starkeyi promoter, inserting guide RNA, as well as confirming cas9 protein expression.
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