Biosynthesis of Long-Chain ω-Hydroxy Fatty Acids by Engineered

Apr 1, 2019 - Long-chain hydroxy fatty acids (HFAs) are rare in nature but have many promising industrial applications. In this study, we developed a ...
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Biotechnology and Biological Transformations

Biosynthesis of long-chain #-hydroxy fatty acids by engineered Saccharomyces cerevisiae Jingjing Liu, Chuanbo Zhang, and Wenyu Lu J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.9b00109 • Publication Date (Web): 01 Apr 2019 Downloaded from http://pubs.acs.org on April 1, 2019

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Biosynthesis of long-chain ω-hydroxy fatty acids by engineered Saccharomyces

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cerevisiae

3 4

Jingjing Liu a, Chuanbo Zhang a , Wenyu Lu a,b,c*

5

a

6

300072, PR China;

7

b

8

Education, Tianjin, 300072, PR China.

9

c

10

School of Chemical Engineering and Technology, Tianjin University, Tianjin

Key Laboratory of System Bioengineering (Tianjin University), Ministry of

SynBio Research Platform, Collaborative Innovation Center of Chemical Science

and Engineering (Tianjin), Tianjin, 300350, PR China

11 12

* Corresponding

13

Tel.: +86-22-27892132; fax: +86-22-27400973.

14

E-mail address: [email protected]

author: Wenyu Lu

15 16 17 18 19 20 21 22 23

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Abstract

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Long-chain hydroxy fatty acids (HFAs) are rare in nature but have many promising

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industrial applications. In this study, we developed a biosynthesis method to produce

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long-chain ω- hydroxy fatty acids. Through disruption of the acyl-CoA synthetases

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FAA1 and FAA4 and the fatty acyl-CoA oxidase POX1, a Saccharomyces cerevisiae

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strain was engineered to accumulate free fatty acids (FFAs). Subsequently, the

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cytochrome P450 monooxygenase CYP52M1 from Starmerella bombicola was

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introduced to convert FFAs to HFAs, leading to the production of C16 and C18 HFAs

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at the ω or ω-1 positions. Next, CYP52M1 was reconstituted with the homologous

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reductase S. bombicola CPR and the heterologous reductase Arabidopsis thaliana

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cytochrome P450 reductase. The results showed that the CYP52M1-AtCPR1 system

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significantly increased in FFA the hydroxylation. Moreover, a self-sufficient P450

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enzyme system was constructed to achieve higher transformation efficiency. Finally,

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fed-batch fermentation yielded as much as 347 ± 9.2 mg/L ω-HFAs.

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Key words: Long-chain ω-hydroxy fatty acids, Saccharomyces cerevisiae,

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Cytochrome P450, Cytochrome P450 reductase, Synthetic biology

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1. Introduction

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Depletion of energy-related resources and increased levels of CO2 in the

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atmosphere, leading to global climate change, have driven the development of

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environmentally friendly processes, particularly those involving microbes, for the

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production of fuels and commercial chemicals.1-3 In addition, microbial-based

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processes

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chemical selectivity, both of which facilitate their industrial development.4

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Long-chain (C14–C18) hydroxy fatty acids (HFAs) are valuable chemicals that have a

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carboxyl and a hydroxyl group, and they can be easily converted into other derivatives

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that exhibit good reactivity, stability, and viscosity.5 Owing to their unique properties,

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long-chain HFAs are widely used in various fields, such as food, chemical, and

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cosmetic industries, and serve as synthetic intermediates for pseudoceramides,

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polyesters, and cyclic lactones.6 Recently, their pharmaceutical attributes, including

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antibiotic, anti-inflammatory, and antidiabetic effects, have also been revealed.7, 8 In

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particular, the positions of the hydroxyl group in the fatty acid chain plays a vital role

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in its physiological mechanisms and chemical applications. Hydroxylation of the

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hydrocarbon located close to the carboxyl group results in α- or β-hydroxylation,

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which affects human health.9 Omega HFAs (ω-HFAs) are fatty acids with a hydroxyl

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group at the terminal end. These multifunctional compounds have a broad range of

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applications, including use as adhesives, lubricants, and potential anticancer

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agents,10,11 and serve as building materials for the synthesis of polymers, such as

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bioplastics, with high resistance to water, low toxicity, good biocompatibility, and

have less safety concerns associated with them and also have and higher

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excellent chemical versatility.12,13

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Given their broad commercial uses, substantial effort has been put into producing

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HFAs chemically or biologically. Direct synthesis of products with the desired

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specific hydroxylation is difficult to accomplish through chemical catalysis because of

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the limitations of selective carbon atoms and harsh reaction conditions.14

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Alternatively, microorganisms such as yeast, 15 Escherichia coli, 16, 17 Bacillus18 allow

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producing HFAs through selective enzymatic hydroxylation. HFAs can be obtained

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via two biocatalytic reactions: (a) hydration of the double bond(s) of an unsaturated

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fatty acid by a hydratase, and (b) the oxidation of the fatty acid by an oxidase (e.g.

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P450 monooxygenases). For example, gamma octalactone/decalactone can be

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synthesized from octanoic or decanoic acid through gamma hydroxylation by

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Mortierella species.19 A large number of microorganisms producing hydratases

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(oleato and linoleato hydratases) are able to introduce a hydroxyl group at position 10

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or 13 of C18 unsaturated fatty acids.20 For example, Bacillus megaterium can

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hydroxylate oleic acid on carbon atoms 1, 2, and 3 to produce different hydroxy oleic

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acids.21 Candida tropicalis produces HFAs as by-products when cultured on alkanes

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or fatty acids as the main carbon source.22 However, the engineering of fatty acid

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biosynthesis with a self-sufficient P450 enzymatic complex in the same heterologous

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host is a new concept.

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Saccharomyces cerevisiae is a conventional and well-studied production host for

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which mature genetic tools for metabolic pathway manipulation are available. It has

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been successfully manipulated to produce numerous valuable platform chemicals and

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biofuels.23,

24

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medium, can utilize inexpensive renewable feedstock, and has a fast growth rate,

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facilitating its broad industrial utilization.25 Therefore, S. cerevisiae is an appropriate

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candidate for de novo synthesis of HFAs from sugars. However, wild-type S.

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cerevisiae is incapable of accumulating free fatty acids (FFAs) and subsequently

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catalyzing them to HFAs because it possess a pathway for β-oxidation. Theoretically,

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to endow yeast with the ability to convert glucose to HFAs, it is necessary to

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overproduce FFAs by blocking FFA and preventing fatty acid degradation through

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β-oxidation, transform FFAs to HFAs via exogenous enzymatic hydroxylation, and

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integrate these two pathways into one metabolic route.

Furthermore, S. cerevisiae is easily cultured in chemically defined

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First, to accumulate high levels of FFAs in S. cerevisiae, it is essential to

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interrupt FFA reactivation and prevent fatty acid degradation through β-oxidation.26, 27

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In S. cerevisiae, fatty acids are mainly synthesized de novo as activated fatty acids

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(fatty acyl-CoAs) by cytosolic fatty acid synthase (FAS), which is composed of two

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subunits encoded by FAS1 and FAS2.28, 29 Subsequently, downstream modifications

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are necessary for the production and excretion of FFAs. S. cerevisiae has six known

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acyl-CoA synthetases encoded by FAA1, FAA2, FAA3, FAA4, FAT1, and FAT2,30 and

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FFAs will be rapidly re-activated by these fatty acyl-CoA synthetases to fatty

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acyl-CoAs, whose accumulation feedback hinders fatty acid biosynthesis and

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secretion.31 Previous studies have shown that FFAs are secreted and accumulate after

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deleting

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Δfaa1Δfaa2Δfaa3Δfaa4 knockout strain did not excrete higher levels of FAA than a

acyl-CoA

synthetases,

encoded

by

FAA1

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FAA4,

but

a

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Δfaa1Δfaa4 strain.27 This is consistent with earlier research showing that the majority

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of synthetase activity is attributed to the long-chain acyl-CoA synthetases FAA1 and

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FAA4.30 β-Oxidation is the catabolism of fatty acid molecules to generate acetyl-CoA

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and provide energy in the peroxisome, and is a major contributor to the loss of fatty

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acids.32, 33 POX1, encoding the fatty acyl-CoA oxidase , is responsible for the first

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step of this pathway. Li et al. removed POX1 and observed a 4-fold increase in FFA

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content when compared with that in the wild-type control.34

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After FFAs accumulate in the biocatalytic system, they will be persistently

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converted to HFAs. The four types of enzymes involved in the biocatalysis of FAAs

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to HFAs are cytochrome P450 monooxygenase, hydratase, hydroxylase, and

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lipoxygenase; among these, cytochrome P450 monooxygenase is known to

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hydroxylate FFAs to HFAs.21, 35 In eukaryote systems, class II P450 enzymes along

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with their heme donor, cytochrome P450 reductase (CPR), are mainly involved in

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catalyzing intricate reactions, such as regio- and stereo-specific hydroxylation of

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various endogenous and exogenous compounds,36 and these reactions are known to be

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rate-limiting steps.37 In general, terminal or subterminal HFAs are synthesized by

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members of microbial CYPs, including CYP52 and CYP153, through hydroxylation

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of fatty acids at specific positions. Several CYP52 genes have been identified in

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Starmerella bombicola, and these genes encode isozymes with diverse substrate

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specificities.38

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In this study, we engineered S. cerevisiae to directly produce de novo ω-HFAs

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(Fig. 1). We then evaluated the mechanisms of ω-HFAs generation in the engineered

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strains and analyzed the yield in fed-batch fermentation. The results showed that this

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method was promising for large-scale production of long-chain ω-HFAs.

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2. Materials and Methods

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2.1 Reagents, strains, and medium

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CYP52M1 (GenBank: EU552419), S. bombicola CPR (SbCPR; GenBank: EF050789),

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and Arabidopsis thaliana CPR1 (AtCPR1; GenBank: BT008426.1) were synthesized

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with codon optimization by Jinsirui Biotechnology Co., Ltd. (Nanjing, China) and

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were cloned into plasmid pUC57. S. cerevisiae BY4741 was used as the parent strain

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for the construction of all engineered strains. The engineered yeast strains were grown

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in auxotrophic SD plates39 containing 20 g/L glucose, 6.7 g/L yeast nitrogen base, 2

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g/L amino acid mixture (without leucine, tryptophan, uracil, adenine, and histidine for

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auxotrophs as appropriate), and 20 g/L agar. Phanta Max Super-Fidelity DNA

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Polymerase was purchased from Vazyme Botech Co., Ltd. (Nanjing, China). Primers

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were synthesized by GENEWIZ (Beijing, China). DNA gel mini purification and mini

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plasmid extraction kits were purchased from TIANGEN (Beijing, China).

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2.2 Strain construction

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The expression cassettes consisted of a promoter, structural gene, and terminator and

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were constructed by fusion polymerase chain reaction (PCR). Next, 45-bp overlaps

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were designed between the adjacent fragments such that they could be assembled into

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S. cerevisiae genome. All promoters, terminators, and POX1, FAA1, FAA4 were

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amplified from enomic DNA of S. cerevisiae BY4741. POX1A-HIS3-POX1B,

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FAA4A-LEU2-FAA4B

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FAA1A-LEU2-FAA1B,

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constructed by fusion PCR and were integrated into S. cerevisiae genome. The

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PGK1p-CYP52M1-ADH1t,

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expression cassettes were constructed by fusion PCR and were integrated into the HO

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site of S. cerevisiae separately. Then a CYP52M1-AtCPR1 fusion gene was generated

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using the widely used GSTSSGSG linker. All DNA fragments were transformed into

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yeast cells using the lithium acetate method.39All strains used in this study are listed

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in Table 1. The expression cassettes and primers used for strain construction in this

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study are shown in Fig. S1 and Table S1, respectively.

TDH3-SbCPR-TDH2t,

expression

and

cassettes

were

TDH3-AtCPR1-TDH2t

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2.3 Yeast strain cultivation and fermentation

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A single colony grown on SD plates was inoculated to 5-mL of yeast peptone

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dextrose medium (YPD) and incubated overnight at 30°C with shaking at 220 rpm.

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Then, aliquots were transferred to 250-mL shake flasks containing 30 mL of YPD at

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an initial optical density at 600 nm (OD600) of 0.05 and cultivated at 30°C with

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shaking at 220 rpm for 4 days. Each sample was analyzed in triplicate.

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The strain B06 was applied for batch and fed-batch fermentation in a 5-L

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bioreactor. A single colony obtained from the plate was inoculated into a 250-mL

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shake flask containing 30-mL of YPD and cultivated at 30°C with shaking at 220 rpm

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overnight. For batch fermentation, the overnight culture was transferred to a 500-mL

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shake flask containing 100-mL of YPD with an initial OD600 0.05 and cultured at

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30°C with shaking at 220 rpm for 18 h. The culture was then applied for seed culture,

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and a 10% (v/v) solution was inoculated into a 5-L bioreactor containing 2-L of YPD.

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Fermentation was carried out at 30°C with an initial pH of 5.5 and an air flow rate of

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2 L/min. Dissolved oxygen was maintained at approximately 35% by stirring. The pH

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was controlled at 5.5 with NH3·H2O and 5 N H2SO4.40

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During the fed-batch fermentation, glucose was used as the main carbon source

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for cell growth and synthesis of target products. After 24 h, concentrated glucose

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solution (500 g/L, 1000 mL) mixed with glutamate solution (10 g/L, 12 mL),

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microelement stock solution (12 mL/L, 10 mL), and vitamin stock solution (10 mL/L,

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12 mL)41 was intermittently fed into the bioreactor every 12 h to a glucose

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concentration 20 g/L.

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2.4 Extraction of FAAs and long-chain ω-HFAs

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The extraction process was conducted as described previously.42 Two milliliters of

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culture broth was centrifuged at 10500×g for 5 min to collect the cell pellet and the

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supernatant separately. Before extraction, C15:0-FFA (25 μg) or ω-OH-C15:0-FFA

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(25 μg) was added as an internal standard. For the extraction of extracellular fatty

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acids, 500 μL ethyl acetate was added, and the solution was oscillated for 10 min and

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then centrifuged at 10500×g for 10 min. For intracellular fatty acids and HFAs, 500

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μL ethyl acetate was added to the cell pellet, oscillated for 10 min with glass beads,

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and then centrifuged at 10500×g for 10 min. The upper ethyl acetate layer was

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recovered.

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2.5 Gas chromatography-mass spectrometry (GC-MS) analysis and quantification of

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FAAs and HFAs

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The extract solution was evaporated with nitrogen gas and the extract was exposed to

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2 mL of 2 N H2SO4 in methanol at 70°C for 1 h to generate fatty acid methyl esters

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(FAMEs) and hydroxy fatty acid methyl esters (HFAMEs).43 For analysis of FFAs,

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the FAMEs were extracted with hexane. For analysis of HFAs, the HFAMEs were

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extracted with hexane, evaporated with nitrogen gas, and further converted into their

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trimethylsilyl derivatives by incubation with an excess of N,O-bis (trimethylsilyl)

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trifluoroacetamide at 70°C for 1 h.43 The solution was cooled down to room

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temperature and filtered through a 0.22-μm membrane for GC-MS.

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Briefly, a Bruker SCION 456 GC-FID was used for FAME quantification. The

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injector and detector temperature were set at 300°C and 310°C, respectively. The

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oven heating procedures were as previously described,44 and 1 μL sample was

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injected at a split ratio of 10. Target product was quantified relatively by the peak area

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normalized to the internal standard peak area. The structures of the HFAs were further

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confirmed by GC-MS analysis. For this, 1 μL sample was analyzed at a split ratio of

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10 on a Shimadzu GCMS-TQ8030 equipped with an Agilent Technologies HP-5MS

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GC column (30 m × 0.250 mm × 0.25 μm) using helium as the carrier gas. The

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injection temperature was set at 300°C, and the oven temperature program was as

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follows: 100°C for 2 min, ramp rate of 40°C/min to 200°C and hold for 1 min, ramp

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rate of 4°C/min to 245°C and hold for 1 min, ramp rate of 30°C to 290°C and hold for

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10 min.The ion source temperature was 300°C, and spectra were scanned from m/z

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30–600 with a solvent cutoff at 4 min. HFAs were identified by comparison with the

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reference spectra from Wiley Registry of Mass Spectra. HFA production was

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quantified by normalizing the peak area to the internal standard peak area.

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3. Results and Discussion

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3.1 Construction of △Pox1△Faa1△Faa4 mutant S. cerevisiae and accumulation of

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long-chain FFAs

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To increase the FFA pool, it is necessary to consider that endogenous fatty acids can

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be degraded by β-oxidation in peroxisomes,45 preventing FAAs accumulation. Thus,

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we aimed to inactivate the β-oxidation pathway to improve fatty acid stability and

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availability in S. cerevisiae cell factories. β-Oxidation is executed by four enzymes:

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acyl-CoA oxidase enol-CoA hydratase, 3-hydroxy acyl-CoA dehydrogenase, and

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3-oxoacyl-CoA thiolase. The first and rate-limiting step is catalyzed by acyl-CoA

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oxidase, encoded by POX1 in S. cerevisiae. This strategy results in functional

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disruption of the β-oxidation pathway, thereby preventing yeast cells from using fatty

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acids as a carbon source for cell growth and production.34 Thus, destruction of the

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β-oxidation pathway has become an effective strategy for the efficient accumulation

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of fatty acids in the metabolic engineering of S. cerevisiae.

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Fatty acids are mainly synthesized de novo by a cytosolic FAS as activated fatty

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acids (fatty acyl-CoAs) by condensation of acetyl-CoA and malonyl-CoA, and the

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fatty acyl-CoAs are released as FFAs by thioesterase.29 Unfortunately, FFAs are

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easily re-activated by fatty acyl-CoA synthetases to fatty acyl-CoAs, whose

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accumulation feedback obstructs fatty acid biosynthesis and accumulation.28 To

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circumvent this, we aimed to knock out acyl-CoA synthetases. S. cerevisiae has six

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acyl-CoA synthetases, encoded by FAA1, FAA2, FAA3, FAA4, FAT1, and FAT2. The

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peroxisomal FAT1 and FAT2 were found to be inessential for growth when fatty

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acids were the carbon source.46 Further, FFAs are excreted from yeast cells into the

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growth

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Δfaa1Δfaa2Δfaa3Δfaa4 knockout strain did not show higher FAA levels than a

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Δfaa1Δfaa4 strain.27 These results showed that the majority of synthetase activity was

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centralized on the long-chain acyl-CoA synthetases FAA1 and FAA4. In a previous

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study, yeast cells secreted 207 mg/L FFAs upon knockout of FAA1 and FAA4 and

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overexpression of TesA, a native E. coli thioesterase.47 In another recent study, 520

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mg/L FFAs were obtained by disruption of FAA1 and FAA4 and overexpression of a

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truncated peroxisomal acyl-CoA thioesterase.48 Accordingly, we targeted these

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synthetases to drive FFA overproduction in S. cerevisiae.

medium

upon

disruption

of

FAA1

and

FAA4;

however,

a

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In this study, we performed a systematic analysis of the overproduction and

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accumulation of FFAs by deleting the two main fatty acyl-CoA synthetases encoding

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FAA1 and FAA4 genes to disrupt the re-activation process. Similarly, we disrupted

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POX1, which encodes a fatty acyl-CoA oxidase, in order to interrupt fatty acid

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degradation through β-oxidation. Generally, S. cerevisiae produces primarily C16 and

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C18 FFAs. A wild-type strain produced only 3 mg/L FFAs.45 The cytochrome P450

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enzyme CYP52M1 has been shown to preferentially oxidize C16-C18 saturated and

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unsaturated FFAs preferentially. Therefore, we chose to only identify and measure the

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C16-C18 saturated and unsaturated FFAs. After cultivation for 4 days, processed

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samples were subjected to GC-MS analysis to confirm FFAs production. Four new

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distinct peaks were detected (Fig. S2) and were further identified as hexadecanoic

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acid (C16:1), hexadecenoic acid (C16:0), oleic acid (C18:1), and octadecanoic acid

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(C18:0).49 The mass spectra of the four FFAs were shown in Figure S3, indicating that

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the biosynthesis of C16-C18 FFAs in strain B03. The results showed that the total

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yield of intra-cellular and extracellular C16-C18 FFAs was 336.1 mg/L in the

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△Pox1△Faa1△Faa4 knockout strain B03 (Fig. 2).

269 270

3.2 Selection of CPRs for the CYP52M1 enzyme to oxidize FFAs

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Cytochrome P450s and their heme donors, CPRs, carry out hydroxylation of

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various endogenous and exogenous compounds. Cytochrome P450s are able to

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catalyze complex reactions, such as the regio- and stereoselective oxidation of

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inactivated hydrocarbon C-H bonds to the corresponding hydroxy (C–OH) products.50

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The cytochrome P450 enzyme CYP52M1, from S. bombicola, oxidizes FFAs into

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HFAs, and preferentially oxidizes C16 to C20 FFAs. Moreover, CYP52M1

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hydroxylated fatty acids at their ω- and ω-1 positions.38 In addition, its

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monooxygenase reactivity relies on the electron transfer compatibility of its redox

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partner, CPR51, 52 Thus, it is essential to choose an appropriate functional CPR, which

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will maximize the redox coupling efficiency of P450 enzymes and achieve optimal

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CYP functional activity.

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In this study, we chose two different CPR-encoding genes and co-expressed

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these genes with CYP52M1 in strain B03, resulting in strains B04 (SbCPR-CYP52M1)

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and B05 (AtCPR1-CYP52M1). After cultivation for 4 days, the processed samples

285

were methylated and trimethylsilylated and analyzed by GC-MS. GC-MS analysis

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revealed that four new compounds were generated. Compound 1 (Fig. 3A) showed a

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mass spectrum with prominent ions at m/z 343 (M-15, loss of CH3), 311 (M-47, loss

288

of CH3 and CH3OH), and 117 [(CH3)3SiO+CHCH3] (Fig. 3B) and was identified as

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ω-1-hydroxy palmitic acid.53 Compound 2 (Fig. 3A), displayed a mass spectrum with

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prominent ions at m/z 343 (M-15, loss of CH3), 327 (M-31, loss of OCH3), 311

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(M-47, loss of CH3 and CH3OH), and 103 [(CH3)3SiO+=CH2] (Fig. 3C) and was

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identified as ω-hydroxy palmitic acid.49, 54 Compound 3 (Fig. 3A) exhibited a mass

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spectrum with prominent ions at m/z 369 (M-15, loss of CH3), 337 (M-47, loss of CH3

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and CH3OH), and 117 [(CH3)3SiO+CHCH3] (Fig. 3D) and was identified as

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ω-1-hydroxy oleic acid.55 Compound 4 (Fig. 3A) displayed a mass spectrum with

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prominent ions at m/z 369 (M-15, loss of CH3), 353 (M-31, loss of OCH3), 337

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(M-47, loss of CH3 and CH3OH), and 103 [(CH3)3SiO+=CH2] (Fig. 3E), which was

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identical to those of ω-hydroxy oleic acid54. For the first time, a robust long-chain

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ω-HFAs producing S. cerevisiae was successfully established and highly specific

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production of C16 and C18 ω-HFAs was achieved. GC analysis showed that B05

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containing AtCPR1 from A. thaliana produced 83.2 mg/L long-chain ω-HFAs, which

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was 2.2-fold higher than that in strain B04 containing SbCPR from S. bombicola, in

303

contrast to our expectations (Fig. 4A). Typically, a homologous CYP-CPR

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reconstituted system is chosen because such a system will have high electron transfer

305

compatibility and coupling efficiency to enhance monooxygenase activity.55,

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However, in this study, the heterologous CYP-CPR reconstituted system

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(AtCPR1-CYP52M1) showed a greater increase in the hydroxylation of FFAs,

308

supporting our hypothesis that CYP-CPR interaction plays a vital role in determining

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the level of CYP catalytic efficiency. Therefore, we verified that the reactivity of

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CYP52M1 between homologous and heterologous systems could be attributed to the

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natural electron transfer compatibility and CYP-CPR interaction. Actually, The CPR

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and P450s interaction efficiency was somewhat modulated dependent on the CPR. It

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has been reported that CPR even influence the metabolite pattern of P450,58,

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revealing the importance of the source of CPR in the functional activity of CYP

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reconstituted systems in terms of long-chain ω-HFAs production.

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3.3 Construction of a self-sufficient P450 enzyme system through fusion of CYP52M1

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with AtCPR1 to improve long-chain ω-HFAs production

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In the fermentation of strain B05, the precursor FFAs strongly accumulated and failed

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to be transformed into ω-HFAs (data not shown), which could be explained by the

320

low catalytic efficiency of the CYP-CPR reconstituted system. Our previous studies

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have shown that an artificial cytochrome P450-CPR fusion protein contributes to

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improving the catalytic activity of fusion enzymes.60 Thus, we constructed an

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artificial fusion protein containing CYP52M1 and AtCPR1 to verify the feasibility of

324

this method. The widely used linker GSTSSGSG was applied to construct the

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CYP52M1-AtCPR1 fusion protein in strain B05, yielding strain B06.

59

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As shown in Fig. 4B, the artificial CYP52M1-AtCPR1 fusion protein performed

327

better than co-expression of CYP52M1 and AtCPR1, with long-chain ω-HFAs

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production of up to 148.7 mg/L in shake flask culture; this was a 1.8-fold increase

329

compared with that in strain B05. This result verified the feasibility of the method and

330

further emphasized the importance of the transformation efficiency of the cytochrome

331

P450 enzyme, which may be regarded as the rate-limiting step.

332 333

3.4 Batch and fed-batch fermentation of B06 in a 5-L bioreactor

334

The best long-chain ω-HFAs producing strain, B06, was used for batch and fed-batch

335

fermentation. During batch fermentation, cell growth, residual glucose concentration,

336

ethanol concentration, and ω-HFAs production were simultaneously monitored. As

337

shown in Fig. 5A, during the first 12 h, the cells grew very fast, glucose was

338

consumed quickly, and ω-HFAs synthesis began. Upon depletion of ethanol, ω-HFAs

339

began to accumulate gradually, and the highest yield obtained was 141.7 ± 3.5 mg/L,

340

with an OD600 of approximately 35.5.

341

Next, the strain B06 was applied for fed-batch fermentation. As shown in Fig. 5B,

342

the OD600 of B06 in fed-batch fermentation was approximately 2.8-fold higher than

343

that in batch fermentation. Furthermore, the ω-OHFA yield was significantly further

344

increased up to 347 ± 9.2 mg/L, indicating high-level long-chain ω-HFA production.

345

Taken together, we have constructed yeast cell factories for the production of FFAs

346

and long-chain ω-hydroxy fatty acids. These strains represent a beginning for the

347

establishment of yeast-based commercial bioprocesses for the production of

348

chemicals and advanced biofuels from renewable resources. Our metabolic

349

engineering strategies of pathway balancing not only facilitated the production of

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long-chain ω-hydroxy fatty acids but also provide valuable insights into construction

351

of yeast cell factories for production of other structures of HFAs.

352 353 354 355

Conflicts of interest The authors declare no conflicts of interest.

356

Acknowledgement

357

This work was supported by the National Natural Science Foundation of Chain (No.

358

21878220) and Major Research Plan of Tianjin (16YFXTSF00460).

359

Supporting Information

360

Table S1. Supplementary material Tables.

361

Figure S1. Supplementary material Figures.

362

References

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Figure Captions

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Fig.1. Metabolic pathway from glucose to long-chain HFAs in S. Cerevisiae. FAS1

536

and FAS2, fatty acid synthase; TE, acyl-CoA thioesterase;

537

Fig.2. Production of C16-C18 FFAs by the engineered yeast strains B03 in shake

538

flasks. Data are the mean value of three independent experiments.

539

Fig.3. GC chromatogram and mass spectrum profile from S. cerevisiae B03 (control)

540

and B05 fermentations.

541

Fig.4. Production of long-chain HFAs by the engineered yeast strains B04-B06 in

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shake flasks. Data are the mean value of three independent experiments.

543

Fig.5. Production of long chain HFAs by strain B06 in batch and fed-batch

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cultivations in a 5-L bioreactor. (A) Batch fermentation of B06 in a 5-L bioreactor.

545

(B) Fed-batch fermentation of B06 in a 5-L bioreactor.

546 547 548

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Table 1 Strains involved in this study Name

Description

source

BY4741

MATa; leu2-3,112; met17; ura3-1; his3-11,15

Our lab

POX1 expression cassette in BY4741 was This B01 deleted

study This

B02

FAA1 expression cassette in B01 was deleted study This

B03

FAA4 expression cassette in B02 was deleted study CYP52M1 and SbCPR gene expression cassettes This

B04

were integrated into the HO site of B03 with study selection marker HIS3 CYP52M1

and

AtCPR1

gene

expression This

B05

cassettes were integrated into the HO site of B03 study with selection marker HIS3 CYP52M1-AtCPR1 fusion protein expression This

B06

cassettes were integrated into the HO site of B03 study with selection marker HIS3

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