Whole-Cell Biotransformation of 1,12-Dodecanedioic Acid from Coconut Milk Factory Wastewater by Recombinant CYP52A17 SS Expressing Saccharomyces cerevisiae

: Biotransformation of fatty acids from renewable wastewater as feedstock to value-added chemicals is a fascinating commercial opportunity. α , ω -Dicarboxylic acids (DCAs) are building blocks in many industries, such as polymers, cosmetic intermediates, and pharmaceuticals, and can be obtained by chemical synthesis under extreme conditions. However, biological synthesis can replace the traditional chemical synthesis using cytochrome P450 enzymes to oxidize fatty acids to DCAs. Saccharomyces cerevisiae BY(2R) / pYeDP60-CYP52A17 SS (BCM), a transgenic strain expressing the galactose-inducible CYP52A17 SS cytochrome P450 enzyme, was able to grow in a coconut milk factory wastewater (CCW) medium and produced 12-hydroxydodecanoic acid (HDDA) and 1,12-dodecanedioic acid (DDA). The supplementation of CCW with 10 g / L yeast extract and 20 g / L peptone (YPCCW) markedly increased the yeast growth rate and the yields of 12-HDDA and 1,12-DDA, with the highest levels of approximately 60 and 38 µ g / L, respectively, obtained at 30 ◦ C and pH 5. The incubation temperature and medium pH strongly inﬂuenced the yeast growth and 1,12-DDA yield, with the highest 1,12-DDA formation at 30 ◦ C and pH 5–5.5. Hence, the S. cerevisiae BCM strain can potentially be used for producing value-added products from CCW.


Introduction
Thailand is the world's ninth largest producer of coconut, with the east and south coastal areas being used for the large-scale production of coconuts [1], which amounted to 856,920 tons in 2018 and is increasing annually. Coconut waste was generated from food industry, and it was reported as a pollutant. Coconut milk extraction results in the production of the waste byproducts, which are comprised of solid fat and wastewater. Currently, 2000-3000 kg of coconut milk are lost every day into wastewater during the extraction process [2,3]. The coconut oil in the wastewater pond can be Table 1. Initial characteristics of the CCW used in this study. Data from [7]. Medium chain α,ω-dicarboxylic acids (α,ω-DCAs) are versatile chemical intermediates of different chain length, usually presented as HOOC-(R)n-COOH and a product of economic interest, because they are widely used as feedstocks for chemical products and intermediates, such as polyamides, nylons, lubricants, and perfumes. Normally, α,ω-DCAs are produced from petrochemical processes via chemical reaction under extremely unpleasant conditions of high pressure and temperature and using a strong acid [13,14]. α,ω-DCAs can be produced in two ways; chemical synthesis and fermentation. The chemical synthesis of α,ω-DCAs leads to environmental problems and pollution. Consequently, microbial production of α,ω-DCAs as a greener and sustainable processes is of interest to replace the chemical processes. Microbial production was developed via metabolic engineering and fermentation processes. Omega oxidation (ω-oxidation) is known as hydroxylation of the terminal alkyl carbon of a fatty acid to an alcohol and then further oxidation to a DCA ( Figure 1). ω-Oxidation of fatty acid can generally be divided to three steps. The first step: fatty acid is oxidized into ω-hydroxyfatty acid by cytochrome P450 monooxygenase and a NADPH-cytochrome P450 oxidoreductase complex in the endoplasmic reticulum (ER) membrane [15]. The second step: ω-hydroxyfatty acid is catalyzed to fatty acid aldehyde by fatty alcohol oxidase (FAO). Then, the aldehyde produced in the previous step is further oxidized to DCA by aldehyde dehydrogenase (FAHDH) [16]. While ω-hydroxylating cytochrome P450s can be responsible for oxidizing the initially ω-hydroxy products further, in the absence of other enzymes, dicarboxylic acids can be converted [15]. Fatty acids are enzymically catalyzed to hydroxyl fatty acids by various cytochrome P450 enzymes in vivo from microbes, fungi, plants, and animals. Moreover, in vitro fatty acid oxidation can be performed in situ by fungi, animals, and plants. Some microbes possess the ability to assimilate n-alkane and fatty acid as a carbon source. C. tropicalis ATCC 20336 is capable of oxidizing myristic and oleic acid (saturated and unsaturated fatty acids) to α,ω-DCAs via a ω-oxidation pathway [15]. C. tropicalis expressing CYP52A17 can catabolize methyl tetradecanoate to produce hydroxytetradecanoic [17]. Moreover, C. tropicalis W10-1, a DCA-producing strain, has ability of converting alkane to DCA13 [18]. An expressing CYP52A21 and CYP52A23 in E. coli can oxidize mid-chain fatty acids and longer-chain fatty acids, respectively [19]. While, E. coli expressing AlkBGTL can convert dodecanoic acid methyl ester to 12-hydroxydodecanoic acid methyl ester [20]. oxidizing the initially ω-hydroxy products further, in the absence of other enzymes, dicarboxylic acids can be converted [15]. Fatty acids are enzymically catalyzed to hydroxyl fatty acids by various cytochrome P450 enzymes in vivo from microbes, fungi, plants, and animals. Moreover, in vitro fatty acid oxidation can be performed in situ by fungi, animals, and plants. Some microbes possess the ability to assimilate n-alkane and fatty acid as a carbon source. C. tropicalis ATCC 20336 is capable of oxidizing myristic and oleic acid (saturated and unsaturated fatty acids) to α,ω-DCAs via a ωoxidation pathway [15]. C. tropicalis expressing CYP52A17 can catabolize methyl tetradecanoate to produce hydroxytetradecanoic [17]. Moreover, C. tropicalis W10-1, a DCA-producing strain, has ability of converting alkane to DCA13 [18]. An expressing CYP52A21 and CYP52A23 in E. coli can oxidize mid-chain fatty acids and longer-chain fatty acids, respectively [19]. While, E. coli expressing AlkBGTL can convert dodecanoic acid methyl ester to 12-hydroxydodecanoic acid methyl ester [20]. Saccharomyces cerevisiae is a generally-regarded-as-safe (GRAS) microorganism with genetic engineering advantages and is easy to transfer the technology into industry [14]. There have been several reports on S. cerevisiae as a recombinant microorganism producing DCAs [21]. Initially, the FoCYP539A7 and FoCYP655C2 cytochrome P450 genes from the fungi Fusarium oxysporum were expressed in S. cerevisiae to oxidize fatty acids (caprylic, capric, and lauric acids) into ω-hydroxy fatty acids [22]. Furthermore, decanedioic acid and DDA were produced by S. cerevisiae expressing CYP94C1 and cytochrome reductase ATR1 using renewable sugars and fatty acids as substrates [14]. Subsequently, S. cerevisiae (BCM), which has an extra copy of the BY4741 genetic background harboring the NADPH cytochrome P450 reductase (CPR) gene under its own promotor [23] and the CYP52A17 SS gene under galactose induction, was shown to effectively convert lauric acid into 1,12-DDA [7]. Notably, whole-cell biocatalysts have advantages over isolated enzymes, such as the absence of the high cost and energy for enzyme purification. A whole-cell system is a nonrequirement of cofactor; biotransformation by several enzymes could be continually conducted, which relates to the CYP reaction pathway, so the reaction can be carried out at a near-ambient temperature and ease the process [19]. Moreover, the enzyme environment of a whole cell can protect the protein structure from conformation changes [24]. Thus, this process provides a better alternative for industrial production, which can be applicable to wastewater.
In the study presented here, recombinant S. cerevisiae BCM were used as the whole cell in the biotransformation, as previously reported [7]. An efficient biotransformation would be established to produce 1,12-DDA via CCW, or CCW supplemented with 10 g/L yeast extract and 20 g/L peptone (YPCCW) as a medium by the recombinant BCM. Moreover, the effect of the medium pH and temperature of the biotransformation were also determined. Saccharomyces cerevisiae is a generally-regarded-as-safe (GRAS) microorganism with genetic engineering advantages and is easy to transfer the technology into industry [14]. There have been several reports on S. cerevisiae as a recombinant microorganism producing DCAs [21]. Initially, the FoCYP539A7 and FoCYP655C2 cytochrome P450 genes from the fungi Fusarium oxysporum were expressed in S. cerevisiae to oxidize fatty acids (caprylic, capric, and lauric acids) into ω-hydroxy fatty acids [22]. Furthermore, decanedioic acid and DDA were produced by S. cerevisiae expressing CYP94C1 and cytochrome reductase ATR1 using renewable sugars and fatty acids as substrates [14]. Subsequently, S. cerevisiae (BCM), which has an extra copy of the BY4741 genetic background harboring the NADPH cytochrome P450 reductase (CPR) gene under its own promotor [23] and the CYP52A17 SS gene under galactose induction, was shown to effectively convert lauric acid into 1,12-DDA [7]. Notably, whole-cell biocatalysts have advantages over isolated enzymes, such as the absence of the high cost and energy for enzyme purification. A whole-cell system is a nonrequirement of cofactor; biotransformation by several enzymes could be continually conducted, which relates to the CYP reaction pathway, so the reaction can be carried out at a near-ambient temperature and ease the process [19]. Moreover, the enzyme environment of a whole cell can protect the protein structure from conformation changes [24]. Thus, this process provides a better alternative for industrial production, which can be applicable to wastewater.

Materials and Methods
In the study presented here, recombinant S. cerevisiae BCM were used as the whole cell in the biotransformation, as previously reported [7]. An efficient biotransformation would be established to produce 1,12-DDA via CCW, or CCW supplemented with 10 g/L yeast extract and 20 g/L peptone (YPCCW) as a medium by the recombinant BCM. Moreover, the effect of the medium pH and temperature of the biotransformation were also determined.

Chemicals
The DCA (≥98%), 12-HDDA (97%), and 1,12-DDA (99%), which were used as the standards for the gas chromatography (GC) analysis, were purchased from Sigma-Aldrich, St. Louis, MO, USA. Boron trifluoride-methanol solution for forming ester derivative, galactose, and yeast synthetic drop-out medium supplements without histidine using cultivation of recombinant yeast were also obtained from Sigma-Aldrich, MO, USA. Tert-butyl methyl ether for product extraction was purchased from Merck KGaA, Darmstadt, Germany.

Microorganism and Cultivation Conditions
Saccharomyces cerevisiae BCM expressing CYP52A17 produced the highest 1,12-DDA from lauric acid, as in previous study [7] was used in this study. The formation of the S. cerevisiae BCM yeast strain has been described elsewhere [7]. The yeast strain was cultured in YPGE (Yeast extract Peptone Glucose Ethanol) medium [10 g/L yeast extract, 20 g/L peptone, 2% (v/v) ethanol, 5 g/L glucose] or complete supplement mixture (CSM) without histidine (-His) with appropriate amino acids for the selection of the auxotrophs. The CCW and YPCCW media (CCW adding 10 g/L yeast extract and 20 g/L peptone) were used for the biotransformation procedure. The biotransformation was conducted in 500 mL shake flasks and incubated in a shaking incubator at 30 • C, 200 rpm (shaking diameter is 25 mm). An amount of 5 mL of the culture was collected at several time points for product extraction and quantification by GC. The product concentration (µg/L) and conversion efficiency (% molar conversion of substrate to 12-HDDA or 1,12-DDA products) were calculated in accordance with the GC data. Yeast growth was monitored as the optical density at 600 nm (OD 600 ).

Role of the Recombinant CYP52A17 SS and CCW-Based Media
Saccharomyces cerevisiae BCM were precultured in CSM-His medium (YNB without amino acids 6.7 g/L, glucose 20 g/L, and drop-out supplements without histidine 1.92 g/L) and were then inoculated into YPCCW or CCW to an OD 600 of 0.4. The cultures were cultivated at 30 • C, 200 rpm (shaking diameter is 25 mm) until at an OD 600 of 1, where upon 20 g/L of galactose was added into the cultures to induce CYP52A17 SS expression. Then 5 mL of sample was taken every 12 h for analysis of yeast growth or every 24 h for product formation analysis over 120 h. The non-transformed parental S. cerevisiae BY(2R) strain was cultured in the same manner in parallel as a reference control.

Optimal Temperature
The BCM cells were precultured overnight in 25 mL CSM-His medium at 30 • C with agitation at 200 rpm. The overnight grown cells were then cultured in YPCCW (natural pH 5.5) to an OD 600 of 0.4 before addition of 20 g/L galactose and then cultured at 20, 25, 30, 35, 40, or 45 • C for 120 h with shaking at 200 rpm (shaking diameter is 25 mm). Samples were harvested after 120 h for determination of the product formation and yeast growth. The sample was acidified by addition of 6 M HCl and then tert-butyl methyl ether was added in the sample for extraction. The extracted sample was analyzed by GC. Yeast growth was determined as cell dry weight of which 1 mL of the sample was centrifuged (10,000× g, 5 min, room temperature) to collect the cell pellet and completely dried at 65 • C for 24 h. Then, the dried cell was cooled and weighed afterwards.

Optimal Initial pH of the Medium
The BCM cells were cultured in 25 mL CSM-His medium. The cells were precultured and inoculated and grown in YPCCW medium with galactose as above except the YPCCW was set to an initial pH of 3, 4, 5, 6, 7, or 8. The medium pH was initially adjusted to acidic pH by the addition Processes 2020, 8, 969 5 of 11 of 3 M acetic acid, whereas the alkaline pH was adjusted by adding 3 M NaOH. Then the cultures were incubated at 30 • C for 120 h with shaking at 200 rpm. Samples were harvested after 120 h for yeast growth and acidified to pH 1 by addition of 6 M HCl, extracted into tert-butyl methyl ether, and analyzed by GC for determination of the product formation. Cell growth was monitored by measuring the cell dry weight. A 1 mL of sample was centrifuged (10,000× g, 5 min, room temperature), the pellet was dried at 65 • C for 24 h, and then weighed. Calculation of the difference in weight was performed.

Product Extraction
For product analysis, 1 mL of 6 M HCl (QREC, Auckland, New Zealand) and 5 mL of tert-butyl methyl ether (Merck KGaA, Darmstadt, Germany) was added to 5 mL of the culture sample, vortexed, and shaken at 30 • C for at least 1 h. The mixture was then left for 5-10 min to separate the hydrophilic and organic phases. The upper phase was dried under nitrogen gas, and the dried sample was then derivatized with 14% (w/v) boron trifluoride in methanol (Sigma-Aldrich, MO, USA) and extracted with 1 mL of hexane (Fisher Scientific, Seoul, Korea). The upper phase was analyzed by GC (Section 2.5).

Product Analysis
The concentration of each product was determined by GC (GC-2010A Shimazu, Kyoto, Japan) equipped with a flame ionization detector and DB-wax capillary column (30 m × 0.530 mm × 0.25 µM film thickness) (Agilent, Santa Clara, CA, USA). The column's temperature limit is 20-23 • C. Helium was used as the carrier gas at a flow rate of 1 mL/min. The temperature of column, injector, and detector was 45, 210, and 220 • C, respectively. The sample concentrations were determined by comparison of sample peak retention times with the standards.

Statistical Analysis
All experiments were performed in triplicate, and the data are presented as the mean ± one standard deviation (SD).

Cell Growth of S. cerevisiae BCM in CCW and YPCCW with and without Galactose Induction of CYP52A17 Expression
Conversion of lauric acid from CCW to added-value products is a fascinating commercial opportunity and also reduces the cost of the medium. The S. cerevisiae BCM and the control untransformed BY(2R) strains were grown in CCW or YPCCW. The recombinant BCM strain presented good growth in the YPCCW medium above that of the control BY(2R) strain, and this was dramatically increased by the induction of CYP52A17 SS expression by galactose (Figure 2), where the growth of the recombinant yeast gradually increased up to 60 h and then remained stable (stationary phase). Without galactose, the recombinant yeast initially grew slightly slower in the YPCCW medium but reached a much higher maximal growth and stationary phase at 36 and 42 h, respectively. On the other hand, this recombinant strain grew equally well in the CCW medium with or without galactose, but their growth was still lower than in either YPCCW media. In contrast, the BY(2R) grew poorly in the YPCCW and especially the CCW media.
Thus, the absence of yeast extract and peptone addition to the CCW resulted in a lower cell growth, since they are nitrogen sources and also contain necessary supplements, such as vitamins and amino acids, required for optimal yeast growth [25]. The recombinant yeast could grow in the CCW without any required dilution even though the wastewater (coconut washing line) contained high COD, BOD, and FOG values that exceeded the industrial effluent standards for industrial plants and industrial estates in Thailand [9]. Moreover, the pH of the CCW was 5.5, which is the optimal pH for S. cerevisiae growth. Indeed, maintaining the S. cerevisiae growth medium at pH 5.5 was reported to give a high cell concentration and product formation [17], while adjusting the medium pH to 5-5.5 in the methyl laurate fermentation by the yeast Wickerhamiella sorbophila UHP4 promoted a high cell growth [26]. It is likely that, in this study, the recombinant yeast consumed substrates, such as sugars and fatty acids, from the CCW as alternative carbon sources for its growth. Dodecane and methyl laurate were shown to be able to be assimilated by Candida tropicalis for growth, because C. tropicalis expresses the cytochrome P450 CYP52 gene [27]. The recombinant S. cerevisiae BCM used in this study not only has the galactose-inducible CYP52A17 SS cytochrome P450 gene but also a supplementary copy of the CPR gene under its own promoter as described in previous study [7]. The CYP52A17 gene in combination with a redox partner, such as CPR, can oxidize fatty acids to α,ω-DCAs [15]. Therefore, the recombinant yeast had the ability to assimilate fatty acids in the CCW for growth and DCA production.

Production of DDA and HDDA from YPCCW (with Galactose) Using S. cerevisiae BCM
The S. cerevisiae BCM strain is known to be able to produce 12-HDDA and 1,12-DDA from lauric acid [7]. To determine the DDA production in CCW or YPCCW medium, the recombinant S. cerevisiae BCM was cultured in the CCW or YPCCW media at 30 °C and natural pH (pH 5.5). Galactose was added to the cultures for inducing the expression of CYP52A17 and starting the whole-cell biotransformation. In both the CCW and YPCCW media containing the initial lauric of 20.3 mg/L, DDA and HDDA were both formed, but with different kinetics and yields. In YPCCW, 12-HDDA was detected from 24 h and increased to a maximum level of 60 µg/L (10.56% conversion) in YPCCW 96 h, before falling at 120 h. Its oxidation to DDA was mainly evident as the sharp rise in DDA levels between 48 and 72 h (30 µg/L) with 6.13% conversion and then rose slowly to a maximum level of ca. 38 µg/L at 120 h. In CCW, HDDA was not detected until 72 h and increased steadily to a maximum of 41 µg/L at 120 h (5.37% conversion). Its oxidation to DDA was firstly detected at 96 h and remained at a level of around 20 µg/L up to 120 h (3.28% conversion) (Figure 3). However, no production of either 12-HDDA or 1,12-DDA from the CCW or YPCCW was detected in the control BY(2R) cultivations (data not shown). Moreover, the value of COD and BOD in CCW after the biotransformation separating the biomass were 7186 and 1500 mg/L, respectively. The result indicated that the BOD level after the biotransformation was 57% lower, while the COD value was slightly decrease from the initial level. On the other hand, the biotransformation with biomass led to It is likely that, in this study, the recombinant yeast consumed substrates, such as sugars and fatty acids, from the CCW as alternative carbon sources for its growth. Dodecane and methyl laurate were shown to be able to be assimilated by Candida tropicalis for growth, because C. tropicalis expresses the cytochrome P450 CYP52 gene [27]. The recombinant S. cerevisiae BCM used in this study not only has the galactose-inducible CYP52A17 SS cytochrome P450 gene but also a supplementary copy of the CPR gene under its own promoter as described in previous study [7]. The CYP52A17 gene in combination with a redox partner, such as CPR, can oxidize fatty acids to α,ω-DCAs [15]. Therefore, the recombinant yeast had the ability to assimilate fatty acids in the CCW for growth and DCA production.

Production of DDA and HDDA from YPCCW (with Galactose) Using S. cerevisiae BCM
The S. cerevisiae BCM strain is known to be able to produce 12-HDDA and 1,12-DDA from lauric acid [7]. To determine the DDA production in CCW or YPCCW medium, the recombinant S. cerevisiae BCM was cultured in the CCW or YPCCW media at 30 • C and natural pH (pH 5.5). Galactose was added to the cultures for inducing the expression of CYP52A17 and starting the whole-cell biotransformation. In both the CCW and YPCCW media containing the initial lauric of 20.3 mg/L, DDA and HDDA were both formed, but with different kinetics and yields. In YPCCW, 12-HDDA was detected from 24 h and increased to a maximum level of 60 µg/L (10.56% conversion) in YPCCW 96 h, before falling at 120 h. Its oxidation to DDA was mainly evident as the sharp rise in DDA levels between 48 and 72 h (30 µg/L) with 6.13% conversion and then rose slowly to a maximum level of ca. 38 µg/L at 120 h. In CCW, HDDA was not detected until 72 h and increased steadily to a maximum of 41 µg/L at 120 h (5.37% conversion). Its oxidation to DDA was firstly detected at 96 h and remained at a level of around 20 µg/L up to 120 h (3.28% conversion) (Figure 3). However, no production of either 12-HDDA or 1,12-DDA from the CCW or YPCCW was detected in the control BY(2R) cultivations (data not shown). Moreover, the value of COD and BOD in CCW after the biotransformation separating the biomass were 7186 and 1500 mg/L, respectively. The result indicated that the BOD level after the biotransformation was 57% lower, while the COD value was slightly decrease from the initial level. On the other hand, the biotransformation with biomass led to the higher COD and BOD level (48,706 and 13,470 mg/L), because the yeast cell was produced during the process, and yeast biomass was measured as BOD in the sample [28].
Processes 2020, 8, x FOR PEER REVIEW 7 of 11 the higher COD and BOD level (48,706 and 13,470 mg/L), because the yeast cell was produced during the process, and yeast biomass was measured as BOD in the sample [28]. The yeast cell density (as OD600) in the YPCCW medium was approximately two-fold greater than in the CCW, accounting for the approximately two-fold higher levels of product formation. Thus, the recombinant BCM yeast is able to oxidize fatty acids to DCAs via ω-oxidation, and the increased cell growth would contribute to the enhanced cytochrome P450 enzyme level and, hence, the greater product formation. The initial step of biotransformation is oxidation of fatty acids, which is carried out by a hydroxylase complex, cytochrome P450 monooxygenase with NADPH-CYP oxidoreductase, to oxidize the fatty acid into the ω-hydroxyfatty acid and the corresponding DCA in the ER [15] (Figure 1). The endogenous fatty acid synthetic pathway of S. cerevisiae can combine with the recombinant cytochrome P450 to generate the main products of HDDA and DDA in recombinant S. cerevisiae [14].
It is remarkable that the biotransformation of DCAs has recently been successful. The engineered C. tropicalis, with 16 genes eliminated, such as the native CYP52 enzymes, alcohol oxidases, and alcohol dehydrogenases, was not capable to produce ω-hydroxy tetradecanoic acid from tetradecanoic acid methyl ester. Whereas the strain carrying the P450s CYP52A17 obtained 174 g/L of 14-hydroxytetradecanoic acid at 148 h of bioconversion [17]. The elimination of 16 genes would lead to the lower efficiency of conversion of dodecanoic acid. Therefore, it is quite difficult to apply these modifications for DDA production in S. cerevisiae. However, Candida strains were identified as an opportunistic pathogen in humans that make it hard to generate to the industry [29]. Hence, it is interesting to use a GRAS strain such as the recombinant S. cerevisiae strain used in this study. S. cerevisiae BCM was higher grown in YPCCW and produced more HDDA and DDA than in CCW, so YPCCW was selected to the further study.

Effect of Temperature on HDDA and DDA Production
The effect of temperature on the DDA formation (bioconversion) was evaluated by culturing the recombinant yeast in YPCCW (pH natural = 5.5) at various temperatures (20,25,30,35,40, and 45 °C) using the initial inoculum prepared at 30 °C. The temperature had a similar effect on the growth of the recombinant yeast as on HDDA and DDA production ( Figure 4). The optimum temperature for growth was 30 °C, in terms of the highest biomass, when temperature was increased, the biomass declined four-fold at 30 °C when compared to at 45 °C. The highest concentration of HDDA and DDA at 25.6 and 30 µg/L, respectively, were also found at 30 °C, decreasing slightly at 35 °C and rapidly The yeast cell density (as OD 600 ) in the YPCCW medium was approximately two-fold greater than in the CCW, accounting for the approximately two-fold higher levels of product formation. Thus, the recombinant BCM yeast is able to oxidize fatty acids to DCAs via ω-oxidation, and the increased cell growth would contribute to the enhanced cytochrome P450 enzyme level and, hence, the greater product formation. The initial step of biotransformation is oxidation of fatty acids, which is carried out by a hydroxylase complex, cytochrome P450 monooxygenase with NADPH-CYP oxidoreductase, to oxidize the fatty acid into the ω-hydroxyfatty acid and the corresponding DCA in the ER [15] (Figure 1). The endogenous fatty acid synthetic pathway of S. cerevisiae can combine with the recombinant cytochrome P450 to generate the main products of HDDA and DDA in recombinant S. cerevisiae [14].
It is remarkable that the biotransformation of DCAs has recently been successful. The engineered C. tropicalis, with 16 genes eliminated, such as the native CYP52 enzymes, alcohol oxidases, and alcohol dehydrogenases, was not capable to produce ω-hydroxy tetradecanoic acid from tetradecanoic acid methyl ester. Whereas the strain carrying the P450s CYP52A17 obtained 174 g/L of 14-hydroxytetradecanoic acid at 148 h of bioconversion [17]. The elimination of 16 genes would lead to the lower efficiency of conversion of dodecanoic acid. Therefore, it is quite difficult to apply these modifications for DDA production in S. cerevisiae. However, Candida strains were identified as an opportunistic pathogen in humans that make it hard to generate to the industry [29]. Hence, it is interesting to use a GRAS strain such as the recombinant S. cerevisiae strain used in this study. S. cerevisiae BCM was higher grown in YPCCW and produced more HDDA and DDA than in CCW, so YPCCW was selected to the further study.

Effect of Temperature on HDDA and DDA Production
The effect of temperature on the DDA formation (bioconversion) was evaluated by culturing the recombinant yeast in YPCCW (pH natural = 5.5) at various temperatures (20,25,30,35,40, and 45 • C) using the initial inoculum prepared at 30 • C. The temperature had a similar effect on the growth of the recombinant yeast as on HDDA and DDA production ( Figure 4). The optimum temperature for growth was 30 • C, in terms of the highest biomass, when temperature was increased, the biomass declined four-fold at 30 • C when compared to at 45 • C. The highest concentration of HDDA and DDA at 25.6 and 30 µg/L, respectively, were also found at 30 • C, decreasing slightly at 35 • C and rapidly to a four-fold lower level at 40 • C with no products being detected at 45 • C. Growth and carboxylic production by yeast can be influenced by many factors. Temperature is one of the most important physical parameters. Most laboratory and industrial yeasts generally grow at a wide range of temperatures and are more available for cell reproduction at 25-30 • C [30]. Especially, S. cerevisiae can be grown at a higher temperature (35 • C). The normal growth and metabolic activity would be affected by a lower temperature, whereas the growth of yeast would be suppressed by a higher temperature and carry out its autolysis. Furthermore, microbial activity and fermentation processes are regulated by enzymes, which are sensitive to high temperatures. High temperatures would lead to inactive of enzymes and the denaturation of its tertiary structure. Therefore, temperature is a key factor in biotransformation, which must be carefully regulated through the process [31]. to a four-fold lower level at 40 °C with no products being detected at 45 °C. Growth and carboxylic production by yeast can be influenced by many factors. Temperature is one of the most important physical parameters. Most laboratory and industrial yeasts generally grow at a wide range of temperatures and are more available for cell reproduction at 25-30 °C [30]. Especially, S. cerevisiae can be grown at a higher temperature (35 °C). The normal growth and metabolic activity would be affected by a lower temperature, whereas the growth of yeast would be suppressed by a higher temperature and carry out its autolysis. Furthermore, microbial activity and fermentation processes are regulated by enzymes, which are sensitive to high temperatures. High temperatures would lead to inactive of enzymes and the denaturation of its tertiary structure. Therefore, temperature is a key factor in biotransformation, which must be carefully regulated through the process [31].

Effect of pH on DDA Production
In addition to the microorganism strain and substrate, the cultivation condition also has an important effect on the DDA production rate and yield. To evaluate the influence of the initial medium pH on DDA production, the initial pH of the YPCCW medium was adjusted to various levels (pH 3, 4, 5, 6, 7, or 8). As seen in Figure 5a, the culture exhibited the highest growth (biomass of 14 g/L) at pH 5 and then gradually (almost linearly) decreased with increasing pH up to pH 8. However, the recombinant S. cerevisiae cells were very sensitive to acidic media with very low and essentially no growth at pH 4 and 3, respectively. From the tested pH values (integer values), the biotransformation was optimal at pH 5 (in terms of the highest DDA yield) reaching 32 µg/L for DDA at pH 5, as seen in Figure 5b. There was no HDDA and DDA at pH 3 and only a very small amount of HDDA at pH 4. The quantitative analysis of HDDA and DDA did not differ between pH 6 to 8 but were markedly lower than at pH 5.0. The influence of the media pH on the conversion of lauric acid to HDDA and DDA seen in this study shows a similar pH optimum to that reported for recombinant S. cerevisiae harboring CYP539A7, CYP655C2 [17], and Candida cloacae [32]. Moreover, C. cloacae cells can produce more DDA between pH 4 and 5, but at pH 3 very few products were detected [32]. However, in C. tropicalis, a higher pH (pH 8) culture medium in the production phase showed a low productivity [33]. The medium pH plays a key role in the DCA production process by microorganisms, where it enhances DCA secretion and maintains its solubility [34,35]. This biotransformation provides a potential alternative for industry that can be applied to factory wastewater. Wastewater is another renewable resource that can be used for biotransformation to produce added-value products. To enhance it, the biotransformation can be developed by increasing

Effect of pH on DDA Production
In addition to the microorganism strain and substrate, the cultivation condition also has an important effect on the DDA production rate and yield. To evaluate the influence of the initial medium pH on DDA production, the initial pH of the YPCCW medium was adjusted to various levels (pH 3, 4, 5, 6, 7, or 8). As seen in Figure 5a, the culture exhibited the highest growth (biomass of 14 g/L) at pH 5 and then gradually (almost linearly) decreased with increasing pH up to pH 8. However, the recombinant S. cerevisiae cells were very sensitive to acidic media with very low and essentially no growth at pH 4 and 3, respectively. From the tested pH values (integer values), the biotransformation was optimal at pH 5 (in terms of the highest DDA yield) reaching 32 µg/L for DDA at pH 5, as seen in Figure 5b. There was no HDDA and DDA at pH 3 and only a very small amount of HDDA at pH 4. The quantitative analysis of HDDA and DDA did not differ between pH 6 to 8 but were markedly lower than at pH 5.0. The influence of the media pH on the conversion of lauric acid to HDDA and DDA seen in this study shows a similar pH optimum to that reported for recombinant S. cerevisiae harboring CYP539A7, CYP655C2 [17], and Candida cloacae [32]. Moreover, C. cloacae cells can produce more DDA between pH 4 and 5, but at pH 3 very few products were detected [32]. However, in C. tropicalis, a higher pH (pH 8) culture medium in the production phase showed a low productivity [33]. The medium pH plays a key role in the DCA production process by microorganisms, where it enhances DCA secretion and maintains its solubility [34,35]. This biotransformation provides a potential alternative for industry that can be applied to factory wastewater. Wastewater is another renewable resource that can be used for biotransformation to produce added-value products. To enhance it, the biotransformation can be developed by increasing the high density of cell biomass in the growth phase, and the production can be improved by adjusting the appropriate parameters [36].
the high density of cell biomass in the growth phase, and the production can be improved by adjusting the appropriate parameters [36].

Conclusions
This is the first report on the whole-cell biotransformation of 1,12-DDA from CCW by S. cerevisiae BCM using CCW as the base medium. The obtained data indicated that S. cerevisiae BCM is a suitable strain for cultivation in CCW and especially in YPCCW (both with galactose for induction of CYP52A17 SS expression) for DDA production. The optimum temperature and pH on the biotransformation were found to be 30 °C and pH 5-5.5. That the recombinant S. cerevisiae was able to grow in the CCW-based media and also produce HDDA and DDA makes this strain potentially useful for a variety of biotechnological applications, such as producing value-added products from wastewater.

Conclusions
This is the first report on the whole-cell biotransformation of 1,12-DDA from CCW by S. cerevisiae BCM using CCW as the base medium. The obtained data indicated that S. cerevisiae BCM is a suitable strain for cultivation in CCW and especially in YPCCW (both with galactose for induction of CYP52A17 SS expression) for DDA production. The optimum temperature and pH on the biotransformation were found to be 30 • C and pH 5-5.5. That the recombinant S. cerevisiae was able to grow in the CCW-based media and also produce HDDA and DDA makes this strain potentially useful for a variety of biotechnological applications, such as producing value-added products from wastewater.