Characterization and Production of Rhamnolipid Biosurfactant in Recombinant Escherichia coli Using Autoinduction Medium and Palm Oil Mill Effluent

Suhandono, Sony; Kusuma, Subhan Hadi; Meitha, Karlia

doi:10.1590/1678-4324-2021200301

Abstract

Rhamnolipid is a potent biodegradable surfactant, which frequently used in pharmaceutical and environmental industries, such as enhanced oil recovery and bioremediation. This study aims to engineer Escherichia coli for the heterologous host production of rhamnolipid, to characterize the rhamnolipid product, and to optimize the production using autoinduction medium and POME (palm oil mill effluent). The construction of genes involved in rhamnolipid biosynthesis was designed in two plasmids, pPM RHLAB (mono-rhamnolipid production plasmid) and pPM RHLABC (di-rhamnolipid production plasmid). The characterization of rhamnolipid congeners and activity using high-resolution mass spectrometry (HRMS) and critical micelle concentration (CMC). In order to estimate rhamnolipid yield, an oil spreading test was performed. HRMS and CMC result show E. coli pPM RHLAB mainly produced mono-rhamnolipid (Rha-C_14:2) with 900 mg/L and 35.4 mN/m of CMC and surface tension value, whereas E. coli pPM RHLABC mainly produced di-rhamnolipid (Rha-Rha-C₁₀) with 300 mg/L and 34.3 mN/m of CMC and surface tension value, respectively. The optimum condition to produce rhamnolipid was at 20 h cultivation time, 37 ^oC, and pH 7. In this condition, the maximum rhamnolipid yield of 1245.68 mg/L using autoinduction medium and 318.42 mg/L using 20% (v/v) of POME. In conclusion, the characteristics of the rhamnolipid by recombinant E. coli is very promising to be used in industries as the most economical way of producing rhamnolipid.

Keywords:
rhamnolipid; Escherichia coli; biosurfactant; autoinduction medium; POME

HIGHLIGHTS

Recombinant E. coli can produce mono-rhamnolipid and di-rhamnolipid biosurfactants.

Rhamnolipid congeners were identified using HRMS.

Di-rhamnolipid has lower surface tension and CMC than mono-rhamnolipid.

Rhamnolipid production have been optimized to enhance rhamnolipid yield.

INTRODUCTION

Rhamnolipid is a glycolipid biosurfactant that is naturally produced by Pseudomonas aeruginosa [¹1 Tiso T, Zauter R, Tulke H, Leuchtle B, Li WJ, Behrens B, et al. Designer rhamnolipids by reduction of congener diversity: Production and characterization. Microb Cell Fact. 2017;16:1-14.]. Many rhamnolipid congeners have been identified as having one or two rhamnose residues and β-hydroxy fatty acid chain (C₈-C₁₆) to form mono-rhamnolipid and di-rhamnolipid congeners [²2 Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.]. As a biosurfactant, rhamnolipid has highest potential prospects, such as biodegradability and non-toxicity compared to synthetic surfactants, low levels of critical micelle concentration (CMC), high emulsion capacity and good solubility that could potentially be used in the pharmaceutical, agricultural industries, and enhanced oil recovery technology [³3 Zhou J, Xue R, Liu S, Xu N, Xin F, Zhang W. High di-rhamnolipid production using Pseudomonas aeruginosa KT1115, separation of mono / di-rhamnolipids, and evaluation of their properties. Front Bioeng Biotechnol. 2019;7:1-9.].

Rhamnolipid biosynthesis is linked to three genes, rhlA, rhlB, and rhlC. rhlA encodes the RhlA enzyme that catalyzes the synthesis of the fatty acid dimer of rhamnolipids and free (3-(3-hydroxyalkanoxyloxy) alkanoic acids (HAA). rhlB encodes rhamnosyltransferases I (RhlB), which catalyzes the transfer of activated L-rhamnose to HAA and generates mono-rhamnolipid. rhlC encodes rhamnosyltransferases II (RhlC), which catalyzes the transfer of activated L-rhamnose to mono-rhamnolipid and generates di-rhamnolipid (Figure 1) [⁴4 Sinumvayo JP, Ishimwe N. Agriculture and food applications of rhamnolipids and its production by Pseudomonas aeruginosa. J Chem Eng Process. Technol. 2015;6:2-9.,⁵5 Amani H, Müller MM, Syldatk C, Hausmann R. Production of microbial rhamnolipid by Pseudomonas aeruginosa MM1011 for ex situ enhanced oil recovery. Appl Biochem Biotechnol. 2013;170:1080-93.]. Rhamnolipid synthesized by P. aeruginosa are the most frequently studied of biosurfactant. However, P. aeruginosa is an opportunistic pathogenic bacterium, therefore limited to industrial-scale production [⁶6 Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.]. The pathogenicity of P. aeruginosa for rhamnolipid production can be overcome through genetic engineering in heterologous hosts, such as Escherichia coli.

Figure 1
Molecule structure of mono-rhamnolipid (a) and di-rhamnolipid (b).

In this study, we report the expression of rhamnolipid in recombinant E. coli BL21(DE3) and isolated novel rhamnolipid congeners. A previous study [⁶6 Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.

7 Cabrera-valladares N, Richardson A, Olvera C, Treviño LG, Déziel E, Lépine F, et al. Monorhamnolipids and 3-( 3-hydroxyalkanoyloxy) alkanoic acids (HAAs) production using Escherichia coli as a heterologous host. Appl Microbiol Biotechnol. 2006;73:187-94.-⁸8 Han L, Liu P, Peng Y, Lin J, Wang Q, Ma Y. Engineering the biosynthesis of novel rhamnolipids in Escherichia coli for enhanced oil recovery. J Appl Microbiol. 2014;117:139-50.] has succeeded in producing rhamnolipid in recombinant E. coli, but still low production yield (0.07 - 0.64 g/L) with high-cost material production that using IPTG for T7 promoter induction. So we modified media production by using lactose as an inducer (autoinduction medium) [⁹9 Studier FW. Stable cultures and auto-induction for inducible protein production in E. coli. Methods Mol Biol. 2014;1091:17-22.] and an agricultural-waste namely palm oil mill effluent (POME)-based medium, which is abundant waste and high environmental impact problems in the palm oil industry in Indonesia [¹⁰10 Nur MMA, Hadiyanto H. Enhancement of Chlorella vulgaris biomass cultivated in POME medium as biofuel feedstock under mixotrophic conditions. J Eng Technol Sci. 2015;47:487-97.]. POME has high glycerol and fatty acid contents [¹¹11 Fazli RR, Hertadi R. Production and characterization of rhamnolipids from bioconversion of palm oil mill effluent by the halophilic bacterium Pseudomonas stutzeri. Environ Prog Sustain Energy. 2018;38:1-6.], therefore, it may be used as a carbon source to convert low-value POME to high-value rhamnolipid.

This study aimed to characterize rhamnolipid expression in recombinant E. coli by determining rhamnolipid congeners and activity using high-resolution mass spectrometry (HRMS) and critical micelle concentration (CMC). We also optimize rhamnolipid production using the autoinduction medium and observe the addition of POME in recombinant E. coli.

MATERIAL AND METHODS

Bacterial strains, plasmids, and culture conditions

Escherichia coli TOP10 (NEB, USA) and E. coli BL21 (DE3) (NEB, USA) was used as the heterologous host strain for the plasmids. The plasmid was derived from pUC57 plasmid (Genescript, USA) and inserted rhlAB (pPM RHLAB) and rhlABC sequences (pPM RHLABC). The strains were maintained on LB (Luria Bertani) agar medium at 37 ^oC for 16 h. Experiment were carried out in 250 mL Erlenmeyer flask with 50 mL of production media with following media: autoinduction medium (tryptone, 12 g/L; yeast extract, 24 g/L; (NH₄)₂SO₄, 3.3 g/L; KH₂PO₄, 6.8 g/L; Na₂HPO₄, 7.1 g/L; glucose, 0.5 g/L; lactose, 2 g/L, MgSO₄, 0.15 g/L; trace elements, 0.03 g/L), M9 medium (M9 salt (Na₂HPO₄, KH₂PO₄, NaCl, NH₄Cl), 5.25 g/L; 1 M MgSO₄, 1 M CaCl₂), LB (Luria Bertani) medium (tryptone, 10 g/L; yeast extract, 5 g/L; NaCl, 10 g/L) and palm oil mill effluent/POME (Dermex Agro, Indonesia) mixed with M9 medium. The time and pH of the culture were optimized, and when appropriate, 0.5 mM isopropyl-β-D-thiogalactoside (IPTG) and 1% (w/v) lactose were added to induce the rhlABC gene. The antibiotic concentration used was ampicillin (10⁵ ppm).

Plasmids construction design

The rhlAB gene was designed by positioning rhlA (Acc. No: AAG06867), and rhlB (Acc. No: AAG06866) genes adjacent to each other with a 65 bp nucleotide separating them. The tandem sequence was then ordered to be synthesized at Genescript, USA. The synthesized rhlAB gene was inserted into pUC57 as the backbone plasmid, containing the T7lac promoter, RBS, CDS (rhlAB), rrnb T1 terminator, and T7 terminator, hereinafter referred to as pPM RHLAB. This plasmid constructed (pPM RHLAB) was a donation by the iGEM_ITB2015 team. The rhlC gene sequence (Acc. No: AAG04519) was ordered to be synthesized at Macrogen Inc., South Korea, and codon optimization was performed using the GeneArt^® GeneOptimizer tool for Escherichia coli. The synthetic rhlC gene was equipped with the T7lac promoter, RBS, CDS (rhlC), and T7 terminator. This cassette was then sub-cloned into pPM RHLAB to create pPM RHLABC, which was facilitated by Sph1 and HindIII digestion.

PCR confirmation was carried out using GoTaq^® Green Master Mix (Promega, USA). PCR confirmation was conducted with the specific primer of the rhlAB sequence as follows: forward primer (5’-GTTTCTTCGAATTCGCGGCCGCTTCTAG-3’) and reverse primer (5’-GTTTCTTCCTGCAGCGGCCGCTACTAGTA-3’) in 30 cycles of denaturation at 95 ^oC, annealing at 54 ^oC, and extension at 72 ^oC, while the specific primer of the rhlC sequence as follows: forward primer (5’-CTGCATGCGAAGCCAATACGAC-3’) and reverse primer (5’-TACGCCAAGCTTTATAAACGCAG-3’) in 30 cycles of denaturation at 95 ^oC, annealing at 57 ^oC, and extension at 72 ^oC. The success of this cloning was confirmed by sequencing at Macrogen Inc., South Korea, and analyzed using SnapGeneTM v.4.3.10. The pPM RHLAB and pPM RHLABC plasmids were transformed into competent of E. coli TOP10 for cloning purposes and competent of E. coli strain BL21(DE3) for expression.

Expression of rhamnolipid biosurfactant in recombinant E. coli

A positive E. coli colony containing pPM RHLAB and pPM RHLABC was inoculated into a liquid culture of 5 mL LB medium. Five percent (v/v) of the overnight culture was inoculated into 50 mL LB at 37 ^oC, with a shake at 250 rpm for 2 - 4 h. After OD₆₀₀ reached to obtain OD₆₀₀ of 0.5 - 0.7, five mL of this culture was separated as non-induced culture, and then the other 45 mL was induced by 0.5 mM IPTG (final concentration). After 20 h, the culture was taken to extract rhamnolipid and characterized.

Extraction of rhamnolipid from recombinant E. coli

Extraction of mono-rhamnolipid (pPM RHLAB) and di-rhamnolipid (pPM RHLABC) by liquid extraction [¹²12 Wang Q, Fang X, Bai B, Liang X, Shuler PJ, Iii WAG, et al. Engineering bacteria for production of rhamnolipid as an agent for enhanced oil recovery. Biotechnol Bioeng. 2007;98:842-53.]. The culture was centrifuged for 15 min at 7000 g and 4 ^oC. The supernatant was mixed with chloroform:ethanol (2:1), stirred for 5 min for equilibrium, and repeated for extraction twice. The organic phase was collected and evaporated the solvent by oven-drying and leaving a brown paste (rhamnolipid).

Rhamnolipid congener diversity by HRMS and CMC determination

Rhamnolipid extraction from pPM RHLAB and pPM RHLABC strains was characterized by high-resolution mass spectrometry (HRMS), and the rhamnolipid activity was determined by critical micelle concentration (CMC) as well as surface tension. To determine of rhamnolipid congener diversity from E. coli BL21(DE3) pPM RHLAB and pPM RHLABC, each 10 mg of rhamnolipid were dissolved into deuterated chloroform, and 100 µL solution was injected for TOF-MS analysis in negative ion mode (LCT Premier XE Micromass, USA). The scanning mass spectrum ranged from 300 m/z to 800 m/z. HRMS peaks were identified and analyzed based on [M-H]^- m/z [²2 Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.] to determine rhamnolipid congeners from E. coli pPM RHLAB and E. coli pPM RHLABC.

Each of the surfactant (sodium dodecyl sulfate/SDS as the positive control, mono-rhamnolipid, and di-rhamnolipid) at 50 mg/L - 2500 mg/L concentration was made to determine CMC value. The surface tension of each surfactant was measured until no reduction in surface tension for an added higher concentration of surfactants. The determination of CMC was measured using a Du-Nouy ring tensiometer (Surface Tensiomat® FISHER Model 21, USA). All of the experiments were conducted in triplicate, and the mean values ± standard deviation were reported. The best rhamnolipid activity from recombinant strains (pPM RHLAB or pPM RHLABC) was selected and optimized the production by using autoinduction and POME media.

Determination of the rhamnolipid production curve in recombinant E. coli

The standard growth curve was first created as a reference to estimate the number of living colonies (colony form unit/cfu) on each OD value to calculate the cell number of recombinant E. coli. In this study, the method was used for creating the standard curve throughout OD 0.1 - 0.9 and maintained on LB medium agar containing ampicillin antibiotics (10⁵ ppm) at 37 ºC for 16 hours. Colonies growing on each Petri dish were counted, and a regression curve was made.

The rhamnolipid production curve was carried out by sampling every 3 h of cultivation culture. A 5% (v/v) pre-culture of recombinant E. coli was inoculated into 50 mL of the autoinduction medium and grown at 37 ^oC at 250 rpm. The oil spreading test (OST) was performed to estimate the highest production time and rhamnolipid yield. The experiment was performed in triplicate, and the mean values ± standard deviation were reported.

Analysis of rhamnolipid concentration using oil spreading test (OST)

The oil spreading test (OST) technique was used to analyze the surfactant activity qualitatively. The OST technique was carried out by adding 30 mL of water to a Petri dish (Area: 78.5 cm²) and adding 100 µL of crude oil (from PT Pertamina, Mangunjaya refinery, South Sumatera). A supernatant containing the surfactant was dripped as much as 100 µL at the midpoint of a Petri dish; as a result, an oil-spreading zone (OSZ) appeared [¹³13 Cheng T, Liang J, He J, Hu X, Ge Z, Liu J. A novel rhamnolipid - producing Pseudomonas aeruginosa ZS1 isolate derived from petroleum sludge suitable for bioremediation. AMB Express. 2017:120.]. The area of the OSZ was performed using the NIH ImageJ software [¹⁴14 Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012;9:671-5.] with the following formula:

A r e a_{O S Z} = A r e a_{D I S H} (P i x e l_{O S Z} / P i x e l_{D I S H})

(1)

Area_OSZ and Area_DISH are the areas of the circle of OSZ and the Petri dish (78.5 cm²), while Pixel_OSZ and Pixel_DISH are pixel measurements from the NIH ImageJ software, respectively. Determination of rhamnolipid concentration from recombinant E. coli fermentation culture was carried out using an oil spreading test technique on rhamnolipid standards. The rhamnolipid standard (AGAE Tech, USA) was used from 100 mg/L to 700 mg/L. The Area_OSZ was obtained from the OST at each standard rhamnolipid standard concentration and formed a linear regression curve. The rhamnolipid standard curve was used to estimate the rhamnolipid concentration from recombinant E. coli cultures [¹⁵15 Zhao F, Liang X, Ban Y, Han S, Zhang J, Zhang Y, et al. Comparison of methods to quantify rhamnolipid and optimization of oil spreading method. Tenside Surfactants Deterg. 2016;53:243-8.].

Optimization of pH and temperature of rhamnolipid production in autoinduction medium and POME

Optimization of rhamnolipid production from recombinant E. coli was carried out at variations of pH 4, 7 and 9 and temperatures of 30 ^oC, 37 ^oC and 40 ^oC. Cultures were grown for optimal cultivation time, and subsequently, the supernatant was obtained and measured the concentration of rhamnolipid to show of Area_OSZ, and its value was interpolated by rhamnolipid standard regression. The experiment was performed in triplicate.

The optimal concentration of the POME-based medium was determined by the added variation of POME concentration (10%, 15%, 20%, and 25% (v/v)) in M9 medium. Induction was carried out with 1% (w/v) lactose when the culture OD reached 0.6. Cultures were grown at the optimal cultivation time, temperature, and pH of rhamnolipid production. The supernatant was obtained and measured the concentration of rhamnolipid to show of Area_OSZ, and the value was interpolated by rhamnolipid standard regression. The experiment was performed in triplicate.

RESULTS

Plasmid construction design of rhamnolipid expression

The size of the rhlAB part was 2551 bp, and the rhlC part was 1129 bp (Figure 2). This size was also confirmed by PCR confirmation with the specific primers of rhlAB and rhlC parts (Figure 3).

Figure 2
pPM RHLAB (a) and pPM RHLABC (b) construction map.

Figure 3
PCR confirmation of pPM RHLAB (1) and pPM RHLABC (2) using specific primers for rhlA and rhlB genes and PCR confirmation of RHLABC (3 and 4) with the specific primer rhlC gene. (-) is the negative control.

Figure 2 shows that both parts have the same promoter and terminator, namely T7lac promoter, and T7 terminator. However, pPM RHLAB has an additional terminator, which is the rrnb T1 terminator. The rhlC gene was driven by a separate promoter from the rhlAB gene. PCR confirmation of pPM RHLAB and pPM RHLABC (Figure 3) confirmed that both recombinant strains consisted of desired genes (rhlAB and rhlC). Therefore, it can be concluded that both plasmids were successfully transformed into E. coli BL21(DE3) and continued for rhamnolipid expression and characterization.

Characterization of rhamnolipid expression by HRMS and determination of CMC

Characterization of rhamnolipid expression by HRMS

HRMS analysis aims to confirm rhamnolipid congeners expressed by E. coli pPM RHLAB and pPM RHLABC. Peaks of HRMS (Figure 4) from both rhamnolipid products were analyzed and compared to the rhamnolipid diversity database, which has been reported by Abdel-mawgoud [²2 Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.]. Table 1 and Table 2 show rhamnolipid congeners from rhamnolipid of E. coli pPM RHLAB and pPM RHLABC.

Figure 4
HRMS spectra of the rhamnolipids produced by E. coli pPM RHLAB (a) and E. coli pPM RHLABC. The X- and Y-axes indicate m/z (mass-to-charge ratio) and intensity/relative abundance (%), respectively.

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Table 1
Relative abundance of main rhamnolipid congeners produced by recombinant E. coli pPM RHLAB by HRMS.

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Table 2
Relative abundance of main rhamnolipid congeners produced by recombinant E. coli pPM RHLABC by HRMS.

High-resolution mass spectrometry (HRMS) results show that rhamnolipid from recombinant E. coli pPM RHLAB consist of five rhamnolipid congeners and rhamnolipid from E. coli pPM RHLABC consists of 12 rhamnolipid congeners. Furthermore, E. coli pPM RHLAB produced mono-rhamnolipid congeners, namely Rha-C_14:2 with higher relative abundance (24%) and Rha-C₈ with lower relative abundance (11%). In comparison, the E. coli pPM RHLABC produced di-rhamno mono-lipid (Rha-Rha-C₁₀) with higher relative abundance (99.5%) and mono-rhamno di-lipid (Rha-C₁₀-C_13:1) with lower relative abundance (5%). Therefore, it can be concluded that E. coli pPM RHLAB only produces mono-rhamnolipid (by expression of rhlA, and rhlB genes) and E. coli pPM RHLABC can produce both mono-rhamnolipid and di-rhamnolipid (by expression of rhlA, rhlB, and rhlC genes).

In this stimulated high-resolution mass spectrometry, the ion of Rha-C_14:2 has the highest relative abundance and peak among the other of mono-rhamnolipid congeners, so Rha-C_14:2 was the base peak of rhamnolipid produced by E. coli pPM RHLAB. However, in the di-rhamnolipid congeners, Rha-Rha-C₁₀ has the highest relative abundance and peak among the other of rhamnolipid congeners (mono- or di- types), so Rha-Rha-C₁₀ was the base peak of rhamnolipid produced by E. coli pPM RHLABC. In the interpreting of HRMS result, for instance, Rha-Rha-C₈ has a relative abundance of 63%, meaning the mass spectrum contains 63% as many ions of m/z Rha-Rha-C₁₀ (the base peaks). Note that this does not mean 99.5% of the ions produced have m/z = Rha-Rha-C₁₀ and another 63% have m/z = Rha-Rha-C_8, because it was not possible to produce more than 100%.

Tables 1 and 2 show that recombinant E. coli pPM RHLABC produces novel rhamnolipid congeners that different congeners have been reported, but it was not from E. coli pPM RHLAB [²2 Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.]. The novel rhamnolipid congeners from E. coli pPM RHLABC consist of mono-rhamno mono-lipid (Rha-C_10:2), mono-rhamno di-lipid (Rha-C₁₀-C_13:2 and Rha-C₁₀-C_13:1), and di-rhamno di-lipid (Rha-Rha-C₁₀-C_11:2, Rha-Rha-C₁₂-C_11:2, Rha-Rha-C₁₂-C_13:2, Rha-Rha-C_13:2-C₁₂ and Rha-Rha-C₁₄-C₁₅).

Determination of rhamnolipid CMC from recombinant E. coli

The best biosurfactant activity has a lower surface tension (ST) value and critical micelle concentration (CMC). The critical micelle concentration (CMC) is the minimum concentration required to form micelles and is defined by the surface tension of various surfactant concentrations. Rhamnolipid from E. coli pPM RHLAB and pPM RHLABC showed different values of CMC (Figure 5).

Figure 5
Critical micelle concentration (CMC) of SDS (sodium dodecyl sulfate), mono-rhamnolipid, and di-rhamnolipid. cmc^S, cmc^M, and cmc^D are the values of CMC for SDS, mono-rhamnolipid, and di-rhamnolipid, respectively.

Figure 5 shows that di-rhamnolipid has the lowest CMC value (300 mg/L) with a surface tension value of 34.3 mN/m than mono-rhamnolipid (900 mg/L CMC value and 35.4 mN/m surface tension value). Whereas, sodium dodecyl sulfate had the highest CMC value (2000 mg/L) with a surface tension value of 34.2 mN/m than both biosurfactants. Because di-rhamnolipid from E. coli pPM RHLABC has lower surface tension and CMC, E. coli pPM RHLABC was continued to optimize production by using autoinduction medium and POME-based medium.

**Optimization of rhamnolipid production from recombinant E. coli in autoinduction medium**

The culture duration and physiological conditions for biosurfactant production were essential to optimize for the determination of optimal conditions. Figure 6a shows the rhamnolipid production curve in recombinant E. coli using the autoinduction medium. Optimal production of rhamnolipid can be considered on the production curve at 20 h culture time with Area_OSZ of 48.3 cm². The optimal culture time of 20 h lies in the stationary phase of recombinant E. coli.

Figure 6
Rhamnolipid production from recombinant E. coli in autoinduction medium. TPC analysis is the total plate count is counted in cfu/mL, and area OSZ is the area from the oil spreading test.

Based on Figure 6a, rhamnolipid was early expressed at 9 h of cultivation time with an Area_OSZ of 3.8 cm², but still with a deficient concentration. Production of rhamnolipid begins to be fully expressed at the end of the log phase, and the optimal time was 20 h. However, at the end of the stationary phase (exceed the optimal time), rhamnolipid expression decreased due to enter the cell death phase and the accumulation of toxic substances. On the other sides, the precursor of RhlB (L-rhamnose) may be declined after the optimal time and mainly produced HAA (the expression of rhlA), which lower of surface tension and Area_OSZ than rhamnolipid.

We determined rhamnolipid concentration in culture supernatant from recombinant E. coli culture using oil spreading test and obtained the rhamnolipid standard curve equation; y = 0.073x - 8.8094; R² = 0.99, which x = rhamnolipid concentration and y = Area_OSZ (Figure 6b). Figure 6b shows that there was a positive correlation between Area_OSZ and rhamnolipid concentration; therefore, this method can be applied to estimated rhamnolipid concentrations more accurately than using the staining method, such as anthrone or orcinol reagent, with a spectrophotometer due to overestimating result of rhamnolipid yield measured [¹⁵15 Zhao F, Liang X, Ban Y, Han S, Zhang J, Zhang Y, et al. Comparison of methods to quantify rhamnolipid and optimization of oil spreading method. Tenside Surfactants Deterg. 2016;53:243-8.].

Rhamnolipid production in the wild type, e.g., Pseudomonas aeruginosa, it was dependent on pH and temperature. Hence, we considered observing pH and temperature effects of rhamnolipid production in recombinant E. coli. Based on Figure 7 shows that the optimal rhamnolipid production lies at 37 ^oC with rhamnolipid concentrations reaching 1245 ± 142.49 mg/L compared to temperatures of 30 ^oC (516 ± 66.12 mg/L), and 40 ^oC (130 ± 7.50 mg/L). The optimum pH was found at pH 7, with a similar quantity produced at 37 ^oC. However, changing the pH value affects of rhamnolipid yield with at pH 5 and pH 9 was 499 ± 113.20 mg/L, and 389 ± 68.10 mg/L, respectively.

Figure 7.Optimization
of rhamnolipid production from recombinant E. coli at variations of temperatures and pH. The values are mean ± S.D of triplicate analyses

Optimization of rhamnolipid production in palm oil mill effluent (POME) medium

In this study, we optimized the POME concentration as an economical medium in recombinant E. coli to produce rhamnolipid. POME was mixed with M9 medium as a source of pH buffer and nitrogen sources. The culture in this medium was induced by 1% (w/v) lactose, which optimal lactose concentration to induce T7lac promoter in recombinant E. coli [¹⁷17 Lim H-K, Lee S, Chung S, Jung K, Seo J. Induction of the T7 promoter using lactose for production of recombinant plasminogen kringle 1-3 in Escherichia coli. J Microbiol Biotechnol. 2004;14:225-30.]. Based on Figure 8, the highest concentration of POME medium was obtained at a concentration of 20% (v/v) (318.42 ± 35.12 mg/L), while the lowest concentration was obtained at a concentration of 25% (v/v) (180.40 ± 32.31 mg/L). In comparison, at a concentration of 10% (v/v) and 15% (v/v) was 211.58 ± 24.5 mg/L and 305.59 ± 11.29 mg/L, respectively. However, we found that the optimal range of POME concentration was 15% - 20% (v/v).

Figure 8
Optimization of rhamnolipid production from recombinant E. coli in POME-based medium. The values are mean ± S.D of triplicate analyses.

DISCUSSION

Rhamnolipid is a biodegradable surfactant, which is extensively used in industrial and enviromental application such as the pharmaceutical, food industries, and enhances oil recovery [¹⁸18 Perfumo A, Rudden M, Smyth TJP, Marchant R, Stevenson PS, Parry NJ, et al. Rhamnolipids are conserved biosurfactants molecules : implications for their biotechnological potential. Appl Microbiol. 2013.]. In this study, we transformed the rhamnolipid gene by synthetic approach from Pseudomonas aeruginosa, which is pathogenic bacterium, into a GRAS (generally recognized as safe) strain, such as Escherichia coli. The rhlABC gene was driven by the T7lac promoter to increase synthesis of rhamnolipid. However, the rhlC gene was driven by a separate T7lac promoter from the rhlAB gene. They consist of two separate operons that mimic the two natural operons in Pseudomonas aeruginosa [¹⁶16 Rahim R, Ochsner UA, Olvera C, Graninger M, Messner P, Lam JS, et al. Cloning and functional characterization of the Pseudomonas aeruginosa rhlC gene that encodes rhamnosyltransferase 2, an enzyme responsible for di-rhamnolipid biosynthesis. Mol Microbiol. 2001;40:708-18.]. In P. aeruginosa, the rhlA and rhlB genes are arranged in an operon adjacent to rhlRI, a regulator that plays a role in quorum sensing whereas the rhlC gene was located at a distance far away from the rhlAB operon (PA1131 locus), which has no promoter part in the upstream section [¹⁹19 Nicolò MS, Cambria MG, Impallomeni G, Rizzo MG, Pellicorio C, Ballistreri A, et al. Carbon source effects on the mono / dirhamnolipid ratio produced by Pseudomonas aeruginosa L05, a new human respiratory isolate. N Biotechnol. 2017;39:36-41.].

To investigate the composition of rhamnolipid congeners by E. coli pPM RHLAB and pPM RHLABC whether both plasmids encode mono-rhamnolipid or di-rhamnolipid, each of the rhamnolipids extractions were subjected to HRMS analysis. We found that E. coli pPM RHLAB only encodes mono-rhamnolipid, and E. coli pPM RHLABC may encode mono-rhamnolipid and di-rhamnolipid. However, rhamnolipid congeners by P. aeruginosa mainly consist of Rha-C₁₀ and Rha-Rha-C₁₀-C₁₀ [¹³13 Cheng T, Liang J, He J, Hu X, Ge Z, Liu J. A novel rhamnolipid - producing Pseudomonas aeruginosa ZS1 isolate derived from petroleum sludge suitable for bioremediation. AMB Express. 2017:120.]_, but our recombinant strain mainly produces Rha-C_12:2 (mono-rhamnolipid) and Rha-Rha-C₁₀ (di-rhamnolipid). The difference in rhamnolipid congeners may be caused by various factors such as strains, carbon sources, and culture conditions [²⁰20 Rikalovic MG, Avramovic NS, Karadzic IM. Structure - Function relationships of rhamnolipid and exopolysacharide biosurfactants of Pseudomonas aeruginosa as therapeutic targets in cystic fibrosis lung infections. Prog. Underst. Cyst. Fibros.,2017;127-58.]. Additionally, it influences rhamnolipid activity, which di-rhamnolipid facilitates a decrease in surface tension values [²¹21 Li Z, Zhang Y, Lin J, Wang W, Li S. High-yield di-rhamnolipid production by Pseudomonas aeruginosa YM4 and its potential application in MEOR. Molecules. 2019;24:1433.]. Furthermore, in the analysis of critical micelle concentration (CMC), we found that di-rhamnolipid have lower CMC values and surface tension value compared to mono-rhamnolipid and SDS (sodium dodecyl sulfate) as synthetic/chemical surfactants. Mono-rhamnolipid is less soluble and adsorbed to surfaces more strongly, requiring higher CMC for the solubilization of hydrocarbons than di-rhamnolipid [²²22 Bharali P, Konwar BK. Production and physico-chemical characterization of a biosurfactant produced by Pseudomonas aeruginosa OBP1 Isolated from petroleum sludge. Appl Biochem Biotechnol 2011;164:1444-60.]. Because di-rhamnolipid has lower CMC, di-rhamnolipid has more activities and efficiency than mono-rhamnolipid [¹⁹19 Nicolò MS, Cambria MG, Impallomeni G, Rizzo MG, Pellicorio C, Ballistreri A, et al. Carbon source effects on the mono / dirhamnolipid ratio produced by Pseudomonas aeruginosa L05, a new human respiratory isolate. N Biotechnol. 2017;39:36-41.,²³23 Dhasayan A, Kiran GS, Selvin J. Production and characterisation of glycolipid biosurfactant by Halomonas sp . MB-30 for potential application in enhanced oil recovery. Appl Biochem Biotechnol. 2014;174:2571-84.]. Further, we optimized di-rhamnolipid production from E. coli pPM RHLABC using autoinduction and POME media.

The rhamnolipid production in recombinant E. coli using autoinduction medium was inspired by the research of Studier [⁹9 Studier FW. Stable cultures and auto-induction for inducible protein production in E. coli. Methods Mol Biol. 2014;1091:17-22.], where the production of rhamnolipid itself was not induced by IPTG, but by lactose. This is because IPTG is expensive and not suitable for later to continue on an industrial application. Using the autoinduction medium allows more optimal production of rhamnolipid without knowing specific OD values in the induction process (as was carried out in expressions with the IPTG inducer). Growth of recombinant E. coli using autoinduction medium may use glucose as a primary carbon source until glucose depletes in the mid to late-log phase, and lactose will be used as a second carbon source while inducing T7lac promoter [⁹9 Studier FW. Stable cultures and auto-induction for inducible protein production in E. coli. Methods Mol Biol. 2014;1091:17-22.], so the expression of the rhlABC gene can occur. The glucose and lactose content in autoinduction medium may also increase rhamnolipid yield production. This is because glucose as a source in the formation of rhamnose in rhamnolipid biosynthesis [²⁴24 Abdel-mawgoud AM, Hausmann R, Le F, De E, Markus MM. Rhamnolipids : detection, analysis, biosynthesis, genetic regulation, and bioengineering of production. Biosurfactants. 2011;13-56.]. This autoinduction medium itself has been previously used in protein expression but has never been conducted in rhamnolipid expression from wild-type or recombinant strains. Previous research on rhamnolipid production from recombinant E. coli still uses LB medium and was induced with IPTG [⁶6 Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.,⁸8 Han L, Liu P, Peng Y, Lin J, Wang Q, Ma Y. Engineering the biosynthesis of novel rhamnolipids in Escherichia coli for enhanced oil recovery. J Appl Microbiol. 2014;117:139-50.,²⁵25 Wittgens A, Kovacic F, Müller MM, Gerlitzki M, Santiago-schübel B, Hofmann D, et al. Novel insights into biosynthesis and uptake of rhamnolipids and their precursors. Appl Microbiol Biotechnol 2017;101:2865-78.]. The use of autoinduction medium is a novelty for producing high yield rhamnolipid in recombinant E. coli.

In P. aeruginosa, the wild-type rhamnolipid production strain, the best rhamnolipid production was in the range of 25 - 37 ^oC, and the best pH was in the range of 6 - 6.8, whereas above 42 ^oC and pH 7 decreased rhamnolipid production [²⁶26 Maqsood MI, Jamal A. Factors affecting the rhamnolipid biosurfactant production. Pak J Biotechnol. 2011;8:1-5.]. Similarly, we found that rhamnolipid production in recombinant E. coli was optimum at 37 ^oC and pH 7 using autoinduction medium. P. aeruginosa and E. coli may live inside the human body therefore the human body temperature of 37 ^oC and pH 7 will be comfortable for both microorganisms. Interestingly, for 24 h of cultivation time, our rhamnolipid yield in recombinant E. coli, which harboring pPM RHLABC, by using autoinduction medium was higher (1245 mg/L) than from P. aeruginosa (206 mg/L) [⁷7 Cabrera-valladares N, Richardson A, Olvera C, Treviño LG, Déziel E, Lépine F, et al. Monorhamnolipids and 3-( 3-hydroxyalkanoyloxy) alkanoic acids (HAAs) production using Escherichia coli as a heterologous host. Appl Microbiol Biotechnol. 2006;73:187-94.], and other recombinant strains that have been reported, such as E. coli HB101 (pINC94-rhAB), E. coli BL21(DE3) (ETRABC-rhlABC), and E. coli BL21(DE3) (DJ208-rhlABC) were 70.5 mg/L, 120 mg/L, and 640 mg/L, respectively [⁶6 Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.

7 Cabrera-valladares N, Richardson A, Olvera C, Treviño LG, Déziel E, Lépine F, et al. Monorhamnolipids and 3-( 3-hydroxyalkanoyloxy) alkanoic acids (HAAs) production using Escherichia coli as a heterologous host. Appl Microbiol Biotechnol. 2006;73:187-94.-⁸8 Han L, Liu P, Peng Y, Lin J, Wang Q, Ma Y. Engineering the biosynthesis of novel rhamnolipids in Escherichia coli for enhanced oil recovery. J Appl Microbiol. 2014;117:139-50.]. As a result, it is very promising for further bioprocessing of our recombinant strain to enhance large-scale production.

To investigate the addition of POME in fermentation culture, variations of POME concentration were observed. We found that the optimal concentration was 20% (v/v) in POME addition. POME is an agricultural waste with high BOD and COD content, so the addition of POME exceeding 20% (v/v) may cause nonoptimal bacterial growth and decreased rhamnolipid production. Analysis of POME by GC-MS shows that it contains complex compounds, including glycerol, fatty acids, and other organic compounds with a glycerol content of 49% [¹¹11 Fazli RR, Hertadi R. Production and characterization of rhamnolipids from bioconversion of palm oil mill effluent by the halophilic bacterium Pseudomonas stutzeri. Environ Prog Sustain Energy. 2018;38:1-6.] therefore, it can be used by recombinant E. coli as a substrate to produce rhamnolipid. Glycerol can be converted to lipid precursor for rhamnolipid production as a carbon source by the respiratory metabolism pathway of glycerol in E. coli. In this way, glycerol may be converted to acetyl-CoA, which entered to FAS II (fatty acid synthase type-II) pathway and produce HAA as the precursor of RhlA [²2 Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.]. Production of rhamnolipid using POME medium has been carried out previously in Pseudomonas aeruginosa [²⁷27 Radzuan MN, Banat I, Winterburn J. Production and characterization of rhamnolipid using palm oil agricultural refinery waste. Bioresour Technol. 2017;225:99-105.] and P. stutzeri [¹¹11 Fazli RR, Hertadi R. Production and characterization of rhamnolipids from bioconversion of palm oil mill effluent by the halophilic bacterium Pseudomonas stutzeri. Environ Prog Sustain Energy. 2018;38:1-6.] but has never been carried out in recombinant E. coli. Using POME medium is expected to be used for further economic rhamnolipid production. However, the rhamnolipid yield using POME was lower than using autoinduction medium. It may be considered for further by using POME in the M9 medium with the addition of glucose as a rhamnose substrate to enhance rhamnolipid yield production.

CONCLUSION

Escherichia coli BL21(DE3) recombinant was able produced mono-rhamnolipid (pPM RHLAB) and di-rhamnolipid (pPM RHLABC). The size of rhlAB part was 2551 bp and rhlC part was 1129 bp, which was regulated by T7lac promoters and T7 terminators. The properties of biosurfactants show that di-rhamnolipid have the lowest surface tension and CMC than mono-rhamnolipid and synthetic surfactant (SDS). HRMS analysis of rhamnolipid extraction shows that recombinant E. coli pPM RHLAB mainly produced mono-rhamnolipid (Rha-C_14:2) while E. coli pPM RHLABC strain mainly produced di-rhamnolipid (Rha-Rha-C₁₀). In this study, rhamnolipid production using the autoinduction medium was relatively higher than other systems known today in recombinant Escherichia coli. The best rhamnolipid production was found at 20 h cultivation time, temperature 37 ^oC, pH 7 with Area_OSZ of 48.3 cm². The POME medium successfully produced rhamnolipid with an optimal addition of POME of 20% (v/v) in the medium.

Acknowledgments

The authors are grateful to iGEM ITB 2015 for the donation of mono-rhamnolipid production plasmid.

REFERENCES

¹
Tiso T, Zauter R, Tulke H, Leuchtle B, Li WJ, Behrens B, et al. Designer rhamnolipids by reduction of congener diversity: Production and characterization. Microb Cell Fact. 2017;16:1-14.
²
Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.
³
Zhou J, Xue R, Liu S, Xu N, Xin F, Zhang W. High di-rhamnolipid production using Pseudomonas aeruginosa KT1115, separation of mono / di-rhamnolipids, and evaluation of their properties. Front Bioeng Biotechnol. 2019;7:1-9.
⁴
Sinumvayo JP, Ishimwe N. Agriculture and food applications of rhamnolipids and its production by Pseudomonas aeruginosa. J Chem Eng Process. Technol. 2015;6:2-9.
⁵
Amani H, Müller MM, Syldatk C, Hausmann R. Production of microbial rhamnolipid by Pseudomonas aeruginosa MM1011 for ex situ enhanced oil recovery. Appl Biochem Biotechnol. 2013;170:1080-93.
⁶
Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.
⁷
Cabrera-valladares N, Richardson A, Olvera C, Treviño LG, Déziel E, Lépine F, et al. Monorhamnolipids and 3-( 3-hydroxyalkanoyloxy) alkanoic acids (HAAs) production using Escherichia coli as a heterologous host. Appl Microbiol Biotechnol. 2006;73:187-94.
⁸
Han L, Liu P, Peng Y, Lin J, Wang Q, Ma Y. Engineering the biosynthesis of novel rhamnolipids in Escherichia coli for enhanced oil recovery. J Appl Microbiol. 2014;117:139-50.
⁹
Studier FW. Stable cultures and auto-induction for inducible protein production in E. coli. Methods Mol Biol. 2014;1091:17-22.
¹⁰
Nur MMA, Hadiyanto H. Enhancement of Chlorella vulgaris biomass cultivated in POME medium as biofuel feedstock under mixotrophic conditions. J Eng Technol Sci. 2015;47:487-97.
¹¹
Fazli RR, Hertadi R. Production and characterization of rhamnolipids from bioconversion of palm oil mill effluent by the halophilic bacterium Pseudomonas stutzeri. Environ Prog Sustain Energy. 2018;38:1-6.
¹²
Wang Q, Fang X, Bai B, Liang X, Shuler PJ, Iii WAG, et al. Engineering bacteria for production of rhamnolipid as an agent for enhanced oil recovery. Biotechnol Bioeng. 2007;98:842-53.
¹³
Cheng T, Liang J, He J, Hu X, Ge Z, Liu J. A novel rhamnolipid - producing Pseudomonas aeruginosa ZS1 isolate derived from petroleum sludge suitable for bioremediation. AMB Express. 2017:120.
¹⁴
Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012;9:671-5.
¹⁵
Zhao F, Liang X, Ban Y, Han S, Zhang J, Zhang Y, et al. Comparison of methods to quantify rhamnolipid and optimization of oil spreading method. Tenside Surfactants Deterg. 2016;53:243-8.
¹⁶
Rahim R, Ochsner UA, Olvera C, Graninger M, Messner P, Lam JS, et al. Cloning and functional characterization of the Pseudomonas aeruginosa rhlC gene that encodes rhamnosyltransferase 2, an enzyme responsible for di-rhamnolipid biosynthesis. Mol Microbiol. 2001;40:708-18.
¹⁷
Lim H-K, Lee S, Chung S, Jung K, Seo J. Induction of the T7 promoter using lactose for production of recombinant plasminogen kringle 1-3 in Escherichia coli. J Microbiol Biotechnol. 2004;14:225-30.
¹⁸
Perfumo A, Rudden M, Smyth TJP, Marchant R, Stevenson PS, Parry NJ, et al. Rhamnolipids are conserved biosurfactants molecules : implications for their biotechnological potential. Appl Microbiol. 2013.
¹⁹
Nicolò MS, Cambria MG, Impallomeni G, Rizzo MG, Pellicorio C, Ballistreri A, et al. Carbon source effects on the mono / dirhamnolipid ratio produced by Pseudomonas aeruginosa L05, a new human respiratory isolate. N Biotechnol. 2017;39:36-41.
²⁰
Rikalovic MG, Avramovic NS, Karadzic IM. Structure - Function relationships of rhamnolipid and exopolysacharide biosurfactants of Pseudomonas aeruginosa as therapeutic targets in cystic fibrosis lung infections. Prog. Underst. Cyst. Fibros.,2017;127-58.
²¹
Li Z, Zhang Y, Lin J, Wang W, Li S. High-yield di-rhamnolipid production by Pseudomonas aeruginosa YM4 and its potential application in MEOR. Molecules. 2019;24:1433.
²²
Bharali P, Konwar BK. Production and physico-chemical characterization of a biosurfactant produced by Pseudomonas aeruginosa OBP1 Isolated from petroleum sludge. Appl Biochem Biotechnol 2011;164:1444-60.
²³
Dhasayan A, Kiran GS, Selvin J. Production and characterisation of glycolipid biosurfactant by Halomonas sp . MB-30 for potential application in enhanced oil recovery. Appl Biochem Biotechnol. 2014;174:2571-84.
²⁴
Abdel-mawgoud AM, Hausmann R, Le F, De E, Markus MM. Rhamnolipids : detection, analysis, biosynthesis, genetic regulation, and bioengineering of production. Biosurfactants. 2011;13-56.
²⁵
Wittgens A, Kovacic F, Müller MM, Gerlitzki M, Santiago-schübel B, Hofmann D, et al. Novel insights into biosynthesis and uptake of rhamnolipids and their precursors. Appl Microbiol Biotechnol 2017;101:2865-78.
²⁶
Maqsood MI, Jamal A. Factors affecting the rhamnolipid biosurfactant production. Pak J Biotechnol. 2011;8:1-5.
²⁷
Radzuan MN, Banat I, Winterburn J. Production and characterization of rhamnolipid using palm oil agricultural refinery waste. Bioresour Technol. 2017;225:99-105.

Funding:

This research was funded by LPDP (Indonesia Endowment Fund for Education), grant number FR31122018165662.

Edited by

Editor-in-Chief:

Paulo Vitor Farago

Associate Editor:

Luiz Gustavo Lacerda

Publication Dates

Publication in this collection
11 June 2021
Date of issue
2021

History

Received
15 May 2020
Accepted
18 Dec 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Tiso T, Zauter R, Tulke H, Leuchtle B, Li WJ, Behrens B, et al. Designer rhamnolipids by reduction of congener diversity: Production and characterization. Microb Cell Fact. 2017;16:1-14.

[2] ²
Abdel-mawgoud AM. Rhamnolipids: diversity of structures, microbial origins and roles. Appl Microbiol Biotechnol. 2010;86:1323-36.

[3] ³
Zhou J, Xue R, Liu S, Xu N, Xin F, Zhang W. High di-rhamnolipid production using Pseudomonas aeruginosa KT1115, separation of mono / di-rhamnolipids, and evaluation of their properties. Front Bioeng Biotechnol. 2019;7:1-9.

[4] ⁴
Sinumvayo JP, Ishimwe N. Agriculture and food applications of rhamnolipids and its production by Pseudomonas aeruginosa. J Chem Eng Process. Technol. 2015;6:2-9.

[5] ⁵
Amani H, Müller MM, Syldatk C, Hausmann R. Production of microbial rhamnolipid by Pseudomonas aeruginosa MM1011 for ex situ enhanced oil recovery. Appl Biochem Biotechnol. 2013;170:1080-93.

[6] ⁶
Du J, Zhang A, Hao J, Wang J. Biosynthesis of di-rhamnolipids and variations of congeners composition in genetically-engineered Escherichia coli. Biotechnol Lett. 2017;39:1041-8.

[7] ⁷
Cabrera-valladares N, Richardson A, Olvera C, Treviño LG, Déziel E, Lépine F, et al. Monorhamnolipids and 3-( 3-hydroxyalkanoyloxy) alkanoic acids (HAAs) production using Escherichia coli as a heterologous host. Appl Microbiol Biotechnol. 2006;73:187-94.

[8] ⁸
Han L, Liu P, Peng Y, Lin J, Wang Q, Ma Y. Engineering the biosynthesis of novel rhamnolipids in Escherichia coli for enhanced oil recovery. J Appl Microbiol. 2014;117:139-50.

[9] ⁹
Studier FW. Stable cultures and auto-induction for inducible protein production in E. coli. Methods Mol Biol. 2014;1091:17-22.

[10] ¹⁰
Nur MMA, Hadiyanto H. Enhancement of Chlorella vulgaris biomass cultivated in POME medium as biofuel feedstock under mixotrophic conditions. J Eng Technol Sci. 2015;47:487-97.

[11] ¹¹
Fazli RR, Hertadi R. Production and characterization of rhamnolipids from bioconversion of palm oil mill effluent by the halophilic bacterium Pseudomonas stutzeri. Environ Prog Sustain Energy. 2018;38:1-6.

[12] ¹²
Wang Q, Fang X, Bai B, Liang X, Shuler PJ, Iii WAG, et al. Engineering bacteria for production of rhamnolipid as an agent for enhanced oil recovery. Biotechnol Bioeng. 2007;98:842-53.

[13] ¹³
Cheng T, Liang J, He J, Hu X, Ge Z, Liu J. A novel rhamnolipid - producing Pseudomonas aeruginosa ZS1 isolate derived from petroleum sludge suitable for bioremediation. AMB Express. 2017:120.

[14] ¹⁴
Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012;9:671-5.

[15] ¹⁵
Zhao F, Liang X, Ban Y, Han S, Zhang J, Zhang Y, et al. Comparison of methods to quantify rhamnolipid and optimization of oil spreading method. Tenside Surfactants Deterg. 2016;53:243-8.

[16] ¹⁶
Rahim R, Ochsner UA, Olvera C, Graninger M, Messner P, Lam JS, et al. Cloning and functional characterization of the Pseudomonas aeruginosa rhlC gene that encodes rhamnosyltransferase 2, an enzyme responsible for di-rhamnolipid biosynthesis. Mol Microbiol. 2001;40:708-18.

[17] ¹⁷
Lim H-K, Lee S, Chung S, Jung K, Seo J. Induction of the T7 promoter using lactose for production of recombinant plasminogen kringle 1-3 in Escherichia coli. J Microbiol Biotechnol. 2004;14:225-30.

[18] ¹⁸
Perfumo A, Rudden M, Smyth TJP, Marchant R, Stevenson PS, Parry NJ, et al. Rhamnolipids are conserved biosurfactants molecules : implications for their biotechnological potential. Appl Microbiol. 2013.

[19] ¹⁹
Nicolò MS, Cambria MG, Impallomeni G, Rizzo MG, Pellicorio C, Ballistreri A, et al. Carbon source effects on the mono / dirhamnolipid ratio produced by Pseudomonas aeruginosa L05, a new human respiratory isolate. N Biotechnol. 2017;39:36-41.

[20] ²⁰
Rikalovic MG, Avramovic NS, Karadzic IM. Structure - Function relationships of rhamnolipid and exopolysacharide biosurfactants of Pseudomonas aeruginosa as therapeutic targets in cystic fibrosis lung infections. Prog. Underst. Cyst. Fibros.,2017;127-58.

[21] ²¹
Li Z, Zhang Y, Lin J, Wang W, Li S. High-yield di-rhamnolipid production by Pseudomonas aeruginosa YM4 and its potential application in MEOR. Molecules. 2019;24:1433.

[22] ²²
Bharali P, Konwar BK. Production and physico-chemical characterization of a biosurfactant produced by Pseudomonas aeruginosa OBP1 Isolated from petroleum sludge. Appl Biochem Biotechnol 2011;164:1444-60.

[23] ²³
Dhasayan A, Kiran GS, Selvin J. Production and characterisation of glycolipid biosurfactant by Halomonas sp . MB-30 for potential application in enhanced oil recovery. Appl Biochem Biotechnol. 2014;174:2571-84.

[24] ²⁴
Abdel-mawgoud AM, Hausmann R, Le F, De E, Markus MM. Rhamnolipids : detection, analysis, biosynthesis, genetic regulation, and bioengineering of production. Biosurfactants. 2011;13-56.

[25] ²⁵
Wittgens A, Kovacic F, Müller MM, Gerlitzki M, Santiago-schübel B, Hofmann D, et al. Novel insights into biosynthesis and uptake of rhamnolipids and their precursors. Appl Microbiol Biotechnol 2017;101:2865-78.

[26] ²⁶
Maqsood MI, Jamal A. Factors affecting the rhamnolipid biosurfactant production. Pak J Biotechnol. 2011;8:1-5.

[27] ²⁷
Radzuan MN, Banat I, Winterburn J. Production and characterization of rhamnolipid using palm oil agricultural refinery waste. Bioresour Technol. 2017;225:99-105.

Rhamnolipid congeners	M. Form	[M-H]^- m/z	Relative abundance (%)
Mono-rhamnolipid
Rha-C_8:2	C₁₄H₂₂O₇	302.2312	20
Rha-C₈	C₁₄H₃₆O₇	308.2386	11
Rha-C_12:2	C₁₈H₃₀O₇	358.2986	17
Rha-C_14:2	C₂₀H₃₄O₇	381.2907	24
Rha-C₁₀-C_12:1	C₂₈H₄₆O₉	527.3611	13

Rhamnolipid congeners	M. Form	[M-H]^- m/z	Relative abundance (%)
Mono-rhamnolipid
¹Rha-C_10:2	C₁₆H₂₆O₇	329.2733	21.7
Rha-C_12:2	C₁₈H₃₀O₇	357.3086	48
Rha-C_14:2	C₂₀H₃₄O₇	380.7588	32
¹Rha-C₁₀-C_13:2	C₂₉H₅₂O₉	539.2943	11
¹Rha-C₁₀-C_13:1	C₂₉H₅₄O₉	541.2909	5
Di-rhamnolipid
Rha-Rha-C₈	C₂₀H₃₆O₇	457.1891	63
Rha-Rha-C₁₀	C₂₂H₄₀O₁₁	485.2053	99.5
¹Rha-Rha-C₁₀-C_11:2	C₃₃H₅₂O₁₃	659.5488	22
¹Rha-Rha-C₁₂-C_11:2	C₃₅H₆₀O₁₃	687.5721	44
¹Rha-Rha-C₁₂-C_13:2	C₃₈H₆₄O₁₃	715.6049	38
¹Rha-Rha-C_13:2-C₁₂	C₃₈H₆₄O₁₃	716.6086	19
¹Rha-Rha-C₁₄-C₁₅	C₄₁H₇₈O₁₃	777.3831	8

Brasil