Semi‐rational evolution of the 3‐(3‐hydroxyalkanoyloxy)alkanoate (<scp>HAA</scp>) synthase RhlA to improve rhamnolipid production in <i>Pseudomonas aeruginosa</i> and <i>Burkholderia glumae</i>

Dulcey, Carlos Eduardo; Santos, Yossef López de los; Létourneau, Myriam; Déziel, Éric; Doucet, Nicolas

doi:10.1111/febs.14954

Cited by 19 publications

(16 citation statements)

References 94 publications

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“…The biosynthesis of rhamnolipids starts with the formation of HAA from two β-hydroxy fatty acids by the enzyme RhlA ( Déziel et al, 2003 ). The substrate spectra of different RhlA enzymes are responsible for the chain-length spectrum of the final biosurfactant ( Dulcey et al, 2019 ; Germer et al, 2020 ). Subsequently, rhamnose units are attached to the HAA by activity of RhlB and RhlC, respectively, to form mono- and di-rhamnolipids ( Ochsner et al, 1994 ; Rahim et al, 2001 ).…”

Section: Introductionmentioning

confidence: 99%

Integration of Genetic and Process Engineering for Optimized Rhamnolipid Production Using Pseudomonas putida

Tiso

Ihling

Kubicki

et al. 2020

Front. Bioeng. Biotechnol.

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E. coli HB101 pRK2013 Sm R , hsdR-M + , proA2, leuB6, thi-1, recA; harboring plasmid pRK2013 Ditta et al., 1980 E. coli DH5α pYTSK01K_0G7 DH5α harboring plasmid pYTSK01K_0G7 This study E. coli DH5α pVLT33-PA_rhlABC DH5α harboring plasmid pVLT33-PA_rhlABC Wittgens et al., 2017 E. coli DH5α pBNT Km DH5α harboring plasmid pBNTmcs(t)Km This study S. cerevisiae VL6-48 pYTSK10K_0G7_rhlAB VL6-48 harboring plasmid pYTSK10K_0G7_rhlAB This study E. coli DH5α pYTSK10K_1G7_rhlAB DH5α harboring plasmid pYTSK10K_1G7_rhlAB This study E. coli DH5α pRhon5Hi-2-eyfp DH5α harboring plasmid pRhon5Hi-2-eyfp Troost et al., 2019 S. cerevisiae VL6-48 pYTSK40K_1G7_rhlAB VL6-48 harboring plasmid pYTSK40K_1G7_rhlAB This study E. coli DH5α pYTSK40K_0G7_rhlAB DH5α harboring plasmid pYTSK40K_0G7_rhlAB This study E. coli S17-1 pYTSK40K_1G7_rhlAB S17-1 harboring plasmid pYTSK40K_1G7_rhlAB This study E. coli DH5αλpir pSK02 DH5α λpir harboring Tn7 delivery vector pSK02 for chromosomal integration Bator et al., 2020b E. coli DH5α pSW-2 DH5α harboring plasmid pSW-2 encoding I-SceI nuclease Martinez-Garcia and de Lorenzo, 2011 E. coli DH5αλpir pTNS-1 DH5α λpir harboring plasmid pTNS-1 Choi et al., 2005 E. coli DH5αλpir p pha DH5α λpir harboring plasmid p pha Mato Aguirre, 2019 E. coli PIR2 pEMG-flag1 PIR2 harboring plasmid pEMG-flag1 Blesken et al., 2020 E. coli PIR2 pEMG-flag2 PIR2 harboring plasmid pEMG-flag2 Blesken et al., 2020 E. coli DH5αλpir pMaW03 DH5α λpir harboring plasmid pMaW03 This study P. putida chassis strains P. putida KT2440 Wild type Bagdasarian et al., 1981 P. putida KT2440 flag PP_4328-PP_4344 and PP_4351-PP_4397 Blesken et al., 2020 P. putida KT2440 phaG PP_1408 This study P. putida KT2440 pha PP_5003-PP_5008 Blesken et al., 2020 P. putida KT2440 phaG pha PP_1408 and PP_5003-PP_5008 (phaC1ZC2DFI) This study P. putida KT2440 flag pha PP_4328-PP_4344, PP_4351-PP_4397 and PP_5003-PP_5008 This study P. putida strains used for biosurfactant production P. putida KT2440 pPS05 KT2440 harboring plasmid pPS05 Tiso et al., 2016 P. putida KT2440 SK4 rhlAB, attTn7 integrated, P 14ffg This study P. putida KT2440 sal mRL E SK40 rhlAB, eYFP, attTn7 integrated, P nagAa /nagR, Gm R , tnsABCD This study P. putida KT2440 flag SK4 PP_4328-PP_4344 and PP_4351-PP_4397, rhlAB, attTn7 integrated, P 14ffg Blesken et al., 2020 P. putida KT2440 phaG SK4 PP_1408, rhlAB, attTn7 integrated, P 14ffg This study P. putida KT2440 pha SK4 PP_5003-PP_5008, rhlAB, attTn7 integrated, P 14ffg Blesken et al., 2020 P. putida KT2440 phaG pha SK4 PP_1408 and PP_5003-PP_5008, rhlAB, attTn7 integrated, P 14ffg This study P. putida KT2440 flag pha SK4 PP_4328-PP_4344 and PP_4351-PP_4397 and PP_5003-PP_5008, rhlAB, attTn7 integrated, P 14ffg

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Section: Introductionmentioning

confidence: 99%

Integration of Genetic and Process Engineering for Optimized Rhamnolipid Production Using Pseudomonas putida

Tiso

Ihling

Kubicki

et al. 2020

Front. Bioeng. Biotechnol.

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“…Such an approach using hybrid rhlAB operons from P. aeruginosa and B. glumae verified, that RhlA seems to mainly determine the fatty acid lengths used for the biosynthesis first of HAAs, but subsequent also for rhamnolipids . Similar experiments using the two originating species as hosts for such hybrid operons further indicated an influence of the host organism and its provided 3-hydroxyfatty acids (Dulcey et al, 2019).…”

Section: Tailor-made Rhamnolipids-future Perspectivesmentioning

confidence: 72%

“…In contrast, if the same operon was expressed in P. aeruginosa as host, the amount of C 12 -C 12 congener was only increased in a mixture with a still predominant C 10 -C 10 congener. It was further demonstrated, that mutagenized RhlA reached activities more than twice as much as the wild type RhlA (Dulcey et al, 2019) and amino acid exchanges of RhlB resulted in a shifted pattern of the rhamnolipid composition from C 10 -C 10 to C 10 -C 8 congeners indicating a further specificity of RhlB to specific HAAs containing certain fatty acid length (Han et al, 2014). Further enzyme modifications could result in a much more specific congener enriched composition through improved specificity of responsible enzymes to specific fatty acid chain lengths.…”

Section: Tailor-made Rhamnolipids-future Perspectivesmentioning

confidence: 96%

“…Another purpose for tailor-made rhamnolipids is to define the fatty acid chain lengths for each of the four species and possibly their degree of saturation customized for any type of specific applications. So far most of the publications used rhl genes from P. aeruginosa for the heterologous production of rhamnolipids in different hosts and only a few reports about the successful heterologous expression of rhl genes from Burkholderia Dulcey et al, 2019). However, it has been described for Pseudomonas desmolyticum to produce rhamnolipids with predominant C 6 -C 8 fatty acids (Jadhav et al, 2011), while other bacteria of the genus Thermus produce much longer rhamnolipids with up to 24 carbon atoms and a predominant C 16 -C 16 congener (Řezanka et al, 2011), but none of them were produced heterologously so far.…”

Section: Tailor-made Rhamnolipids-future Perspectivesmentioning

confidence: 99%

“…A further possibility to achieve novel chain lengths in rhamnolipids is to manipulate the involved enzymes by single amino acid or whole domain exchanges to alter the accepted length of 3-hydroxyfatty acids as it was recently done. Thereby, Dulcey et al (2019) created a chimeric RhlA variant using different original enzyme domains for RhlA originating form P. aeruginosa and B. glumae. Combined in an operon with rhlB from P. aeruginosa, the newly designed enzyme produced rhamnolipids with a predominant C 12 -C 12 congener when heterologous expressed in B. glumae, which is the average between the typical short-chain rhamnolipids from Pseudomnas and the long-chain rhamnolipids from Burkholderia.…”

Section: Tailor-made Rhamnolipids-future Perspectivesmentioning

confidence: 99%

See 2 more Smart Citations

Heterologous Rhamnolipid Biosynthesis: Advantages, Challenges, and the Opportunity to Produce Tailor-Made Rhamnolipids

Wittgens

Rosenau

2020

Front. Bioeng. Biotechnol.

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The first heterologous expression of genes responsible for the production of rhamnolipids was already implemented in the mid-1990s during the functional identification of the rhlAB operon. This was the starting shot for multiple approaches to establish the rhamnolipid biosynthesis in different host organisms. Since most of the native rhamnolipid producing organisms are human or plant pathogens, the intention for these ventures was the establishment of non-pathogenic organisms as heterologous host for the production of rhamnolipids. The pathogenicity of producing organisms is one of the bottlenecks for applications of rhamnolipids in many industrial products especially foods and cosmetics. The further advantage of heterologous rhamnolipid production is the circumvention of the complex regulatory network, which regulates the rhamnolipid biosynthesis in wild type production strains. Furthermore, a suitable host with an optimal genetic background to provide sufficient amounts of educts allows the production of tailor-made rhamnolipids each with its specific physico-chemical properties depending on the contained numbers of rhamnose sugar residues and the numbers, chain length and saturation degree of 3-hydroxyfatty acids. The heterologous expression of rhl genes can also enable the utilization of unusual carbon sources for the production of rhamnolipids depending on the host organism.

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Protein engineering approaches for enhanced catalytic efficiency

Zhang

Chen

2020

Biomass, Biofuels, Biochemicals

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Semi‐rational evolution of the 3‐(3‐hydroxyalkanoyloxy)alkanoate (HAA) synthase RhlA to improve rhamnolipid production in Pseudomonas aeruginosa and Burkholderia glumae

Cited by 19 publications

References 94 publications

Integration of Genetic and Process Engineering for Optimized Rhamnolipid Production Using Pseudomonas putida

Integration of Genetic and Process Engineering for Optimized Rhamnolipid Production Using Pseudomonas putida

Heterologous Rhamnolipid Biosynthesis: Advantages, Challenges, and the Opportunity to Produce Tailor-Made Rhamnolipids

Protein engineering approaches for enhanced catalytic efficiency

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