Application of AlkBGT and AlkL from Pseudomonas putida GPo1 for Selective Alkyl Ester ω-Oxyfunctionalization in Escherichia coli

Abstract: The enzyme system AlkBGT from Pseudomonas putida GPo1 can efficiently -functionalize fatty acid methyl esters. Outer membrane protein AlkL boosts this -functionalization. In this report, it is shown that whole cells of Escherichia coli expressing the AlkBGT system can also -oxidize ethyl nonanoate (NAEE). Coexpression of AlkBGT and AlkL resulted in 1.7-fold-higher -oxidation activity on NAEE. With this strain, initial activity on NAEE was 70 U/g (dry weight) of cells (g cdw ), 67% of the initial activity on me… Show more

“…Pathway AlkBGTHJL facilitated exclusive mono-ethyl DCA production from ethyl nonanoate and methyl nonanoate. This exclusive production was a clear improvement compared to earlier studies, wherein AlkBGTL or AlkBGTJL enzymes were applied 58,65,78,116 . Furthermore, mono-ethyl dicarboxylic acid production using AlkBGTHJL also requires less energy and oxygen input than when only AlkBGTL is applied.…”

“…This could be due to the fact that a methyl ester was the substrate. AlkB activities are higher on methyl nonanoate then on ethyl nonanoate 58,116 ; this might apply to the ω-aldehydes as well. Still, this would not explain the large differences between the rates of alcohol and aldehyde oxidation.…”

“…Ethyl heptanoate does not seem to be a good substrate, as can be concluded from the low product titres. Methyl/ethyl heptanoate were tested before as substrates for the AlkBGT system and were also not ω-oxidized efficiently 65,116 . The reason for this remains unknown.…”

“…Recently, we have demonstrated that E. coli expressing AlkBGT(L) can also ω-oxidize esters with an alkyl chain >1 116 . By increasing the alkyl chain length, the ω-oxidation activity on shorter fatty acid esters improved greatly.…”

“…AlkB overoxidizes ethyl nonanoate to 9-oxo ethyl nonanoate and mono-ethyl azelate 116 . We determined this overoxidation activity of whole cells expressing AlkBGTL from the pBTL10 plasmid by the addition of the intermediates 9-hydroxy ethyl nonanoate and 9-oxo methyl nonanoate and measuring the initial activities (Table 3.1).…”

Production of medium-chain, a, omega-bifunctional monomers from fatty acids and n-alkanes

“…Pathway AlkBGTHJL facilitated exclusive mono-ethyl DCA production from ethyl nonanoate and methyl nonanoate. This exclusive production was a clear improvement compared to earlier studies, wherein AlkBGTL or AlkBGTJL enzymes were applied 58,65,78,116 . Furthermore, mono-ethyl dicarboxylic acid production using AlkBGTHJL also requires less energy and oxygen input than when only AlkBGTL is applied.…”

“…This could be due to the fact that a methyl ester was the substrate. AlkB activities are higher on methyl nonanoate then on ethyl nonanoate 58,116 ; this might apply to the ω-aldehydes as well. Still, this would not explain the large differences between the rates of alcohol and aldehyde oxidation.…”

“…Ethyl heptanoate does not seem to be a good substrate, as can be concluded from the low product titres. Methyl/ethyl heptanoate were tested before as substrates for the AlkBGT system and were also not ω-oxidized efficiently 65,116 . The reason for this remains unknown.…”

“…Recently, we have demonstrated that E. coli expressing AlkBGT(L) can also ω-oxidize esters with an alkyl chain >1 116 . By increasing the alkyl chain length, the ω-oxidation activity on shorter fatty acid esters improved greatly.…”

“…AlkB overoxidizes ethyl nonanoate to 9-oxo ethyl nonanoate and mono-ethyl azelate 116 . We determined this overoxidation activity of whole cells expressing AlkBGTL from the pBTL10 plasmid by the addition of the intermediates 9-hydroxy ethyl nonanoate and 9-oxo methyl nonanoate and measuring the initial activities (Table 3.1).…”

Production of medium-chain, a, omega-bifunctional monomers from fatty acids and n-alkanes

Enhanced production of nonanedioic acid from nonanoic acid by engineered Escherichia coli

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