Production of 8S- and 10S-hydroxy polyunsaturated fatty acids by recombinant Escherichia coli cells expressing mouse arachidonate 8S-lipoxygenase

Murine Alox8 versus the human ALOX15B ortholog: differences and similarities

Human arachidonate 15-lipoxygenase type B is a lipoxygenase that catalyzes the peroxidation of arachidonic acid at carbon-15. The corresponding murine ortholog however has 8-lipoxygenase activity. Both enzymes oxygenate polyunsaturated fatty acids in S-chirality with singular reaction specificity, although they generate a different product pattern. Furthermore, while both enzymes utilize both esterified fatty acids and fatty acid hydro(pero)xides as substrates, they differ with respect to the orientation of the fatty acid in their substrate-binding pocket. While ALOX15B accepts the fatty acid "tail-first," Alox8 oxygenates the free fatty acid with its "head-first." These differences in substrate orientation and thus in regio- and stereospecificity are thought to be determined by distinct amino acid residues. Towards their biological function, both enzymes share a commonality in regulating cholesterol homeostasis in macrophages, and Alox8 knockdown is associated with reduced atherosclerosis in mice. Additional roles have been linked to lung inflammation along with tumor suppressor activity. This review focuses on the current knowledge of the enzymatic activity of human ALOX15B and murine Alox8, along with their association with diseases.

Enzymatic Formation of Protectin Dx and Its Production by Whole-Cell Reaction Using Recombinant Lipoxygenases

In the human body, docosahexaenoic acid (DHA) contained in fish oil is converted to trace amounts of specialized pro-resolving mediators (SPMs) as the principal bioactive metabolites for their pharmacological effects. Protectin Dx (PDX), an SPM, is an important medicinal compound with biological activities such as modulation of endogenous antioxidant systems, inflammation pro-resolving action, and inhibition of influenza virus replication. Although it can be biotechnologically synthesized from DHA, it has not yet been produced quantitatively. Here, we found that 15S-lipoxygenase from Burkholderia thailandensis (BT 15SLOX) converted 10S-hydroxydocosahexaenoic acid (10S-HDHA) to PDX using enzymatic reactions, which was confirmed by LC-MS/MS and NMR analyses. Thus, whole-cell reactions of Escherichia coli cells expressing BT 15SLOX were performed in flasks to produce PDX from lipase-treated DHA-enriched fish oil along with E. coli cells expressing Mus musculus (mouse) 8S-lipoxygenase (MO 8SLOX) that converted DHA to 10S-HDHA. First, 1 mM DHA (DHA-enriched fish oil hydrolysate, DFOH) was obtained from 455 mg/L DHA-enriched fish oil by lipase for 1 h. Second, E. coli cells expressing MO 8SLOX converted 1 mM DHA in DFOH to 0.43 mM 10S-HDHA for 6 h. Finally, E. coli cells expressing BT 15SLOX converted 0.43 mM 10S-HDHA in MO 8SLOX-treated DFOH to 0.30 mM (108 mg/L) PDX for 5 h. Consequently, DHA-enriched fish oil at 455 mg/L was converted to 108 mg/L PDX after a total of 12 h (conversion yield: 24% (w/w); productivity: 4.5 mg/L/h). This study is the first report on the quantitative production of PDX via biotechnological approaches.

Biotransformation of C20- and C22-polyunsaturated fatty acids to 11S- and 13S-hydroxy fatty acids by Escherichia coli expressing 11S-lipoxygenase from Enhygromyxa salina

PURPOSE

Peroxidation and reduction of 11S- and 13S-positions on C20 and C22 polyunsaturated fatty acids (PUFAs) by Escherichia coli expressing highly active arachidonate (ARA) 11S-lipoxygenase (11S-LOX) from Enhygromyxa salina with the reducing agent cysteine.

RESULTS

The specific activity and catalytic efficiency of ARA 11S-LOX from E. salina were 4.1- and 91-fold higher than those of only reported ARA 11S-LOX from Myxococcus xanthus, respectively. The hydroxy fatty acids (HFAs) obtained by the biotransformation of ARA, eicosapentaenoic acid (EPA), docosapentaenoic acid (DPA), and docosahexanoic acid (DHA) by Escherichia coli expressing 11S-LOX from E. salina in the presence of cysteine were identified as 11S-hydroxyeicosatetraenoic acid (11S-HETE), 11S-hydroxyeicosapentaenoic acid (11S-HEPE), 13S-hydroxydocosapentaenoic acid (13S-HDPA), and 13S-hydroxydocosahexaenoic acid (13S-HDHA), respectively. The recombinant cells converted 3 mM of ARA, EPA, DPA, and DHA into 2.9 mM of 11S-HETE, 2.4 mM 11S-HEPE, 1. 9 mM 13S-HDPA, and 2.2 mM 13S-HDHA in 60, 80, 120, and 120 min, corresponding to productivities of 72.5, 40.4, 18.5, and 22.4 μM min^-1 and conversion yields of 96.7, 80.0, 62.3, and 74.6%, respectively.

CONCLUSIONS

We report the highest concentrations, conversion yields, and productivities of 11S- and 13S-hydroxy fatty acids from C20- and C22-PUFAs achieved via E. coli expressing highly active E. salina 11S-LOX.

Bioconversion of C20- and C22-polyunsaturated fatty acids into 9S,15S- and 11S,17S-dihydroxy fatty acids by Escherichia coli expressing double-oxygenating 9S-lipoxygenase from Sphingopyxis macrogoltabida

Double-oxygenating lipoxygenase (LOX) converted C20- and C22-polyunsaturated fatty acids (PUFAs) into C20 dihydroxy fatty acids (DiHFAs) as inflammatory mediators and C22 DiHFAs as specialized pro-resolving mediators, which are involved in the resolution of inflammation and infection in humans, and their isomers, respectively. However, the quantitative bioconversion of C20- and C22-PUFAs into 9S,15S- and 11S,17S-DiHFAs has been not attempted to date, respectively. Here, we performed the efficient quantitative production of 9S,15S- and 11S,17S-DiHFAs by Escherichia coli expressing 9S-LOX from Sphingopyxis macrogoltabida. The optimal bioconversion conditions of the C20 PUFA arachidonic acid or the C22-PUFA docosahexaenoic acid were pH 8.5, 35 °C, 6 mM substrate, and 5 g dry cells/L for C20 PUFAs or 7 g dry cells/L for C22 PUFAs, respectively. Under these conditions, E. coli expressing double-oxygenating 9S-LOX from S. macrogoltabida converted arachidonic acid, eicosapentaenoic acid, docosapentaenoic acid_n-3, and docosahexaenoic acid into 5.85 mM 9S,15S-dihydroxyeicosatetraenoic acid, 5.79 mM 9S,15S-dihydroxyeicosapentaenoic acid, 5.89 mM 11S,17S-hydroxydocosapentaenoic acid_n-3, and 5.24 mM 11S,17S-dihydroxydocosahexaenoic acid in 40, 30, 50, and 60 min, with conversion yields of 97.5%, 96.5%, 98.1%, and 87.3%; and volumetric productivities of 8.78, 11.6, 7.07, and 5.24 mM/h, respectively. To date, these are the highest concentrations, conversion yields, and volumetric productivities reported in the bioconversion of C20- and C22-PUFAs into DiHFAs.