Abstract
BackgroundWe have recently developed a one-step, genetically encoded immobilization approach based on fusion of a target enzyme to the self-crystallizing protein Cry3Aa, followed by direct production and isolation of the fusion crystals from Bacillus thuringiensis. Using this approach, Bacillus subtilis lipase A was genetically fused to Cry3Aa to produce a Cry3Aa–lipA catalyst capable of the facile conversion of coconut oil into biodiesel over 10 reaction cycles. Here, we investigate the fusion of another lipase to Cry3Aa with the goal of producing a catalyst suitable for the conversion of waste cooking oil into biodiesel.ResultsGenetic fusion of the Proteus mirabilis lipase (PML) to Cry3Aa allowed for the production of immobilized lipase crystals (Cry3Aa–PML) directly in bacterial cells. The fusion resulted in the loss of PML activity, however, and so taking advantage of its genetically encoded immobilization, directed evolution was performed on Cry3Aa–PML directly in its immobilized state in vivo. This novel strategy allowed for the selection of an immobilized PML mutant with 4.3-fold higher catalytic efficiency and improved stability. The resulting improved Cry3Aa–PML catalyst could be used to catalyze the conversion of waste cooking oil into biodiesel for at least 15 cycles with minimal loss in conversion efficiency.ConclusionsThe genetically encoded nature of our Cry3Aa-fusion immobilization platform makes it possible to perform both directed evolution and screening of immobilized enzymes directly in vivo. This work is the first example of the use of directed evolution to optimize an enzyme in its immobilized state allowing for identification of a mutant that would unlikely have been identified from screening of its soluble form. We demonstrate that the resulting Cry3Aa–PML catalyst is suitable for the recyclable conversion of waste cooking oil into biodiesel.
Highlights
We have recently developed a one-step, genetically encoded immobilization approach based on fusion of a target enzyme to the self-crystallizing protein Cry3Aa, followed by direct production and isolation of the fusion crystals from Bacillus thuringiensis
We showed that genetic fusion of Cry3Aa to lipase A from Bacillus subtilis resulted in Cry3Aa–lipA crystals capable of catalyzing the conversion of coconut oil to biodiesel with high efficiency over 10 reactions cycles [34]
Production and characterization of Cry3Aa‐fusion crystals Since the Cry3Aa N-terminus is known to undergo partial processing [38], the production of Cry3Aa–Proteus mirabilis lipase (PML) and Cry3Aa–Dieselzyme 4 (DLZM4) was achieved by creating genetic fusions that link these lipases to the C-terminus of Cry3Aa
Summary
We have recently developed a one-step, genetically encoded immobilization approach based on fusion of a target enzyme to the self-crystallizing protein Cry3Aa, followed by direct production and isolation of the fusion crystals from Bacillus thuringiensis. Using this approach, Bacillus subtilis lipase A was genetically fused to Cry3Aa to produce a Cry3Aa–lipA catalyst capable of the facile conversion of coconut oil into biodiesel over 10 reaction cycles. Vegetable oil is a common feedstock for biodiesel production, though its relatively high price [5] and its negative impact on food security make it less appealing With these concerns in mind, one attractive alternative is waste cooking oil (WCO). While an acid pre-treatment step can be Heater et al Biotechnol Biofuels (2019) 12:165
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