Abstract
BackgroundWhen using the microbial cell factories for green manufacturing, several important issues need to be addressed such as how to maintain the stability of biocatalysts used in the bioprocess and how to improve the synthetic efficiency of the biological system. One strategy widely used during natural evolution is the creation of organelles which can be used for regional control. This kind of compartmentalization strategy has inspired the design of artificial organelle-like nanodevice for synthetic biology and “green chemistry”.ResultsMimicking the natural concept of functional compartments, here we show that the engineered thermostable ketohydroxyglutarate aldolase from Thermotoga maritima could be developed as a general platform for nanoreactor design via supramolecular self-assembly. An industrial biocatalyst-(+)-γ-lactamase was selected as a model catalyst and successful encapsulated in the nanoreactor with high copies. These nanomaterials could easily be synthesized by Escherichia coli by heterologous expression and subsequently self-assembles into the target organelle-like nanoreactors both in vivo and in vitro. By probing their structural characteristics via transmission electronic microscopy and their catalytic activity under diverse conditions, we proved that these nanoreactors could confer a significant benefit to the cargo proteins. The encapsulated protein exhibits significantly improved stability under conditions such as in the presence of organic solvent or proteases, and shows better substrate tolerance than free enzyme.ConclusionsOur biodesign strategy provides new methods to develop new catalytically active protein-nanoreactors and could easily be applied into other biocatalysts. These artificial organelles could have widely application in sustainable catalysis, synthetic biology and could significantly improve the performance of microbial cell factories.Graphical
Highlights
When using the microbial cell factories for green manufacturing, several important issues need to be addressed such as how to maintain the stability of biocatalysts used in the bioprocess and how to improve the synthetic efficiency of the biological system
Preparation of recombinant proteins for nanoreactor construction The engineered ketohydroxyglutarate aldolase from T. maritima can self-assemble into a virus-like dodecahedron particle with 60 subunits (Fig. 1) [15]
A γ-lactamase mutant from Microbacterium hydrocarbonoxydans was selected as a model biocatalyst and placed in the interior of the nanocage. γ-Lactamase is a versatile enzyme that is widely used for the enzymatic resolution of racemic 2-azabicyclo [2.2.1] hept-5-en-3-one (Vince lactam) [17,18,19,20,21]
Summary
When using the microbial cell factories for green manufacturing, several important issues need to be addressed such as how to maintain the stability of biocatalysts used in the bioprocess and how to improve the synthetic efficiency of the biological system. One strategy widely used during natural evolution is the creation of organelles which can be used for regional control. This kind of compartmentalization strategy has inspired the design of artificial organelle-like nanodevice for synthetic biology and “green chemistry”. The well-defined barriers formed by lipid membranes or proteins constrain certain incompatible chemical processes in the nano-spatial scale [1,2,3]. This brings several advantages, such as: (a) increasing the local concentrations of enzymes and substrates; (b) protecting the unstable catalysts or volatile intermediates from unsuitable environments; and (c) creating unique. Two kinds of enzymes (ribulose-1,5-bisphosphate carboxylase– oxygenase and carbonic anhydrase) are encapsulated in the protein cage to enhance CO2 fixation [8, 9].
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