AS
A.D.D. Scott
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Natural life is extraordinarily complex, which by definition means that it has many interconnected and functioning parts. The goal of synthetic biology is to engineer living systems, though due to their very complexity they remain recalcitrant to engineering. What if it were possible to reduce the complexity to a finite amount of parts that are well understood and therefore possible to manipulate. That is the motivation for constructing a so called minimal cell.
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Natural life is extraordinarily complex, which by definition means that it has many interconnected and functioning parts. The goal of synthetic biology is to engineer living systems, though due to their very complexity they remain recalcitrant to engineering. What if it were possible to reduce the complexity to a finite amount of parts that are well understood and therefore possible to manipulate. That is the motivation for constructing a so called minimal cell.
Journal article
(2016)
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Andrew Scott, Marek Noga, P. de Graaf, Ilja Westerlaken, Esengul Yildirim, Christophe Danelon
The goal of bottom-up synthetic biology culminates in the assembly of an entire cell from separate biological building blocks. One major challenge resides in the in vitro production and implementation of complex genetic and metabolic pathways that can support essential cellular functions. Here, we show that phospholipid biosynthesis, a multiple-step process involved in cell membrane homeostasis, can be reconstituted starting from the genes encoding for all necessary proteins. A total of eight E. coli enzymes for acyl transfer and headgroup modifications were produced in a cell-free gene expression system and were co-translationally reconstituted in liposomes. Acyl-coenzyme A and glycerol-3-phosphate were used as canonical precursors to generate a variety of important bacterial lipids. Moreover, this study demonstrates that two-step acyl transfer can occur from enzymes synthesized inside vesicles. Besides clear implications for growth and potentially division of a synthetic cell, we postulate that gene-based lipid biosynthesis can become instrumental for ex vivo and protein purification-free production of natural and non-natural lipids.
...
The goal of bottom-up synthetic biology culminates in the assembly of an entire cell from separate biological building blocks. One major challenge resides in the in vitro production and implementation of complex genetic and metabolic pathways that can support essential cellular functions. Here, we show that phospholipid biosynthesis, a multiple-step process involved in cell membrane homeostasis, can be reconstituted starting from the genes encoding for all necessary proteins. A total of eight E. coli enzymes for acyl transfer and headgroup modifications were produced in a cell-free gene expression system and were co-translationally reconstituted in liposomes. Acyl-coenzyme A and glycerol-3-phosphate were used as canonical precursors to generate a variety of important bacterial lipids. Moreover, this study demonstrates that two-step acyl transfer can occur from enzymes synthesized inside vesicles. Besides clear implications for growth and potentially division of a synthetic cell, we postulate that gene-based lipid biosynthesis can become instrumental for ex vivo and protein purification-free production of natural and non-natural lipids.