“Cell-free system”的意思、由来-开放百科全书

cliA cell-free system is an in vitro tool widely used to study biological reactions that happen within cells apart from a full cell system, thus reducing the complex interactions typically found when working in a whole cell.^[1] Subcellular fractions can be isolated by ultracentrifugation to provide molecular machinery that can be used in reactions in the absence of many of the other cellular components.^[2] Eukaryotic and prokaryotic cell internals have been used for creation of these simplified environments.^[3]^[4] These systems have enabled cell-free synthetic biology to emerge, providing control over what reaction is being examined, as well as its yield, and lessening the considerations otherwise invoked when working with more sensitive live cells.^[5]

Types

Cell-free systems may be divided into two primary classifications: cell extract-based, which remove components from within a whole cell for external use, and purified enzyme-based, which use purified components of the molecules known to be involved in a given process.^[6]^[7] The cell extract-based type are susceptible to problems like quick degradation of components outside their host, as shown in a study by Kitaoka et al. where a cell-free translation system based on Escherichia coli (E. coli), of the cell extract-based type, had the mRNA template degrade very quickly and led to the halt of protein synthesis.^[8]

Preparation

The methods of preparation vary between situations of both types of cell-free systems.

Cell extract–based

Purified enzyme–based

Cell-free synthetic pathway biotransformation biosystems can be prepared by mixing a number of purified enzymes and coenzymes.^[3]^[16] For example, tightly coupled ribosomes, which are compact and highly active, have been extracted and refined from E. coli through sucrose-density-gradient centrifugation.^[17]^[7]

Uses

Cell-free synthetic pathway biotransformation biosystems are proposed as a new low-cost biomanufacturing platform compared to microbial fermentation used for thousands of years.^[3]^[16] Cell-free biosystems have several advantages suitable in industrial applications:^[6]

Protein synthesis

Metabolic manipulation

Engineering of metabolic processes have been achieved through cell-free systems.^[10]^[3] Bujara et al., for example, were able to use glycolytic network extracts, consisting of enzymes from E. coli that produced dihydroxyacetone phosphate, to analyze in real-time the metabolite concentrations while altering enzyme levels, with the end result of optimal production of dihydroxyacetone phosphate.^[25] Further, Calhoun and Swartz were able to use a glycolytic intermediate to fuel a cell-free system, enabling relatively inexpensive ATP generation compared to reagent usage in phosphoenolpyruvate reactions.^[26]

Unnatural amino acid incorporation

Cell-free systems have also been used to incorporate unnatural amino acids.^[26]^[27] Shimizu et al. were able to change a stop codon to a sense codon by omitting the RF1 release factor, indicating ability to insert desired amino acids in unnatural situations. This is of use in systems where working inside a cell is problematic, such as the process of amino acid metabolism preventing specific labelling of amino acids that would be useful in multidimensional NMR spectroscopy.^[28] Kigawa et al.were able to successfully label amino acids in a cell-free system where amino acid metabolism was no longer present, thus making such systems useful to NMR studies.^[28]

References

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