概要

Cell-Free Protein Synthesis System for Building Synthetic Cells

Published: April 19, 2024
doi:

概要

This protocol describes the Cell-Free Protein Synthesis (CFPS) system used in constructing synthetic cells. It outlines key stages with representative results in different micro-compartments. The protocol aims to establish best practices for diverse laboratories in the synthetic cell community, advancing progress in synthetic cell development.

Abstract

The Cell-Free Protein Synthesis (CFPS) system has been widely employed to facilitate the bottom-up assembly of synthetic cells. It serves as the host for the core machinery of the Central Dogma, standing as an optimal chassis for the integration and assembly of diverse artificial cellular mimicry systems. Despite its frequent use in the fabrication of synthetic cells, establishing a tailored and robust CFPS system for a specific application remains a nontrivial challenge. In this methods paper, we present a comprehensive protocol for the CFPS system, routinely employed in constructing synthetic cells. This protocol encompasses key stages in the preparation of the CFPS system, including the cell extract, template preparation, and routine expression optimization utilizing a fluorescent reporter protein. Additionally, we show representative results by encapsulating the CFPS system within various micro-compartments, such as monolayer droplets, double-emulsion vesicles, and chambers situated atop supported lipid bilayers. Finally, we elucidate the critical steps and conditions necessary for the successful assembly of these CFPS systems in distinct environments. We expect that our approach will facilitate the establishment of good working practices among various laboratories within the continuously expanding synthetic cell community, thereby accelerating progress in the field of synthetic cell development.

Introduction

The synthesis of synthetic or artificial cells has emerged as a highly prominent field of interdisciplinary research, attracting substantial interest from scientists across the domains of synthetic biology, chemistry, and biophysics. These scientists are united by the common goal of constructing a minimal living cell1,2,3. The rapid growth of this field has been in step with significant advancements in critical technologies, such as recombinant DNA manipulation4, biomimetic materials5, and microfabrication techniques for compartmentalization6, including the Cell-Free Protein Synthesis (CFPS) method7. CFPS systems encompass the essential cellular machinery for transcription and translation, providing the foundational framework for the development and integration of multifunctional artificial cells.

Although CFPS techniques are frequently used in the assembly of synthetic cells, developing a robust and tailored CFPS system for the assembly of various synthetic cell systems remains a complex challenge. Currently, numerous CFPS systems are available, derived from both prokaryotes and eukaryotes model organisms8, each specialized for particular applications in synthetic cell synthesis. Beyond their central roles in transcription and translation, CFPS systems vary in their main components and associated preparation procedures. These variations, which include differences in cell extracts, RNA polymerases, template preparation methods, and buffer compositions, are largely due to the distinct development trajectories pursued by research groups that have intensively optimized their systems for maximal protein yield.

Among the various components of the CFPS system, the cell extract is a critical enzymatic pool for transcription and translation, and thus a key determinant of CFPS performance9. Escherichia coli (E. coli)based CFPS is the most commonly utilized system due to its status as the best-understood prokaryotic organism. Furthermore, a fully reconstituted CFPS system comprising individually purified proteins and ribosomes, known as PURE10, has been developed by Ueda's research group, which is particularly suited for applications requiring a clear background. Today, even E. coli-based CFPS systems have diversified, especially in terms of the source strains for the extrac11 and methods of preparation12,13, RNA polymerase14,15, energy sources16,17, and buffer systems18,19. The most frequently used strains include K12 and B strain derivatives, such as A1920, JM10921, BL21 (DE3)22, and Rossetta223, alongside their genetically modified counterparts.

Initially, E. coli strains with reduced RNase and protease activities were chosen to enhance mRNA stability and the stability of newly synthesized recombinant proteins, leading to increased final protein yields24. Subsequently, E. coli extracts were engineered to facilitate specific post-translational modifications, including glycosylation25, phosphorylation26, and lipidation27, were developed to achieve the above posttranslational modifications. Additionally, an array of additives such as molecular chaperons28 and chemical stabilizers have been incorporated to aid the folding of target proteins, contributing to the diversification of CFPS systems. The bacteriophage T7 RNA polymerase, known for its high processivity, is predominantly employed for transcription, although other polymerases such as SP629 have also been utilized. E. coli endogenous RNA polymerase has been adapted for the prototyping of genetic circuits leveraging sigma factors30. Lastly, a variety of energy precursors31,32,33 and different salts and buffer components19,34,35 have been systematically optimized to enhance productivity.

Besides the CFPS system itself, the encapsulation methods as well as compartmentalization materials are also vital for the successful synthetic cell assembly. Various systems that have been developed to successfully encapsulate the CFPS reaction include surfactant-stabilized water/oil droplets, lipid/polymer, and their hybrid unilamellar vesicles (with diameters ranging from 50 nm to several μm), as well as planar-supported lipid bilayers. However, due to the complexed molecule content of the CFPS system, the success rate of encapsulation depends on specific cases, particularly for the formation of vesicles. To improve the success rate and efficiency of encapsulation of CFPS, various microfluid chips have been developed to facilitate the formation of both droplets and vesicles36. Nevertheless, additional chips and devices will need to be established.

This protocol delineates an E. coli CFPS system utilizing the BL21(DE3) strain, which is a commonly employed host for recombinant protein production. The protocol encompasses a detailed account of the cell extract preparation, template preparation, and standard expression optimization using a fluorescent reporter protein. Moreover, we present exemplary outcomes achieved by encapsulating the CFPS system within diverse micro-compartments, including monolayer droplets, double emulsion vesicles, and chambers situated atop supported lipid bilayers. Finally, we expound upon the pivotal procedural elements and the requisite conditions indispensable for the successful establishment of these CFPS systems within distinct environmental contexts.

Protocol

1. Extract preparation

  1. Streak the E. coli BL21 (DE3) strain from a glycerol stock onto a Luria Bertani (LB) agar plate and incubate for at least 15 h at 37 °C.
  2. Prepare an overnight preculture by inoculating a single colony from the freshly prepared LB plate into a 50 mL flask of Luria Bertani (LB) medium.
  3. Inoculate 5 mL of preculture into 500 mL of 2xYTPG medium in a 3 L baffled Erlenmeyer flask. Grow it at 37 °C with vigorous shaking (between 220 rpm and 250 rpm) and harvest the cells when they reach the mid-log phase (OD600 ~ 3). Then, place the cell cultures in cold icy water for 10 min and centrifuge at 8,000 × g for 15 min at 4 °C.
    NOTE: In this step, the glucose in 2xYTPG medium can be omitted for specific applications9,12.
  4. Resuspend the resulting cell pellets in 35 mL of prechilled S30 buffer A, followed by centrifugation at 8,000 × g for 15 min at 4 °C. Discard the supernatant.
  5. Repeat step 1.4 twice.
    NOTE: The cell pellets can be stored at -80 °C if not used immediately.
  6. Resuspend the final pellets in S30 buffer B (e.g., use 1.1 mL of S30 buffer B per 1 g of cell pellet) and disrupt the cells by one pass through French Press at 17,000 psi.
    1. For using the French Press, follow the user manual and transfer the cell suspension to the French press metal disruption chamber, ensuring that all components are assembled and the bottom valve of the disruption chamber is closed.
    2. Transfer the assembled disruption chamber to the hydraulic platform and secure the safety lock.
    3. Turn on the hydraulic pump and start the disruption.
    4. Control the outlet valve to enable the cell suspension to flow out of the outlet tube into a new 50 mL tube. Adjust the flow speed to ensure efficient disruption, ideally one drop at a time. Maintain the pressure above the lower limit of 15,000 psi.
  7. Centrifuge the resulting lysate at 30,000 × g for 30 min at 4 °C and collect the supernatant. Repeat the centrifugation once and collect the supernatant. Add 0.3 volume of preincubation buffer into the collected supernatant and incubate with gentle shaking at 37 °C for 80 min.
    NOTE: The use of preincubation buffer could increase the final yield though it has been reported that an empty run-off (without preincubation buffer) could also improve the efficiency37,38, which depends on the corresponding source strain.
  8. Dialyze the resulting run off mixture for 2 h against 2 L of S30 buffer C, exchange the dialysis buffer once with 2 L of fresh S30 buffer C, and dialyze overnight at 4 °C39.
    NOTE: The second step of overnight dialysis can be shortened to approximately 3 h.
  9. Collect the dialyzed sample and centrifuge at 30,000 × g for 30 min at 4 °C. Collect the supernatant and aliquot into appropriate volumes and flash freeze immediately in liquid nitrogen.
    NOTE: The frozen sample can be stored at -80 °C at least for 6 months to 1 year without loss of efficiency.

2. T7 RNA polymerase

  1. Transform pAR1219 plasmid into BL21(DE3) star E. coli competent cells40.
  2. Inoculate 10 mL of an overnight culture into 1 L of LB medium (containing 100 µg/mL ampicillin). Grow the cells at 37 °C until OD600 reaches 0.6-0.8.
  3. Start the induction by adding a final concentration of 1 mM IPTG. Induce the cells for an additional 5 h and harvest by centrifugation at 8,000 × g for 15 min at 4 °C. Store the cell pellets at -80 °C for up to several weeks.
  4. Resuspend the cell pellets in 30 mL of T7 buffer A and disrupt the cells by one pass through the French Press at 15,000 psi. Remove the cell debris by centrifugation at 20,000 × g for 30 min at 4 °C.
  5. Add streptomycin sulfate drop by drop to the supernatant from the previous step, reaching a final concentration of 4% (w/v). After a short incubation on ice, centrifuge at 20,000 × g for 30 min at 4 °C.
  6. Filter the supernatant through a 0.45 µm filter membrane and load the filtered sample onto a strong anion exchange column (column volume of 40 mL), which was preequilibrated with 10 column volumes of T7 buffer B, via an automated liquid chromatograph system.
  7. Wash the loaded column with 50 column volumes of T7 buffer B and elute the sample with 10 column volumes of low salt (50 mM NaCl) and high salt (500 mM) T7 buffer C mixtures, establishing a linear concentration gradient of NaCl from 50 to 500 mM at a flow rate of ~3 mL/min41.
  8. Collect the peak fractions and analyze by SDS-PAGE.
    NOTE: T7 polymerase exhibits a predominate band at ~100 kDa, while significant amounts of impurities still appear on the SDS-PAGE gel.
  9. Pool the fractions containing T7 polymerase and dialyze against 2 L of T7 buffer C overnight.
  10. Add glycerol to reach a final concentration of 10% and concentrate the resulting mixture to a final concentration of 3-4 mg/mL by ultrafiltration42.
    NOTE: If precipitation appears during the concentration process, stop immediately and remove the precipitates by centrifugation.
  11. Adjust the glycerol concentration to 50%. Aliquot and flash freeze the sample with liquid nitrogen. Store at −80 °C for a longer period.
    NOTE: A small aliquot could also be stored at -20 °C for at least 1 month without loss of efficiency.

3. Buffer preparation

  1. Prepare buffers as indicated in Table 1 a day before usage.

4. Template design and preparation

  1. Clone the gene of interest into a T7 promoter-based vector or generate a linear PCR product containing the gene of interest.
    NOTE: See the discussion section for design principles.
  2. Prepare the plasmid from an overnight culture using a plasmid extraction kit.
    NOTE: We recommend selecting a plasmid kit that includes an isopropanol precipitation step followed by a washing procedure with 70% ethanol.
  3. Dissolve the dried DNA in a small volume of ultrapure water to a concentration between 200 µg/mL and 500 µg/mL, as determined by a micro volume spectrophotometer.
  4. Optional: Directly express proteins from linear PCR products.
    NOTE: In this case, a PCR purification step is needed.

5. Mg2+ and K+ optimization

  1. Prepare a master mix for Mg2+ concentration screening as indicated in Table 2, or for K+ concentration screening as indicated in Table 3.
  2. Transfer the master mix into individual microfuge tubes or a V-shaped 96-well plate.
  3. Pipette the exact volume of Mg2+ or K+ stock solutions into individual microfuge tubes or the V-shaped 96-well plate and complete the CFPS reactions with ultrapure water. Incubate the reactions for at least 2 h.
    NOTE: If using a V-shaped 96-well plate, seal the plate with a plastic cover to prevent evaporation.
  4. Take out 2 µL of the reaction mixture and transfer into a black 96-well plate for fluorescence measurements by a plate reader.
    NOTE: We use a fluorescent plate reader with the following setup: excitation/emission: 485/528, Gain: 50, Read height: 7.00 mm. However, one would need to tune their plate reader to generate a specific calibration curve using purified fluorescent proteins.

6. Encapsulation

  1. Droplet
    1. Prepare a surfactant-containing fluorinated oil (2% PFPE-PEG in HFE7500) or a lipid-mineral oil solution by dissolving lipid in mineral oil (refer to step 6.2.1)
    2. Prepare a total volume of 100 µL of CFPS reaction by combining the corresponding reagents 2-18 from Table 4. Add CFPS reaction to 500 µL of the previously prepared oil in a 1.5 mL tube and then, rub the tube vigorously on the tube rack 50x to form fine (water-in-oil) droplets. Incubate the tube at 30 °C to perform the reaction.
      NOTE: Simple microfluidics chips could also be used to generate homogenous droplets as well43.
  2. Giant unilamellar vesicles (GUVs)
    1. Preparing the lipid-mineral oil solution
      1. Add 57 µL of chloroform into a 4 mL glass vial and then add 18 µL of 25 mg/mL 1-palmitoyl-2-oleoyl-glycerol-3-phosphocholine (POPC) lipids to form the chloroform lipid solution, achieving a final concentration of 8 mM (use other lipids with similar final concentrations).
        NOTE: This mixing step was to ensure homogeneous mixing of different lipids.
      2. Evaporate the chloroform under an argon flow for 15 min, and then, further evaporate under vacuum for 1 h.
      3. Dissolve the resulting dry lipids in 1,500 µL of mineral oil, reaching a final concentration of 400 µM. Incubate the mixture overnight at room temperature.
    2. Forming an interfacial lipid layer
      1. Add 500 µL of the outer solution (see Table 5) to a 1.5 mL tube, and slowly layer 250 µL of lipid-mineral oil solution on top of the outer solution. Incubate at room temperature for 30 min to form a stable interfacial lipid layer.
    3. Preparation of the inner solution
      1. Mix all the reagents in Table 6 to form the preinner solution and keep it on ice until use. Complete the inner solution by adding T7RNAP, S30 extract, and DNA template into the preinner solution as reagents 16-18 listed in Table 4.
        NOTE: Increasing encapsulated sucrose concentration above 250 mM might inhibit cell-free translation44.
    4. Formation of GUVs
      1. Add 50 µL of inner solution to a 1.5 mL new tube containing 500 µL of lipid-mineral oil, pipette up and down rapidly, and vortex vigorously.
      2. Leave the tube on ice for 10 min and slowly add 20 µL of the emulsion mixture to the top of the oil phase in the 1.5 mL tube from step 6.2.2.
      3. Centrifuge at 800 × g (use a centrifugation speed ranging from 100 × g to 1000 × g) for 10 min at 4 °C and observe the formation of GUVs at the bottom of the tube.
        NOTE: A higher specific centrifugation speed could be used; however, one would consider that the centrifugation speed could influence the size of formed GUVs45.
      4. Remove the upper oil phase.
      5. Aspirate 30 µL of GUVs at the bottom of the tube carefully. Incubate the collected GUVs at 30 °C.
        NOTE: The optimal incubation temperature varies for different proteins.
      6. Use Confocal Laser Scanning Microscopy (LSM) to monitor the expression of fluorescent proteins.
  3. Supported lipid bilayer (SLB)
    1. Preparation of SLB chambers
      1. Piranha-clean 24 x 24 mm #1.5 coverslips by adding seven drops of sulfuric acid and two drops of 50% hydrogen peroxide to the center of each cover slide. Incubate the reactants on the coverslips for at least 45 min; rinse thoroughly with ultrapure water.
      2. Assemble the reconstitution chamber by attaching a cut 0.5 mL microfuge tube onto the cleaned coverslips using optical glue cured under an ultraviolet lamp (365 nm) for 10 min to form a reaction chamber.
    2. SLB formation
      1. Dissolve 80 mol% 1,2-dioleoyl-sn-glycerol-3-phosphocholine (DOPC), 19.95 mol% 1,2-dioleoyl-sn-glycerol-3-phospho-L-serine (DOPS), and 0.05 mol% Atto488-DOPE (1,2-dioleoyl-sn-glycero-3-phosphoethanolamine = DOPE), mix in chloroform, dry under mild nitrogen flow and vacuum for 1 h to remove the solvent completely.
      2. Rehydrate the dried lipid film in SLB buffer A, resulting in a final lipid concentration of 4 mg/mL.
      3. Vortex and sonicate the resulting samples until they become clear.
      4. Dilute 4 mg/mL of SUVs with 130 µL of SLB buffer A, transfer 75 µL of the suspension to the preformed reaction chambers, and incubate it on a heat block at 37 °C for 1 min. Add 150 µL of SLB buffer A to the reaction chamber for further incubation for 2 min.
      5. Wash the chamber with 2 mL of SLB buffer B (SLB buffer A without MgCl2) prior to a buffer exchange to the S30 buffer C with 0.4% (w/v) BSA for CFPS reactions, leaving 100 µL of buffer inside the chamber to prevent the formed SLB from drying out.
      6. Remove the residual S30 buffer C and add the CFPS reaction mixture into the SLB chamber carefully. Incubate the chamber at 30 °C and monitor the expression under a confocal laser scanning microscope.

Representative Results

For each new batch of cell extract and T7 RNA polymerase, it is recommended to perform a basic screening of both Mg2+ and K+ concentrations to ensure the optimal performance of the CFPS system. The fluorescence of superfolder GFP can serve as an indicator of the overall yield of the CFPS system under varying conditions, as illustrated in Figure 1A,B. Additionally, a parallel yield comparison of the CFPS system across different compartments is shown in Figure 1C, demonstrating consistent performance in encapsulated CFPS systems, albeit with a slight decrease in GUVs, potentially due to the influence of sucrose46. Furthermore, CFPS reactions were successfully encapsulated in droplets (Figure 2), GUVs (Figure 3), and atop SLBs (Figure 4).

Figure 2A highlights the formation of emulsion droplets, evident when the oil solution became turbulent. The expression of green/red fluorescent proteins (GFP and mCherry) was captured using a confocal laser scanning microscopy. Figure 3 showcased the success of the encapsulation of CFPS reaction within GUVs through the simple emulsion transfer process. The red channel indicated the labeled lipids; the green channel showed the expression of superfolder GFP; and the yellow channel represented an inert fluorescent dye. Figure 4A shows the SLB chamber where the CFPS reaction could be deposited. Within this chamber, an SLB was formed on top of the glass coverslip, with the CFPS reaction mixture placed atop the preformed SLB, enabling imaging via a confocal laser scanning microscopy. As indicated in Figure 4B, SLB was visualized by labeled lipids, shown in green, while the expressed small GTPase Cdc42 fused with mCherry was shown in magenta. The in-situ expression of mCherry-Cdc42 was observable, along with the reversible membrane targeting process, under the microscope. However, the CFPS system utilized was supplemented with prenylation machinery, as detailed in a recent publication47.

Figure 1
Figure 1: Optimization and comparison of the CFPS system. Screening of (A) Mg2+ concentration and (B) K+ concentrations for the CFPS system in bulk. (C) A bar chart showing protein expression yields in different compartments. The fluorescence of superfolder GFP was used to determine the yield of the CFPS system, measured by a plate reader or a confocal laser scanning microscope. Abbreviations: CFPS = cell-free protein synthesis; GFP = green fluorescent protein; sfGFP = superfolder GFP; GUV = giant unilamellar vesicle; SLB = supported lipid bilayer. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Cell-free protein synthesis in droplets. (A) A photo of encapsulated CFPS reactions in surfactant-stabilized water-in-oil droplets. (B) Brightfield and (C,D) fluorescence images of CFPS of (C) mCherry and (D) superfolder GFP encapsulated in droplets visualized by confocal laser scanning microscopy. Superfolder GFP is indicated in green; mCherry is indicated in magenta. Scale bars = 20 µm. Abbreviations: CFPS = cell-free protein synthesis; GFP = green fluorescent protein. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Cell-free protein synthesis in GUVs. (A) A photo of encapsulated CFPS reactions in GUVs. (BD) Fluorescence image of encapsulated CFPS within POPC GUVs, expressing superfolder GFP. (B) The lipid bilayer was labeled with 0.05% labeled Atto647N-DOPE lipids, shown in red, (C) an inert dye shown in yellow, and (D) superfolder GFP was indicated in green. Scale bars = 20 µm. Abbreviations: CFPS = cell-free protein synthesis; GFP = green fluorescent protein; GUV = giant unilamellar vesicle; POPC = 1-palmitoyl-2-oleoyl-glycerol-3-phosphocholine; DOPE = 1,2-dioleoyl-sn-glycero-3-phosphoethanolamine. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Cell-free protein synthesis of small GTPase protein-Cdc42 on top of SLBs. (A) Schematic illustration of the reconstitution of Cdc42's membrane targeting and RhoGDI-dependent membrane extraction on SLBs, as visualized by confocal laser scanning microscopy. The prenylation machinery was implemented via a prenlytransferase-enriched extract, which is detailed described elsewhere.47. (B) An orthogonal view of the pre- and postprenylation of the reaction mixture on top of SLB. (C,D) Time series of mCherry-Cdc42 intensity on the membrane (pink) and in solution (black) during (C) membrane targeting and (D) membrane extraction. Scale bars = 10 µm. (AD) were adapted from Kai et al.47. Please click here to view a larger version of this figure.

Table 1: List of buffers. NOTE: Add β-mercaptoethanol and DTT just before use. Please click here to download this Table.

Table 2: Pipetting scheme for Mg2+ concentration screening. Please click here to download this Table.

Table 3: Pipetting scheme for K+ concentration screening. Please click here to download this Table.

Table 4: Inner-solution composition. Please click here to download this Table.

Table 5: Outer solution composition. Please click here to download this Table.

Table 6: Preinner solution composition. Please click here to download this Table.

Discussion

This manuscript outlines a modified Cell-Free Protein Synthesis (CFPS) system designed for use in various micro-compartments across synthetic cell platforms, including water-in-oil droplets, GUVs, and SLBs. We utilized the standard E. coli recombinant protein expression host strain, BL21(DE3), as the source extract for constructing protein-centric synthetic cell systems. This approach yielded approximately 0.5 mg/mL of protein across different compartments. While other customized extract source strains could be used, these systems have been primarily optimized for a specific type of protein or metabolic activity, which may be suboptimal for general protein expression. Recent advancements in quantitative mass spectrometry analysis have facilitated pilot studies on the proteomic analysis of cell lysate48,49, particularly under various preparation conditions.

Despite gaining insights from these studies, establishing a quantitative correlation between these identified protein factors and the overall performance of CFPS systems remains challenging. This gap left unanswered questions about how to quantitatively assess the performance of a given batch of extract. Additionally, there has been no systematic and parallel comparison of different source strains reported. In this study, we utilized 2xYPTG medium to boost biomass production, a strategy recommended to transition to 2xYPT when utilizing endogenous RNA polymerase for transcription. Despite suggestions that T7 polymerase could be integrated into the extract preparation procedure45, we opted for a separate preparation protocol for S30 extract and T7 RNA polymerase to reduce high batch-to-batch variations.

The production of target protein is intrinsically linked to the central transcription/translation process. Proper template design and purity are crucial for successful cell-free expression. In addition to the plasmid template, linear double-stranded DNA generated by PCR can also be employed, offering suitability for screening and high-throughput applications. Unlike conventional template design for in vivo expression in E. coli, template design in the E. coli cell-free system is simplified without the need for expression induction considerations. The only essential element of a cell-free expression template is a T7 regulatory sequence. However, in some instances, the 5' sequence of the target gene could influence the translation initiation, depending on the secondary structure formed by the corresponding transcribed mRNA. If the ribosome-binding site is located within a stable stem loop of the transcribed mRNA, translation initiation could be significantly hindered, leading to poor overall expression. Similarly, consecutive rare codons can hinder expression and should be optimized, similar to in vivo studies. This can be achieved through open-source servers dedicated to codon optimization50 and mRNA secondary structure prediction51.

Regarding the buffer system, we utilized an acetate buffer supplemented with creatine phosphate and creatine kinase as the sources of energy regeneration in our experimental setup. This setup yielded a moderate expression level and a relatively fast kinetic, attributable to the single-step energy regeneration reaction catalyzed by creatine kinase using creatine phosphate. While some researchers have shifted to a glutamate buffer system, citing its closer resemblance to the cellular environment52, we observed no significant differences in protein expression yields with our current protocols. However, recent proteomic analysis indicated that different buffer systems in combination with extract processing methods could influence the final expression yield19. Concerning energy precursors, diverse substrates have been investigated by numerous research groups to achieve cost-effectiveness and heightened expression yields53,54. In the context of the presented CFPS system, creatine phosphate and creatine kinase were deliberately chosen. This selection was motivated by the efficiency of energy regeneration achievable through a single-step reaction and the absence of interference with endogenous enzymes inherited from the extract. Consequently, this configuration establishes a straightforward yet robust system well-suited for various micro-compartment environments.

As indicated in the represented results, we demonstrated successful protein expression in three distinct microcompartments: water-in-oil droplets stabilized by semi-fluorinated oil, GUVs formed through emulsion transfer, and atop a supported lipid bilayer. The versatility of protein expression across different micro-compartments highlights the robustness of our CFPS system for synthetic cell construction. Among these encapsulation methods, the emulsion droplet technique was a notably straightforward approach for encapsulating the CFPS system, requiring only agitation or vortexing. However, these droplets tend to be unstable due to precarious water interface, a limitation that could be addressed by adding lipids or surfactants into the oil phase. Despite the practicality of stabilized water-in-oil droplets, they do not fully replicate the natural cell environment, which consists of two aqueous compartments separated by a cell membrane. Instead of droplets, giant unilamellar vesicles (GUVs) with sizes exceeding 1 micron were established to mimic cells more closely. The CFPS system was encapsulated within the lipid bilayer of these vesicles, furnishing transcription and translation machinery for diverse synthetic cell systems55.

Emulsion transfer, also known as double emulsion, stands out as the typical technique for encapsulating CFPS reactions, owing to its mild preparation process and relatively high encapsulation efficiency compared to solvent-free methods. However, the generation of double emulsion vesicles can range from simple centrifugation steps to the use of microfluidic-assisted emulsion transfer, each method with its associated advantages and disadvantages, as summarized elsewhere36. The successful encapsulation of the CFPS system within GUVs relies on tuning osmolarity and applying the proper force to traverse the oil-water interface. Although the emulsion transfer method described here is the most straightforward and requires no specific lab equipment, the efficiency and homogeneity of generated GUVs could vary between different batches. Moreover, all emulsion transfer methods must deal with residual oil in the lumen of the formed bilayer interface, necessitating an additional oil removal step56, which may pose challenges in kinetic projects.

Finally, we have shown the successful expression of CFPS atop a Supported Lipid Bilayer (SLB), offering a valuable approach for projects requiring protein synthesis in proximity to the lipid biomembrane environment. Through the utilization of the presented CFPS system, we have demonstrated its successful application in characterizing the reversible membrane targeting process of Cdc4247, a central protein molecule crucial for cellular polarity. In summary, the consistent medium expression yields and inherent robustness observed in various micro-compartments highlight the potential of this CFPS system in the construction of diverse synthetic cell systems. This capability can be further extended to include various protein-centered models, ultimately advancing towards the realization of minimal cells.

開示

The authors have nothing to disclose.

Acknowledgements

M. Y. acknowledges the funding from the Postgraduate Research & Practice Innovation Program of Jiangsu Province, China (Grant No. KYCX22_2803). L.K. is thankful for the support of the Natural Science Research of Jiangsu Higher Education Institutions of China, China (Grant No. 17KJB180003), the Natural Science Foundation of Jiangsu Normal University, China (Grant No. 17XLR037), Priority Academic Program Development of Jiangsu Higher Education Institutions, China, and the Jiangsu Specially-Appointed Professor program, China.

Materials

1,2-dioleoyl-sn-glycero-3-phosphocholine(DOPC) Avanti 850375P
1,2-dioleoyl-sn-glycero-3-phospho-L-serine (sodium salt)(DOPS) Avanti 840035P
1,4 dithiothreitol (DTT) Sigma-Aldrich 1.11474
1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) Avanti 850457P
3,5-cyclic AMP (cAMP) Sigma-Aldrich A9501
50 mL tubes Eppendorf Eppendorf Tubes BioBased
50% hydrogen peroxide Sigma-Aldrich 516813
Acetate Sigma-Aldrich A6283
Agar powder Sigma-Aldrich 05040
Alanin Sigma-Aldrich A4349
Amicon Stirred Cells MerckMillipore UFSC05001
Ammonium acetate (NH4OAc) Sigma-Aldrich A7262
Arginin Sigma-Aldrich A4474
Asparagin Sigma-Aldrich A0884
Aspartat Sigma-Aldrich A5474
ATP Roche 11140965001
Atto 488 DOPE Sigma-Aldrich 67335
Atto 647N DOPE Sigma-Aldrich 42247
Baffled Erlenmeyer flask Shuniu 250 mL, 1000mL
Bovine Serum Albumin(BSA) Roche 10711454001
Centrifugetube Eppendorf Eppendorf Tubes 3810X
Centrifugetube rack Eppendorf 0030119819
Chemiluminescence and epifluorescence imaging system Uvitec Alliance Q9 Advanced
Chloroform Sigma-Aldrich 288306
Confocal Laser Scanning Microscopy (LSM) ZEISS LSM 780
Countess Cell Counting Chamber Slides Thermo Fisher Scientific C10283
Coverslip Thermo Scientific Menzel BB02400500A113MNZ0
creatine kinase (CK) Roche 10127566001
Creatine phosphate (CP) Sigma-Aldrich 10621714001
Culture dish Huanqiu 90 mm
Cystein Sigma-Aldrich C5360
Cytidine 5'-triphosphate disodium salt (CTP) aladdin C101487
Dialysis membrane Spectrum Standard RC Tubing MWCO: 12-14 kD
E.Z.N.A. Cycle Pure Kit Omega Bio-Tek D6492-01
Electro-Heating Standing-Temperature Cultivator Yiheng instrument DHP-9602
Ethylenediaminetetraacetic acid(EDTA) Biosharp 1100027
Fluorescent plate reader BioTek Synergy 2
Fluorinated oil Suzhou CChip scientific instrument 2%HFE7500
Folinic acid Sigma-Aldrich 47612
French Press G.Heinemann HTU-DIGI-Press
Glucose Sigma-Aldrich G7021
Glutamat Sigma-Aldrich G5667
Glutamin Sigma-Aldrich G5792
Glycerol Sigma-Aldrich G5516
Glycin Sigma-Aldrich G7126
Guanosine 5'-triphosphate sodium salt hydrate(GTP) Roche 10106399001
HEPES Sigma-Aldrich H3375
HiPrep Q FF 16/10 Cytiva 28936543
Histidin Sigma-Aldrich H6034
Isoleucin Sigma-Aldrich I5281
Isopropyl-β-D-thiogalactopyranoside (IPTG) Sigma-Aldrich I5502
K2HPO4 Sigma-Aldrich P8281
KH2PO4 Sigma-Aldrich P5655
Leucin Sigma-Aldrich L6914
Lysin Sigma-Aldrich L5501
Magnesium acetate tetrahydrate (Mg(OAc)2 ) Sigma-Aldrich M5661
Magnesium chloride(MgCl2) Sigma-Aldrich M2670
Methionin Sigma-Aldrich M8439
Microcentrifuge Eppendorf 5424 R
Mineral oil Sigma-Aldrich M5904
Mini-PROTEAN Tetra Cell Systems Bio-Rad 1645050
Multipurpose Centrifuge Eppendorf 5810 R
NaN3 Sigma-Aldrich S2002
Nucleic Acid & Protein UV-Assay Measurements IMPLEN NanoPhotometer N60
NucleoBond Xtra Maxi kit for transfection-grade plasmid DNA MACHEREY-NAGEL 740414.5
Nunc-Immuno MicroWell 96 well polystyrene plates Sigma-Aldrich P8616
PCR Thermal Cycler Eppendorf Mastercycler nexus
Peptone Sigma-Aldrich 83059
Phenylalanin Sigma-Aldrich P8740
Phosphoenolpyruvat (PEP) GLPBIO GC44635
PMSF Sigma-Aldrich PMSF-RO
Polyethylene glycol 8000 (PEG 8000) Sigma-Aldrich 89510
Potassium Acetate(KOAc) Sigma-Aldrich P5708
Potassium chloride(KCl) Sigma-Aldrich P9541
Potassium glutamate (K-glutamate) Sigma-Aldrich G1501
Potassium hydroxide(KOH) Sigma-Aldrich 221473
Prolin Sigma-Aldrich P8865
Pyruvate kinase (PK) Sigma-Aldrich P9136
Serin Sigma-Aldrich S4311
Shaker Zhichushakers ZQZY-AF8
Sodium chloride(NaCl) Sigma-Aldrich S5886
Sodium hydroxide(NaOH) Sigma-Aldrich S5881
Sucrose aladdin S112226
Sulfuric acid Sigma-Aldrich 339741
Syringe Filters Jinteng 0.45 μm
Test tube Shuniu 20 mL
TGX FastCast Acrylamide Kit, 12% Bio-Rad #1610175
ThermoMixer Eppendorf ThermoMixer C
Threonin Sigma-Aldrich T8441
Tris base Sigma-Aldrich V900483
tRNA Roche 10109550001
Tryptone Sigma-Aldrich T7293
Tryptophan Sigma-Aldrich T8941
Tyrosin Sigma-Aldrich T8566
UTP Trisodium salt (UTP) aladdin U100365
Vacuum Pump with Circulated Water System Zhengzhou Greatwall Scientific Industrial and Trade Co.Ltd SHB-Equation 1
Valin Sigma-Aldrich V4638
Vortex Mixers Kylin-Bell Vortex QL-861
Water purification system MerckMillipore Direct ultrapure water (Type 1)
Yeast extract Sigma-Aldrich 70161
β-mercaptoethanol Sigma-Aldrich 444203

参考文献

  1. Elani, Y. Interfacing living and synthetic cells as an emerging frontier in synthetic biology. Angew Chem Int Ed Engl. 60 (11), 5602-5611 (2021).
  2. Cho, E., Lu, Y. Compartmentalizing cell-free systems: toward creating life-like artificial cells and beyond. ACS Synth Biol. 9 (11), 2881-2901 (2020).
  3. Silverman, A. D., Karim, A. S., Jewett, M. C. Cell-free gene expression: an expanded repertoire of applications. Nat Rev Genet. 21 (3), 151-170 (2020).
  4. Zhang, L., Guo, W., Lu, Y. Advances in cell-free biosensors: principle, mechanism, and applications. Biotechnol J. 15 (9), e2000187 (2020).
  5. Lu, Y., Allegri, G., Huskens, J. Vesicle-based artificial cells: materials, construction methods and applications. Mater Horiz. 9 (3), 892-907 (2022).
  6. Fu, Z., Ochsner, M. A., De Hoog, H. P., Tomczak, N., Nallani, M. Multicompartmentalized polymersomes for selective encapsulation of biomacromolecules. Chem Commun (Camb). 47 (10), 2862-2864 (2011).
  7. Ayoubi-Joshaghani, M. H., et al. Cell-free protein synthesis: the transition from batch reactions to minimal cells and microfluidic devices. Biotechnol Bioeng. 117 (4), 1204-1229 (2020).
  8. Yue, K., Chen, J. Y., Li, Y. Q., Kai, L. Advancing synthetic biology through cell-free protein synthesis. Comput Struct Biotechnol J. 21, 2899-2908 (2023).
  9. Kwon, Y. C., Jewett, M. C. High-throughput preparation methods of crude extract for robust cell-free protein synthesis. Sci Rep. 5, 8663 (2015).
  10. Shimizu, Y., et al. Cell-free translation reconstituted with purified components. Nat Biotechnol. 19 (8), 751-755 (2001).
  11. Schwarz, D., et al. Preparative scale expression of membrane proteins in Escherichia coli-based continuous exchange cell-free systems. Nat Protoc. 2 (11), 2945-2957 (2007).
  12. Levine, M. Z., Gregorio, N. E., Jewett, M. C., Watts, K. R., Oza, J. P. Escherichia coli-based cell-free protein synthesis: protocols for a robust, flexible, and accessible platform technology. J Vis Exp. (144), e58882 (2019).
  13. Cole, S. D., Miklos, A. E., Chiao, A. C., Sun, Z. Z., Lux, M. W. Methodologies for preparation of prokaryotic extracts for cell-free expression systems. Synth Syst Biotechnol. 5 (4), 252-267 (2020).
  14. Shin, J., Noireaux, V. Efficient cell-free expression with the endogenous E. coli RNA polymerase and sigma factor 70. J Biol Eng. 4, 8 (2010).
  15. Mcmanus, J. B., Emanuel, P. A., Murray, R. M., Lux, M. W. A method for cost-effective and rapid characterization of engineered T7-based transcription factors by cell-free protein synthesis reveals insights into the regulation of T7 RNA polymerase-driven expression. Arch Biochem Biophys. 674, 108045 (2019).
  16. Kim, T. W., et al. Prolonged cell-free protein synthesis using dual energy sources: combined use of creatine phosphate and glucose for the efficient supply of ATP and retarded accumulation of phosphate. Biotechnol Bioeng. 97 (6), 1510-1515 (2007).
  17. Kim, D. M., Swartz, J. R. Regeneration of adenosine triphosphate from glycolytic intermediates for cell-free protein synthesis. Biotechnol Bioeng. 74 (4), 309-316 (2001).
  18. Liu, Y., Fritz, B. R., Anderson, M. J., Schoborg, J. A., Jewett, M. C. Characterizing and alleviating substrate limitations for improved in vitro ribosome construction. ACS Synth Biol. 4 (4), 454-462 (2015).
  19. Rasor, B. J., et al. Mechanistic insights into cell-free gene expression through an integrated-omics analysis of extract processing methods. ACS Synth Biol. 12 (2), 405-418 (2023).
  20. Kim, D. M., Kigawa, T., Choi, C. Y., Yokoyama, S. A highly efficient cell-free protein synthesis system from Escherichia coli. Eur J Biochem. 239 (3), 881-886 (1996).
  21. Li, J. J., Li, P. X., Liu, Q., Li, J. J., Qi, H. Translation initiation consistency between in vivo and in vitro bacterial protein expression systems. Front Bioeng Biotechnol. 11, 1201580 (2023).
  22. Shrestha, P., Holland, T. M., Bundy, B. C. Streamlined extract preparation for Escherichia coli-based cell-free protein synthesis by sonication or bead vortex mixing. Biotechniques. 53 (3), 163-174 (2012).
  23. Sun, Z. Z., et al. Protocols for implementing an Escherichia coli based tx-tl cell-free expression system for synthetic biology. J Vis Exp. (79), e50762 (2013).
  24. Zubay, G. In vitro synthesis of protein in microbial systems. Annu Rev Genet. 7, 267-287 (1973).
  25. Jaroentomeechai, T., et al. Single-pot glycoprotein biosynthesis using a cell-free transcription-translation system enriched with glycosylation machinery. Nat Commun. 9 (1), 2686 (2018).
  26. Katsura, K., et al. Phosphorylated and non-phosphorylated HCK kinase domains produced by cell-free protein expression. Protein Expr Purif. 150, 92-99 (2018).
  27. Suzuki, T., et al. N-terminal protein modifications in an insect cell-free protein synthesis system and their identification by mass spectrometry. Proteomics. 6 (16), 4486-4495 (2006).
  28. Chi, H., Wang, X., Li, J., Ren, H., Huang, F. Chaperonin-enhanced Escherichia coli cell-free expression of functional CXCR4. J Biotechnol. 231, 193-200 (2016).
  29. Endo, Y., Sawasaki, T. High-throughput, genome-scale protein production method based on the wheat germ cell-free expression system. Biotechnol Adv. 21 (8), 695-713 (2003).
  30. Shin, J., Noireaux, V. An E. coli cell-free expression toolbox: Application to synthetic gene circuits and artificial cells. ACS Synth Biol. 1 (1), 29-41 (2012).
  31. Jewett, M. C., Swartz, J. R. Mimicking the Escherichia coli cytoplasmic environment activates long-lived and efficient cell-free protein synthesis. Biotechnol Bioeng. 86 (1), 19-26 (2004).
  32. Ryabova, L. A., Vinokurov, L. M., Shekhovtsova, E. A., Alakhov, Y. B., Spirin, A. S. Acetyl phosphate as an energy source for bacterial cell-free translation systems. Anal Biochem. 226 (1), 184-186 (1995).
  33. Guzman-Chavez, F., et al. Constructing cell-free expression systems for low-cost access. ACS Synth Biol. 11 (3), 1114-1128 (2022).
  34. Jewett, M. C., Swartz, J. R. Substrate replenishment extends protein synthesis with an in vitro translation system designed to mimic the cytoplasm. Biotechnol Bioeng. 87 (4), 465-472 (2004).
  35. Caschera, F., et al. High-throughput optimization cycle of a cell-free ribosome assembly and protein synthesis system. ACS Synth Biol. 7 (12), 2841-2853 (2018).
  36. Yue, K., et al. Bottom-up synthetic biology using cell-free protein synthesis. Adv Biochem Eng Biotechnol. 185, 1-20 (2023).
  37. Liu, D. V., Zawada, J. F., Swartz, J. R. Streamlining Escherichia coli S30 extract preparation for economical cell-free protein synthesis. Biotechnol Prog. 21 (2), 460-465 (2005).
  38. Kim, T. W., et al. Simple procedures for the construction of a robust and cost-effective cell-free protein synthesis system. J Biotechnol. 126 (4), 554-561 (2006).
  39. McPhie, P. [4] Dialysis. Methods Enzymol. 22, 23-32 (1971).
  40. Froger, A., Hall, J. E. Transformation of plasmid DNA into E. coli using the heat shock method. J Vis Exp. (6), e253 (2007).
  41. Kai, L., et al. Systems for the cell-free synthesis of proteins. Methods Mol Biol. 800, 201-225 (2012).
  42. Lobb, R. J., et al. Optimized exosome isolation protocol for cell culture supernatant and human plasma. J Extracell Vesicles. 4, 27031 (2015).
  43. Hori, Y., Kantak, C., Murray, R. M., Abate, A. R. Cell-free extract based optimization of biomolecular circuits with droplet microfluidics. Lab Chip. 17 (18), 3037-3042 (2017).
  44. Takahashi, H., Ogawa, A. Preparation of a millimeter-sized supergiant liposome that allows for efficient, eukaryotic cell-free translation in the interior by spontaneous emulsion transfer. ACS Synth Biol. 9 (7), 1608-1614 (2020).
  45. Adir, O., et al. Preparing protein producing synthetic cells using cell free bacterial extracts, liposomes and emulsion transfer. J Vis Exp. (158), e60829 (2020).
  46. Kai, L., Dotsch, V., Kaldenhoff, R., Bernhard, F. Artificial environments for the co-translational stabilization of cell-free expressed proteins. PLoS One. 8 (2), e56637 (2013).
  47. Kai, L., Sonal, H. T., Schwille, P. Reconstitution of a reversible membrane switch via prenylation by one-pot cell-free expression. ACS Synth Biol. 12 (1), 108-119 (2023).
  48. Foshag, D., et al. The E. Coli S30 lysate proteome: a prototype for cell-free protein production. N Biotechnol. 40, 245-260 (2018).
  49. Garenne, D., Beisel, C. L., Noireaux, V. Characterization of the all-E. coli transcription-translation system mytxtl by mass spectrometry. Rapid Commun Mass Spectrom. 33 (11), 1036-1048 (2019).
  50. Puigbo, P., Guzman, E., Romeu, A., Garcia-Vallve, S. Optimizer: A web server for optimizing the codon usage of DNA sequences. Nucleic Acids Res. 35, W126-W131 (2007).
  51. Wiegand, D. J., Lee, H. H., Ostrov, N., Church, G. M. Cell-free protein expression using the rapidly growing bacterium vibrio natriegens. J Vis Exp. (145), e59495 (2019).
  52. Calhoun, K. A., Swartz, J. R. An economical method for cell-free protein synthesis using glucose and nucleoside monophosphates. Biotechnol Prog. 21 (4), 1146-1153 (2005).
  53. Kim, D. M., Swartz, J. R. Prolonging cell-free protein synthesis with a novel ATP regeneration system. Biotechnol Bioeng. 66 (3), 180-188 (1999).
  54. Nishimura, K., et al. Cell-free protein synthesis inside giant unilamellar vesicles analyzed by flow cytometry. Langmuir. 28 (22), 8426-8432 (2012).
  55. Teh, S. Y., Khnouf, R., Fan, H., Lee, A. P. Stable, biocompatible lipid vesicle generation by solvent extraction-based droplet microfluidics. Biomicrofluidics. 5 (4), 044113 (2011).

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記事を引用
Cao, M., Yang, M., Li, Y., Yue, K., Shen, L., Kai, L. Cell-Free Protein Synthesis System for Building Synthetic Cells. J. Vis. Exp. (206), e66626, doi:10.3791/66626 (2024).

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