ABSTRACT
Feedback mechanisms play a critical role in the maintenance of cell homeostasis in the presence of disturbances and uncertainties. Motivated by the need to tune the dynamics and improve the robustness of synthetic gene circuits, biological engineers have proposed various designs that mimic natural molecular feedback control mechanisms. However, practical and predictable implementations have proved challenging because of the complexity of synthesis and analysis of complex biomolecular networks. Here, we analyze and experimentally validate a first synthetic biomolecular controller executed in vitro. The controller is based on the interaction between a sigma and an anti-sigma factor, which ensures that gene expression tracks an externally imposed reference level, and achieves this goal even in the presence of disturbances. Our design relies upon an analog of the well-known principle of integral feedback in control theory. We implement the controller in an Escherichia coli cell-free transcription-translation (TXTL) system, a platform that allows rapid prototyping and implementation. Modeling and theory guide experimental implementation of the controller with well-defined operational predictability.
INTRODUCTION
Robustness against perturbations and uncertainties is fundamental to biological systems that continuously sense and respond to their environment. At the cellular level, it is often desired to maintain precise control over a variety of molecular components and pathways to achieve complex behaviors that require the interaction of intracellular or extracellular biomolecules.1,2 This is often achieved by tightly regulating gene expression in such a way that it follows a desired set point independent of exogenous or endogenous disturbances. Feedback is a mechanism that enables organisms to achieve reliable and robust functionality.3–7 Feedback mechanisms underlie homeostasis, a phenomenon in which physiological variables are continuously monitored and adjusted so as to maintain a desired equilibrium value which is defined by a set point (also known as a reference signal), in the presence of biological noise that may perturb the natural state of the system.8–10
Reference tracking in the presence of disturbances, a classical objective in electrical and mechanical systems, is often solved by incorporating integral feedback to control a process (also known as a plant).11 In such a scheme, one wants a variable of interest (called the output) to track a signal (called the reference). This is achieved by incorporating in the controller the mathematical integration of the difference between the reference and the output (the error signal). The “internal model principle” in control theory states, in essence, that the existence of an integrator in the control loop is necessary for the tight regulation of the concentration of an output species in the presence of disturbances or stimuli.12 Inspired by these ideas from engineering and control theory, there have been several recent designs13–16 and implementations17–18 of biomolecular integral feedback controllers. These implementations are not completely satisfactory in that it is very difficult to make quantitative predictive models of their behaviors, in large part due to the biological noise which is found in cellular systems, which makes it hard to achieve precise control over model parameters, thereby complicating the design and feasibility of the system.19–21 Plasmid copy number is also limited by the origin of replication, decreasing the adjustability of experiments.22
In this work, we exploit the versatility of an all E. coli TXTL platform to prototype a biological controller circuit. TXTL reactions contain the native transcription, translation, and metabolic machineries23,24 required to achieve gene expression over at least ten hours. As opposed to a living host, in a TXTL reaction one can precisely set the concentrations and stoichiometries of DNA parts, and thus finely tune gene circuits easily. TXTL reactions are typically performed at the microliter scale or above, far from any biological noise, thus allowing flexibility in designing and optimizing the genetic network.25 Experimental disturbances, such as those perturbing the amount of DNA or other reaction components, can be carried out at any time. TXTL reactions are executed in high-throughput, facilitating the rapid characterization of dynamic circuits. By virtue of such advantages, several synthetic gene circuits have been implemented in TXTL with a successful modeling framework.26–29
In this article, we constructed a synthetic biomolecular integral controller that precisely controls the expression of a target gene. Our strategy relies on a molecular sequestration reaction that enables error computation between the reference and the output signal while exploiting the natural interaction between the E. coli sigma factor σ28 and the anti-σ28, FlgM.30 We demonstrate that the output is linearly proportional to the input, in other words, it tracks the reference signal, and this happens for a large dynamic range of input only in the closed-loop configuration (when the sequestration reaction is active). We develop an ordinary differential equation (ODE) model and perform systematic TXTL experiments to parameterize and validate the model. We then successfully predict the controller response in various reaction conditions using the parameterized model. When disturbances are added, only the closed-loop controller enables the output to reject the disturbances. Our results demonstrate that our synthetic biomolecular controller is capable of regulating gene expression robustly in an E. coli TXTL toolbox. We anticipate that such an approach could be useful for diagnostics applications,31 for constructing dynamical systems in vitro32 or for programming synthetic cell systems.33,34
RESULTS
Designing an integral feedback controller
Our primary goal is to construct a genetic network which can accurately regulate the expression of a target gene in such a manner that the concentration of a desired (“output”) protein follows a “reference” or input signal linearly, for a large dynamic range of input values. The output should remain at the same concentration when an unknown disturbance affects the system. These desired characteristics of the network should be maintained independently of changes in reference or input values.
In electrical and mechanical control systems, “integral feedback” controllers are routinely used in order to achieve reference tracking in the presence of perturbations and uncertainties. Motivated by this analogy, various possible designs of such controllers have been discussed substantially in the context of biological systems.13–16,26 The present work is inspired by our previous work,26 in which we introduced a computational design based on RNA based controllers; no experimental validation was provided. Here, we start from that design, modifying it to allow for direct genetic regulation and provide an experimental validation. In this approach, the goal of the controller is to ensure that the intermediate output Z follows the reference signal, which is a scaled value of input PX (Fig. 1a). To determine the deviation of the output from the reference signal, a comparison between both is required without affecting their activity. For that, PX and Z are sensed internally using biochemical reactions such that X and Y represent the input signal and the output signal, respectively. When the output is smaller than the reference signal, the error signal XFREE (X-Y) is detected, and this signal is used in order to correct deviations of the output from the reference signal. For a case when the output is larger than the reference signal, free Y sequesters X to reduce the output. One of the key reasons that this controller is able to improve substantially upon that in26 is that it implements an effective error computation through protein interactions; in contrast, RNA-based designs suffer from the fact that RNAs degrade much faster than proteins, making an effective error computation very hard to implement experimentally.35 In contrast, the degradation of the proteins used in this work can be ignored.
Our biomolecular implementation of an integral feedback controller requires three genes: an input gene x, under the promoter PX, an output gene z, under the promoter PZtot (the target gene) and a proxy gene y, under the promoter PYtot for the target gene (Fig. 1b). Genes x, y and z encode for respective proteins X, Y, and Z. Note that x, y and z have the same concentrations and correspond to the same biochemical species as PX, PYtot and PZtot respectively. The protein X acts as a transcriptional activator for promoters PYtot and PZtot. For Y to truly represent Z, it is necessary that the same promoter must be used to express Y and Z, therefore PYtot and PZtot are identical. An error computation is achieved through a molecular sequestration between X and Y such that when X binds to Y or vice versa, both proteins become biologically inactive (a phenomenon, also known as annihilation).13 Only free X (XFREE, not bound to Y) can activate transcription. It is also required that the synthesis of Y and Z should be overall regulated by XFREE. For that, basal expression from the genes y and z should be negligible so that in the absence of XFREE, the production of Y and Z is negligible. Here and elsewhere, the term “closed-loop configuration” means that the feedback is present through the sequestration reaction; otherwise, when the feedback mechanism is not present, the controller is referred to as in the “open-loop configuration”. We establish that reference tracking is only possible in the closed-loop case, where the output linearly depends on the concentration of PX (Fig. 1c). In the open-loop case, the output depends nonlinearly on the concentration of PX and PZtot. Because the error signal (XFREE) is mathematically integrated over time in the closed-loop case, the output should be able to follow the reference signal even when disturbances are added to the plant (Fig. 1a and c).
To test the controller experimentally in TXTL, we employed three plasmids (Fig. 1d): P70a-S28, expressing E. coli sigma factor 28 from a sigma 70 promoter; P28a-FlgM, expressing the antisigma 28 (FlgM) from a σ28 promoter; and P28a-deGFP, expressing the reporter deGFP from a σ28 promoter. In the open-loop controller, FlgM is replaced by mSA (same protein size), which is not sequestered by σ28, nor does it directly interact with any reaction rates. Here and elsewhere, for simplification, σ28, FlgM and immature deGFP are denoted as X, Y and Z, while promoters P70a and P28a are denoted as PX and PYtot (same as PZtot) respectively, and the mSA control gene is denoted as yc and the respective promoter as PYCtot.
The output tracks the input linearly in the closed-loop configuration
Our first goal was to establish that when the controller operates in the closed loop configuration, the output follows linearly the changes in the concentration of input PX, thus tracking the reference signal. A nonlinear dependence of the output on PX would suggest otherwise. To test this in TXTL reactions, we added 0.1-0.7 nM PX and 1 nM each of PZtot and either PYCtot for the open-loop operation (Fig 2a) or PYtot for the closed-loop operation (Fig 2b). In the open-loop case, we found that changes in the deGFP concentrations depend nonlinearly on the changes in the input concentration of PX (Fig. 2c), suggesting that the output is unable to track the reference signal over the tested range. In contrast, the closed-loop endpoint deGFP concentrations were linearly proportional to the concentration of PX (Fig.2d), suggesting reference tracking.
The output of the closed-loop controller should be able to follow the changes in input signal linearly independent of the time when it is modified. To test this capability, we performed a step change in the input PX concentration during the course of the reaction. For that, we added different amounts of PX to TXTL reactions in the open-loop (Fig. 2e) and closed-loop (Fig. 2f) system after four hours of incubation with 1 nM each of PZtot and either PYCtot or PYtot, respectively. As mentioned earlier, we observed that the controller’s output follows linearly the input only when operated in the closed-loop configuration (Fig. 2g and h). Note that the deGFP produced in the closed-loop configuration is much smaller than that produced in the open-loop configuration because the activator needed to express the deGFP is sequestered. As a control, we also tested that changes in the concentration of PYCtot have no effect on the output (Fig. S1), confirming that the different version of Y that is expressed by yc gene does not interact with X. We also found that in the absence of PX, deGFP is not produced (Fig. S2), confirming that the production of Y and Z are completely governed by X through the activation reaction.
These experimental observations agree with the expected controller operation. When X is larger than Y, (i.e. the output is lagging behind the reference), XFREE increases the production of Y and Z. As more Y is available in the reaction to sequester with X, X and Y converge to specific values that would allow Z to follow the reference signal. In the absence of the sequestration reaction, error computation is absent (no feedback) and so X directly regulates Z production without comparing with the reference signal.
Mathematical model and parameterization
To understand the controller operation, we developed a simple coarse-grained model that captures the dynamic response of the controller in both open and closed-loop configurations (Fig. 3a). For that, we consider the synthesis of each protein as a two-step reaction: a transcription reaction for mRNA synthesis and then a translation reaction for the corresponding protein synthesis. The parameters α and β are transcription and translation rates, respectively. Here and elsewhere, subscripts to the parameters indicate the corresponding species. Each mRNA species (U, V and W) has a degradation rate denoted as δ while we ignore the protein degradation rate.35 The parameter k is the sequestration rate. Transcriptional activation is modeled as a one-step reaction, where X binds to the promoters PY and PZ separately at a rate of ω and dissociates at a rate of v. In the activated state, these genes produce Y and Z proteins at an increased transcription rate, denoted as α+. Considering the mass-conservation, we assume that PYtot = PY + PY+ and PZtot = PZ + PZ+ at all times. An additional reaction is added into the model to account for the maturation of newly synthesized deGFP (Z) into a fluorescent deGFP (G),24,32 which is the read-out signal (Fig. 3a). Here onwards, fluorescent deGFP is referred as deGFP. From chemical reactions, we built an ODE model (shown in Fig. 3b) to determine the response of the controller over time.
An accurate representation of a system model requires determining specific parameter values at which the model quantitatively follows the system dynamics. However, parameter estimation can be nontrivial, as there can be multiple sets of parameter values that may vary by several orders of magnitude and could still fit the measured data. Therefore, to simplify the problem, we isolated the measured responses into two sets, in such a manner that we required fewer parameters to fit a particular set of experimental data. For this, we first found the model parameter values that provided the best fit to the measured open-loop response, since the number of parameters involved in the open loop case are less than in the closed-loop case (see Methods). We then used these parameter values to fit the closed-loop response while allowing only the remaining parameters to vary (see Methods). Moreover, we started the model fitting manually with an initial guess of parameters derived from the literature.23–29,35 Once we found the possible values that provide a qualitative agreement between the model and the measured response, we used an iterative least-squares fitting procedure to find a range of parameter values that gave us the best fit (see Methods). The means of the resulting parameters (Table 1) were then used along with the ODE model (Fig. 3b) to calculate the mean trajectories with 95% confidence intervals (Fig. 3c and d). Histograms of the input and estimated parameter distributions are shown in Fig. 3e.
To cross-validate the parameterized model, we predicted the deGFP response for two different settings of input conditions. In the first setting, the concentration of PX was increased from 0 nM to 0.1-0.7 nM (in a step manner) after 2 hours of incubation in the presence of initial 0.7 nM of PYtot and PZtot each (Fig. 4a, 4b and Fig. S3). In the second setting, the concentration of PY was varied from 0.2 nM to 1 nM at the beginning of the reaction while keeping the initial concentration of PX and PZ at 0.7 nM each (Fig. S4). In all the cases, the predicted responses followed the measured responses closely.
Model simplification
To get a better insight into the controller response, further simplification of the proposed model is required. Based on the extracted parameter values, we sought to minimize the number of variables in the model while still capturing the essential dynamics of the controller. From the extracted parameter values, we observed that the basal expression of y and z genes is almost negligible; therefore we set αv and αw to zero in the simplified model. As the transcriptional activation reaction is much faster than the other reactions involved in the reaction network, we used a quasi-steady state approximation to replace the ODEs of PY+ and PZ+ by their steady-state expressions (see SI Note 1). As the transcription reaction is much faster than the translation reaction, a similar approximation was used to model the synthesis of X and Z using single reactions for each, while keeping the two-step synthesis of Y to ensure that we consider an appropriate delay in the overall system dynamics. This leads to a simplified model (shown in Fig 4c), which can produce dynamic response similar to that of the original model (Fig. 4d, e, and Fig. S5).
We can now use the simplified model to determine analytically how the output depends on the reaction parameters and the input. In our implementation of the controller, the reporter protein deGFP (G) has no degradation tag, consequently we cannot observe a steady state behavior in the measured response. However, a linear dependence of the time derivative of G on Z (see Fig. 4c), suggests that when Z reaches a steady-state, G should increase at a constant rate over time (see Fig. S6). To determine this constant rate, we first used the simplified model to determine the steady state value of Z (see SI Note S1) and then we calculated the analytical solution of G over time, as shown in Fig. 4f. The output G increases at a constant rate that is the scaled value of the input PX and used as a reference signal.
Note that because of the quasi-steady state approximation (see SI Note S1), the analytical solution can only be used to determine the closed-loop controller response when all other reactions reached a steady-state. We then used the extracted parameters to calculate this constant rate and found that it closely matches the observed response shown in Fig. 2d, confirming that the controller output tracks the reference signal in the closed-loop configuration. Further insight into the controller operation can be gained by analyzing the simplified model to determine how the error signal is processed in the closed loop configuration of the controller. The analytical equation of XFREE clearly shows that the error signal (which is X-Y) is integrated mathematically by the controller (see SI Note S1).
Closed loop control enables disturbance rejection
One of the main theoretical advantages of integral feedback controllers is their ability to minimize the effect on the output of disturbances on the system.9 This is due to the effective error computation with an integral operation that allows the controller to maintain the desired output even when a disturbance affects the system. In the aforementioned section, we showed that the implemented controller can be interpreted as an integral feedback mechanism (see SI Note S1). Therefore, we expect that the closed-loop system is able to reject disturbances in an appropriate sense. To test this, we introduced disturbances in the concentration of the biochemical species PYtot and PZtot. In practical settings, variation in the DNA concentration is one of the most biologically relevant parameters. This is because in vivo gene concentration can vary significantly due to fluctuations in plasmid copy number,36 and several designs have been proposed in order to ameliorate the effect of copy number variation.37,38 Notably, the TXTL reaction platform allows us to design such an experiment, where DNA template concentrations can be changed at any time during the course of a reaction due to the TXTL reaction settings.
In this design, the reference signal is independent of the amount of y and z genes (in Fig. 4f) so that any disturbances in these species should not perturb the deGFP response when the controller is operating in the closed-loop configuration. To test this, we first used the ODE model (Fig. 3b) to predict the controller response in the open-loop and closed-loop configurations where the concentrations of PYtot and PZtot were varied from 0.2 to 0.7 nM, keeping a fixed 0.2 nM initial concentration of PX. We observed a less than 10% variation in the deGFP response for the closed-loop case, compared to over 300% variation in the open-loop case (Fig. S7). In the closed-loop operation, an increase in PYtot increases the amount of Y, but as more Y is available to sequester X, less XFREE is available to activate the production of Y and Z. Even though PZtot was increased, XFREE is reduced such that the reporter protein (G) remains the same, independently of the amount of PZtot (Fig. S8). For the open loop case, as there is no feedback, an increase in PZtot significantly increases the production of G (Fig. S9).
Encouraged by these results, we experimentally tested the same conditions in TXTL reactions. We added 0.2 nM PX and increasing concentrations of PYtot = PZtot, from 0.2 nM to 0.7 nM to reactions, and tracked the deGFP output over time for the open-loop (Fig 5a) and the closed-loop (Fig 5b) configurations. In the open-loop case, the output signal increased with the increasing concentration of PYCtot = PZtot due to the lack of feedback (Fig 5c). However, in the closed-loop case, the output signal was independent of the increasing PYtot = PZtot, thus confirming that the controller rejected the disturbance in their concentrations (Fig 5d), as predicted by integral feedback theory
Similarly to reference tracking, rejection of disturbances should be independent of the way that the disturbance is introduced in the system. To test this, we characterized the controller response to a step change in the concentrations of PYtot and PZtot as disturbances. We started the reaction with PX, PYCtot and PZtot concentrations each set to 0.2 nM, and after four hours of incubation, additional PYCtot and PZtot were added (see Methods) (Fig. 5e). For the closed-loop case, instead of PYCtot, PYtot was added in the same amounts (Fig. 5f). The output was not perturbed in the presence of the disturbances (Fig. 5g,h) only in the closed-loop case, as expected based on our understanding of the controller. We also tested the controller’s response for a wide range of disturbances when different initial concentrations of DNA were used, and the disturbance was added in different amounts (See Fig. S10, S11). In each case, we found a similar robust controller response in the closed-loop settings.
DISCUSSION
In this work, we constructed a synthetic biomolecular integral controller circuit for effective and robust control of gene expression. We demonstrated that in the closed-loop configuration, the output followed the input signal linearly over a wide range of conditions, even under step changes in input. By harnessing the natural interaction between the sigma factor σ28 and the anti-σ28, FlgM, a strong sequestration reaction is realized that allowed an effective computation of the error between the reference and the output signal. This error signal is then integrated mathematically. Because of this, and as predicted by theory, the closed-loop controller output rejects the disturbances introduced in the DNA concentration. In contrast, the open-loop controller is unable to reject the disturbances, as noticed by the large variations of the output signal. This illustrates the advantage of closed-loop architectures, where an error computation is employed.
Mathematical models play an important role in understanding complex synthetic networks. They provide insight into the operation of networks, and serve to guide experimentation. Here, we developed an ODE model for the integral controller that quantitatively explains the transient as well as the steady-state behavior of all the species involved in the system. We were able to obtain an effective model parameterization, by isolating parameters for each set of experimental data before finding their optimum values to achieve the best fit. Even though the presented model is a coarse-grained mechanistic model, it enabled us to explain the measured response of the controller, and can also predict dynamic trajectories for a wide range of operating conditions accurately. Based on the extracted parameter values, we derived a simplified version of the original model that is as effective as the original model and can be used for further theoretical analysis in order to gain deeper insight into the operation of the controller.
We have limited the model to the measured dynamic trajectories for up to 10 hours. Experimentally, after 10 hours, we observed effects of resource limitations (Fig. S12). We assume that the TXTL reactions have an unlimited source of energy for the first 10 hours in the range of plasmid concentrations used. After this point, we start to see a decrease of transcription and translation rates consistent with the depletion of energy resources and biochemical changes such as pH drop.24 The current ODE model assumes an unlimited energy source and therefore ignores the experimental results when that assumption no longer holds. Future work could incorporate resource competition and depletion. Because the controller was implemented in a TXTL reaction platform at the scale of a few microliters, a deterministic model was used while ignoring the biological noise. For in vivo applications, it may be desirable to extend the deterministic model to a stochastic model to consider intrinsic the biological noise.36 We used a molecular sequestration reaction to realize the error computation. This strategy has been used previously to design closed-loop biomolecular controllers for reference tracking and disturbance rejection.13–18 Although our design is a variation of those in,13,26 it differs from them in substantial ways in its biological instantiation. Our results are unique in the sense that we have a well-characterized controller that is realized in all E. coli TXTL system, where biological noise is negligible compared to in vivo implementations. In the latter, biological noise plays a dominant role in governing the system dynamics.18 Because of this, we can not only precisely regulate gene expression, but can also accurately predict the dynamic response of the integral controller. Our controller design, which uses a genetic network, can also be easily tailored to regulate any other gene of interest such as those involved in controlling metabolic rates, a task which might not be feasible using a post-transcriptional based controller.13 We also demonstrate disturbance rejection capabilities of our controller when a constant or a step disturbance is added to DNA concentration (PYtot and PZtot); disturbances in DNA concentration are realistic because they typically arise in in vivo or in vitro genetic networks. Such experiments are not feasible using an in vivo reaction platform, thereby limiting the usage of the controller in rapid prototyping and implementation.
Notably, for the current architecture, disturbance rejection is only possible when perturbations do not directly influence the parameters involved in governing the steady-state response of the reporter protein (shown in Fig. 4f). It is also important to note that the closed-loop controller can only reject the disturbance provided that the genes y and z are at the same concentration and that the added disturbance to both is the same, ensuring that at any time during the reaction it holds that PYtot = PZtot. To achieve this operating condition in vivo, Y and Z could be expressed on the same operon, controlled by a single promoter. Finally, in this work, we demonstrated that the closed-loop controller can robustly control single gene expression of the deGFP fluorescent reporter protein taken as a model process to be controlled. However, we anticipate that the controller design could be extended to tightly regulate multiple genes that encode other biologically relevant proteins simultaneously or could be employed within a complex network system where multiple processes required tight regulation to improve robustness and performance of the network.
Molecular controllers capable of robust gene regulation are needed in synthetic biology in order to implement more complex circuit networks. The well-characterized and rationally implemented synthetic integral feedback controller we presented here is capable of addressing these challenges to advance biological engineering, and could lead to the development of powerful, synthetic network systems capable of achieving complexity similar to that found at the cellular level, to develop cell-free applications such as calibrated biomanufacturing or programming synthetic cells for specific tasks.
METHODS
Mathematical modeling and parameter estimation
The simulated response of the controller was determined by numerically integrating ODE models (Fig. 3b) using MATLAB ode23s solver unless otherwise specified. Initial conditions for each molecular species are described in the figure captions, and the values of reaction parameters are shown in Table 1. For the cases where there is a step change in the DNA concentration over the course of the reaction, similar settings were used to determine the model response numerically.
For parameter estimation, first we found initial guesses of parameter values that qualitatively agreed with the measured open-loop response. We then randomly sampled a set of input parameters from a uniform distribution within a bounded interval (upper and lower bounds of 15% each) centered around the initial guess values. This input set of parameters was then optimized to minimize the error between the model and measured open-loop responses for all five trajectories (shown in Fig. 3c). To find the best fit, the least squares error between the model and the measured response was minimized using the MATLAB fmincon function. During the fitting, each input parameter was allowed to vary from 0.1 to 10 times with respect to the input value. Further constraints were placed on some parameters so that they lie within a feasible range. For example, the activated transcriptional rate must be several orders of magnitude larger than the basal expression (αV+>>αV and αZ+>>αZ) and the transcriptional rates of the x gene and activated y and z genes should be in the same order (αX≈αY+≈αZ+) (See SI Table S1). Because in the open-loop case, a modified version of y gene (denoted as yc) is expressed from the promoter PYtot and cannot sequester with X, parameters αV, αV+, δV, αγ, κ and PYtot were set to zero. Once we found the optimum set of parameter values that provided the best fit for the open-loop response, these parameter values were then fixed during fitting all five trajectories of the closed-loop response (shown in Fig. 3d) while varying only αV, αV+, δV, αY and κ. This resulted in a set of 15 parameters that fit both open and closed-loop responses (Fig. 3c and d, respectively). The fitting process was repeated 1000 times, which gave a range for the 16 parameters (Fig. 3e) with 95% confidence interval.
TXTL Preparation and Reactions
The all E. coli cell-free TXTL extract was prepared from BL21 Rosetta 2 from Novagen, as described previously.23,24 The TXTL system is commercially available as the product “myTXTL” from Arbor Biosciences. TXTL reactions are composed of 1/3 volume cell lysate, with the remaining 2/3 volume containing plasmids, amino acids, and reaction buffers. All TXTL reactions contained 50 mM HEPES pH 8, 1.5 mM ATP and GTP, 0.9 mM CTP and UTP, 0.2 mg/mL tRNA, 0.26 mM coenzyme A, 0.33 mM NAD, 0.75 mM cAMP, 0.068 mM folinic acid, 1 mM spermidine, 30 mM 3-PGA, 1.5% PEG8000, 30 mM maltodextrin, 3 mM each of 20 amino acids, 90 mM K-glutamate, and 4 mM Mg-glutamate. TXTL reactions were assembled using the Labcyte Echo 550 liquid handler, to volumes of 2 μl in a 96-well V-bottom plate (Corning Costar 3357 with caps Costar 3080) and incubated at 29°C.
DNA
Plasmids were constructed using standard cloning techniques. Each plasmid contains the untranslated region UTR1, and either the σ70 promoter P70a or the σ28 promoter P28a, all described previously.23,24,35 For experiments with step changes in the concentration of DNA, the TXTL reactions were assembled in the same manner, using the Labcyte Echo 550, and incubated in a plate reader at 29°C. Reactions were then taken out of the plate reader, and the additional DNA was added to the reaction using the Labcyte Echo 550. The well plate was then immediately returned to the plate reader. The total time that the well plate was out of the reader and at room temperature was less than two minutes. The step-change of DNA added to the reactions diluted the TXTL reaction by less than 5%. Plasmid sequences can be found in the Supplementary Note S2.
TXTL Time-Course Fluorescence Measurements
Fluorescence kinetics were performed using the reporter protein deGFP, a truncated version of eGFP that is more translatable in the TXTL system (25.4 kDa, 1 mg/mL = 39.38 μM).23 Measurements were carried out on Synergy H1 and Neo2 (Biotek Instruments) plate readers, using an excitation of 485 nm and emission of 525 nm, measuring every 3 minutes. To quantify the concentration of deGFP on the plate readers, a standard curve of intensity vs. deGFP concentration was made using recombinant eGFP (Cell Biolabs Inc.).35 All reactions were performed in at least triplicate.
ACKNOWLEDGMENTS
This material is based upon work supported by the Defense Advanced Research Projects Agency (contracts FA8650-18-1-7800 and HR0011-16-C-01-34), the National Science Foundation (contract 1817936), and the Air Force Office of Scientific Research (contract FA9550-14-1-0060)