Team:Freiburg/Project/Cellfree Expression
Methodology Cell-free Expression
Why Do We Use Cell-free Expression?
Cell-based protein expression is a well established method to obtain large amounts of a target protein. It enables accumulation and purification of the protein in quantities sufficient for various in vitro applications. Nonetheless, it is a tedious task to generate all the genetically modified organisms if a variety of proteins needs to be expressed. Additionally, purification of a distinct protein can not be performed according to a generalized protocol, but has to be optimized for every protein separately. Cell-free expression represents a possibility to overcome many challenges of conventional protein expression and offers many advantages concerning our project in particular.1) Generally speaking, it saves a lot of time and money to avoid the generation of genetically modified organisms for every protein. Suitable DNA sequences are constructed once, for example by having it synthesized by a company, and can be stored until needed. In terms of purification, cell-free expression avoids the need for cell lysis and therefore circumvents this harsh procedure, thus preserving the protein. In cell-based expression, too strong induction often results in aggregated and therefore non-functional protein. This risk is minimized by using cell-free expression, since the expressed protein is dispersed in a far larger volume than the intracellular space.2) For translating DNA templates into protein microarrays in a microfluidic set-up, cell-free expression is the method of choice. This system is capable of expressing many different sequences at once. Additionally, the microfluidic setup provides the opportunity to constantly supplement the expression. Replacing depleted components, like dNTPs, amino acids or energy sources like creatine phosphate, enables higher yields of protein.
Basics of Cell-free Expression
Cell-free protein production opens new perspectives for the direct manipulation of expression compartments in combination with reduced complexity of physiological requirements. The technology is therefore in particular suitable for the general synthesis of difficult proteins including toxins and membrane proteins as well as for the analysis of their functional folding in artificial environments. A further key application of cell-free expression is the fast and economic labeling of proteins for structural and functional applications. As extract sources, wheat embryos, various cell lines from cell culture and Escherichia coli cells, are currently employed for the cell-free production of proteins.
Our DiaMIX
We developed our own low-budget protocol for expressing proteins in a prokaryotic cell-free expression system based on an Escherichia coli lysate. Most of the established cell-free expression systems are based on rabbit reticulocytes, wheat germ cells, insect cells or E. coli cells. Due to the prokaryotic origin of most of the proteins expressed during our project, we decided to develop our own low-budget prokaryotic cell-free expression system, the DiaMIX, based on an E. coli cell culture. To produce the DiaMIX we used the E. coli strain BL21, as it is carrying a gene coding for the T7 RNA polymerase, which facilitates an improved expression of proteins during the cell-free expression. The cells were induced with IPTG prior to further treatment to initialize T7 polymerase expression, therefore allowing a high rate of protein synthesis. Since all the coding sequences used in our project were manufactured synthetically, the E. coli BL21 cells were additionally transformed with a plasmid (pRARE2) containing the coding sequence of tRNAs for the translation of rare codons (AGA, AGG; AUA, CUA, GGA, CCC and CGG). According to an optimized protocol adapted from the European Molecular Biology Lab (EMBL) Heidelberg, the lysate was prepared from E. coli BL21 cells, frozen in liquid nitrogen and afterwards stored at -80°C. This lysate contains the whole transcription and translation apparatus of the cell, allowing a successful expression of proteins from DNA templates. However, the E. coli lysate is just one of the main components of the DiaMIX. To finally be able to express proteins, the system needs additional buffers, amino acids, nucleotides and energy sources. We obtained an L-amino acid kit from Sigma-Aldrich and prepared an accurate mix ourselves. The energy generating system based on creatine phosphate, phosphokinases and buffers as well as the mix containing nucleotides and amino acids (see protocol LINK) were prepared and added to the lysate directly before expression. After adding all three components the complete cell-free expression mix was subsequently used to express proteins. Therefore, the reaction was started by adding DNA coding for the respective proteins. To verify the functionality of our system we compared it to a commercially available kit.
Proof of Protein
To validate the expression of correctly folded proteins applying the DiaMIX we used various methods like fluorescence measurements (link protocol), luciferase assays (link protocol) and Western Blots (link protocol). One of our first approaches was the expression of GFP (LINK), which can be detected via its fluorescence. For expression of GFP we used a plasmid template (LINK) that was added to the self-prepared expression mix. Expression was then visualized via a microplate reader measurement that monitored the increase in emitted light at a wavelength of 520nm during progression of the expression. To verify the obtained data from this measurement a Western Blot was performed additionally. We used GFP antibodies to show the expression of GFP in our mix. If you are interested in the results of this experiment, have a look here. As a second test for our system we performed a luciferase assay. In contrast to the expression of GFP which can be followed by a gradually rising of GFP over time, the luciferase assay is based on the emittance of light when luciferin is conversed into oxyluciferin. This reaction is catalyzed by the enzyme luciferase and doesn’t allow a tracking of expression over time. Moreover it is not dependent on correct folding and offers detection within seconds. We used the coding sequence of the firefly luciferase (pBESTlucTM) to express the protein with our cell-free expression system. The substrate luciferin was added to the mix after expression was finished. Then, the luminescence was measured at once using a microplate reader. For more information about the outcome of this analysis, check out our results. This analysis helped us to evaluate the concentration of expressed protein in the cell-free expression system.
Step by Step Validation
Since we aim to use cell-free expression in the DiaCHIP, we decided to validate the process in single steps. Starting with expression in a tube we spotted already expressed proteins on iRIF slides to check, whether or not we expressed detectable antigens that interacted with our antibodies at hand. As a next step we spotted our expression system on the slide without starting the reaction beforehand. By letting it incubate on a specific surface we could check for further possibilities. Lastly, we performed a cell-free expression from immobilized DNA in the finished setup of glass and PDMS slide.
Immobilizing DNA on PDMS
One of the core components of the DiaCHIP is the copying mechanism that allows production of a protein microarray from a DNA template. The following section summarizes our achievements concerning this procedure. Altogether we established a cell-free expression system that can be used to translate proteins from DNA immobilized on a PDMS slide. The expressed protein is then immobilized on the opposite glass slide via a specific tag system resulting in a distinct pattern. A microfluidic system is used to flush the slide with an antibody solution. Specific antibody-antigen interactions were successfully detected by imaging reflectometric interference (iRIf), a label-free detection method. For diagnostic applications, the immobilized proteins are antigenic peptides, specific for a certain pathogen.
The first step needed for copying the DNA array is to genetically fuse antigen coding sequences to a 10xHis tag that is used for surface immobilization later on. The whole expression cassette including promoter and terminator regions is amplified by PCR using an amino-labeled reverse primer. Via this amino group, the DNA is immobilized on an activated PDMS surface. The forward primer used for this PCR is labeled with Cy3. As it is shown in figure 1, spotting the DNA on the activated surface resulted in a distinct pattern visualized by Cy3 fluorescence.
Spotting of Expressed GFP on Slide
To establish, whether our cell-free expression system reaches protein concentrations high enough to detect in the iRIf, we spotted already cell-free expressed GFP on iRIF slides. This not only gave us information about the amount of protein, but also on its folding. By seeing an interaction with a corresponding antibody in the iRIf measurement, we could draw conclusions on the epitope.
On-slide Expression of GFP
First, we could detect wether the interaction between tagged proteins and the surface was strong enough to bind the proteins as soon as they were formed. This can be detected when measuring the slide in the iRIf afterwards. Secondly we wanted to assess if the surface was specific enough to not bind components of the mix itself.
In-chamber Expression of GFP
This step would show us if we would get our setup to work as a whole. Moreover, we could estimate, whether the diffusion patterns in a flow chamber differed too much from that in a suitable reaction tube.
Cell-free Expression of Antigens
Our biggest goal was to express antigens with the required tags in a concentration and folding state that suffices for an iRIf measurement. Here we focused on a C. tetani epitope flagged by a double His6 and a Spy-Tag (Spy-tag überhaupt erwähnen? Gute Frage, aber wir erwähnen den Spy-Catcher als Biobrick, oder? Dann macht das ja iwie schon Sinn den nochmal aufzugreifen) For cloning of this construct we used our own cloning site (link) and a vector that we optimized for cell-free expression. The antigen was expressed in a tube reaction and spotted onto a Ni-NTA surface afterwards. Sadly, we could not show binding of the respective antibodies/serum with the iRIf measurement device. This could be due to folding problems of the antigen during cell-free expression. Moreover, the concentration of expressed C. tetani antigen might not have been high enough to be detected by iRif measurements.
Testing Different Conditions
To identify the optimal DNA concentration that results in a maximum protein expression, we testet different conditions. For evaluation we used DNA concentrations in the range of 1 to 5 ng per 50 µl reaction. To verify our results every reaction was performed in triplicates with every reaction being treated the same way. We could show that the protein amount was highest when a DNA concentration of 2 µg was used (fig. X) For this experiment, we used DNA coding for the enzyme luciferase. The protein concentration could therefore be measured at once using the luciferase assay. Another component whose concentration is crucial for optimal cell-free expression, is magnesium. To evaluate the effects of different magnesium concentrations we started multiple cell-free expression mixes using different magnesium starting concentrations (12 to 16 mM). Magnesium was added to the mix in the form of magnesium acetate and cell-free expression took place for 2 hours. We again used triplicates for each reaction and treated all samples in the same manner (link protocol). After expression, a luciferase assay could visualize the protein concentration in the different reaction mixes. We could show that a magnesium acetate concentration of 12 mM resulted in the highest protein concentration (fig.X).