Our membrane proteins (also referred to as "receptors") enable the polymerization of cells into three-dimensional cellular matrices during bioprinting. Therefore, our receptors present biotin or biotin-binding proteins on their surface, and - being co-injected with a biotinylated linker peptide into streptavidin solution - immediately 'glue' to each other by the means of synthetic biology, allowing printing of defined three-dimensional cellular structures.

Figure 1: A) Schematic depiction of the modular structure of the created genetic receptor constructs. B) Schematic depiction of the modular structure of the membrane receptors for cross-linking of cells via biotin-streptavidin interactions.

The following extracellular domains were constructed and tested:
1) A biotinylated receptor containing an extracellular biotin acceptor peptide that is endogenously biotinylated by a coexpressed biotin ligase (BirA) and thus presents biotin groups at the cell surface.

The biotin acceptor peptide (BAP) is a 15 amino acid peptide sequence originating from E. coli. ^[1] Being biotinylated by the biotin ligase BirA at a lysine residue within the recognition sequence, it mediates the functionality of the receptor by presenting biotin, allowing the interaction of the cell surface with streptavidin in the reservoir solution. The biotin ligase BirA is therefore encoded by the same vector as the receptor, with an internal ribosome entry site (IRES) allowing translation of two open reading frames (ORFs) from a single polycistronic mRNA. BirA is targeted to the ER via an Igκ signal peptide as well as an ER retention signal (C-terminal KDEL-sequence), allowing it to biotinylate translocating proteins possessing the recognition sequence.

2) Receptors presenting an extracellular avidin variant.

These avidin derivates, by design, allow the functional fusion of the otherwise tetrameric avidin molecule with our receptor. Two different variants were used here: The so-called enhanced monomeric avidin, a single subunit avidin that is able to bind biotin as a monomer, and a single-chain avidin, which resembles the naturally occuring avidin tetramer, but has the subunits being connected via polypeptide linkers. By linking the C-terminus with the N-terminus of the adjacent monomer the whole tetravalent avidin has only one N- and one C-terminus and can thus be fused to a type-I membrane protein for surface presentation.

Both receptor types generally mediate the same purpose: By interacting with the complementary component in the printing reservoir, cells are being cross-linked due to the polyvalent binding of streptavidin molecules to polyvalent biotinylated proteins.

The general, modularized design of our membrane proteins (which we did for prokaryotic cells such as E. coli and eukaryotic cells such as HEK cells) is generally comparable (see Fig. 1). In both cases the expression of the membrane protein is controlled by a promoter, secretion into the endoplasmic reticulum or the periplasmic space is enabled by a appropriate signal peptide. Following the signal peptide the functional extracellular domain (biotinylated or biotin-binding) is fused as a protein fusion followed in RFC[25] by an antibody binding site that can be used in experiments do quantify the surface presentation of the synthetic membrane protein. The membrane insertion is done in eukaryotes using a simple single-span transmembrane domain and in eukaryotes using a bacterial autotransporter that integrates into the outer membrane of gram-negative bacteria. By using this modular design that is even cross-kingdom functional we enabled future teams to present various protein domains on the surface of bacteria and mammalian cells and successfully generated cells to test our inventive bioprinting approach.

For determining a signal peptide suitable for our construct, we tested a total of three signal peptides - one taken from the parts registry, and two designed by ourselves.

• The EGFR signal peptide was taken from the iGEM parts registry ([http://parts.igem.org/Part:BBa_K157001:Design BBa_K157001]) and combined with a BioBrick encoding the CMV promoter sequence ([http://parts.igem.org/Part:BBa_K747096 BBa_K747096]) via the RFC10 cloning standard.

• The BM40 and Igκ signal peptides were designed by us, providing additional spacing as well as a Kozak sequence to the 5'-UTR of the constructs and combined with a BioBrick encoding the CMV promoter sequence ([http://parts.igem.org/Part:BBa_K747096 BBa_K747096]) via the RFC10 cloning standard.

As shown below, the EGFR signal peptide taken from the parts registry is constructed in a way that the signal peptide ORF immediately follows the RFC10 cloning scar after the CMV promoter, thus resulting in a very short 5’ untranslated region (UTR) of the transcribed mRNA. The combination of the CMV promoter with the synthesized BM40 and Igκ signal peptides allows for a considerably longer 5’ UTR of the resulting mRNA - additionally allowing them to contain a full Kozak consensus sequence by design. The Kozak sequence is recognized by the ribosome as a translational start site; this element missing or deviating from the consensus sequence may considerably decrease translation efficiency.^[2] For the EGFR signal peptide construct, a Kozak sequence is not present, as it would have to preceed the start codon ATG - a position which is occupied by the RFC10 cloning scar. Since both the distance from the promoter to the open reading frame as well as the Kozak consensus sequence are considered crucial parameters for expression levels^[3], BM40 and Igκ signal peptide constructs are likely to resut in increased expression levels compared to proteins containing the EGFR signal peptide from the parts registry.

As the quantitative functionality of signal peptides had to be determined before including one of these into the final receptor constructs, the three options (Igκ, BM40, EGFR) were tested via bioinformatic tools as well as a secretion assay of luciferase constructs.

The [http://www.cbs.dtu.dk/services/SignalP SignalP] server, being able to discriminate between the hydrophobic signal peptide sequence and the hydrophobic transmembrane domain^[4], can determine whether a sequence possesses the biophysical requirements for functioning as a signal peptide. Furthermore, it is able to predict the probable cleavage site of the signal peptide after its translocation into the ER. For all constructs, signal peptide functionality is predicted, as well as a potential cleavage site. The complete translated amino acid sequences of the respective receptor constructs were used as input. The algorithm for eukaryotes with default D-cutoff value was chosen.

Figure 2: A) Schematic depiction of a protein-coding mRNA containing a 5'- and 3'-UTR, the first of which being an important factor in translation efficiency. B) Identification of signal peptide functionality and cleavage site within the receptor construct containing the EGFR, Igκ and BM40 signal peptide via the SignalP 4.1 server. Plotted probabilities represent the raw cleavage site “C-score”, the signal peptide “S-score” and the combined cleavage site “Y-score”. C) ClustalW multiple sequence alignment of the BM40, EGFR and Igκ signal peptide construct, depicting a gap for the EGFR-signal peptide construct compared to the newly designed ones, indicating smaller length of the 5'-UTR . For the Igκ and BM40 signal peptide constructs, a T7 promoter spacer as well as a Kozak sequence increase the distance between TATA-box and protein-coding region.

For all three signal peptides, the high S-score indicates high signal peptide functionality. For the Igκ signal peptide, a cleavage site between amino acid 20 and 21 within the signal peptide is predicted. For the BM40 signal peptide, a cleavage site between amino acid 17 and 18 is predicted, and for the EGFR signal peptide, a cleavage site between amino acid 24 and 25 is predicted.

For the quantification of signal peptide functionality via a luciferase assay, three constructs were created and tested - each containing one of three signal peptides (the EGFR signal peptide, the Igκ signal peptide or the BM40 signal peptide) and a nanoluciferase as well as a CMV promoter, a Strep-tag II for immunochemical detection and the hGH polyadenylation signal sequence. Not containing a transmembrane domain, the nanoluciferase fusion protein is being translocated into the ER and then secreted into the medium. Using a luciferase assay, one can quantifiy the amount of luminescence - and thus, proportionally, the amount of secreted luciferase - by measuring the conversion of luciferin into visible light and integrating it over a timespan of 5 s. Therefore, medium samples were taken every 12 h after transfection of cells and measured via the Promega NanoGlo® luciferase assay system according to the manufacturer's instructions.
Hier fehlt noch die Diskussion der Ergebnisse!

Figure 3: A) Schematic depiction of the genetic constructs used for signal peptide testing via a secretion luciferase assay. B) Results of the luciferase assay, showing luminescence in relative luminescence units (RLU) as a function of time for the previously described three different signal peptide constructs as well as a control construct containing no signal peptide. C) Detection of secreted luciferases in the medium via a Western Blot, using an anti-Strep-tag II antibody as well as an alkaline phosphatase-coupled secondary antibody for detection.

Apart from the functional parts that mediate the (strept)avidin-biotin interaction, other elements in the receptor were designed to make sure it is optimally translocated to the membrane, as stable as possible, and easily detectable.

For anchoring in the membrane, we decided to use a type-I membrane protein, which has a single membrane span with defined localization of N- and C-terminus out- and inside of the cell, respectively. As the Epidermal Growth Factor Receptor (EGFR) has already been successfully used in the iGEM project of Freiburg 2008, we decided to base our project on the same transmembrane domain. The N-terminal transmembrane α-helix of human EGFR ([http://www.uniprot.org/uniprot/P00533 UniProt P00533], amino acids 622-653) was herefore chosen (see below the topology prediction of EGFR via the [http://www.cbs.dtu.dk/services/TMHMM/ TMHMM 2.0 server for the prediction of transmembrane helices]^[5]). A stop-transfer sequence, that is also present in the endogeneous EGFR, consisting of clustered, positively charged amino acids - being characteristic for type I membrane proteins - was added at the C-terminus, and the sequence was furthermore flanked by a (GGGGC)₂-linker at the N- and C-terminus, respectively. The addition of a stop-transfer sequence as in the naturally occuring EGFR sequence, as well as the addition of flexible linkers, makes our EGFR-TMD an improvement over the BioBrick [http://partsregistry.org/wiki/index.php?title=Part:BBa_K157002 BBa_K157002], which does not possess either of these elements.

A) Multiple sequence alignment of human EGFR (see [http://www.uniprot.org/uniprot/P00533 UniProt P00533]), the EGFR transmembrane domain BioBrick from the registry ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K157002 BBa_K157002] and the extended EGFR transmembrane designed by us, containing a charged stop-transfer domain as well as linker elements at the C- and N-termini. B) Transmembrane domain prediction by the [http://www.cbs.dtu.dk/services/TMHMM/ TMHMM 2.0 server], indicating positioning of N- and C-termini out- and inside of the cell, respectively, as well as predicting functionality of transmembrane regions. C) Schematic depiction of the C-terminal stop-transfer sequence of the receptor.

Moreover, the receptor contains three functional elements for its detection: The intracellularly located red fluorescent protein mRuby 3 for detection of the receptor via fluorescence microscopy, an extracellular epitope domain for immunochemical detection via A3C5-antibody fragments and an intracellular Strep-tag II for the detection and purification via immunochemical methods.

The vector furthermore contains the poly-adenylation signal of human growth hormone (hGH) for functional polyadenylation of the transcribed mRNA. A description for the respective functional elements is given in the following sections.

Antibodies have various areas of application in life science, including protein detection, pulldown experiments and even immunotherapy. Having originally been discovered in 1995 during an in vitro screening for antibodies against cytomegaloviral proteins^[6], the A3C5 antibody is an established molecular tool for specific recognition of proteins. By tagging cell surface proteins with an epitope specifically recognized by A3C5 (being a peptide sequence of 11 amino acids), one is easily able to detect tagged proteins via immunofluorescence microscopy, FACS or one may purify them via pulldown experiments. Through the latter, one may also screen for in vivo interaction partners of the tagged protein.

Having originally been engineered as a monomeric form of the red fluorescent protein eqFP611, mRuby variants are sine of the brightest red fluorescent proteins available. ^[7] With an excitation maximum at a wavelength of 558 nm and an emission wavelength maximum of 605 nm, the resulting stokes shift of 57 nm makes mRuby a good choice for fluorescent microscopy imaging and, thus, allows the visualization of the receptor in its cellular environment by being fused to the C-terminus of the transmembrane domain. mRuby is especially powerful for the fusion with receptors - not only due to its small size and high stability, but also due to the fact that, in comparison with eGFP, it appears up to 10 times brighter in membrane enviroments. The mRuby variant used here is mRuby 3, having been engineered for even more improved brightness and photostability.^[8]

The Strep-tag II is an eight amino acid peptide sequence (WSHPQFEK) that specifically interacts with streptavidin and can thus be used for easy one-step purification of the receptor via biochemical and immunochemical methods.^[9]

The concept of bioluminescence has a great meaning for several invertebrate species, allowing communication with other individuals, signaling receptiveness or deterring predators.^[10] The most common enzyme responsible for the creation of bioluminescence are the luciferases (from the latin words ’lux’ and ’ferre’, meaning ’light-carrier’). These enzymes, among others found in fireflies and deep-sea shrimp, commonly consume a substrate called luciferin as well as energy in the form of ATP or reduction equivalents in order to create light-emission through oxidation. The underlying mechanism hereby relies on the creation of an instable, highly excited intermediate under the consumption of energy. This high-energy intermediate then spontaneously falls back into a state of lower energy, emitting the energetical difference as visible light. While mainly being used as a folded, stabilizing element at the N-terminus for the construct containing the biotin acceptor peptide, the nanoluciferase could also be used for advanced binding studies via luciferase assays.^[11]

Reaction scheme of the reaction catalyzed by the NanoLuc nanoluciferase. Taken from the NanoGlo Assay Kit manual.

Luciferases have also found their way into biotechnological applications.^[12] The simplistic concept of creating visible (and thus easily measurable) light makes luciferases ideal reporters for the expression of secretable proteins via a corresponding assay. This project also made use of a luciferase for the determination of expression levels of the BAP surface receptor while providing a stable and folded domain at the N-terminus, as well as having been used for the choice of signal peptide. The monomeric luciferase used in this project, the so-called ’NanoLuc™'^[13] (due to terms of simplicity referred to as ’nanoluciferase’ in the following), can be fused to other proteins in order to make their expression visible and quantifiable. This engineered luciferase emits a steady, easily detectable glow when exposed to its substrate, while being only 19 kDa large and being brighter, more specific and steadier than other luciferases commonly found in nature. Using luciferases for the quantification of expression levels offers several advantages over fluorescent proteins, including higher sensitivity and smaller size.

Last but not least, high expression levels of the receptor, so that a high avidity for the interaction may be reached. The CMV promoter (taken from the parts registry, [http://parts.igem.org/Part:BBa_K74709 BBa_K74709]) therefore enables constitutively high expression of the receptor - and, in the case of the BAP-construct, the biotin ligase BirA.

We wanted to generate semi-stable transfected cells for initial testing and stably integrated cells for final experiments and the later bioprinting experiments. As there was the need for such BioBrick-compatible vectors, we adapted the pDSG vector system (semi-stable, transient: BBa_K2170300) and the pcDNA5 vector system (stable integration using a co-transfected rekombinase: BBa_K2170301).

For the first trials of testing our constructs in human cells, we chose the MEXi™ cell line for semi-stable transfection. MEXi™ is a suspension HEK293E cell line by iba lifesciences that encodes the viral protein EBNA1 in it's genome. EBNA1, being a protein derived from Eppstein-Barr-Virus that mediates the viruses' replication initiation, gene regulation and maintenance of its DNA in the host cell. The second part of the MEXi™ system is made up by the pDSG-IBA vector that carries the specific origin of replication that is recognized by EBNA1. EBNA1 binds to this origin, and recruits the replication apparatus as well as inducing the maintenance of the inserted DNA in the host's nucleus, leading to the episomal maintenance and co-replication of the plasmid during every division cycle.^[14]

Thus, we cloned our receptor constructs into the pDSG-iGEM vector and then transfected the MEXi™ cells using the PEI transfection method (see methods). Polyethylene imin (PEI) as a cationic polymer forms complexes with the negatively charged DNA. These complexes are taken up by the cell via endocytosis and carried to the nucleus. ^[15]

• Abbildung semistabile transfektion schematisch

Printing tissues - or even only parts of organs - requires billions and bilions of cells. An average liver, for example, weighs about three pounds and hosts ~10⁸ cells per gram tissue. ^{[16] [17]}

Since transiently and even semi-stably transfected cells do not propagate the transfected DNA indefinitely, repeated transfection of cells would be unwise due to the high consumption of time and ressources. Therefore, we created three stable cell lines that chromosomally encode the respective receptor constructs. For this purpose we used the FlpIn™-System by invitrogen. The three compound system consists of HEK-TRex™-293 cells that harbour one chromosomal Flp recombination target (FRT) site, a Flp recombinase expression plasmid and the plasmid encoding the receptor as well as another FRT site for stable integration.^[18] The detailed principle of the intergration is described in the figure below.

Cells that succesfully integrated the plasmid into their genome will lose their resistance for Zeocin™ but become resistant to hygromycin B (hygB), since the plasmid encodes the hygB-phosphotransferase, a kinase inactivating hygB by phophorylation.^[19] Thus the transfected cells can be easily selected via hygromycin B. To ensure that the resistence does not come from non-intergrated plasmid, this process takes several weeks and divison cycles.

The succesful integration of the pcDNA plasmids was verified by genome-PCR (see methods). Therefor we designed three primers: One that binds to the SV40 promotor and part of the following FRT site, one that binds part the hygromycin restistance gene and another one for the lacZ-Zeocin sequence. In the event of stable integration the size of the amplicons will be around 550 bp, according to the distance between the SV40 and the hygromycine resistance gene. Wheareas in case of no intergration the amplicon size will be around 400 since this corresponds to the distance between the SV40 and the lacZ-Zeocin sequences. The results are shown in figure on the left. The lower band visible in the samples 2-5 leads us to the conslusion that despite hygromycine selection the cells are not yet a monoculture, something we also observed in the flow cytometry analysis further discussed below.

For better traceabilty we supplied all of our receptor constructs with reporter genes like mRuby and/or Nanoluciferase. mRuby is located on the C-terminus respectively the cytosolic end of our transmembrane receptors right before the Strep-tag. Cells that express and fold the protein properly should give a signal of 605 nm (red) when exited at around 558 nm (rfp channel).^[20] We tested our contructs three diffrent cell types: HEK293T adherent cells that were stably transfected, HEK293E suspension cells that were semi-stably transfected and N2a cells, a mouse neuroblastoma cell line, that we transiently transfected.

As you can see on the images the signal developed over time. In the beginning, before selection, the protein was visible in little dots and therefor seemed to be localized more in subcellular oragnelles than in the membrane. During selection on hygromycin B resistency most of the cells died, leaving some resistant cells behind, which over time grew to bigger foci consisting of stably transfected cells only (See picture B). For the BAP-receptor there was hardly to no fluorescence detectable neither in semi-stable nor in the stable transfection approach. But in latter case the cells still grew on hygromycin B and formed foci, which leads us to the conclusion that chromosomal intergration was susccesful (as already shown via PCR) hence there must be some problem in later steps of protein maturation. After 2 weeks of selection on hygromycin B the foci were harvested and expanded. The cells seemed to recover fast and moreover the red dots nearly disappeared leaving only the membrane o fthe scA-receptor cells illuminated by mRuby.

To make sure the receptor is properly presented on the surface of the cells and to quantify the yield of stably transfected cells we used flow cytometry analysis. In order to check the viability of the cells the dye calceinAM was used. This aromatic calcein derivative passes the cell membrane. In the cytoplasm the acetoxymethoxyl (AM) group is cleaved of by esterases what enables the substance to complex Ca²⁺ ions leading to a bright green fluorescence. The cells where additionally incubated with anti-A3C5-Fab labeled with Dy634, a fluorescent dye emitting light of 658 nm wavelegth. The intrinsic fluorescence made up by mRuby could - as visible in the graph below - only be detected in the scAvidin receptor cells and not in the BAP-Receptor cells. This is not further surprising since the cells showed hardly to no fluorescence under the microscope as well. But interestingly we got a positive signal for A3C5 (anti-A3C5-Dy634) in the BAP-receptor cells meaning that the protein must be expressed and as well be located in the membrane. The scAvidin-receptor cells show both mRuby fluorescence as well as the Dy634 signal. The latter is in contrast to the microscopy results even higher in BAP-receptor cells with around 90% being positive for Dy634 whereas only half of the scA-receptor cells are located in the positive gate.

Another way to verify the succesful transfection and protein expression is given by the two tags (A3C5 and Strep-Tag) that are included in the receptor design, which allow detection via western blot analysis.

After transfecting mammalian cells with the receptor constructs and selecting them for 2 weeks on hygromycin, we lysed the cells and checked for the presence of Strep- and A3C5-tag via western blot using primary antibodies against the respective tags und secondary alkaline phosphatase coupled antibodies (see methods). As the figure shows, the Strep-tag wasn't detectable via WB - however, the A3C5-tag-WB shows significant singular bands at the size of our proteins. This data corresponds with the flow cytometry results again showing that the BAP receptor is also present in the non-fluorescent cells.

Quantification of mRNA expression levels by RT-q-PCR

The characterization of our transfected mammalian cells showed that the two receptors containing an avidin variant were expressed and translocated to the outer cell membrane. The biotin-presenting receptor containing the biotin-acceptor peptide, though, showed a very low fluorescence signal. Therefore, the success of the stable integration was tested by PCR of the genomic integration, which lead to the conclusion that the construct was transfected and integrated sucessfully, hinting at a problem downstream of the integration. In order to understand where the source of this problem was, we took a closer look at the expression levels of the different receptors by analyzing mRNA levels in comparison to each other and to the housekeeping gene (HGK) GAPDH.

For a better comparibility, we used the same amount of cells for each receptor and not only reviewed cells with stably integrated but also cells with the episomal stable receptor constucts. After extraction of the total mRNA from the cells the quality and integrity was measured by Bioanalyzer. All samples showed a RNA integrity number (RIN) above 9 which means that the total mRNA is pure and does not have any contamination. During the first step of RT-qPCR the total mRNA in converted to cDNA by a reverse transcriptase, which is then used in the actual quantitative PCR to quantify the amount of a specific mRNA was produced by the cells. For this reason two primer pairs were designed. One of them was designed to bind the exact same region in all of the different receptor mRNAs and amplify the same part of the receptor. Contrary to that the second pair was supposed to bind only in the biotin presenting receptor and amplify a part that is unique to this receptor. By this method we wanted to observe if only one part of the mRNA is unstable or if the general mRNA level of this receptor is decreased.

For the evaluation of the raw data we used the ΔΔC_P method^[21] in which the crossing points (C_P values) of a gene of interest and of a reference gene are compared and normalized with a constantly expressed HKG, to get an idea of the relative amounts of the mRNA of interest.

In the following you can see the results of our experiments. We compared the expression levels of Trex which were transfected with our different receptor constructs and with non-transfected (NT) Trexs.

Fig.x

As can be seen the ΔΔC_P values of the mRNA of the eMA and scAvidin constructs are with a 1,2 x  10⁶ fold increase for scAvidin and 1.5 x 10³ fold increase for eMA, significantly higher than those of the BAP construct. The analysis of the different primer pairs in the two regions of the BAP construct also showed similar values. A difference in C_P value is tatamount to the relative amount of the analysed mRNA in the cell.

Together with the result that the integration of the constuct into the genome was successful we can conclude that our first assumption, that the missing RFP signal in cells, which were transfected with the BAP construct, is caused by a reduced mRNA stability, is correct.

High resolution imaging using scanning electron microscopy (SEM)

As we wanted to obtain high resolution images from the transgenic cells transfected with our modular membrane proteins we contacted the experts on electron microscopy in Munich and Prof. em. Dr. Wanner (LMU Munich) agreed to help us with scanning electron microscopic imaging. Even better Prof. Wanner has developed a method in which he can correlate the fluorescence signal of a sample with the high resolution images obtained in SEM. As this kind of preparation and imaging takes a while we had to start 2 weeks before wiki freeze and at that point we did not have enough stably integrated (T-Rex 293 HEK) cells, yet. Thus we used transient transfected, semi-stable MEXI HEK 293T cells that were pulled down with magnetic beads. For this immuno precipitation we incubated scAvidin-receptor and eMA-receptor cells with biotinylated magnetic beads and on the other side cells transfected with the BAP-receptor together with streptavidin-coupled magnetic beads.

Design of an autotransporter construct for bacterial surface display

Besides the design of biotinylated and biotin-binding receptors for eukaryotic cells we also wanted to apply our biotINK approach for prokaryotic cells. For this purpose we designed an autotransporter device that is able to present biotinylated or biotin-binding protein domains on the surface of E. coli. These constructs for the bacterial surface display are well known in the field of protein engineering of therapeutic proteins, such as antibodies. Here they are used to screen libraries of different antibodies concerning their affinity towards a given therapeutic target. We based our design on the autotransporter EspP that has been developed in the Lab of Prof. Skerra ^[22].

This system works very well (see Fig. A^[23]) and we "bricked" it down into RFC[10] and RFC[25] BioBricks. At first we tested different inducible bacterial promoter systems (e.g. "TetR repressed GFP"; BBa_K577893) that are available in the parts registry, but when we saw that two of the available systems did not work in our own hands, we decided to built the system on our own. We used the Tet-Repressor generator that was available on the distribution plates (BBA_I739001) as we believe that it is very important for the standardization in SynBio to use available parts even if it is more work to replace genetic elements that are already in place. Downstream of this repressor generator we designed and fused a BioBrick (BBa_K2170141) that encodes a double Tet-Operator (Tet-Repressor binding site together with a bacterial promoter and an signal peptide of the outer membrane protein A (OmpA^[24]) from E. coli that has a 3' RFC[25] restriction site to allow the protein fusion of proteins that are secretet into the bacterial periplasm when expressed with this BioBrick. As a proteinfusion we then assembled a protein cargo domain that is generally exchangeable for any protein that is so small in size that it can be transported through the outer membrane by the EspP autotransporter. In our project we used the same extracellular domains as for the eukaryotic receptors: enhanced monomeric Avidin (eMA; BBa_K2170204), single-chain Avidin (scAvidin; BBa_K2170205) and a composite part composed of a N-terminal Biotinylation acceptor peptide (BAP) and a C-terminal NanoLuciferase (together shown as BAP; ; BBa_K2170118, see Fig. B). Further downstream our design features a A3C5-epitope tag that can be recognized by a high affinity Fab-fragment and is generally used to detect and quantify the surface display of the cargo domain^[25]. Further downstream of this affinity tag we fused the BioBrick for the EspP autotransporter from E. coli^[26][27] which is then followed by a bacterial terminator. For the termination we again chose a well working terminator from the distribution plate ("double terminator"; BBa_B0010-BBa_B0012).
But this was just the DNA-part. What is expected to happens on a protein level? The construct constantly produces Tet-repressor that binds to thet Tet-Operator and repressed the promoter activity of the autotransporter gene. As soon as the inducer anhydrotetracycline (aTc) is added to the culture, it binds to the Tet-repressor that can't bind any more to the Tet-operator and thus the expression of the autotransporter can be regulated. Although the TetR-system is known to be a tight promoter system there is always a certain background expression with most promoters. If the protein expression of the autotransporter is induced using aTc the autotransporter is transcribed and translated. Due to the bacterial signal peptide the protein is secreted into the bacterial periplasm (the space between the two bacterial membranes of gram-negative bacteria such as E. coli). When present in the bacteria periplasm the autotransporter diffused to the outer membrane and inserts into the membrane. After the integration into the outer membrane the protein cargo is transportet through the beta-barrel of the autotransporter and is pre sented on the bacterial surface. We are sure that this BioBrick will be a valuable contribution to the Parts Registry as it allows future teams to display small protein domains on the surface of gram-negative bacteria, such as E. coli.

Results: Testing the bacterial autotransporter system

For the testing of our autotransporter constructs we transformed all three autotransporter constructs together with a secreted NanoLuc luciferase, which served as a control, into E. coli JK321^[28]. Transformed cells were grown in LB-medium supplemented with chloramphenicol (pSB1C3-vector) at 30°C and 180 RPM. In the morning a stationary over night culture was used to inoculate 50 mL fresh medium with 1 mL of culture. The cultures were grown to OD₅₅₀ = 0.5 and then the induction of the protein production was started using aTc: "non" = non-induced; "low" = 25 ng/mL aTc; "high" = 200 ng/mL. After induction the cultures were grown for further 5 h at the same concitions and cells were afterwards stored at 4°C until they were used for analysis or bioprinting.
After the cell harvest the optical density (OD₅₅₀) was determined again as it is known that a high expression of EspP makes the outer membrane of E. coli permeable and this drastically affects cellular viability. For the scAvidin-autotransporter and the secreted BAP-NanoLuc autotransporter at high inducer concentration show clearly reduced viability as they did not show any growth after induction at OD₅₅₀ = 0.5 (see Fig. A). In order to analyze the functionality of the whole design and these new BioBricks we subjected each of the twelve cultures to three different treatments and determined subsequently the amount of NanoLuc luciferase using the manufacturers substrate kit (Thanks to our sponsor Promega ;). At first the total NanoLuc luciferase content was determined in samples that were just washed once with PBS and contained the whole bacterial cell (see Fig. B), bacterial cells that were incubated with PPA-buffer (periplasmic extraction buffer; 500 mM sucrose, 100 mM Tris/HCl pH 8.0, 1 mM EDTA) that extracts the proteins present in the periplasm (see Fig. C) and finally the culture supernatant of the cultivated bacterial cells (see Fig. D). The total NanoLuc activity is only present in bacteria that are transformed with a plasmid encoding the luciferase and there is a clear dependency of inducer concentration a detected luciferase activity. In the samples where a periplasmic extract was prepared the luciferase activity is highest in the samples of the secreted luciferase as the EspP-fused BAP-NanoLuc is attached to the cells and only proteins from lysed cells are present in the periplasmic extract. In the case of the samples where the supernatant of the cultures was analyzed the luciferase activity is present in both "high" induced samples.

As the luciferase activity only gave an indication for the subcellular localization of the cargo-autotransporter fusion protein, we also performed flow cytometry measurements. For this purpose the same cells were stained with app. 10 µM A3C5-Fab that was coupled to the fluorescent dye Dy634-NHS and 100 µM of the chemical compound biotin-atto488. Cells were incubated for 2 h at 4°C, washed twice with PBS and analyzed using a FACSAria II flow cytometer (BD bioscience, voltages for fluorescence channels were all at 750 V).

For the channels FITC (biotin-atto488) and Dy634 (A3C5-F_ab-Dy634, detected using a HeNe laser (633 nm) and a 660/20 band pass filter) the fluorescence signal was measured and mean values are given. The cells showed a homogeneious population in the FSC/SSC plot. The A3C5-F_ab staining detected high signals up til a mean of over 4000 for the eMA-autotransporter dependent on the inducer concentration. For the same bacterial cells the binding of biotin-Atto488 could be confirmed as well. The single chain Avidin (scAvidin) cells showed absolutely no A3C5 signal but a low Biotin-Atto488 background signal that could be caused by biotin-importers that transport biotin into the cells or the slow diffusion into the periplasm of E. coli. In contrast the BAP-Receptor also shows a high surface presentation as seen in the A3C5 signal of nearly 4000 for the "high" induced sample. The elevated biotin-Atto488 is unexpected but could be explained by the weakened and partly permeable out membrane that does not stop the small-molecule dye from entering the periplasm.

Discussion: The autotransporter is working and can present small protein cargos on the bacterial surface

The performed experiment confirm the functionality of the device including the tetracyclin repressed promoter, the secretion into the bacterial periplasm as well as the presentation of the protein cargon on the bacterial outer membrane. In agreement with the expectation the 62 kDa big scAvidin with its extremely strong fold is too big in size for the autotransporter and can not be presented on the bacterial surface. In contrast the smaller BAP-NanoLuc (19 kDa for the NanoLuc) or the eMA (15 kDa) both can be efficiently presented on the surface. The enzymatic biotinylation of the Biotin Acceptor Peptide (BAP) using recombinant BirA biotin ligase is well established but could not be show before the wiki freeze. In Summary the whole device works great but there seems to be a limitation concerning the size of proteindomains that can be presented with the EspP autotransporter. We are curious to see what future iGEM teams will use the EspP Autotransporter in the future.

References