BioBricks used: BBa_J61002 (Arkin Lab 2006)

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team (here) that hamper the success in biosensors development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Output) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by replacing the IPTG sensing unit present in the Sensynova platform with various synthetic promoters that are regulated by small molecules.

Background Information

Promoter libraries can be created by varying many different as-pects of a wildtype promoter such as the upstream element prior to the -35 region, the downstream element, after the -10 region prior to -1, and its core sequence, between the -35 and -10 regions (Schlabach et al., 2010). In this study, we propose to use the PLac promoter sequence as our wildtype for creating promoter designs varying different areas of its sequence. One of such variation will be the substitution of the -35 and -10 currently found in PLac with the -35 (TTGACA) and -10 (TATAAT) regions found to be the most commonly occurring in E. coli natural promoters (Hawley and McClure, 1983, DeBoer, 1985, Harley and Reynolds, 1987). These were chosen to be the constant region between different promoter designs.

By analyzing the findings of Harley and Reynolds (1987) and Lisser and Margalit (1993), the decision to vary the number of base pairs in the region present between the -35 and -10 elements to 17 base pairs instead of the 18 present in the wildtype PLac. Variations of the upstream and downstream regions where the lac operon would normally bind to will also be investigated in this study by the production of three different promoter designs resulting in a diverse promoter library.

Design Stage

As seen in Figure 3(B), the regions known to be important for a reliable promoter expression (-35 and -10 regions) were changed to variant of the wildtype but kept constant between the three distinctive designs. These regions were discovered to be the most frequent occurring -35 and -10 regions in native E. coli promoters by Harley and Roberts in 1987. The sequences between such converged regions were kept constant as per the wildtype for designs 2 (P2) and 3 (P3). For design 1 (P1) however, they were randomized in order to test its effect. The decision to reduce the number of base pairs from 18, found in PLac, to 17 was made due to the results of the study by Harley and Roberts in 1987, listing this number to be the most frequent occurring number of base pairs gap found in regions in native E. coli promoters.

Design 1 (P1) was made by randomizing all elements of the promoter while only keeping the -35 and -10 regions constant. The upstream element (US element) of P2 were randomized while keeping the downstream element (DS element) conserved as per wildtype. The DS element of P3 however, was randomized while keeping the upstream element conserved. This systematic approach of randomization was chosen as it allows for the most variation between promote designs allowing for a rich synthetic promoter library.

In order to implement these synthetic promoter detector variants into the Sensynova platform, designs were made by replacing the IPTG detection module of our framework with the promoter library.

Figure 4: SBOL Visual Detailing Detector Promoter Variants

Implementation

The promoter designs were sent off for synthesis by IDT as single stranded oligos.

Using Q5 PCR, the three designs P1, P2, and P3 were converted into double stranded DNA. Once PCR purified, samples were restrict digested using EcoRI and SpeI. Digests were subject to gel electrophoresis.

The plasmid backbone, BBa_J61002, was digested using EcoRI and XbaI and purified following gel electrophoresis.

Promoter designs were assembled into BBa_J61002 using BioBrick cloning. Ligations were transformed into E. coli DH5α cells and grown overnight.

Colony PCR was performed to check ligations. Colonies picked for this protocol were streaked onto a LB-agar plate.

Colonies were picked from streaked plates and cultures were prepared for miniprepping. DNA samples were then sent off for sequencing to ensure that the constructs were correct. Sequencing data can be found on the Parts page.

Conclusions and Future Work

Though we have generated a sizable library of promoters of varying strengths and functions, we lacked the time to complete its characterization by the screening against targeted molecules.

Due to time constraints, we also lacked the time to characterise these parts into the Sensynova platform within the lab.

References

Becker, N., Peters, J., Lionberger, T. and Maher, L. (2012). Mechanism of promoter repression by Lac repressor–DNA loops. Nucleic Acids Research, 41(1), pp.156-166.
DeBoer, H. (1985). Microbial hybrid promoters. US4551433 A.

Harley, C. and Reynolds, R. (1987). Analysis of E.Coli Promoter sequences. Nucleic Acids Research, 15(5), pp.2343-2361.

Hawley, D. and McClure, W. (1983). Compilation and analysis of Escherichia coli promoter DNA sequences. Nucleic Acids Research, 11(8), pp.2237-2255.

Lisser, S. and Margalit, H. (1993). Compilation of E.coli mRNA promoter sequences. Nucleic Acids Research, 21(7), pp.1507-1516.

Liu, M., Tolstorukov, M., Zhurkin, V., Garges, S. and Adhya, S. (2004). A mutant spacer sequence between -35 and -10 elements makes the Plac promoter hyperactive and cAMP receptor protein-independent. Proceedings of the National Academy of Sciences, 101(18), pp.6911-6916.

Schlabach, M., Hu, J., Li, M. and Elledge, S. (2010). Synthetic design of strong promoters. Proceedings of the National Academy of Sciences, 107(6), pp.2538-2543.

BioBricks used: BBa_J33201(Edinburgh ), BBa_K2205022 (New)

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team that hamper the success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Reporter) by three E. coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by replacing the IPTG detector part of the Sensynova design with different detecting parts. In particular, an Arsenic sensing part will be used.

Background Information

The part BBa_J33201 was made by the Edinburgh team in 2006.

This part consists of the promoter of the E. coli JM109 chromosomal arsenic detoxification operon (ars operon), including the ArsR repressor binding site and the arsR gene encoding the arsR repressor protein, together with its ribosome binding site. Addition of any other genes to the 3' end of this part will result in their expression being dependent on the presence of sodium arsenate or sodium arsenite. Arsenite or arsenite anion binds to the repressor protein ArsR, resulting in inability to repress the promoter. Based on Edinburgh's 2006 team experiments, a concentration of 1 micromolar sodium arsenate in LB is sufficient for essentially full expression, though this will vary according to conditions.

Design Stage

In order to introduce the Arsenic sensing part in the Sensinova framework, the part BBa_K2205008 containing the RBS B0034, the lasI coding sequence and the double terminator B0015 has been included in the design. The new part BBa_K2205022 presents biobrickable suffix and prefix and has been designed to have specific overhangs to be assembled in the plasmid pSB1C3 by Gibson assembly method.

Figure 2: The new part BBa_K2205022 based on the previous Arsenic detector design BBa_J33201, implemented by the Sensynova part coding for the connector 1, BBa_K2205008.

Figure 3: The expression vector pSB1C3 with BBa_K2205022. (click on the plasmid to enlarge it).

Implementation

The part has been obtained by gBlock synthesis from IDT and subsequently assembled into the plasmid using NEB HI-Fi kit. The assembly mix was heat-shock transformed in competent DH5α and plated on Chloramphenicol LB plates. The colonies were tested through colony PCR and confirmed by sequencing. Sequencing data can be found on the Parts page.

In the presence of arsenic, the repression will be avoided by binding the repressor ArsR This bound allows the transcription of the downstream gene, lasI. This gene encodes for the quorum sensing molecule C12, which acts as a connector to the processing cell.

Characterisation

Qualitative assay. Due to time constraints only a preliminary qualitative assay was carried out. Co-cultures of Arsenic detector, processor unit and 3 different reporter modules carrying two chromoproteins (BBa_K2205016, BBa_K2205018) and sfGFP (BBa_K2205015) were inoculated and grown overnight in LB+chloramphenicol (12.5ng/ul). The day after the cultures were diluted at OD600 0.1 and mixed together to obtain co-cultures with ratio 1:1:13 (detector:processor:reporter). The samples were supplemented with different concentration of Arsenic (0ppb, 10ppb, 50ppb, 100ppb) to induce the expression of quorum sensing molecules and eventually achieve the chromoproteins visualisation (Figures 6, 7, 8).

Figure 6: Pellets collected after overnight co-cultures of Arsenic detector (BBa_K2205022) + processor (BBa_K2205012) + Pink Chromoprotein reporter (BBa_K2205018) in ratio 1:1:13, with different concentrations of Arsenic (0ppb, 10ppb, 50ppb, 100ppb).

Figure 7: Pellets collected after overnight co-cultures of Arsenic detector (BBa_K2205022) + processor (BBa_K2205012) + Blue Chromoprotein reporter (BBa_K2205016) in ratio 1:1:13, with different concentrations of Arsenic (0ppb, 10ppb, 50ppb, 100ppb).

Figure 8: Pellets collected after overnight co-cultures of Arsenic detector (BBa_K2205022) + processor (BBa_K2205012) + sfGFP reporter (BBa_K2205015) in ratio 1:1:13, with different concentrations of Arsenic (0ppb, 10ppb, 50ppb, 100ppb).

The preliminary qualitative assay above shows that there is no significant difference among the samples when inoculated with Arsenic in different concentrations and the controls (no Arsenic). Optimisation of the Arsenic detection into the Sensynova framework is required.

Conclusions and Future Work

The results demonstrate that further characterisation needs to be conducted in order to optimise the Arsenic detector variant in the Sensynova platform. However, due to time constraints, we adapted the IPTG framework modelling results to the preliminary experiments conducted for the framework customised as the Arsenic biosensor. In order for future characterisation of this part, the model should be modified in order to guide in vivo efforts accordingly.

References

Brenner K, Karing D, Weiss R, Arnold F (2007) Engineered bidirectional communication mediates a consensus in a microbial biofilm consortium. Proc Natl Acad Sci USA 104(44): 17300 - 17304
de Mora K, Joshi N, Balint BL, Ward FB, Elfick A, French CE (2011) A pH-based biosensor for detection of arsenic in drinking water. Anal Bioanal Chem 400(4):1031-9 (Epub 2011 Mar 27).

BioBricks used: BBa_K2205023 (New), BBa_K2448006 (Evry Paris-Saclay 2017), BBa_K2448050 (Evry Paris-Saclay 2017)

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team that hamper the success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Output) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by implementing the biosensor created by the 2017 Evry Paris-Saclay iGEM team into the Sensynova platform as part of our collaboration requirement.

Background Information

This biosensor was designed, made and submitted to the iGEM registry by the Evry Paris-Saclay 2017 team.

We chose to use this system as a variant to the IPTG detector module present in the Sensynova platform in order to fulfil the requirement of collaborating with another iGEM team.

The image below, provided to us by the Evry Paris-Saclay 2017 team, details the psicose biosensor design. It features the PLac derivative promoter PTAC (BBa_K180000), a RBS (BBa_B0034), the PsiR coding sequence, the terminator (BBa_B0015), the synthetic promoter pPsitac2, a RBS (BBa_B0034), a mCherry coding sequence and finally the terminator (BBa_B0015) flanked by the iGEM prefix and suffix.

The inducible system works as detailed in the diagram below. When pTAC is induced due to the presence of IPTG, PsiR is transcribed and binds to the pPsitac2 promoter repressing the transcription of the mCherry protein. When psicose is present, the sugar binds to PsiR, freeing up the promoter and subsequently the colour output.

Design Stage

In order to implement the psicose biosensor variant to the Sensynova platform, a design was created by replacing the IPTG sensing system in the original detector module with the construct detailed above, creating part BBa_K2205023 .

We chose to replace the PTAC promoter with the constitutive promoter present within the platform in order to eliminate the need for induction with IPTG. In place of the colour output present in the Evry Paris-Saclay design, we have added our part BBa_K2205008, which produces our first connector in order to trigger a response from following modules of the Sensynova platform.

Part BBa_K2205023 detailed above was designed using Benchling and ordered for synthesis through IDT. Using Benchling, virtual digestions and ligations were simulated resulting in the plasmid map detailed below.

Implementation

The Psicose detector construct obtained by gBlock synthesis has been designed to include required overhangs for Gibson assembly into the linearized plasmid pSB1C3.

The plasmid backbone was acquired by digestion of the part BBa_K2205015 with XbaI and SpeI, cutting out the original sfGFP construct.

The Psicose detector construct was assembled into the plasmid backbone using the NEB Hi-Fi kit and transformed into DH5α E. coli cells. miniprepping. DNA samples were then sent off for sequencing to ensure that the constructs were correct. Sequencing data can be found on the Parts page.

Characterisation

A preliminary qualitative assay was carried out as an initial test for this construct. Co-cultures of Psicose detector, processor unit and sfGFP reporter (BBa_K2205015) were inoculated and grown overnight in LB+chloramphenicol (12.5 ng/ul).

The day after the cultures were diluted at OD600 0.1 and mixed together to obtain co-cultures with ratio 1:1:13 (detector:processor:reporter). The samples were supplemented with 33.22 mM Psicose to induce the expression of quorum sensing molecules and eventually achieve the reporter visualisation (Figures 8).

Conclusions and Future Work

The results demonstrate that further characterisation needs to be conducted in order to optimise the psicose detector variant in the Sensynova platform however, due to time constraints resulted from synthesis delays, we lacked the time to be able to do so. The preliminary experiments conducted for the framework customised as the psicose biosensor were conducted by following data resulted from the model of the framework customised as the IPTG sensor. In order for future characterisation of this part, the model should be modified in order to guide in vivo efforts accordingly.

We also lacked the time to co-culture this part with the Sensynova platform's multiple modules in order for the creation of variants for the Evry Paris-Saclay. The part BBa_K2205023, the Evry Paris-Saclay's psicose biosensor system as the detecting unit of the platform, has been submitted to the iGEM registry for future work and characterisation by future teams.

References

iGEM Community. (2017). Team Evry Paris-Saclay 2017. [online] Available here.

BioBricks used: BBa_K2205029 (New), BBa_K2205030 (New), BBa_K749021(TMU-Tokyo 2012 )

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team that hamper the success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Output) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by implementing the formaldehyde biosensor as a variant to the detector module of the Sensynova platform.

Background Information

The formaldehyde biosensor, part BBa_K749021, was selected was originally made and submitted to the iGEM registry by the TMU-Tokyo 2012 team.

This part was chosen as a variant to the detector module present in the Sensynova platform due to the fact that our adaptor module present in the framework, Sarcosine Oxidase, was made in order to convert glyphosate into formaldehyde, in order to overcome the limitation in the detection of glyphosate due to its little-known knowledge.

The BBa_K749021 is composed of the formaldehyde sensitive promoter BBa_K749008, the formaldehyde regulator protein frmR (BBa_K749004) coding sequence, a GFP coding sequence and a double terminator (BBa_B0010 and BBa_B0012). The Formaldehyde sensitive promoter expression is normally repressed by FrmR however, when Formaldehyde is present, the bond is broken triggering transcription of the GFP coding sequence and subsequently the triggering a colour output.

Design Stage

In order to implement the Formaldehyde biosensor variant to the Sensynova platform, a design was created by replacing the IPTG sensing system in the original detector module with the construct detailed above, creating part BBa_K2205030 .

We chose to redesign the Formaldehyde biosensor detailed above to mirror the design used when producing the Psicose detector variant. The system detailed in the image below is made up of the constitutive promoter present within the platform triggering transcription of the FrmR repressing the PfrmR and subsequently the connector 1 of the Sensynova platform. We have also replaced the colour output present in the TMU-Tokyo design, we have added our part BBa_K2205008, which produces our first connector in order to trigger a response from following modules of the Sensynova platform in the presence of Formaldehyde.

Part BBa_K2205030 detailed above was designed using Benchling and virtual digestions and ligations were simulated resulting in the plasmid map detailed below.

This part was created as a design only. The part BBa_K2205030 was not ordered for synthesis through IDT and subsequently not submitted to the registry.

Conclusions and Future Work

Due to time constraints, we lacked the time to synthesise, implement and characterise this part into the Sensynova platform within the lab. Future work on this part would include characterisation in vivo guided by the modelling of the framework when customised as a formaldehyde biosensor and testing against the Sarcosine Oxidase adaptor module currently present in the framework.

References

iGEM Community (2012), Team TMU-Tokyo. Available here. [Accessed 1 Nov 2017]

BioBricks made and used: BBa_K2205005 (New), BBa_K1632013 (2015 Tokyo Tech part), BBa_K1632007(2015 Tokyo Tech part)

Rationale and Aim

Sensynova multicellular biosensor platform has been developed to overcome the limitations that hamper success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Reporter) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This part can be used within the platform as a processor unit. Real world applications of biosensors are limited by many factors, one of which is that with most biosensors there is not a readout signal showing if the biosensor is working when not in use, i.e that the cells are still alive and have not lost their biosensor phenotypes. This can make them difficult to use, as well as market, since their viability comes into question as well as leading to false negatives/positives. Biosensors which rely on expression of a reporter signal may also suffer from unobserved activation due to weak or inconstant induction.

For this section of the project, as an improvement on a part by the Tokyo Tech 2015 team (BBa_K1632013), we aim to produce a biobrick compatible part which is able to constitutively express a reporter signal prior to activation (to show that it is functioning) and to amplify a weak or inconsistent induction signal by permanently switching from an [OFF] to [ON] state after induction.

Background Information

Expression of the E. coli type 1 fimbriae gene is tightly regulated and phase dependent, i.e expression is either completely [ON] or [OFF] (Klemm, 1986). This change in expression is controlled by the action of two proteins FimB and FimE which independently act upon a 300bp promoter region upstream of the fimbriae gene. The 300bp promoter region is inverted to either activate or suppress expression (McClain et al., 1991). Typical gene regulation mechanisms rely on up or down regulation of a promoter from a baseline expression, the fimbriae mechanism of ‘ALL’ or ‘NONE’ makes it a useful tool for synthetic biology applications. While the FimB protein inverts the promoter back and forth between [ON] and [OFF] states the FimE protein permanently inverts the promoter from [ON] to [OFF]. This inversion can be used to amplify weak or inconsistent induction signals.

Since the part we are making is designed to amplify a weak signal which can then be detected by a downstream ‘reporter’ cell the quorum sensing system from P. aeruginosa was adapted to allow for signal transfer between cells. The rhlI gene from P. aeruginosa produces the quorum sensing molecule N-butyryl-AHL (C4-AHL) (Parsek et al.,2000) (J64718), this molecule is membrane permeable and able to induce expression of a promoter upstream of sfGFP in another cell (K2205015).

Design Stage

To construct the Fim reporter switch 3 separate gBlocks were designed with overlapping adaptor regions homologous to the iGEM prefix and suffix to allow for Gibson assembly into the pSB1C3 backbone whilst retaining biobrick compatibility. The individual genes and other components are shown in (Table 1). The 1st gBlock sequence starts with a RBS (B0034) upstream of the fimE ORF (K137007) with no promoter region, this is to allow for other promoters to be cloned in upstream of the part. Downstream of the fimE gene is a double terminator (B0015). All RBS and terminator sequences used are B0034 and B0015 respectively. The switching mechanism consists of the Fim promoter sequence (K1632004) flanked by two RBS-ORF-Terminator sequences. While in the native [OFF] state the Fim promoter drives expression of eforRed (K592012) and when flipped to the [ON] state drives expression of rhlI (J64718). The rationale behind using the fimE gene instead offimB is that it permanently inverts the promoter region meaning weak induction signals can be amplified by the Fim switch.

Implementation

To assemble the Fim switch part the isothermal Gibson assembly cloning method was chosen as it would significantly shorten the time taken to assemble 3 separate sequences compared to traditional cloning methods. The 3 gBlock DNA fragments shown in (Table 1) were amplified by high fidelity Q5 PCR and the pSB1C3 backbone was digested with restriction enzymes EcoRI and PstI.

The Gibson assembly reaction re-forms the iGEM prefix and suffix regions at the 5’ and 3’ ends of the Fim switch part making the component biobrick compatible while leaving no scarring regions. Following assembly, the plasmid was transformed into chemically competent DH5α E. coli and colonies patched onto LB Chloramphenicol agar plates. A single patch showed the correct red colour indicative of the eforRed chromoprotein (see Figure 3).

The red patch was cultured in LB chloramphenicol overnight and the plasmid DNA extracted by miniprep. The plasmid was digested with restriction enzymes XbaI and PstI. The image in Figure 4 shows the DNA bands from the digested Fim switch plasmid.

The Fim switch insert is 2882 bp in length which makes performing standard short sequencing reads challenging as multiple reactions are required to completely sequence the entire part. To overcome this we used our in-house Illumina MiSeq to completely sequence the entire plasmid. Following quality control analysis the sequence was assembled and shown to be a match to the expected Fim switch part.

A problem we found with the Fim switch was that a subset of the colonies were prematurely switching from red to white. This is likely due to a low level of leaky expression of the fimE gene which then inverts the promoter region upstream of the eforRed gene. A single white colony was picked and cultured for use in downstream testing as a control as the switching of the promoter should express the rhlI gene and therefor produce the C4 quorum sensing molecule.

Characterisation

To test the functionality of the Fim switch, ensuring that C4 AHL is produced, the strain was cultured with a reporter strain (K2205015) which produces GFP in response to the quorum sensing molecule C4 AHL. Due to a small sub-population of the Fim switch strain being white, a single white colony was picked and cultured separately. This strain was used as a positive control as it should produce C4 AHL. Both the majority (red) Fim switch strains and minority flipped (white) Fim switch strains were tested for C4 AHL production by co-culture with the reporter strain. Initially the Fim switch strains were spotted onto a lawn of the reporter strain (Figure 5) followed by quantitative analysis of the strains by co-culture in a 96 well microplate (Figure 6). This culture is then co-cultured with the reporter cell. This reporter cell detects C4 AHL and expresses GFP in response.

Conclusions

The aim of the Fim switch part was to make a processor module which can be visually inspected for functionality. The Fim switch has been shown to expresses the eforRed chromoprotein under normal (uninduced) conditions which allows the user to both determine that the strain is alive and has maintained the Fim switch plasmid. Following induction, the Fim promoter flips direction and begins expressing RhlI which synthesises the C4-AHL quorum sensing molecule. This has been shown to successfully induce expression of sfGFP in the reporter strain (BBa_K2205015).

Despite several attempts we were unable to produce a Fim switch testing construct where fimE expression could be controlled using the E. coli arabinose inducible promoter. Though transformations did yield some colonies when trying to make this part, none were red in colour. This possibly indicates that the arabinose inducible promoter (even when grown on 0.5% w/v glucose) is still too active. The design for this construct has been submitted (BBa_K2205006).

Future Work

Since there is some leaky expression of the fimE gene (even without a promoter) to fine tune the Fim switch the lac operator could be inserted upstream of the fimE RBS to repress unwanted expression. The part could then be used following the addition of IPTG. An alternative method would be to clone a transcriptional terminator upstream of the fimE RBS to prevent leaky expression from elsewhere in the plasmid.

References

P. Klemm, Two regulatory fim genes, fimB and fimE, control the phase variation of type 1 fimbriae in Escherichia coli. EMBO J 5, 1389-1393 (1986).

M. S. McClain, I. C. Blomfield, B. I. Eisenstein, Roles of fimB and fimE in site-specific DNA inversion associated with phase variation of type 1 fimbriae in Escherichia coli. J Bacteriol 173, 5308-5314 (1991).

M. R. Parsek, E. P. Greenberg, Acyl-homoserine lactone quorum sensing in gram-negative bacteria: a signaling mechanism involved in associations with higher organisms. Proc Natl Acad Sci U S A 97, 8789-8793 (2000).

BioBricks used: BBa_K2205024 (New), BBa_K2205025 (New), BBa_K2205027 (New), BBa_K2205028 (New), BBa_K274371 (Cambridge 2009), BBa_K274381 (Cambridge 2009)

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team that hamper the success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Reporter) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by inserting two different sensitivity tuner constructs between the processing units of the Sensynova platform; BBa_K274371 and BBa_K274381 .

Background Information

Both selected sensitivity tuner constructs were made and submitted to the iGEM registry by the Cambridge 2009 team.

They were chosen as variants to the empty processing module present in the Sensynova platform due to the fact that, although they have been included in the iGEM distribution kit since their submission in 2009, they have yet to be successfully implemented into a team’s system, as far as we are aware.

The 2007 Cambridge iGEM team built 15 different constructs that amplified the PoPS output of the promoter pBad/AraC detailed by image below taken from the Cambridge 2009 team's wiki.

The 2009 Cambridge iGEM team then re-designed these constructs to be PoPS converters, as image below taken from their wiki details, and generated a set sensitivity tuners corresponding to Cambridge 2007’s amplifiers.

BBa_K274371 – P2 Phage Sensitivity Tuner

This part is made up of an RBS (BBa_B0034), an org activator coding sequence (BBa_I746350) from P2 phage, the double terminator BBa_B0015 (made up of BBa_B0010 and BBa_B0012) and the inducible promoter PO (BBa_I746361) from P2 phage.

BBa_K274381 – PSP3 Phage Sensitivity Tuner

This part is made up of an RBS (BBa_B0034), a pag activator coding sequence (BBa_I746351) from PSP3 phage, the double terminator BBa_B0015 (made up of BBa_B0010 and BBa_B0012) and the inducible promoter PO (BBa_I746361) from P2 phage.

Design Stage

In order to implement these two sensitivity tuner variants into the Sensynova platform, designs were made by inserting the above parts between the two constructs forming the empty processor module of our framework.

Using Benchling, virtual digestions of the two sensitivity tuners and ligations to the part K2205010, the connector 1 receiver module, were carried out. These two new constructs were then virtual digested and ligated to the part K2205011, the connector 2 reporter module, resulting in the two plasmid maps detailed below; parts K2205024 and K2205025.

Implementation

The sensitivity tuners parts BBa_K274371 and BBa_K274381 were requested from the iGEM parts registry. Upon arrival, parts were transformed in DH5α E. coli cells. Colonies were picked and cultures were prepared for miniprepping. Minipreps were digested with XbaI and PstI for BioBrick assembly.

The part K2205010 contained in pSB1C3, was digested using SpeI and PstI to allow for the insertion of the processing variants directly after the Las controlled promoter (pLas) that would trigger transcription of sensitivity tuners in the presence of connector 1 of the Sensynova platform.

Ligations were set up overnight using NEB’s T4 ligase and transformed in DH5α E. coli cells. Colony PCR was performed to check ligations. Colonies picked for this protocol were streaked onto a LB-agar plate.

Colonies picked from streaked plates and cultures were prepared for miniprepping. Minipreps were digested with SpeI and PstI to allow for the insertion of the part K2205011 directly after the PO promoter.

The part K2205010 contained in pSB1C3, was digested using XbaI and PstI for BioBrick assembly. Ligations were set up overnight using NEB’s T4 ligase and transformed in DH5α E. coli cells. Colony PCR was performed to check ligations. Colonies picked for this protocol were streaked onto a LB-agar plate.

Colonies picked from streaked plates and cultures were prepared for miniprepping. DNA samples were then sent off for sequencing to ensure that the constructs were correct. Sequencing data can be found on the Parts page.

Conclusions and Future Work

Due to time constraints, we lacked the time to characterise these parts into the Sensynova platform within the lab. The parts BBa_K2205024 and BBa_K2205025, the parts BBa_K274371 and BBa_K274381 respectively as processing units of the platform, were been submitted to the iGEM registry for future work and characterisation by future teams.

The intermediate parts BBa_K2205027 and BBa_K2205028, the parts BBa_K274371 and BBa_K274381 respectively resulted from the ligation to the first part of processing unit of the platform prior to the ligation to part of processing unit of the platform, were also submitted to the registry.

References

iGEM Community. (2009). Team Cambridge 2009. [online] Available here [Accessed 30 Oct. 2017].

BioBricks used: BBa_K2205001 (New), BBa_K2205002 (New), BBa_K515105 (Imperial College London 2011)

Rationale and Aim

deGFP is a variant of Green Fluorescent Protein (GFP). It was initially designed by Shin and Noireaux (2010) for expression in cell-free protein synthesis (CFPS) systems and is more efficiently translated than other variants (e.g. eGFP). Through talks with other biosensor developers (for example, Chris French), and after reviewing legislation regarding the use of synthetic biology outside of the lab environment, the importance of CFPS systems as a chassis was highlighted. Despite its importance, CFPS systems can still suffer from some issues such as lower total protein synthesis than whole cells. By standardising and characterising a GFP variant which has been modified to have enhanced expression in these systems, it is hoped that CFPS will become a more attractive option for researchers.

The aims for this section of the project were: (i) to standardise deGFP as a BioBrick and submit it to the iGEM repository, (ii) to demonstrate expression of deGFP in commercially available cell-free systems, and (iii) to characterise expression of deGFP in E. coli cells.

Background Information

deGFP is a modified variant of eGFP developed by Shin and Noireaux which is more efficiently translated in CFPS systems. It was designed by truncating the N-terminal sequence and introducing silent mutations which removed internal ribosome binding like sequences. The C-terminal sequence is also truncated as this has been shown to not be necessary for maximal fluorescence (Li et al. 1997). By removing ribosome binding like sequences, Shin and Noireaux have reduced the amount of incorrect ribosome binding events and hence increased translation efficiency. The length of the protein also contributes to enhanced translation efficiency by reducing the time and resources required for this process to reach completion.

Design Stage

The deGFP sequence was taken from the Addgene database (Plasmid #40019). The sequence was found to have no illegal restriction sites (i.e. no EcoRI, XbaI, SpeI, or PstI sites). A strong, standard Anderson promoter (J23100) and RBS (B0034) was added before the deGFP sequence with biobrick scar sites between each part. A double terminator (B0015) was added after the deGFP sequence. The entire construct was flanked by 30 bp overhangs with the pSB1C3 plasmid, such that the construct could be Gibson assembled into a pSB1C3 plasmid digested with XbaI and SpeI (Figure 1). Extra bases were added between the overhangs and the construct so that once the part was assembled into the plasmid, the XbaI and SpeI sites could be regenerated and the biobrick prefix and suffix restored. This construct (J23100-deGFP) with the overhangs was submitted to IDT for synthesis as a gBlock.

Figure 1: Top: SBOL Visual schematic of BBa_K2205002 (J23100-deGFP). Bottom: plasmid map for BBa_K2205002 in pSB1C3 plasmid backbone - generated by Benchling.

Implementation

The J23100-deGFP construct described above was Gibson assembled into a pSB1C3 plasmid using the NEB Hi-Fi assembly kit. To do this, pSB1C3 was digested with XbaI and SpeI to create a linearised plasmid backbone. The deGFP gBlock DNA was prepared according to the IDT protocol and assembled into the linear plasmid backbone according to the NEB Hi-Fi Protocol. The assembly mixture was then transformed into commercial DH5α cells and incubated on chloramphenicol plates overnight. Colonies which were green under UV light were picked and grown in 5 mL LB broth overnight before undergoing plasmid extraction. Successful insertion of the J23100-deGFP construct into pSB1C3 was confirmed through a restriction digest with EcoRI and PstI followed by gel electrophoresis . Figure 2 shows that the insert was successfully inserted as the double digest resulted in two linear bands at ~2100 bp (linear plasmid) and ~800 bp (deGFP). The DNA samples were then sent for sequencing to ensure that the construct was correct. Sequencing data can be found on the Parts page.

Figure 2: Restricition digest gel of BBa_K2205002 in pSB1C3. Plasmid DNA was digested with EcoRI and PstI. The digest mixture was then analysed on an agarose gel with NEB 1KB ladder. Fragments were visulaised at ~2100 bp (lineraised pSB1C3), and at ~800 bp (BBa_K2205002 insert).

Characterisation

The expression of deGFP was first tested in E. coli cells using an experimental procedure similar to that used in the Interlab study. Cells transformed with pSB1C3-J23100-deGFP were grown in 10 mL LB broth overnight and OD600 nm was measured. Culture was added to 3 separate falcon tubes and made up to 12 mL with LB with chloramphenicol such that the starting OD600 of the culture was approximately 0.02. This set-up was repeated with cells containing an identical plasmid and construct, except sfGFP was in place of deGFP. As a control, untransformed cells were also prepared identically except the LB did not contain chloramphenicol. Tubes with only LB and LB+chloramphenicol were also prepared as blanks.

The cultures were shake-incubated at 37oC. 300 μL samples from each tube were taken at time points of 15 mins, 2 hours, 4 hours, and 6 hours and stored at 4oC until the end of the experiment. 100 μL of each sample were then added to a 96-well plate. Fluorescence (excitation 485 nm, emission 510 nm) and absorbance (OD600 nm) were measured using a BMG-Labtech fluostar optima plate reader. Fluorescence intensity and grow rates for all three cell types were calculated over time (Figure 3). It was found that while cells expressing sfGFP had a much higher fluorescence intensity than cells expressing deGFP, the growth rate for cells with deGFP was closer to that of untransformed cells. This suggests that in vivo, either deGFP has lower expression than sfGFP, or each molecule of deGFP emits less fluorescence.

Figure 3: a) fluorescence intensity of E. coli cells overtime. Each bar represents an average of three repeats, and error bars represent +/- standard error. Fluorescence intensity was negative corrected to LB media. b) growth rate of E. coli cells over time. Each bar represents an average of three repeats, and error bars represent +/- standard error. OD¬600 was negative corrected to LB media.

Figure 4: Visual fluorescence of E. coli cells under UV light. Image shows WT cells (left), cells expressing deGFP (middle), and cells expressing sfGFP (right).

The Exeter iGEM team aided us in characterising the deGFP using Fluorescence Activated Cell Sorting (FACS) to get single-cell data. The J23100-deGFP plasmid DNA (BBa_K2205002) was transformed into Top10 E. coli cells by the Exeter iGEM team. They then used a FACS machine to analyse the fluorescence of 10,000 cells in 2 cultures of wild types cells, and 5 cultures of Top10 cells expressing deGFP. We then analysed the data to determine that approximately ~50% of cells in the culture were fluorescent (Figure 5).

Figure 5: Single cell data for E. coli cells expressing deGFP (collected by Exeter iGEM). Columns 1-6: cells expressing deGFP. Columns 7 and 8: wild type Top10 cells. Red parts of the bar are non-fluorescent cells, green parts are fluorescent cells.

Expression of deGFP in a cell-free protein synthesis (CFPS) system was then tested. Commercial S30 cell free kits for circular DNA from Promega were used so that results could be easily compared between labs. Reactions were prepared as described in the manufacturer’s protocol. Briefly, a master mix for 10 reactions was prepared (200 μL S30 premix, 150 μL S30 extract, 25 μL amino acid mix minus leucine, 25 μL amino acid mix minus cysteine) and 40 μL was added to nine tubes. To three tubes 1.2 μg J23100-deGFP was added, and J23100-sfGFP plasmid DNA was added to a further three. All reactions were then made up to 50 μL with nuclease-free water and transferred to a 96-well plate. Reactions were incubated in a BMG Labtech Fluostar Optima plate-reader at 37oC with fluorescence readings (excitation 485 nm, emission 510 nm) every 15 mins. It was found that, as expected, expression of the J23100-deGFP construct showed fluorescence above background level (Figure 6). It was also found that expression of the J23100-sfGFP construct in a CFPS system results in higher levels of fluorescence than deGFP. Therefore, although deGFP may show improved expression in CFPS systems than other GFP variants, sfGFP still shows higher fluorescence levels.

Figure 6: CFPS Expression of J23100-deGFP and J23100-sfGFP Constructs. Time course for increase in fluorescence intensity of CFPS systems expressing GFP constructs over time. Each data point is an average of triplicate results, and error bars show +/- standard error. CFPS system with no DNA (Red) was used as the negative control.

Conclusions and Future Work

We have successfully managed to BioBrick standardise deGFP for the first time, and have fully characterised this reporter, both in cells and in cell-free systems. As expected, this GFP variant showed fluorescence in both types of chassis. We also compared this GFP variant to superfolder GFP (sfGFP), which as far as we are aware has not been done before. We found that sfGFP had a higher fluoresence intensity in whole cells and CFPS systems compared to deGFP.

deGFP was engineered from the eGFP variant originally by removing RBS-like binding sites from the sequence, and truncating the sequence in an attempt to enhance translational efficiency. It may be possible in the future to engineer a better alternative to deGFP by using sfGFP as a starting point, rather than eGFP.

References

Li X., Zhang G., Ngo N., Zhao X., Kain S.R., Huang C.C., (1997), Deletions of the Aequorea victoria green fluorescent protein define the minimal domain required for fluorescence, J. Biol. Chem., 272:28545–9, doi: 10.1074/jbc.272.45.28545
Shin, J., and Noireaux, V., (2010), Efficient Cell-Free Expression with the Endogenous E. coli RNA Polymerase and Sigma Factor 70, J. Biol. Eng., 4:8, doi: 10.1186/1754-1611-4-8

BioBricks used: BBa_K2205016(New),BBa_K2205017(New),BBa_K2205018(New), BBa_K1033915(Uppsala 2013), BBa_K1033925 (Uppsala 2013), BBa_K1033929 (Uppsala 2013)

Rationale and Aim

The Sensynova multicellular biosensor platform has been developed to overcome the limitations identified by our team that hamper success in biosensor development. One of these limits regards the lack of modularity and reusability of the various components. Our platform design, based on the expression of three main modules (Detector, Processor and Reporter) by three E.coli strains in co-culture, allows the switch of possible variances for each module and the production of multiple customised biosensors.

This section of the project is based on testing the modularity of the system by replacing the sfGFP output part of the Sensynova platform design with three different output chromoprotein variants; BBa_K1033929 (aeBlue), BBa_K1033925 (spisPink) and BBa_K1033915 (amajLime).

Background Information

All three selected chromoproteins were made and submitted to the iGEM registry by the Uppsala 2013 team.

They were chosen as variants to the sfGFP present in the Sensynova platform as they exhibit of strong colour readily observed in both LB cultures and in agar plates when expressed.

All three proteins have significant sequence homologies with proteins in the GFP family.

BBa_K1033915 – amajLime

The amajLime protein is a yellow-green chromoprotein extracted from the coral Anemonia majano. It was first extracted and characterized by Matz et al. under the name amFP486 (UniProtKB/Swiss-Prot: Q9U6Y6.1 GI: 56749103 GenBank: AF168421.1) and codon optimized for E coli by Genscript. The protein has an absorption maximum at 458 nm giving it a yellow-green colour visible to the naked eye.

BBa_K1033925 – spisPink

The spisPink protein is a pink chromoprotein extracted from the coral Stylophora pistillata. It was first extracted and characterized by Alieva et al. under the name spisCP (GenBank: ABB17971.1) and codon optimized for E. coli by Genscript. The protein has an absorption maximum at 560 nm giving it a pink colour visible to the naked eye. The strong colour is readily observed in both LB or on agar plates after less than 24 hours of incubation.

BBa_K1033929 – aeBlue

The aeBlue protein is a blue chromoprotein extracted from the basal disk of a beadlet anemone Actinia equine. It was first extracted and characterized by Shkrob et al. 2005 under the name aeCP597 and codon optimised for E. coli by Bioneer Corp. The protein has an absorption maximum at 597nm and a deep blue colour visible to the naked eye. The protein aeBlue has significant sequence homologies with proteins in the GFP family. The coding sequence for this protein was originally submitted to the registry as BBa_K1033916 by the 2012 Uppsala iGEM team.

Design Stage

In order to implement these three chromoprotein variants into the Sensynova platform, designs were made by replacing the sfGFP in the original reporter module with the parts detailed above that were ordered from the iGEM parts registry.

Using Benchling, virtual digestions of the three chromoproteins and ligations to the part K2205013, the connector 2 receiver module detailed above, were carried out resulting in the three plasmid maps detailed below; parts K2205016, K2205017 and K220518.

Implementation

The chromoproteins aeBlue (BBa_K1033929), amajLime (BBa_K1033915) and spisPink (BBa_K1033925) parts were requested from the iGEM parts registry. Upon arrival, parts were transformed in DH5α E. coli cells. Colonies were picked and overnight cultures were prepared for miniprepping. Minipreps were digested with XbaI and PstI for BioBrick assembly.

The part K2205013 contained in pSB1C3, was digested using SpeI and PstI to allow for the insertion of the chromoproteins directly after the RhI controlled promoter (pRhI) that would trigger transcription of colour proteins in the presence of connector 2 of the Sensynova platform.

Stared colonies picked from streaked plates and cultures were prepared for miniprepping. DNA samples were then sent off for sequencing to ensure that the constructs were correct. Sequencing data can be found on the Parts page.

Characterisation

Initial testing of these three chromoprotein reporter variants was conducted by inoculating 1ml of LB containing the antibiotic Chloramphenicol with a colony from each colour proven by colony PCR and sequencing data to be correct and grown at 37° for 2 hours as well as a control of wildtype DH5α.

Cultures were then plated onto a LB agar + Chloramphenicol plate which were then innoculated in four locations with 10μl of connector 2 (C12 - Rhl) and grown overnight resulting in the picture below.

There is a visible vibrant colour change present for both the spisPink and the aeBlue chromoprotein variants however, as the colour of the amajLime is very similar to the wildtype colour, both in cultures, pelleted and plated, the colour is difficulty distinguished. For this reason, it was decided to carry forward the two brightest chromoproteins for further testing while optimising amajLime separately.

In order to test these two chromoproteins reporter variants into the Sensynova framework, cultures of IPTG detector, processor unit and three reporter modules, two chromopreteins and the sfGFP control, were inoculated and grown overnight in LB+chloramphenicol (12,5ng/μl).

The cultures were then diluted at OD600: 0,1 and mixed together to obtain co-cultures with ratio 1:1:1 and 1:1:13. Some samples were supplemented with 1mM IPTG to induce the expression of quorum sensing molecules and eventually achieve the chromoproteins visualisation (Figures 6, 7, 8).

Figure 6: Pellets collected after overnight co-cultures of IPTG detector (BBa_K2205009) + processor (BBa_K2205012) + Pink Chromoprotein reporter (BBa_K2205018) in ratios 1:1:1 and 1:1:13, with and without 1mM IPTG.

Figure 7: Pellets collected after overnight co-cultures of IPTG detector (BBa_K2205009) + processor (BBa_K2205012) + Blue Chromoprotein reporter (BBa_K2205016) in ratios 1:1:1 and 1:1:13, with and without 1mM IPTG.

Figure 8: Pellets collected after overnight co-cultures of IPTG detector (BBa_K2205009) + processor (BBa_K2205012) + sfGFP reporter (BBa_K2205015) in ratios 1:1:1 and 1:1:13, with and without 1mM IPTG.

The three experiment sets clearly demonstrate that the framework is optimised when a higher concentration of cells expressing the reporter device is present (Figures 6, 7, 8, samples labelled 1:1:13).

Although a background signal is visible in the systems expressing the pink (BBa_K2205018) and the sfGPF (BBa_K2205015) reporters, the blue reporter (BBa_K2205016) due to its lowest background level, constitutes the most suitable reporter module for the Sensynova platform when customised as IPTG biosensor.

Conclusions and Future Work

The qualitative results detailed above highlight the crucial advantage of our multicellular, modular framework, as it enables each component to be optimised avoiding any extra cloning steps. As each biosensor may be different and require specific designs and optimisation, easily choosing and changing modules and predicting in silico the bacterial community behaviour is essential for the development of new biosensors.

References

Alieva, N., Konzen, K., Field, S., Meleshkevitch, E., Hunt, M., Beltran-Ramirez, V., Miller, D., Wiedenmann, J., Salih, A. and Matz, M. (2008). Diversity and Evolution of Coral Fluorescent Proteins. PLoS ONE, 3(7), p.e2680.

iGEM Community. (2013). Team Uppsala 2013. [online] Available at: https://2013.igem.org/Team:Uppsala [Accessed 30 Oct. 2017].

Matz, M., Fradkov, A., Labas, Y., Savitsky, A., Zaraisky, A., Markelov, M. and Lukyanov, S. (1999). Nature Biotechnology, 17(10), pp.969-973.

Shkrob, M., Yanushevich, Y., Chudakov, D., Gurskaya, N., Labas, Y., Poponov, S., Mudrik, N., Lukyanov, S. and Lukyanov, K. (2005). Far-red fluorescent proteins evolved from a blue chromoprotein fromActinia equina. Biochemical Journal, 392(3), pp.649-654.