Designed by: WEI KUANGYI   Group: iGEM18_GreatBay_China   (2018-10-01)

TALE2 sp6

A stabilised version of J23119 (Part:BBa_J23119) by adding an up-element, a TALE2 binding site, and a genetic circuit encoding for TALE2. Also a member of the TALE stabilised promoter family, characterized and sequenced by team GreatBay_China 2018.

An Introduction to TALE stabilised promoters

Genetic engineering requires elaborative design and sensible proportion of different components. For instance, unbalanced enzyme expression in metabolic engineering would lead to not only shunted flux to the product, but also unnecessary waste of carbon source and host growth inhibition. Plasmids are common engineering tools used to tune gene expression. People often assume that plasmids exist in stable copies, but this is a misleading assumption to make as plasmid copy number is actually subjected to huge variability. Altered chassis strains, new culture medium composition, different temperature, and difference in growth phase all hugely affect plasmid copy number. In our case, although E. coli and yeast are engineered separately, they eventually would be cultured together and probably using very different conditions because compromise is made to meet both requirements of both species. Subsequently, gene expression regulated by such design is easily agitated, leading to potential failure of synthetic device.

Transcription-activator-like-effector (TALE) stabilised promoters are a type of promoters able to untie gene expression level from gene copy number using an incoherent feedforward loop (iFFL) in which transcription-activator-like effectors (TALEs) function as a perfectly non-cooperative negative regulation. While copy number accretes gene expression, it also elevates the repression to the gene expression, thus has canceled out the effect of copy number on expression level. This design can also eliminate the impact of the location of genes (whether they are placed on plasmids or in the genome, and wherein the genome) on gene expression.

Having comprehended the incredible capability and potential of TALEsp, we were deeply inspired yet felt sorry that there were only six TALEsp available to use. In metabolic engineering and other areas of synthetic biology, people select promoters very carefully to ensure the most suitable strength is chosen, which seems difficult given so few candidates. Therefore, we expanded the TALEsp library through mutating core promoters of existing TALEsp, and adding TALE binding sites to the classical consensus promoter J23119, we created six more TALEsp, and have added all of twelve TALEsps to the iGEM Registry.

Biobrick Design

All promoters are placed on the standard biobrick assembly compatible backbone pSB1C3, with a RBS (BBa_B0034) reporter gene sfGFP (BBa_K1679038) downstream of the promoters in between the restriction sites of SpeI and PstI. So teams can change reporter genes as they wish.

For TALE stabilised promoters repressed by the same TALE, the only difference between them is the sequence of the core promoter which the TALE binds to. By replacing this promoter, new TALE stabilised promoters could then be easily created. For making the process more convenient, we designed this composite part in which a genetic circuit encoding for amilCP, a blue pigment, replaces the core promoter sequence, and downstream are a RBS, a coding sequence of sfGFP, and a terminator. Two restriction sites of BsaI are put on the two ends of the amilCP circuit. By adding the same digestion sites on the promoter to be assembled, the amilCP circuit could be substituted by Golden Gate. The blue colour of amilCP and green colour of sfGFP provide a rapid distinguishment of the successful construct. If the amilCP circuit is not replaced, the colony grown would be blue as amilCP is being expressed. But if a promoter sequence substitutes amilCP circuit, sfGFP would be expressed instead of amilCP, making the colony fluorescent and easy to recognise.

Except for TALE1sp1 and TALE2sp1 which were synthesized de novo by Genscript, we assembled the rest of TALEsps by first obtaining core promoters using SOE PCR then replacing the amilCP circuit with them.


In order to verify the stabilization effect of the pTALE promoter family, we assembled all promoter members onto three backbones:

  • pUC20: ~500
  • pR6K: ~15
  • pSC101: ~1

An identical sfGFP is placed downstream of all promoters as a reporter gene. Three constitutive promoters: J23119, J23101, J23105, with the same sfGFP downstream were characterized along with the pTALE promoters as a reference of promoter strength. The green fluoresce was measured by flow cytometry. (see methods in our protocols).

To decide whether pTALE can perform as expected in metabolic pathways, maintaining the pre-set ratio of production enzymes for ensuring optimal flux to the product, we tested pTALE1 sp1 and pTALE2 sp1 by comparison to pTac, a frequently-used IPTG inducible promoter, using an geraniol synthesis operon ( containing a GPPS ( and a GES ( Similar to the characterisation of green fluoresce characterization, three backbones: pUC20, pR6K, pSC101 are used.

The results indicate that TALEsp are able to buffer against the change in plasmid copy number and the location of genes in the organism, maintaining a reasonably constant fluoresce level except for TALE1sp3. The fluorescence driven the TALE1sp3 shows a positive correlation with copy number.

Moreover, to decide whether TALEsp can perform as expected in metabolic pathways, maintaining the pre-set ratio of production enzymes for ensuring optimal flux to the product, we tested TALE1 sp1 and TALE2 sp1 by comparison to pTac, a frequently-used IPTG inducible promoter, using an geraniol synthesis operon ( containing a GPPS ( and a GES ( They are co-expressed with a pMVA-only vector to provide a sufficient and stable supply of precursors IPP and DMAPP. Similar to the characterisation of green fluoresce characterization, three backbones: pUC20, pR6K, pSC101 are used.

With pTac promoters, geraniol yield increased with the copy number of the vector, showing positively correlated relation. However, when TALE stabilized promoter (TALEsp) was used, higher the copy number of the vector, lower the production of geraniol, being the opposite of pTac. And the stronger TALEsp promoter, TALE1sp1 gave generally reduced yield compared to its weaker counterpart TALE2sp1. TALE2 sp6 whose strength measure with fluorescence is about half of the strength of TALE2 sp1 produced the lowest titre among the four promoters tested. Interestingly, the graphs of the TALE stabilised promoters appeared to be seemingly parallel to each other.

We surmised that the yield of geraniol was affected by two factors: the expression level of enzymes and the cellular burden. As for enzyme expression, there exists an optimal gene expression level that produces just enough enzyme to metabolize all the substrate. The yield would be the greatest at this level. But if lower than this level, production would increase with enzyme expression since there is a surplus of substrates. And if the enzyme expression is higher, the more enzymes now becomes a cellular burden as it no longer contributes to more product.

In the case of pTac, it fits into the scenario when the gene expression is lower than the optimum: higher copy produced more enzymes to catalyze geraniol synthesis reaction. As for TALE stabilized promoters, the expression level of enzymes would remain unchanged regardless of copy number due to the stabilization nature of TALEsp (Check our Design [1]). So in low copy vector where the cellular burden isn’t significant, the product yield is only related to the strength of the promoter, explaining why TALE2 sp1 has better performance than both TALE1 sp1 and TALE2 sp6 as it’s closer to the optimum. But when the copy number increases, the expression level is unaffected while the cellular burden rises sharply because much more TALE would be made to stabilize expression, leaving less energy available for geraniol synthesis. And it in turns answers why a negative trend of production is shown when regulated by TALEsp.

Improvement based on J23119

Upon addition of a TALE2 genetic circuit, Part:BBa_J23119 is engineered to become a core promoter

We first add an up-element which is an insulating spacer to separate it from the upstream TALE, creating an intermediate promoter UP119. Then the sequence between -35 region and -10 region of UP119 was altered to make a binding site for TALE2. The fluorescence characterisation results prove that the addition of UP119 on Part:BBa_J23119 has no significant impact on its strength. The potential advantage of UP-element is that it separates the core promoter from other parts upstream, hence reducing the influence of those parts on the core promoter.

Figure. 6 Differences in the sequence between J23119, UP119, and TALE2 sp6 core promoter

Figure. 7 Fluorescence characterization results show a distinct consistency of GFP expression regardless change in copy number whereas J23119 and UP119 give rise in fluorescence at higher copy.

The strength of TALE2 sp6 is remarkably lower than Part:BBa_J23119, but has an almost constant transcription level on three different levels of copy number, since the transcription level of Part:BBa_J23119 increases as the copy number increases. As a result, we have proven that TALE2 sp6 has significantly improved the expression consistency than Part:BBa_J23119.

Sequence and Features

Assembly Compatibility:
  • 10
  • 12
    Illegal NheI site found at 1513
    Illegal NheI site found at 1921
    Illegal NheI site found at 3059
  • 21
    Illegal BglII site found at 113
    Illegal XhoI site found at 2152
    Illegal XhoI site found at 2692
  • 23
  • 25
    Illegal AgeI site found at 747
    Illegal AgeI site found at 849
    Illegal AgeI site found at 1767
    Illegal AgeI site found at 2277
  • 1000