Team:Slovenia/TheSwitchDesignedTALregulators
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Revision as of 07:42, 26 September 2012
TAL-based transcriptional regulators
We created several TAL repressors by different terminal fusions of the KRAB repression domain with TAL DNA-binding domains and reporter plasmids with their respective binding sites. We created several TAL activator constructs by C-terminal fusions of the VP16 domain with TAL DNA-binding domains and reporter plasmids with their respective binding sites. We improved and characterised the NicTAL DNA-binding domain (deposited by the iGEM2010 team Slovenia) by adding a missing subdomain of the protein and created a designed repressor. TAL:KRAB fusions exhibited over 90% repression of reporter gene expression regardless of the position of the KRAB domain. Minimal promoters used for construction of reporter plasmids showed no or minimal leakiness and were activated over 1500-fold by the TAL:VP16 fusions Our experimental results on designed TAL regulators provided parameters for the quantitative deterministic modeling of bistable switches. |
Designed TAL transcriptional regulators
For the past two decades, engineered zinc finger proteins have been extensively used for targeting specific DNA sequences. However, in spite of the many years of technological development, engineered zinc finger proteins are not able to target every desired DNA sequence due to the impact of neighbouring fingers on the recognition of base pairs. Recently DNA-binding proteins with a simpler DNA recognition code were discovered. Transcription activation like (TAL) effectors are bacterial plant pathogen transcription factors that bind to DNA by recognizing a specific DNA sequence in which each base pair binds a single tandem repeat in in the TAL DNA-binding domain (Figure 1A). A tandem TAL repeat contains 33 to 35 amino acids, where the 12th and the 13th amino acid, called a “repeat variable diresidue” (RVD), are responsible for specific interactions with the corresponding base pair (Scholze and Boch, 2011). As evident from the crystal structure of TAL effectors (Mak et al., 2012; Deng et al., 2012; Figuer 1B), all TAL repeats have almost identical conformations, differing only in the RVDs. This modularity of TAL effector binding domains therefore makes them a perfect tool to target specific DNA sequences.
Figure 1. The structure of TAL effectors. (A) Schematic representation of TAL effector structure and its DNA-binding domain (red), containing multiple 34 aminoacid tandem repeats with RVDs at the 12th and 13th residue (Scholze and Boch, 2011). (B) 3D structure of a TAL effector. |
Figure 2. 3D structures of TAL DNA-binding domains fused with the KRAB repression domain (A) and VP16 activation domain (B). of a TAL effector. |
To date, TAL effectors have mostly been used as a tool for plant or mammalian genome editing. The basic idea is the same as with zinc finger nucleases, with TALs replacing zinc fingers as the specific DNA-binding domain (Miller et al., 2010). Several groups (Miller et al., 2011; Zhang et al, 2011) have also designed TAL effectors for specific gene activation, by fusing them with either the Herpes simplex virus VP16 activation domain or its tetrameric derivative VP64 (Figure 2). After we already initiated the iGEM 2012 project, TAL repressors were reported by Garg et al., who created TAL effectors fused with the KRAB transcriptional repression domain.
Results
TAL transcriptional activators and repressors were basic tools in our iGEM project. We designed and characterised three functional TAL regulators (TALA, TALB and TALD) by fusing TAL DNA-binding domains with a VP16 activation domain or a KRAB repression domain (Figure 3A), as shown on Figure 2. To asses the activity of designed TAL regulators, we also designed reporter plasmids, which contain several repeats of TAL binding sites upstream of either a CMV promoter (repression) or a minimal promoter (activation) (Figure 3B).
In addition to the synthesis of new TAL effector-based parts and their characterization, our team also improved a part which was deposited in the Registry by the Slovenian iGEM2010 team. They synthesized a TAL effector, named NicTAL, which did not work as expected in mammalian cells. We discovered that a subdomain next to the DNA-binding domain was missing, because the requirements for the functional TAL binding domains have not been known two years ago. We linked the missing domain to the DNA-binding domain of NicTAL from the Registry. Additionally we prepared chimeric proteins of the NicTAL-DNA binding domain and KRAB or VP16 domains, generating another repressor and activator pair and demonstrated the newly acquired functionality of the NicTAL-based regulators.
Figure 3. Schematic representation of the tested plasmids. (A) TAL repressors; fusions of TAL DNA-binding domains with the KRAB repression domain. (B) TAL activator; fusion of TAL DNA-binding domain with the VP16 activation domain. Expression of TAL effectors is under the control of constitutive CMV promoter. (C) Reporter plasmids used to test efficiency of TAL regulators. TAL DNA-binding sites are placed upstream of either a CMV promoter (repression) or a minimal promoter (activation), driving the expression of reporter genes (firefly luciferase or mCitrine). |
Designed repressors
Figure 4. Schematic representation of repression experiments. (A) In the absence of a TAL repressor, the reporter gene is constitutively expressed. (B) When a TAL repressor is expressed, it binds to its respective DNA-binding site upstream of the CMV promoter and represses transcription of the reporter gene with the KRAB domain. |
Results show that the previously non-functional NicTAL2010:KRAB fusion (NicTAL DNA-binding domain constructed by the iGEM2010 team Slovenia) acquired functionality with the N-terminal addition of a subdomain to the TAL DNA-binding domain (Figure 5). An excellent repression ability of NicTAL2012:KRAB (the improved version by the 2012 team) was observed. The NicTAL2012 repressor was further characterised by testing the effect of a different number of binding sites upstream of the PCMV promoter on the inhibition of reporter expression. Results presented in figure 6 show that the maximal effect of the bound TAL regulator plateaus at 7 or more copies of binding sites per operator. In all further experiments we used plasmids with 10 copies of TAL DNA-binding sites.
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Designed activators
Due to the mechanism of action of the VP16 domain and our previous results with the TAL:KRAB repressor (Figure 5, the position of the effector domain does not influence TAL binding), we decided to test only the C-terminal variant of the TAL:VP16 fusion (Figure 3A). Both tested TAL activators exhibited over 1500-fold activation of the mCitrine reporter at reporter to activator ratios 1:2. In addition, we have confirmed that the minimal promoter used to drive the expression of the reporter gene shows no (or minimal) leakiness - this trait makes this promoter an excellent element for genetic systems, where tight transcriptional regulation is needed.
Figure 7. Schematic representation of activation experiments. (A) In the absence of a TAL activator, there is no expression of the reporter gene. (B) When TAL activator is present, it binds to its DNA-binding site upstream of the minimal promoter and activates transcription of the reporter gene. |
Figure 8. TAL activators strongly activate reporter gene expression. Number of DNA-binding sites specific for NicTAL12:KRAB repressor dictates the efficiency of inhibition of reporter expression. HEK293T cells were cotransfected with TAL activator constructs under the CMV promoter (different quantities, for ratios see the x axis), and mCitrine reporter plasmids (Figure 3B) containing 10 copies of binding sites for the designated TAL activator upstream of a minimal promoter (50 ng). Along with the tested constructs we transfected cells with 20 ng of mCherry fluorescent protein under the HSV-TK promoter as transfection control. Fluorescence was measured 3 days post-transfection. All experiments were executed in 3 biological replicates and repeated over 3 times with similar results. |
Figure 2. Components of the mutual repressor switch based on TAL repressors. The system consists of 6 operons - 2 operons that express different TAL repressors from constitutive promoters with TAL binding sites that ensure mutual repression (TALA binding sites [A] on the construct expressing TALB repressor and vice versa), 2 operons that express TAL repressors from inducible promoters, and 2 operons that constitutively express inducer-dependent transcription factors. |
References
Deng, D., Yan, C., Pan, X., Mahfouz, M., Wang, J., Zhu J. K., Shi, Y., and Yan, N. (2012) Structural basis for sequence-specific recognition of DNA by TAL effectors. Science 335, 720-723.
Garg, A., Lohmueller, J. J., Silver, P. A. and Armel, T.Z. (2012) Engineering synthetic TAL effectors with orthogonal target sites. Nucleic Acids Res. 40, 7584-95.
Mak, A. N., Bradley, P., Cernadas, R. A., Bogdanove, A. J., and Stoddard, B. L. ( 2012) The crystal structure of TAL effector PthXo1 bound to its DNA target. Science 335, 716-719.
Miller, J. C , Tan, S., Qiao, G., Barlow, K. A., Wang, J., Xia, D. F., Meng, X., Paschon, D. E., Leung, E., Hinkley, S. J., Dulay, G. P., Hua, K. L., Ankoudinova, I., Cost, G. J., Urnov, F. D., Zhang, H. S., Holmes, M. C., Zhang, L., Gregory, P. D., and Rebar, E. J. (2011) A TALE nuclease architecture for efficient genome editing. Nat. Biotechnol. 29, 143-148.
Scholze, H., and Boch, J. (2011) TAL effectors are remote controls for gene activation. Curr. Opin. Microbiol. 14, 47-53.
Zhang, F., Cong, L., Lodato, S., Kosuri, S., Church, G. M., and Arlotta, P. (2011) Efficient construction of sequence-specific TAL effectors for modulating mammalian transcription. Nat. Biotechnol. 29, 149-153.
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