Part:BBa_K4729707
Ptac + VirG TiBo542 N80D + repABCa
Contents
Introduction
Agrobacterium mediated transformation is one of the most prolific methods for plant engineering, by far the most common method for iGEM teams as well. However, working with Plant Synbio is still far from a straightforward endeavor. This year, we set our sights on creating molecular tools that facilitate achieving successful transformation in non-model plant species, one of them is our Best Composite Part.
In nature, members of the genus Agrobacterium (Alphaproteobacteria) are soil-borne plant pathogens that integrate hormone producing genes in the host plant genome to cause growth deformities and tumors. This mechanism can be explored by substituting the oncogenes by genes of interest, thus integrating them in the plant chromosomes. The most well known strain, Agrobacterium tumefaciens, promotes crown-gall disease in most dicotyledonous plants, however, other strains such as Agrobacterium rhizogenes are also able to transform plant cells (Bahramnejad et al., 2019[2]; Barton et al., 2018[3]). Despite their wide use, Agrobacterium mediated plant transformation is still only well established for a handful of model organisms, which makes it hard for iGEM teams to engineer local species.
Part of the problem lies in the high specificity between plants and the necessary Agrobacterium strain for transformation. As we found out, getting hold of the correct Agrobacterium strain for a plant species (if one is even known) is extremely hard, reaching up to hundreds of Euros and months of shipping time. This is made even worse by the confusing and often conflicting nomenclature of existing strains (De Saeger et al., 2021[7]).
Therefore, we created a composite part that aims to improve the efficiency and host range of Agrobacterium strains by leveraging the virG transcription factor as a Master-Switch plant transformation. With it, we hope to enable future teams to further extend the garden of plant projects in iGEM.
The molecular machinery of plant transformation
Both the molecular machinery for plant infection and the DNA fragment that is excised and integrated into the plant genome are located in a nonessential, mobile plasmid called the Ti or Ri plasmid (for Agrobacterium tumefaciens and rhizogenes, respectively). In its infection cycle, the metabolites released by plant wounds attract Agrobacterium chemotactically. These same phenolic compounds also activate the virulence response in Agrobacterium.
The T-DNA is composed of genes for the tumor formation and for the production of metabolites that are used as a carbon source by the bacterium, these are flanked by direct repeats (T-DNA borders) that are recognized by vir genes and are essential for the excision, transport, and integration in the plant genome. The T-DNA border sequence plays a fundamental role in the biotechnology applications of Agrobacterium, as the genes of interest to be transformed in plants must also be flanked by direct repeats (Ozyigit et al.[11], 2013). Which genes are included in the T-DNA are the main factor in differentiating Agrobacterium strains, while the T-DNA of A. tumefaciens strains promoters the formation of overground tumors, the gene products of A. rhizogenes T-DNA result in the formation of the hairy root phenotype (Bouchez & Tourneur[4], 1991; Slightom et al.[12], 1986).
The virulence (vir) region is a cluster of ~30 coding sequences responsible for the DNA transfer mechanisms, two of those genes, VirA and VirG, form a two component system in which VirA is a transmembrane histidin kinase and VirG the cytoplasmic response regulator (Cho & Winans[5], 2005). Upon binding to plant phenolic compounds (acetosyringone etc.), VirA phosphorylates VirG, which in turn functions as a transcription factor that binds to vir gene promoters and activates their transcription. Therefore, VirG can be seen as a “master regulator” of Agrobacterium virulence.
Controlling the expression of this master regulator through its overexpression or the inclusion of extra copies from more potent strains has been shown to increase transformation efficiency and host range (Anand et al.[1], 2019).
The virG Master-Switch construct
We propose the use of a helper plasmid that decouples the expression of VirG from the VirA two component system, skipping the need for optimizing the bacteria growth medium and the use of phenolic compounds that emulate the plant response. By fine tuning the expression of this “master-switch” of Agrobacterium virulence, we aim to take control of the transformation machinery and tailor it to individual plant species. Here, we present the result of our engineering efforts and the multiple iterations of the design-build-test-learn cycle that culminated in our part.
Constitutive expression
The initial design for our construct relied on maximizing the expression of a second copy of the endogenous virG from A. rhizogenes Arqua1. This was based on the assumption that a maximum induction of the virulence genes would lead to the best transformation results. This approach was also used to improve transformation efficiency in celery and rice (Liu et al.[14], 1992). As a backbone, we chose the pSRK L1 entry vector, which was provided by the lab of our PI Anke Becker, has a pBBR1 broad host range ori.
Based on the data gathered from our Anderson Promoter characterization, we identified J23102 as the strongest constitutive promoter, and designed a construct that used this promoter to drive the expression of the endogenous VirG CDS basic part we amplified from A. rhizogenes ARqua1.
However, after more thorough research, and - most importantly - after consulting with Sebastian Concioba, we found that strong virulence induction might be an extremely high metabolic burden for the cell, leading to slower growth and possibly even an overall decrease in transformation efficiency. This prompted us to return to the drawing board and rethink how our composite part could work.
Inducible expression
Sodium Salicylate inhibits cell growth
Cross-talk assay
Sequence and Features
- 10INCOMPATIBLE WITH RFC[10]Illegal PstI site found at 3840
- 12INCOMPATIBLE WITH RFC[12]Illegal NheI site found at 4468
Illegal PstI site found at 3840 - 21INCOMPATIBLE WITH RFC[21]Illegal BglII site found at 1741
Illegal BamHI site found at 262
Illegal BamHI site found at 1917
Illegal BamHI site found at 2209
Illegal XhoI site found at 227
Illegal XhoI site found at 3480
Illegal XhoI site found at 3834
Illegal XhoI site found at 7176 - 23INCOMPATIBLE WITH RFC[23]Illegal PstI site found at 3840
- 25INCOMPATIBLE WITH RFC[25]Illegal PstI site found at 3840
Illegal NgoMIV site found at 111
Illegal NgoMIV site found at 2054
Illegal NgoMIV site found at 3894
Illegal NgoMIV site found at 4119
Illegal NgoMIV site found at 4224
Illegal NgoMIV site found at 5254
Illegal AgeI site found at 5733 - 1000COMPATIBLE WITH RFC[1000]
References
[1] Anand, A., Che, P., Wu, E., & Jones, T. J. (2019). Novel Ternary Vectors for Efficient Sorghum Transformation. In Z.-Y. Zhao & J. Dahlberg (Eds.), Sorghum (Vol. 1931, pp. 185–196). Springer New York. https://doi.org/10.1007/978-1-4939-9039-9_13
[2] Bahramnejad, B., Naji, M., Bose, R., & Jha, S. (2019). A critical review on use of Agrobacterium rhizogenes and their associated binary vectors for plant transformation. Biotechnology Advances, 37(7), 107405. https://doi.org/10.1016/j.biotechadv.2019.06.004
[3] Barton, I. S., Fuqua, C., & Platt, T. G. (2018). Ecological and evolutionary dynamics of a model facultative pathogen: Agrobacterium and crown gall disease of plants. Environmental Microbiology, 20(1), 16–29. https://doi.org/10.1111/1462-2920.13976
[4] Bouchez, D., & Tourneur, J. (1991). Organization of the agropine synthesis region of the T-DNA of the Ri plasmid from Agrobacterium rhizogenes. Plasmid, 25(1), 27–39. https://doi.org/10.1016/0147-619X(91)90004-G
[5] Cho, H., & Winans, S. C. (2005). VirA and VirG activate the Ti plasmid repABC operon, elevating plasmid copy number in response to wound-released chemical signals. Proceedings of the National Academy of Sciences, 102(41), 14843–14848. https://doi.org/10.1073/pnas.0503458102
[6] Colognori, D., Trinidad, M., & Doudna, J. A. (2023). Precise transcript targeting by CRISPR-Csm complexes. Nature Biotechnology, 1–9. https://doi.org/10.1038/s41587-022-01649-9
[7] De Saeger, J., Park, J., Chung, H. S., Hernalsteens, J.-P., Van Lijsebettens, M., Inzé, D., Van Montagu, M., & Depuydt, S. (2021). Agrobacterium strains and strain improvement: Present and outlook. Biotechnology Advances, 53, 107677. https://doi.org/10.1016/j.biotechadv.2020.107677
[8] Gelvin, S. B. (Ed.). (2018). Agrobacterium Biology: From Basic Science to Biotechnology (Vol. 418). Springer International Publishing. https://doi.org/10.1007/978-3-030-03257-9
[9] Meyer, A. J., Segall-Shapiro, T. H., Glassey, E., Zhang, J., & Voigt, C. A. (2019). Escherichia coli “Marionette” strains with 12 highly optimized small-molecule sensors. Nature Chemical Biology, 15(2), Article 2. https://doi.org/10.1038/s41589-018-0168-3
[10] Mostafavi, M., Lewis, J. C., Saini, T., Bustamante, J. A., Gao, I. T., Tran, T. T., King, S. N., Huang, Z., & Chen, J. C. (2014). Analysis of a taurine-dependent promoter in Sinorhizobium meliloti that offers tight modulation of gene expression. BMC Microbiology, 14, 295. https://doi.org/10.1186/s12866-014-0295-2
[11] Ozyigit, I. I., Dogan, I., & Artam Tarhan, E. (2013). Agrobacterium rhizogenes-Mediated Transformation and Its Biotechnological Applications in Crops. In K. R. Hakeem, P. Ahmad, & M. Ozturk (Eds.), Crop Improvement: New Approaches and Modern Techniques (pp. 1–48). Springer US. https://doi.org/10.1007/978-1-4614-7028-1_1
[12] Slightom, J. L., Durand-Tardif, M., Jouanin, L., & Tepfer, D. (1986). Nucleotide sequence analysis of TL-DNA of Agrobacterium rhizogenes agropine type plasmid. Identification of open reading frames. Journal of Biological Chemistry, 261(1), 108–121. https://doi.org/10.1016/S0021-9258(17)42439-2
[13] Stukenberg, D., Hensel, T., Hoff, J., Daniel, B., Inckemann, R., Tedeschi, J. N., Nousch, F., & Fritz, G. (2021). The Marburg Collection: A Golden Gate DNA Assembly Framework for Synthetic Biology Applications in Vibrio natriegens. ACS Synthetic Biology, 10(8), 1904–1919. https://doi.org/10.1021/acssynbio.1c00126
chassis | A. tumefaciens |