Composite

Part:BBa_K4729707

Designed by: Yasoo Morimoto   Group: iGEM23_Marburg   (2023-10-10)
Revision as of 10:00, 12 October 2023 by Yasoo mn (Talk | contribs)

Ptac + VirG TiBo542 N80D + repABCa

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.


Figure of the virulence pathway
Figure 1: XXX

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. The endogenous VirG CDS was PCR amplified from gDNA extracted from A. rhizogenes ARqua1 and cloned in the level 0 entry vector from the Marburg Collection. The primers used were designed to also remove internal BsmBI cutting sites.


Anderson comparison Agrobacterium - E.coli
Figure 2:

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

Next, we decided to change the design by using an inducible promoter system. By doing that, not only could we delay the virulence response until it was actually needed, but also open up the potential for fine-tuning the virulence response for each plant species of interest. Here we faced another challenge, the lack of basic parts that are well characterized in Agrobacterium. While some efforts have been made in shedding light on the function of inducible systems in this organism, its volume still pales in comparison to other model organisms.

We selected 9 promoters from the “Marionette Collection”, which contains a number of inducible systems highly optimized (in E. coli) for high dynamic range and low leakyness (Meyer et al.[9], 2019). Additionally, Ptrc and Ptau were also included (Mostafavi et al.[10], 2014; Stukenberg et al.[13], 2021). Another consideration made when selecting the promoter systems to characterize was to include ones that use non-phenolic compounds as inducers (Ptau, IPTG, Pbetl, and Pbad), in the hope of minimizing cross talk with the native VirA/VirG two component system.


Inducible systems in A. rhizogenes ARqua1
Figure 3:

The results in Fig. 3 show relative luminescence (RLU) output from H2O mock induction and maximum induction. This experiment demonstrated that most promoters did not respond significantly to induction in A. rhizogenes ARqua1, notable exceptions were Ptac, Pvan, PnahR and Ptau. With first two showing the highest overall induction strength and Ptau the widest dynamic range, in fact, the baseline expression of Ptau was as low as the dummy promoter, both at the threshold of detection for the plate reader used in the experiment, this demonstrates that the expression of Ptau is tightly regulated and has virtually zero leakiness. Overall, PnahR appeared to have a good middle ground between expression strength and orthogonality, and was selected for driving the expression of VirG in our Master-Switch construct.


Sodium Salicylate inhibits cell growth

Unfortunately, we noticed in the previous experiment that despite the high luminescence output, cultures grown in 100 µM of sodium salicylate showed significantly slower growth rates. This prompted us to investigate the issue further and record the growth curve of the same strains used in the previous experiment in a medium containing a serial dilution of sodium salicylate.

Agrobacterium cell growth during induction
Figure 4: XXX

As shown in Figure 4, the maximum induction concentration of 100 µM and the first 1:10 dilution resulted in severe growth inhibition.

Agrobacterium are usually are equipped to tolerate such plant defense compounds as sodium salicylate and vanillin, and no toxicity was reported on previous characterizations using Agrobacterium tumefaciens C58, pointing at a possible strain specific behavior in A. rhizogenes ARqua1 (Colognori et al, 2023; Gelvin, 2018; Schuster & Reisch, 2021). Based on this data, we chose to streamline our VirG expression candidates to Ptac and Ptau, combining high expression potential with low leakiness. In addition to the promoters, we also looked into literature for different variants of the VirG transcription factor, and built a combinatorial library of constructs.

There is a multitude of Agrobacterium strains with differing characteristics and virulence strengths. The strain A281 in particular, is able to transform a broader range of plant species and has higher efficiency due to its pTiBo542 Ti plasmid. Introducing copies of its virG and virB operons in regular strains has been shown to recreate the improved efficiency. This heightened activity is primarily attributed to the existence of V7I and I106T mutations in the coding sequence of the variant. (Chen et al., 1991).

While the virulence of Agrobacterium usually depends on external signals for its activation through the VirA/VirG two component system, certain mutations in VirG may result in a “constitutive” phenotype, where VirG binds to vir gene promoters and triggers virulence independent of being activated by VirA. One of these mutations, the change of one amino acid at position 54 from an asparagine (N) to aspartate (D) has been shown to cause in enhanced transformation efficiency in many plants (Chen et al., 1991; De Saeger et al., 2021). However, no “constitutitve” variety of virG(pTiBo542) has been produced so far. So, we used bioinformatic tools to identify the aminoacid in the longer virG(pTiBo542) that is equivalent to the position 54 in virG(N54D), and reproduced the mutation. Based on sequence alignments, we identified this site at position 80 of virG(pTiBo542).



Sequence alignment of VirG
Figure 5:


Constructs containing combinations of the endogenous A. rhizogenes ARqua1 virG, virG(pTiBo542), virG(pTiBo542 N80D), and the promoters Ptau and Ptac. This combinatory library was then transformed in A. rhizogenes ARqua1 for determining if an increase of plant transformation efficiency could be detected.



in vivo results
Figure 6:

After the initial observation of results three days post-transformation with Ptau_super80_pSRK (fig. XA), Ptac_super80_pSRK (fig. XC), and Ptac_TiBo542_pSRK (fig. XB), there was a noticeable decline in transformation efficiency which went from previous 46% (link to baseline results) to a range between 29% to 37% (fig. XA-C). To address this issue promptly and avoid any unnecessary delays, our team initiated troubleshooting procedures. This involved conducting stability assay tests to gain a deeper understanding of the factors contributing to the reduction in transformation efficiency.


The pVS1 and pBBR1 oris cannot be stably maintained in A. rhizogenes

The pSRK entry vector carries the pBBR1 (broad host range) ori and was initially selected for our VirG overexpression constructs, due to its medium copy number in Alphaproteobacteria and compatibility with E. coli (Antoine & Locht[17], 1992; Blázquez et al.[18], 2023). However, after observing that strains carrying both 35S:RUBY:KanR and Master Switch plasmids displayed lower transformation efficiency when compared to strains solely carrying the 35S:RUBY plasmid, we decided to investigate further. This led to the suspicion that the two plasmids might be unstable when co-existing in Agrobacterium, negatively affecting cell health and thus decreasing overall transformation efficiency. In order to verify this hypothesis, we conducted a stability assay in A. rhizogenes ARqua1 carrying 35S:RUBY:KanR and Ptau_super80_pSRK. Cultures were grown overnight and used to inoculate a new liquid culture, until 5 overnight cultures were obtained. Samples from all days were verified via colony PCR.


in vivo results
Figure 6:

By the 4th overnight culture, the cell density in all cultures of Agrobacterium carrying the pSRK constructs was already visible low, meanwhile, Agrobacterium carrying pABCa constructs grew normally. The colony PCR revealed that after 4 days, both plasmids were lost in plain LB and LB (gen+strep) cultures. In LB (gen+spec), the 35S:RUBY:KanR plasmid was detected in the 4th day and lost in the 5th. Based on these results, we opted to use the pABCa backbone for our VirG expression constructs, despite its lower copy number when compared to pSRK (Antoine & Locht[17], 1992; Döhlemann et al.[19], 2017).


in vivo results
Figure 6:

Three days after transforming Arabidopsis with the two pABCa constructs, Ptac_TiBo542_pABCa and Ptac_super80_pABCa, we observed transformation rates that were still notably low when compared to our baseline experiments. However, this outcome indicated a positive aspect of our work – our strains seemed not to lose our construct plasmid. This result aligned with our cultivation practices, as we only cultured Agrobacterium for 1-2 days, and plasmid loss seems to occur after 4 days. Moreover, the pABCa plasmid exhibited stability and demonstrated comparable transformation efficiency after 3 days when compared to constructs with the pSRK backbone.
Upon evaluating our most recent results 10 days post-transformation with constructs containing the pSRK backbone, we were surprised to witness an unexpected increase in the number of RUBY-positive plants compared to the 3-day post-transformation results. The current efficiency levels now seem to be on par with the outcomes from the baseline experiments. With the assumption that pABCa behaves similarly, we anticipate obtaining comparable results ten days after transformation, and we anticipate these results to be available within the next week.



Conclusion from this and outlook or something like that:

In our future endeavors, we plan to seek out a multi-copy ori that combines the advantageous traits of both the pSRK and pABCa backbones. This will ensure stability while allowing for high copy numbers in our plasmids. We are dedicated to testing all of our constructs, with particular emphasis on the most promising ones, in a variety of non-model plants such as the Bambara groundnut. Our goal is to establish if we can achieve results comparable to, or even better than, those obtained in our baseline experiments.
Furthermore, our upcoming research will focus on refining the optimal concentration of taurine for Ptau. This fine-tuning process will help us create ideal virulence activity conditions for our transformations. With the current results at our disposal, along with forthcoming data and possible new experiments, we aim to develop a standardized toolkit. This toolkit will provide the iGEM community with the means to efficiently transform non-model plant species, enabling them to tackle local challenges using their native plant varieties.


Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal PstI site found at 3840
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 4468
    Illegal PstI site found at 3840
  • 21
    INCOMPATIBLE 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
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal PstI site found at 3840
  • 25
    INCOMPATIBLE 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
  • 1000
    COMPATIBLE 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

[14] Liu, C.-N., Li, X.-Q., & Gelvin, S. B. (1992). Multiple copies of virG enhance the transient transformation of celery, carrot and rice tissues by Agrobacterium tumefaciens. In Plant Molecular Biology (Vol. 20, Issue 6, pp. 1071–1087). Springer Science and Business Media LLC. https://doi.org/10.1007/bf00028894

[15] Chen, C.-Y., Wang, L., & Winans, S. C. (1991). Characterization of the supervirulent virG gene of the Agrobacterium tumefaciens plasmid pTiBo542. Molecular and General Genetics MGG, 230(1), 302–309. https://doi.org/10.1007/BF00290681

[16] Schuster, L. A., & Reisch, C. R. (2021). A plasmid toolbox for controlled gene expression across the Proteobacteria. Nucleic Acids Research, 49(12), 7189–7202. https://doi.org/10.1093/nar/gkab496

[17] Antoine, R., & Locht, C. (1992). Isolation and molecular characterization of a novel broad-host-range plasmid from Bordetella bronchiseptica with sequence similarities to plasmids from Gram-positive organisms. Molecular Microbiology, 6(13), 1785–1799. https://doi.org/10.1111/j.1365-2958.1992.tb01351.x

[18] Blázquez, B., León, D. S., Torres-Bacete, J., Gómez-Luengo, Á., Kniewel, R., Martínez, I., Sordon, S., Wilczak, A., Salgado, S., Huszcza, E., Popłoński, J., Prieto, A., & Nogales, J. (2023). Golden Standard: A complete standard, portable, and interoperative MoClo tool for model and non-model proteobacteria. Nucleic Acids Research, gkad758. https://doi.org/10.1093/nar/gkad758

[19] Döhlemann, J., Wagner, M., Happel, C., Carrillo, M., Sobetzko, P., Erb, T. J., Thanbichler, M., & Becker, A. (2017). A Family of Single Copy repABC-Type Shuttle Vectors Stably Maintained in the Alpha-Proteobacterium Sinorhizobium meliloti. ACS Synthetic Biology, 6(6), 968–984. https://doi.org/10.1021/acssynbio.6b00320


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chassisA. tumefaciens