Difference between revisions of "Team:FAU Erlangen/Description"

Colorectal cancer is the second-largest cause of cancer-related death. While the primary tumor is relatively easy to remove surgically, metastases present dangerous complications. The major hurdles in treating the secondary tumors are locating them, eliminating only the aberrant cells, and reducing the negative treatment side-effects. Thus our iGEM Team at FAU Erlangen will create a bispecific antibody as a targeting marker, enabling T-lymphocytes to target colorectal cancer cells. Our protein is designed as a Bispecific T-cell Engager (BiTE) as novel pathway for T-lymphocytes, a component of the body’s immune system to actively attack cancer cells. The challenge being to test several different approaches for producing bispecific antibodies in E. coli regarding the production efficacy, the ease of the procedure, and the stability and binding affinity of the product. We hereby strive to gain new insights that will prove beneficial in streamlining the production process of bispecific antibodies and reducing production costs.

Since the application of bispecific antibodies is a relatively new approach, current protocols for production are not yet standardized. In most cases mammalian cells are used for the expression of these proteins. However, this expression system is associated with very high costs and proves to be very time-consuming. The use of the bacterial host Escherichia coli poses an alternative for the expression of recombinant protein. It is well published and provides many advantages over the expression in mammalian cells, such as a far cheaper cultivation due to the higher proliferation rate and faster protein production. Despite these benefits, producing proteins of mammalian origin in E. coli has been shown to be difficult since post-translational modifications are often vital to protein folding and function and cannot be replicated in these bacterial systems. Especially for complex proteins like antibodies, misfolding is often detrimental for their solubility and performance.
Devising a reliable and well applicable procedure to successfully express a functional bispecific antibody in bacterial cells is crucial in fully accessing their therapeutic potential by facilitating cost- and time-effective research. However, published protocols vary immensely and offer no conclusive approach to producing recombinant, bispecific antibodies in bacteria.

For our experiments we chose to create a bispecific antibody against CD3 on T-lymphocytes and GPA33. GPA33 can be found on 95% of all colorectal cancer cells, thereby allowing them to be specifically targeted. By also binding CD3, the bispecific antibody can bring cytotoxic T-lymphocytes (CTLs) into direct contact with the cancer cells, which activates the CTLs to release their cytotoxic granules and kill the malignant cell. Our protein is designed as a Bispecific T-cell Engager (BiTE) and consists of two distinct single-chain variable Fragments (scFv) that are connected via a flexible linker.
We are going to use a pET27b plasmid with a T7 promoter and lacZ control in the E. coli strain Arctic Express. This strain is engineered to tolerate a high level of protein expression and shows improved protein folding capacity. It is well published that periplasmic expression of recombinant protein offers an oxidizing environment that is beneficial for correct protein folding, as well as a reduced number of proteases that may degrade our protein. For this reason, we plan to use a PelB leader sequence to transport our constructs to the periplasm of E. coli for synthesis.

In summary, we pursue three approaches:

In our first approach, we plan on expressing a complete BiTE molecule that will serve as reference for our other production strategies.

In our second approach, we express the two scFvs separately as fusion proteins with SpyTag or SpyCatcher, respectively. This system relies on a split domain of the FbaB protein from Streptococcus pyogenes to form a covalent, isopeptide bond upon co-culturing. This allows us to avoid the possible problem of producing a large, complex protein that could result in the formation of insoluble aggregates. Furthermore, the SpyTag/SpyCatcher system is fashioned after a modular concept. If this approach proves to be successful, it will be possible to express several effector subunits with varying affinities or functions, i.e. different antigen specificities or enzymatic activity, and connect them. This will allow for a flexible modular system that might be adapted with regards to current requirements in a fast and easy manner.

In our last approach, we intend to produce CD3- and GPA33-specific antibody fragments, so called Fabs, and link them together via disulfide bonds. This chemical conjugation is achieved by using a bis-dibromomaleimide cross-linker, providing a versatile method to produce bispecific antibodies.

To test the binding activity of our products, we will perform killing assays with blood derived CTLs. We will further test their stability at different temperatures and pH conditions.

By programming a neural network, it will also be possible to predict potential allergenicity of our bispecific antibodies. This will also prove beneficial as a prognostic tool to produce other recombinant proteins and their possible clinical application.

Altogether, the assays will provide a comparative evaluation of the properties of our different products and permit the assessment of their respective value for clinical or scientific application.

We are a team that is tackling problems of the emerging field of molecular immunology - no team in Erlangen has done this before. Here in Erlangen, we have an optimal professional network, since the newly established Masters-Program has been opened to sustain the ongoing research in this field, from which we can benefit greatly. Furthermore, our Team has an interdisciplinary approach as we have sub-teams working on chemical ligation of Fab-Fragments and a deep-learning approach to predicting immune reactions concerning different allergens. Our interdisciplinary approach is comprehensive as it covers the cure as well as the side effects by predicting these with our neural network software.

References

Gruber, M.; Schodin, B. A.; Wilson, E. R.; Kranz, D. M. (1994): Efficient tumor cell lysis mediated by a bispecific single chain antibody expressed in Escherichia coli. In: Journal of immunology (Baltimore, Md. : 1950) 152 (11), S. 5368–5374.
Heath, J. K.; White, S. J.; Johnstone, C. N.; Catimel, B.; Simpson, R. J.; Moritz, R. L. et al. (1997): The human A33 antigen is a transmembrane glycoprotein and a novel member of the immunoglobulin superfamily. In: Proceedings of the National Academy of Sciences of the United States of America 94 (2), S. 469–474. DOI: 10.1073/pnas.94.2.469.
Hull, Elizabeth A.; Livanos, Maria; Miranda, Enrique; Smith, Mark E. B.; Chester, Kerry A.; Baker, James R. (2014): Homogeneous bispecifics by disulfide bridging. In: Bioconjugate chemistry 25 (8), S. 1395–1401. DOI: 10.1021/bc5002467.
Kuipers, Ernst J.; Grady, William M.; Lieberman, David; Seufferlein, Thomas; Sung, Joseph J.; Boelens, Petra G. et al. (2015): Colorectal cancer. In: Nature reviews. Disease primers 1, S. 15065. DOI: 10.1038/nrdp.2015.65.
Lee, Yong Jae; Jeong, Ki Jun (2015): Challenges to production of antibodies in bacteria and yeast. In: Journal of bioscience and bioengineering 120 (5), S. 483–490. DOI: 10.1016/j.jbiosc.2015.03.009.
Liu, Yongkang; Huang, He (2018): Expression of single-domain antibody in different systems. In: Applied microbiology and biotechnology 102 (2), S. 539–551. DOI: 10.1007/s00253-017-8644-3.
Osada, T.; Hsu, D.; Hammond, S.; Hobeika, A.; Devi, G.; Clay, T. M. et al. (2010): Metastatic colorectal cancer cells from patients previously treated with chemotherapy are sensitive to T-cell killing mediated by CEA/CD3-bispecific T-cell-engaging BiTE antibody. In: British journal of cancer 102 (1), S. 124–133. DOI: 10.1038/sj.bjc.6605364.
Sedykh, Sergey E.; Prinz, Victor V.; Buneva, Valentina N.; Nevinsky, Georgy A. (2018): Bispecific antibodies: design, therapy, perspectives. In: Drug design, development and therapy 12, S. 195–208. DOI: 10.2147/DDDT.S151282.
Spadiut, Oliver; Capone, Simona; Krainer, Florian; Glieder, Anton; Herwig, Christoph (2014): Microbials for the production of monoclonal antibodies and antibody fragments. In: Trends in biotechnology 32 (1), S. 54–60. DOI: 10.1016/j.tibtech.2013.10.002.
Steeg, Patricia S. (2016): Targeting metastasis. In: Nature reviews. Cancer 16 (4), S. 201–218. DOI: 10.1038/nrc.2016.25.
Thie, Holger; Schirrmann, Thomas; Paschke, Matthias; Dübel, Stefan; Hust, Michael (2008): SRP and Sec pathway leader peptides for antibody phage display and antibody fragment production in E. coli. In: New biotechnology 25 (1), S. 49–54. DOI: 10.1016/j.nbt.2008.01.001.

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