Abstract: STAT3 is one of the seven family members of the STAT transcription factor family. STAT3 has become a very attractive target for cancer therapy and other diseases. It has a prominent role in cancer development as well as progression. However, there are still no STAT3 inhibitors applied in the clinic. One of the underlying reasons might be the complicated regulation of STAT3 function. Not only do many signaling pathways converge on STAT3, it is also a redox sensitive transcription factor. Therefore, STAT3 activity is determined by a plethora of different intracellular and extracellular signals. STAT3 also affects many different cellular functions and has a role in each hallmark of cancer, either through its role as a transcription factor or through one of its diverse non-transcriptional functions. This thesis focuses on the STAT3 small molecule inhibitor field, by trying to further explore the mechanism of action of novel and widely used STAT3 inhibitors. In addition, we developed a new method to discover specific STAT3 inhibitors. Interestingly, we found that STAT3 was not targeted directly, but rather STAT3 is inactivated due to oxidation of cysteine residues on the protein. In Paper I, we developed a cell-based high-throughput screening system to evaluate STAT3 transcriptional activity. This was used to screen 28.000 compounds, where after several additional screening steps four lead compounds were selected for further evaluation. All four compounds inhibited STAT3 transcriptional activity. Their mechanisms of action however appeared to be diverse. One compound, KI16, was found to preferentially inhibit STAT3 function compared to STAT1, and inhibited STAT3-driven phenotypes. In Paper II, we used differential scanning fluorimetry (DSF) to highlight some of the shortcomings of other in vitro STAT3 inhibitor methods. Two STAT3 protein truncations were used to evaluate SH2 domain binders of STAT3 as well as binding specificity of wellknown STAT3 small molecule inhibitors. Phosphopeptides were able to specifically ...
Relation: I. Iryna Kolosenko, Yasmin Yu, Sander Busker, Matheus Dyczynski, Jianping Liu, Martin Haraldsson, Caroline Palm Apergi, Thomas Helleday, Katja Pokrovskaja-Tamm, Brent D.G. Page. Identification of novel small molecules that inhibit STAT3-dependent transcription and function. PLoS One. 2017 June 21; 12(6): e0178844. ::doi::10.1371/journal.pone.0178844 ::pmid::28636670 ::isi::000404118300018; II. Matthieu Desroses, Sander Busker, Juan Astorga-Wells, Sanaz Attarha, Iryna Kolosenko, Roman A. Zubarev, Thomas Helleday, Dan Grandér, Brent D. G. Page. STAT3 differential scanning fluorimetry and differential scanning light scattering assays: Addressing a missing link in the characterization of STAT3 inhibitor interactions. J Pharm Biomed Anal (JPBA). 2018 July 14; 160: 80-88. ::doi::10.1016/j.jpba.2018.07.018 ::pmid::30086509 ::isi::000444661300010; III. Sander Busker, Weixing Qian, Martin Haraldsson, Lars Johansson, Belen Espinosa, Sanaz Attarha, Iryna Kolosenko, Jianping Liu, Markus Dagnell, Dan Grandér, Elias S. J. Arnér, Katja Pokrovskaja-Tamm, Brent D.G. Page. Disrupting oncogenic STAT3 activity by targeting TrxR1 with irreversible covalent inhibitors. [Submitted]; http://hdl.handle.net/10616/46755
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