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Design, Synthesis and Evaluation of Covalent Inhibitors for Tissue Transglutaminase and Factor XIIIaAkbar, Abdullah 23 September 2019 (has links)
Transglutaminases are a family of enzymes expressed in various tissues of our body. Some are expressed ubiquitously while others are specific to a tissue. Their primary catalytic activity is to crosslink substrates via an isopeptidic bond. The work described in this thesis focuses on two of these transglutaminases; human tissue transglutaminase (hTG2) and human factor XIIIa (FXIIIa). Divided into two projects for each enzyme, the main objective of this thesis was directed towards the discovery of potent and selective covalent inhibitors for each isozyme, namely hTG2 and hFXIIIa. The first project was concentrated on the inhibition of hTG2 activity. Ubiquitously expressed in tissues, hTG2 is a multifunctional enzyme. Its primary activity is the formation of isopeptide bonds between glutamine and lysine residues found on the surface of proteins or substrates. In addition to its catalytic activity, hTG2 is also a G-protein, distinguishing it from other members of the transglutaminase family. Much evidence illustrates that hTG2’s multifunctional abilities are conformationally regulated between its “open” and “closed” forms. Overexpression and unregulated hTG2 activity has been associated with numerous human diseases; however, most evidence has been collected for its association with fibrosis and celiac sprue. More recently, elevated hTG2 expression has been linked to cancer stem cell survival and metastatic phenotype in certain cancer cells. These findings call for the development of suitable and potent inhibitors that selectivity inactivate human hTG2 as a potential therapeutic target. Starting with previously designed acrylamide based peptidomimetic irreversible inhibitors, a structure-activity relationship (SAR) study was conducted. In this work, >20 novel irreversible inhibitors were prepared and kinetically evaluated. Our lead inhibitors allosterically inhibited GTP binding by locking the enzyme in its open conformation, as demonstrated both in vitro and in cells. Furthermore, our most potent and efficient irreversible inhibitors revealed selectivity for hTG2 over other relevant members of the transglutaminase family (hTG1, hTG3, hTG6 and hFXIIIa), providing higher confidence towards our goal of developing an ideal drug candidate. The second project was concentrated on the inhibition of hFXIIIa activity. In the blood, coagulation factor XIII (FXIII) is a tetrameric protein consisting of two catalytic A subunits (FXIII-A2) and two carrier/inhibitory B (FXIII-B2) subunits. It is a zymogen, which is converted into active transglutaminase (FXIIIa) in the final phase of coagulation cascade by thrombin proteolytic activity and Ca2+ binding. hFXIII is essential for hemostasis and thus its deficiency results in severe bleeding conditions. Further, hFXIIIa mechanically stabilizes fibrin and protects it from fibrinolysis. Due to the enzyme’s involvement in the stability of blood clots, inhibition of hFXIIIa activity has been linked to thrombotic diseases. Furthermore, inhibitors of the enzyme have the therapeutic potential to be used as anticoagulant agents. The current number of selective and potent inhibitors of hFXIIIa are few, mainly due to the similarity between its catalytic pockets and hTG2. Inspired by a poorly reactive hTG2 inhibitor discovered in this work’s hTG2 SAR study, we synthesized a small library of covalent inhibitors for hFXIIIa. Our kinetic results from this pioneering SAR study will pave the way for future hFXIIIa inhibitor SAR studies.
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