Browsing by Subject "covalent bond"

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    Small-Molecule Covalent Modification of Conserved Cysteine Leads to Allosteric Inhibition of the TEAD⋅Yap Protein-Protein Interaction
    (Elsevier, 2019) Bum-Erdene, Khuchtumur; Zhou, Donghui; Gonzalez-Gutierrez, Giovanni; Ghozayel, Mona K.; Si, Yubing; Xu, David; Shannon, Harlan E.; Bailey, Barbara J.; Corson, Timothy W.; Pollok, Karen E.; Wells, Clark D.; Meroueh, Samy O.; Biochemistry and Molecular Biology, School of Medicine
    The Hippo pathway coordinates extracellular signals onto the control of tissue homeostasis and organ size. Hippo signaling primarily regulates the ability of Yap1 to bind and co-activate TEA domain (TEAD) transcription factors. Yap1 tightly binds to TEAD4 via a large flat interface, making the development of small-molecule orthosteric inhibitors highly challenging. Here, we report small-molecule TEAD⋅Yap inhibitors that rapidly and selectively form a covalent bond with a conserved cysteine located within the unique deep hydrophobic palmitate-binding pocket of TEADs. Inhibition of TEAD4 binding to Yap1 by these compounds was irreversible and occurred on a longer time scale. In mammalian cells, the compounds formed a covalent complex with TEAD4, inhibited its binding to Yap1, blocked its transcriptional activity, and suppressed expression of connective tissue growth factor. The compounds inhibited cell viability of patient-derived glioblastoma spheroids, making them suitable as chemical probes to explore Hippo signaling in cancer.
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    Transient ligand‐enabled transition metal‐catalysed C‐H functionalisation
    (Wiley, 2019) Niu, Ben; Yang, Ke; Lawrence, Brianna; Ge, Haibo; Chemistry and Chemical Biology, School of Science
    Transition metal‐catalysed C‐H bond functionalisation is one of the most efficient and powerful strategies in synthetic organic chemistry to derivatize otherwise inert sites of organic molecules for the construction of C‐C and C‐heteroatom bonds. However, additional steps are often required in order to install the directing groups to realize the positional functionalisation of the substrates. These tedious steps run counter to the step‐economical nature of the C‐H activation. In contrast, direct functionalisation of the substrate, utilizing the transient ligands, avoids the unnecessary steps for the prefunctionalisation of the substrates. In this mini review, we will provide a short journey for the major progress made in this field for the C‐H functionalisation on sp2 and sp3 carbon centres with different transient working modes, including the covalent, hydrogen, and ionic bonds.