C-terminal Binding Protein (CtBP) is a transcriptional co-regulator that downregulates the expression of many tumor-suppressor genes. Utilizing a crystal structure of CtBP with its substrate 4-methylthio-2-oxobutyric acid (MTOB) and NAD+ as a guide, we have designed, synthesized, and tested a series of small molecule inhibitors of CtBP. From our first round of compounds, we identified 2-(hydroxyimino)-3-phenylpropanoic acid as a potent CtBP inhibitor (IC50 = 0.24 μM). A structure-activity relationship study of this compound further identified the 4-chloro- (IC50 = 0.18 μM) and 3-chloro- (IC50 = 0.17 μM) analogues as additional potent CtBP inhibitors. Evaluation of the hydroxyimine analogues in a short-term cell growth/viability assay showed that the 4-chloro- and 3-chloro- analogues are 2-fold and 4-fold more potent, respectively, than the MTOB control. A functional cellular assay using a CtBP-specific transcriptional readout revealed that the 4-chloro- and 3-chloro-hydroxyimine analogues were able to block CtBP transcriptional repression activity. This data suggests that substrate-competitive inhibition of CtBP dehydrogenase activity is a potential mechanism to reactivate tumor-suppressor gene expression as a therapeutic strategy for cancer.
The design and development of irreversible kinase inhibitors is an expanding frontier of kinase drug discovery. The current approach to develop these inhibitors utilizes ATP-competitive inhibitor scaffolds to target non-catalytic cysteines in the kinase ATP-binding site. However, this approach is limited as not all kinases have a cysteine in the ATP-binding site that can be targeted. In this work, we report a complementary approach to developing irreversible kinase inhibitors that utilizes the substrate-binding site. Using the catalytic subunit of cAMP-dependent protein kinase (PKACα) as a model system, we have designed and synthesized an irreversible inhibitor based on the substrate-competitive inhibitor scaffold PKI(14-22) that covalently modifies non-catalytic Cys199 in the PKACα substrate-binding site. The new compound inhibits PKACα (IC50 = 11.8 ± 1.1 nM), is ∼100-fold selective for PKACα in a kinase panel, and covalently labels the kinase as demonstrated by fluorescence, mass spectrometry, and kinetics experiments. This study demonstrates the feasibility of utilizing this new approach to develop irreversible inhibitors for any of the eighty-nine kinases that possess a similar non-catalytic cysteine in their substrate-binding sites.
To facilitate analyses of purinergic signaling in peripheral nerve glia, we review recent literature and catalog purinergic receptor mRNA expression in cultured mouse Schwann cells (SCs). Purinergic signaling can decrease developmental SC proliferation, and promote SC differentiation. The purinergic receptors P2RY2 and P2RX7 are implicated in nerve development and in the ratio of Remak SCs to myelinating SCs in differentiated peripheral nerve. P2RY2, P2RX7, and other receptors are also implicated in peripheral neuropathies and SC tumors. In SC tumors lacking the tumor suppressor NF1, the SC pathway that suppresses SC growth through P2RY2‐driven β‐arrestin‐mediated AKT signaling is aberrant. SC‐released purinergic agonists acting through SC and/or neuronal purinergic receptors activate pain responses. In all these settings, purinergic receptor activation can result in calcium‐independent and calcium‐dependent release of SC ATP and UDP, growth factors, and cytokines that may contribute to disease and nerve repair. Thus, current research suggests that purinergic agonists and/or antagonists might have the potential to modulate peripheral glia function in development and in disease.
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