The stability of the Wnt pathway transcription factor beta-catenin is tightly regulated by the multi-subunit destruction complex. Deregulated Wnt pathway activity has been implicated in many cancers, making this pathway an attractive target for anticancer therapies. However, the development of targeted Wnt pathway inhibitors has been hampered by the limited number of pathway components that are amenable to small molecule inhibition. Here, we used a chemical genetic screen to identify a small molecule, XAV939, which selectively inhibits beta-catenin-mediated transcription. XAV939 stimulates beta-catenin degradation by stabilizing axin, the concentration-limiting component of the destruction complex. Using a quantitative chemical proteomic approach, we discovered that XAV939 stabilizes axin by inhibiting the poly-ADP-ribosylating enzymes tankyrase 1 and tankyrase 2. Both tankyrase isoforms interact with a highly conserved domain of axin and stimulate its degradation through the ubiquitin-proteasome pathway. Thus, our study provides new mechanistic insights into the regulation of axin protein homeostasis and presents new avenues for targeted Wnt pathway therapies.
In the version of this caption initially published, the cover artwork was credited to Erin Dewalt, based on imagery from the author, rather than stating that it was created by Michael B. Battles and the design was by Erin Dewalt. The error has been corrected in the HTML and PDF versions of the caption. ERRATUM In the version of this article initially published, the genus name 'Mycoplasma' was incorrectly used in place of the correct 'Mycobacterium'. The error has been corrected in the HTML and PDF versions of the article. ERRATUM npg
Summary
Toll-Like Receptor (TLR) signaling is a key component of innate immunity. Aberrant TLR activation leads to immune disorders via dysregulation of cytokine production, such as IL-12/23. Herein we identify and characterize PIKfyve, a lipid kinase, as a critical player in TLR signaling using apilimod as an affinity tool. Apilimod is a potent small molecular inhibitor of IL-12/23 with an unknown target and has been evaluated in clinical trials for patients with Crohn’s disease or rheumatoid arthritis. Using a chemical genetics approach, we show that it binds to PIKfyve and blocks its phosphotransferase activity, leading to selective inhibition of IL-12/23p40. Pharmacological or genetic inactivation of PIKfyve is necessary and sufficient for suppression of IL-12/23p40 expression. Thus, we have uncovered a novel phosphoinositide-mediated regulatory mechanism that controls TLR signaling.
Identification of novel, validated targets remains a top priority in modern drug discovery. Chemical genetics represents a powerful approach to the discovery of new targets. Unlike the traditional target-based screen that relies on a predefined, sometimes poorly validated target, a chemical genetics-based phenotypic screen probes the entire molecular signaling pathway in an efficient and unbiased manner for the most drug-sensitive node. The most significant obstacle associated with this approach is identification of the efficacy targets of small-molecule probes. The huge potential of chemical genetics cannot be realized without the establishment of reliable mechanisms for target identification. In this article, we describe each essential element of the chemical genetics process, discuss common challenges that the field is facing, and critically review various biochemical and genetics approaches recently developed for target deconvolution. We also attempt to summarize lessons that we have collectively learned and provide a practical perspective to facilitate the advancement of chemical genetics.
Tankyrase 1 and 2 have been shown to be redundant, druggable nodes in the Wnt pathway. As such, there has been intense interest in developing agents suitable for modulating the Wnt pathway in vivo by targeting this enzyme pair. By utilizing a combination of structure-based design and LipE-based structure efficiency relationships, the core of XAV939 was optimized into a more stable, more efficient, but less potent dihydropyran motif 7. This core was combined with elements of screening hits 2, 19, and 33 and resulted in highly potent, selective tankyrase inhibitors that are novel three pocket binders. NVP-TNKS656 (43) was identified as an orally active antagonist of Wnt pathway activity in the MMTV-Wnt1 mouse xenograft model. With an enthalpy-driven thermodynamic signature of binding, highly favorable physicochemical properties, and high lipophilic efficiency, NVP-TNKS656 is a novel tankyrase inhibitor that is well suited for further in vivo validation studies.
Spinal muscular atrophy (SMA), a
rare neuromuscular disorder, is
the leading genetic cause of death in infants and toddlers. SMA is
caused by the deletion or a loss of function mutation of the survival
motor neuron 1 (SMN1) gene. In humans, a second closely related gene
SMN2 exists; however it codes for a less stable SMN protein. In recent
years, significant progress has been made toward disease modifying
treatments for SMA by modulating SMN2 pre-mRNA splicing. Herein, we
describe the discovery of LMI070/branaplam, a small molecule that
stabilizes the interaction between the spliceosome and SMN2 pre-mRNA.
Branaplam (1) originated from a high-throughput phenotypic
screening hit, pyridazine 2, and evolved via multiparameter
lead optimization. In a severe mouse SMA model, branaplam treatment
increased full-length SMN RNA and protein levels, and extended survival.
Currently, branaplam is in clinical studies for SMA.
The Wnt signaling pathway is critical to the regulation of key cellular processes. When deregulated, it has been shown to play a crucial role in the growth and progression of multiple human cancers. The identification of small molecule modulators of Wnt signaling has proven challenging, largely due to the relative paucity of druggable nodes in this pathway. Several recent publications have identified small molecule inhibitors of the Wnt pathway, and tankyrase (TNKS) inhibition has been demonstrated to antagonize Wnt signaling via axin stabilization. Herein, we report the early hit assessment of a series of compounds previously reported to antagonize Wnt signaling. We report the biophysical, computational characterization, structure-activity relationship, and physicochemical properties of a novel series of [1,2,4]triazol-3-ylsulfanylmethyl)-3-phenyl-[1,2,4]oxadiazole inhibitors of TNKS1 and 2. Furthermore, a cocrystal structure of compound 24 complexed to TNKS1 demonstrates an alternate binding mode for PARP family member proteins that does not involve interactions with the nicotinamide binding pocket.
The crystal structures of tankyrase 1 (TNKS1) in complex with two small-molecule inhibitors, PJ34 and XAV939, both at 2.0 Å resolution, are reported. The structure of TNKS1 in complex with PJ34 reveals two molecules of PJ34 bound in the NAD(+) donor pocket. One molecule is in the nicotinamide portion of the pocket, as previously observed in other PARP structures, while the second molecule is bound in the adenosine portion of the pocket. Additionally, unlike the unliganded crystallization system, the TNKS1-PJ34 crystallization system has the NAD(+) donor site accessible to bulk solvent in the crystal, which allows displacement soaking. The TNKS1-PJ34 crystallization system was used to determine the structure of TNKS1 in complex with XAV939. These structures provide a basis for the start of a structure-based drug-design campaign for TNKS1.
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