Novel K-Ras G12C Switch-II Covalent Binders Destabilize Ras and Accelerate Nucleotide Exchange

Nnadi, Chimno I; Jenkins, Meredith L.; Gentile, Daniel R.; Bateman, Leslie A.; Zaidman, Daniel; Balius, Trent E.; Nomura, Daniel K.; Burke, John E.; Shokat, Kevan M.; London, Nir

doi:10.1021/acs.jcim.7b00399

Cited by 44 publications

(37 citation statements)

References 39 publications

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“…[30] Known covalentl igandsb ind to ah ighly flexible allosteric pocket, which traps KRas G12C in the inactiveG DP-bound state (thereby confirming its druggability). [30] In Table 1, the variousH -bond interactions are displayed for 10 KRas G12C structures containing ac ovalently bound acrylamide ligand, as well as the W QB values obtained for each interaction on the reference ligand. [30] In Table 1, the variousH -bond interactions are displayed for 10 KRas G12C structures containing ac ovalently bound acrylamide ligand, as well as the W QB values obtained for each interaction on the reference ligand.…”

Section: Case Study2:k Ras G12cmentioning

confidence: 88%

“…[29] KRas is a small Gprotein, which is rendered constitutively active by the G12C mutation, leadingt oa bnormal cell growth.The mutation has been shown to be implicated in 40 %o fK Ras-driven lung cancers. [30] Known covalentl igandsb ind to ah ighly flexible allosteric pocket, which traps KRas G12C in the inactiveG DP-bound state (thereby confirming its druggability). [31] Additionally,covalent ligands can specifically target the mutatedK Ras G12C ,s paring the wildtype protein and offering the opportunity for oncogene-specific inhibition.…”

Section: Case Study2:k Ras G12cmentioning

confidence: 88%

“…[31] Additionally,covalent ligands can specifically target the mutatedK Ras G12C ,s paring the wildtype protein and offering the opportunity for oncogene-specific inhibition. [30] In Table 1, the variousH -bond interactions are displayed for 10 KRas G12C structures containing ac ovalently bound acrylamide ligand, as well as the W QB values obtained for each interaction on the reference ligand. For the remaining two of the 12 selected structures (PDB IDs 4M21 and 6ARK),n oH -bonds could be reliably identified.…”

Section: Case Study2:k Ras G12cmentioning

confidence: 99%

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DUckCov: a Dynamic Undocking‐Based Virtual Screening Protocol for Covalent Binders

et al. 2019

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Thanks to recent guidelines, the design of safe and effective covalent drugs has gained significant interest. Other than targeting non‐conserved nucleophilic residues, optimizing the noncovalent binding framework is important to improve potency and selectivity of covalent binders toward the desired target. Significant efforts have been made in extending the computational toolkits to include a covalent mechanism of protein targeting, like in the development of covalent docking methods for binding mode prediction. To highlight the value of the noncovalent complex in the covalent binding process, here we describe a new protocol using tethered and constrained docking in combination with Dynamic Undocking (DUck) as a tool to privilege strong protein binders for the identification of novel covalent inhibitors. At the end of the protocol, dedicated covalent docking methods were used to rank and select the virtual hits based on the predicted binding mode. By validating the method on JAK3 and KRas, we demonstrate how this fast iterative protocol can be applied to explore a wide chemical space and identify potent targeted covalent inhibitors.

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Section: Case Study2:k Ras G12cmentioning

confidence: 88%

Section: Case Study2:k Ras G12cmentioning

confidence: 88%

Section: Case Study2:k Ras G12cmentioning

confidence: 99%

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DUckCov: a Dynamic Undocking‐Based Virtual Screening Protocol for Covalent Binders

et al. 2019

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“…NV3CP was produced following the procedure described in Hussey et al 72 . K-Ras G12C (1-169) was expressed and purified as described in Nnadi et al 18 .…”

Section: Protein Sources Expression and Purificationmentioning

confidence: 99%

“…Historically, the most widespread approach for the design of such inhibitors relied on the incorporation of an electrophile into an already optimized reversible recognition element 4,[9][10][11] , most notably in kinase inhibitors 4,[12][13][14][15][16] . More recently, large-scale covalent virtual screens have also emerged as a method for the discovery of covalent binders [17][18][19][20][21][22] . While successful, in silico docking still has its limitations: it is limited to targets for which a crystal structure (or a high-quality model) is available; and second, it cannot efficiently address protein flexibility.…”

Section: Introductionmentioning

confidence: 99%

Rapid covalent-probe discovery by electrophile fragment screening

Resnick

Bradley

Gan

et al. 2018

Preprint

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Covalent probes can display unmatched potency, selectivity and duration of action, however, their discovery is challenging. In principle, fragments that can irreversibly bind their target can overcome the low affinity that limits reversible fragment screening. Such electrophilic fragments were considered non-selective and were rarely screened. We hypothesized that mild electrophiles might overcome the selectivity challenge, and constructed a library of 993 mildly electrophilic fragments. We characterized this library by a new high-throughput thiol-reactivity assay and screened them against ten cysteine-containing proteins. Highly reactive and promiscuous fragments were rare and could be easily eliminated. By contrast, we found selective hits for most targets. Combination with high-throughput crystallography allowed rapid progression to potent and selective probes for two enzymes, the deubiquitinase OTUB2, and the pyrophosphatase NUDT7. No inhibitors were previously known for either. This study highlights the potential of electrophile fragment screening as a practical and efficient tool for covalent ligand discovery.Fragment based screening, which focuses on very low molecular-weight compounds, is a successful hit discovery approach for reversible inhibitors 28,29 , that has led to several drugs and chemical probes 29,30 . Compared to traditional HTS, fragment-based screening offers better coverage of chemical space and higher probability of binding due to lower complexity 31,32 . The major limitation in fragment-based screening is the weak binding affinity of fragment hits, which not only necessitates very sensitive biophysical detection methods, coupled with elaborate validation cascades to eliminate attendant artefacts, but additionally makes progressing hits to potency difficult and expensive. In particular, it requires large compound series with typically ambiguous structure-activity relationships, because no method to date can reliably rationalize which are the dominant interactions of the original fragment. Screening covalent fragments addresses both problems: covalent binders are easy to detect by mass spectrometry; and because the dominant interaction is unambiguous, namely the covalent bond, designing followup series is simplified, and the primary hits are already potent.A prominent covalent fragment screening approach is disulfide tethering 33,34 , which entails incubating a library of disulfide-containing fragments with the target. Disulfide exchange with the target cysteine selects for fragments that are reversibly stabilized in its vicinity. Disulfide tethering was successfully applied to a variety of targets containing both native and introduced cysteine residues 35 . Recently it led to the discovery of a promising K-Ras G12C inhibitor 36 . Disulfides are not, however, suitable as cellular probes, and replacing them with a suitable electrophile is in general no less challenging than starting from a reversible ligand.A potential solution is to directly screen mild electrophile fragments. Electrophile...

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