Brian R. Baer scite author profile

Despite decades of research, efforts to directly target KRAS have been challenging. MRTX849 was identifi ed as a potent, selective, and covalent KRAS G12C inhibitor that exhibits favorable drug-like properties, selectively modifi es mutant cysteine 12 in GDPbound KRAS G12C , and inhibits KRAS-dependent signaling. MRTX849 demonstrated pronounced tumor regression in 17 of 26 (65%) KRAS G12C -positive cell line-and patient-derived xenograft models from multiple tumor types, and objective responses have been observed in patients with KRAS G12C -positive lung and colon adenocarcinomas. Comprehensive pharmacodynamic and pharmacogenomic profi ling in sensitive and partially resistant nonclinical models identifi ed mechanisms implicated in limiting antitumor activity including KRAS nucleotide cycling and pathways that induce feedback reactivation and/or bypass KRAS dependence. These factors included activation of receptor tyrosine kinases (RTK), bypass of KRAS dependence, and genetic dysregulation of cell cycle. Combinations of MRTX849 with agents that target RTKs, mTOR, or cell cycle demonstrated enhanced response and marked tumor regression in several tumor models, including MRTX849-refractory models. SIGNIFICANCE :The discovery of MRTX849 provides a long-awaited opportunity to selectively target KRAS G12C in patients. The in-depth characterization of MRTX849 activity, elucidation of response and resistance mechanisms, and identifi cation of effective combinations provide new insight toward KRAS dependence and the rational development of this class of agents.

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Identification of the Clinical Development Candidate MRTX849, a Covalent KRAS^G12C Inhibitor for the Treatment of Cancer

Fell

et al. 2020

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Capping off an era marred by drug development failures and punctuated by waning interest and presumed intractability toward direct targeting of KRAS, new technologies and strategies are aiding in the target’s resurgence. As previously reported, the tetrahydropyridopyrimidines were identified as irreversible covalent inhibitors of KRASG12C that bind in the switch-II pocket of KRAS and make a covalent bond to cysteine 12. Using structure-based drug design in conjunction with a focused in vitro absorption, distribution, metabolism and excretion screening approach, analogues were synthesized to increase the potency and reduce metabolic liabilities of this series. The discovery of the clinical development candidate MRTX849 as a potent, selective covalent inhibitor of KRASG12C is described.

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Time-Dependent Inactivation of P450 3A4 by Raloxifene: Identification of Cys239 as the Site of Apoprotein Alkylation¹

Baer

Wienkers

Rock

2007

Chem. Res. Toxicol.

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Time-dependent inactivation of cytochrome P450s is typically a result of substrate bioactivation to form reactive species that subsequently alkylate the heme group, apoprotein, or both. The chemical identity of many reactive intermediates is generally proposed based on the products of trapping reactions with nucleophilic agents as only a few P450-drug adducts have been directly characterized. We describe the use of mass spectrometry to show that a single equivalent of raloxifene is bound to the intact P450 apoprotein. Furthermore, mass analysis of peptides following digestion with proteinase K revealed that the covalently bound drug is localized to residue Cys239. A mass shift of 471 Da to the intact protein and peptide, relative to control samples, indicated that time-dependent inactivation of P450 3A4 occurred through the raloxifene diquinone methide intermediately prior to nucleophilic attack of the sulfur of Cys239. Association between raloxifene adduction to P450 3A4 apoprotein and the observed time-dependent inactivation was further investigated with the use of cysteine-specific modifying reagents. When P450 3A4 was treated with iodoacetamide or N-(1-pyrene)iodoacetamide, which alkylated residue Cys239 exclusively, time-dependent inactivation of P450 3A4 by raloxifene was prevented. The change in protein mass of 471 Da combined with the protection from inactivation that occurred through pre-alkylation of Cys239 provided conclusive evidence that raloxifene-mediated P450 3A4 inactivation occurred through the bioactivation of raloxifene to the diquinone methide and subsequent alkylation of Cys239.

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Bioactivation of 4-Ipomeanol by CYP4B1: Adduct Characterization and Evidence for an Enedial Intermediate

Baer

Rettie

Henne

2005

Chem. Res. Toxicol.

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4-Ipomeanol (IPO) is a pneumotoxin that is bioactivated to a reactive intermediate that binds to DNA and other cellular macromolecules. Despite over 30 years of research in this area, detailed structural information on the nature of the IPO reactive intermediate is still lacking. In the present study, we reacted IPO with rabbit CYP4B1 in the presence of exogenous nucleophiles and analyzed the products by liquid chromatography/electrospray ionization-mass spectrometry. Coincubation of IPO and rabbit CYP4B1 with glutathione gave rise to multiple products due likely to the presence of both sulfur and nitrogen nucleophiles in the same trapping molecule. Reaction mixtures containing equimolar N-acetyl cysteine (NAC) and N-acetyl lysine (NAL) provided a major NADPH- and CYP4B1-dependent product. A combination of high-resolution mass spectrometry and two-dimensional NMR analysis following large-scale isolation of the biologically derived material provided evidence for an N-substituted cysteinyl pyrrole derivative of IPO, analogous to that characterized previously in model chemical studies conducted with cis-2-butene-1,4-dial. Purified native rabbit lung CYP4B1 and purified recombinant rabbit CYP4B1 produced the trapped NAC/NAL-IPO pyrrole adduct at rates of 600-700 nmol/nmol P450/30 min. A panel of 14 commercially available recombinant human CYPs was also studied, and substantial rates of IPO bioactivation (>100 nmol/nmol/30 min) were observed with CYP1A2, CYP2C19, CYP2D6, and CYP3A4. These studies provide evidence for the formation of an enedial reactive intermediate during CYP-mediated IPO bioactivation, identify multiple human liver P450s capable of IPO bioactivation, and demonstrate that the same reactive intermediate is formed by both rabbit CYP4B1 and human P450s.

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Benzylic Oxidation of Gemfibrozil-1-O-β-Glucuronide by P450 2C8 Leads to Heme Alkylation and Irreversible Inhibition

Baer

DeLisle

Allen

2009

Chem. Res. Toxicol.

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Gemfibrozil-1-O-beta-glucuronide (GEM-1-O-gluc), a major metabolite of the antihyperlipidemic drug gemfibrozil, is a mechanism-based inhibitor of P450 2C8 in vitro, and this irreversible inactivation may lead to clinical drug-drug interactions between gemfibrozil and other P450 2C8 substrates. In light of this in vitro finding and the observation that the glucuronide conjugate does not contain any obvious structural alerts, the current study was conducted to determine the potential site of GEM-1-O-gluc bioactivation and the subsequent mechanism of P450 2C8 inhibition (i.e., modification of apoprotein or heme). LC/MS analysis of a reaction mixture containing recombinant P450 2C8 and GEM-1-O-gluc revealed that the substrate was covalently linked to the heme prosthetic heme group during catalysis. A combination of mass spectrometry and deuterium isotope effects revealed that a benzylic carbon on the 2',5'-dimethylphenoxy group of GEM-1-O-gluc was covalently bound to the heme of P450 2C8. The regiospecificity of substrate addition to the heme group was not confirmed experimentally, but computational modeling experiments indicated that the gamma-meso position was the most likely site of modification. The metabolite profile, which consisted of two benzyl alcohol metabolites and a 4'-hydroxy-GEM-1-O-gluc metabolite, indicated that oxidation of GEM-1-O-gluc was limited to the 2',5'-dimethylphenoxy group. These results are consistent with an inactivation mechanism wherein GEM-1-O-gluc is oxidized to a benzyl radical intermediate, which evades oxygen rebound, and adds to the gamma-meso position of heme. Mechanism-based inhibition of P450 2C8 can be rationalized by the formation of the GEM-1-O-gluc-heme adduct and the consequential restriction of additional substrate access to the catalytic iron center.

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Brian R. Baer

The KRASG12C Inhibitor MRTX849 Provides Insight toward Therapeutic Susceptibility of KRAS-Mutant Cancers in Mouse Models and Patients

Identification of the Clinical Development Candidate MRTX849, a Covalent KRAS^G12C Inhibitor for the Treatment of Cancer

Time-Dependent Inactivation of P450 3A4 by Raloxifene: Identification of Cys239 as the Site of Apoprotein Alkylation¹

Bioactivation of 4-Ipomeanol by CYP4B1: Adduct Characterization and Evidence for an Enedial Intermediate

Benzylic Oxidation of Gemfibrozil-1-O-β-Glucuronide by P450 2C8 Leads to Heme Alkylation and Irreversible Inhibition

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About

Brian R. Baer

The KRASG12C Inhibitor MRTX849 Provides Insight toward Therapeutic Susceptibility of KRAS-Mutant Cancers in Mouse Models and Patients

Identification of the Clinical Development Candidate MRTX849, a Covalent KRASG12C Inhibitor for the Treatment of Cancer

Time-Dependent Inactivation of P450 3A4 by Raloxifene: Identification of Cys239 as the Site of Apoprotein Alkylation1

Bioactivation of 4-Ipomeanol by CYP4B1: Adduct Characterization and Evidence for an Enedial Intermediate

Benzylic Oxidation of Gemfibrozil-1-O-β-Glucuronide by P450 2C8 Leads to Heme Alkylation and Irreversible Inhibition

Contact Info

Product

Resources

About

Identification of the Clinical Development Candidate MRTX849, a Covalent KRAS^G12C Inhibitor for the Treatment of Cancer

Time-Dependent Inactivation of P450 3A4 by Raloxifene: Identification of Cys239 as the Site of Apoprotein Alkylation¹