Addressing Atropisomerism in the Development of Sotorasib, a Covalent Inhibitor of KRAS G12C: Structural, Analytical, and Synthetic Considerations

Conspectus Nearly a century after its first description, configurationally stable axial chirality remains a rare feature in marketed drugs. In the development of the KRASG12C inhibitor sotorasib (LUMAKRAS/LUMYKRAS), an axially chiral biaryl moiety proved a critical structural element in engaging a “cryptic” protein binding pocket and enhancing inhibitor potency. Restricted rotation about this axis of chirality gave rise to configurationally stable atropisomers that demonstrated a 10-fold difference in potency. The decision to develop sotorasib as a single-atropisomer drug gave rise to a range of analytical and synthetic challenges, whose resolution we review here. Assessing the configurational stability of differentially substituted biaryl units in early inhibitor candidates represented the first challenge to be overcome, as differing atropisomer stability profiles called for differing development strategies (e.g., as rapidly equilibrating rotamers vs as single atropisomers). We relied on a range of NMR, HPLC, and computational methods to assess atropisomer stability. Here, we describe the various variable-temperature NMR, time-course NMR, and chiral HPLC approaches used to assess the configurational stability of axially chiral bonds displaying a range of rotational barriers. As optimal engagement of the “cryptic” pocket of KRASG12C was ultimately achieved with a configurationally stable atropisomeric linkage, the second challenge to be overcome entailed preparing the preferred (M)-atropisomer of sotorasib on industrial scale. This synthetic challenge centered on the large-scale synthesis of an atropisomerically pure building block comprising the central azaquinazolinone and pyridine rings of sotorasib. We examined a range of strategies to prepare this compound as a single atropisomer: asymmetric catalysis, chiral chromatographic purification, and classical resolution. Although chiral liquid and simulated moving bed chromatography provided expedient access to initial multikilo supplies of this key intermediate, a classical resolution process was ultimately developed that proved significantly more efficient on metric-ton scale. To avoid discarding half of the material from this resolution, this process was subsequently refined to enable thermal recycling of the undesired atropisomer, providing an even more efficient commercial process that proved both robust and green. While the preparation of sotorasib as a single atropisomer significantly increased both the analytical and synthetic complexity of its development, the axially chiral biaryl linkage that gave rise to the atropisomerism of sotorasib proved a key design element in optimizing sotorasib’s binding to KRASG12C. It is hoped that this review will help in outlining the range of analytical techniques and synthetic strategies that can be brought to bear in addressing the challenges posed by such axially chiral compounds and that this account may provide helpful guidelines for future efforts aimed at the development of such single atropisomer, axially chiral pharmaceutical agents.

[1]  Michael A. Lovette,et al.  Axial Chirality in the Sotorasib Drug Substance, Part 1: Development of a Classical Resolution to Prepare an Atropisomerically Pure Sotorasib Intermediate , 2022, Organic Process Research & Development.

[2]  Kevin D. Nagy,et al.  Axial Chirality in the Sotorasib Drug Substance, Part 2: Leveraging a High-Temperature Thermal Racemization to Recycle the Classical Resolution Waste Stream , 2022, Organic Process Research & Development.

[3]  R. Fernández,et al.  Asymmetric Synthesis of Axially Chiral C−N Atropisomers , 2022, Chemistry.

[4]  Thomas O. Ronson,et al.  Exploration of a Nitromethane-Carbonylation Strategy during Route Design of an Atropisomeric KRASG12C Inhibitor. , 2021, The Journal of organic chemistry.

[5]  H. Emtenäs,et al.  Synthetic and Chromatographic Challenges and Strategies for Multigram Manufacture of KRASG12C Inhibitors , 2021, Organic Process Research & Development.

[6]  B. Tan,et al.  Recent Advances in Catalytic Asymmetric Construction of Atropisomers. , 2021, Chemical reviews.

[7]  N. Xi,et al.  19F NMR spectroscopy as a tool to detect rotations in fluorine substituted phenyl compounds , 2020 .

[8]  T. Fukushima,et al.  Analysis of Interconversion between Atropisomers of Chiral Substituted 9,9’‐Bicarbazole , 2020 .

[9]  A. Mazzanti,et al.  Stereochemistry and Recent Applications of Axially Chiral Organic Molecules , 2020 .

[10]  N. Chen,et al.  Discovery of a covalent inhibitor of KRASG12C (AMG 510) for the treatment of solid tumors. , 2019, Journal of medicinal chemistry.

[11]  Iain D G Campuzano,et al.  Discovery of N-(1-Acryloylazetidin-3-yl)-2-(1H-indol-1-yl)acetamides as Covalent Inhibitors of KRASG12C. , 2019, ACS medicinal chemistry letters.

[12]  Christian Griesinger,et al.  Application of anisotropic NMR parameters to the confirmation of molecular structure , 2018, Nature Protocols.

[13]  Thomas M. Razler,et al.  Adventures in Atropisomerism: Development of a Robust, Diastereoselective, Lithium-Catalyzed Atropisomer-Forming Active Pharmaceutical Ingredient Step , 2018, Organic Process Research & Development.

[14]  P. Atkins,et al.  PHYSICAL CHEMISTRY Thermodynamics, Structure, and Change , 2018 .

[15]  Amanda E. Wakefield,et al.  Cryptic binding sites on proteins: definition, detection, and druggability , 2018, Current Opinion in Chemical Biology.

[16]  J. Gustafson,et al.  Atropisomerism in medicinal chemistry: challenges and opportunities. , 2018, Future medicinal chemistry.

[17]  P. Glunz Recent encounters with atropisomerism in drug discovery. , 2018, Bioorganic & medicinal chemistry letters.

[18]  Z. Gu,et al.  Discovery and Assessment of Atropisomers of (±)-Lesinurad. , 2017, ACS medicinal chemistry letters.

[19]  J. H. T. Horst,et al.  Solvates, Salts, and Cocrystals: A Proposal for a Feasible Classification System , 2016 .

[20]  A. Buckingham Chiral discrimination in NMR spectroscopy , 2015, Quarterly Reviews of Biophysics.

[21]  M. Prashad,et al.  A Scalable Synthesis of an Atropisomeric Drug Substance via Buchwald–Hartwig Amination and Bruylants Reactions , 2014 .

[22]  Sarah J. Nehm,et al.  Cocrystals: Design, Properties and Formation Mechanisms , 2013 .

[23]  John L. Murphy,et al.  Biological stereoselectivity of atropisomeric natural products and drugs. , 2013, Chirality.

[24]  D. Häussinger,et al.  Atropisomerization of di-para-substituted propyl-bridged biphenyl cyclophanes. , 2013, Organic & biomolecular chemistry.

[25]  O. Hucke,et al.  Assessing atropisomer axial chirality in drug discovery and development. , 2011, Journal of medicinal chemistry.

[26]  Ian R Kleckner,et al.  An introduction to NMR-based approaches for measuring protein dynamics. , 2011, Biochimica et biophysica acta.

[27]  O. Hucke,et al.  Revealing Atropisomer Axial Chirality in Drug Discovery , 2011, ChemMedChem.

[28]  S. LaPlante,et al.  The challenge of atropisomerism in drug discovery. , 2009, Angewandte Chemie.

[29]  J. Rohonczy,et al.  Monte Carlo simulation of DNMR spectra of coupled spin systems. , 2008, Journal of magnetic resonance.

[30]  Sarah J. Nehm,et al.  Phase solubility diagrams of cocrystals are explained by solubility product and solution complexation , 2006 .

[31]  W. O. Moss,et al.  A new approach to the rapid parallel development of four neurokinin antagonists. Part 5. Preparation of zm374979 cyanoacid and selective crystallisation of ZM374979 atropisomers , 2004 .

[32]  T. Claridge High-Resolution NMR Techniques in Organic Chemistry , 1999 .

[33]  J. Barrow,et al.  Synthesis and conformational properties of the M(4-6)(5-7) bicyclic tetrapeptide common to the vancomycin antibiotics , 1997 .

[34]  C. Perrin,et al.  Application of two-dimensional NMR to kinetics of chemical exchange , 1990 .

[35]  David S. Stephenson,et al.  Iterative computer analysis of complex exchange-broadened NMR bandshapes , 1978 .

[36]  F. Gasparro,et al.  NMR Determination of the Rotational Barrier in N,N-Dimethylacetamide. , 1977 .

[37]  G. Christie,et al.  LXXI.—The molecular configurations of polynuclear aromatic compounds. Part I. The resolution of γ-6 : 6′-dinitro- and 4 : 6 : 4′ : 6′-tetranitro-diphenic acids into optically active components , 1922 .