Stephen F. Hardy

RAF Inhibitors Activate the MAPK Pathway by Relieving Inhibitory Autophosphorylation

ATP competitive inhibitors of the BRAF(V600E) oncogene paradoxically activate downstream signaling in cells bearing wild-type BRAF (BRAF(WT)). In this study, we investigate the biochemical mechanism of wild-type RAF (RAF(WT)) activation by multiple catalytic inhibitors using kinetic analysis of purified BRAF(V600E) and RAF(WT) enzymes. We show that activation of RAF(WT) is ATP dependent and directly linked to RAF kinase activity. These data support a mechanism involving inhibitory autophosphorylation of RAFs phosphate-binding loop that, when disrupted either through pharmacologic or genetic alterations, results in activation of RAF and the mitogen-activated protein kinase (MAPK) pathway. This mechanism accounts not only for compound-mediated activation of the MAPK pathway in BRAF(WT) cells but also offers a biochemical mechanism for BRAF oncogenesis.

Fragmented Tissue Factor Pathway Inhibitor (TFPI) and TFPI C‐Terminal Peptides Eliminate Serum‐Resistant Escherichia coli from Blood Cultures

BACKGROUND Tissue factor pathway inhibitor (TFPI) is a major regulator of blood clotting. Receipt of recombinant TFPI (rTFPI) protected animals from death in Escherichia coli-induced severe sepsis models and is under evaluation in a phase III clinical trial involving patients with severe community-acquired pneumonia. Because the mechanism of action of rTFPI in acute bacterial infection is not well understood, we sought to identify and map rTFPI peptides that have antimicrobial activity against E. coli. METHODS Fragmented rTFPI and C-terminal TFPI peptide activities against pathogenic E. coli strains were measured in ex vivo blood cultures and in serum. RESULTS The C-terminal peptides exhibited complement-dependent antibacterial activity and directly interacted with the bacterial cell surface of E. coli. Both complement-mediated killing and cell-surface binding were reversed by low amounts of heparin. CONCLUSIONS Our investigation revealed a previously unidentified mechanism of antibacterial activity for TFPI. C-terminal rTFPI fragments kill serum-resistant E. coli though the complement pathway of the innate immune system, suggesting a multimodal mechanism of action of rTFPI that may assist in reducing mortality in animal models of severe sepsis and contribute to therapeutic effectiveness.

Inhibition of prenylated KRAS in a lipid environment

RAS mutations lead to a constitutively active oncogenic protein that signals through multiple effector pathways. In this chemical biology study, we describe a novel coupled biochemical assay that measures activation of the effector BRAF by prenylated KRASG12V in a lipid-dependent manner. Using this assay, we discovered compounds that block biochemical and cellular functions of KRASG12V with low single-digit micromolar potency. We characterized the structural basis for inhibition using NMR methods and showed that the compounds stabilized the inactive conformation of KRASG12V. Determination of the biophysical affinity of binding using biolayer interferometry demonstrated that the potency of inhibition matches the affinity of binding only when KRAS is in its native state, namely post-translationally modified and in a lipid environment. The assays we describe here provide a first-time alignment across biochemical, biophysical, and cellular KRAS assays through incorporation of key physiological factors regulating RAS biology, namely a negatively charged lipid environment and prenylation, into the in vitro assays. These assays and the ligands we discovered are valuable tools for further study of KRAS inhibition and drug discovery.

Abstract B38: Inhibiting mutated KRAS, a broken switch of effector pathways

Mutated forms of KRAS are no longer able to switch effectors between “on” and “off” states. It is known that the function of KRAS is controlled by key parts in the C-terminus, including six consecutive lysines, a terminal prenyl moiety and a terminal carboxymethyl functional group. We set out to discover compounds which would inhibit the function of mutated KRAS as an activator for effectors. This campaign yielded several compounds that blocked biochemical and cellular functions of KRAS with low micromolar activity while not affecting markers outside of KRAS pathways in cells. In order to understand the mode of binding of these compounds to KRAS, we generated different forms of the protein, including unprenylated truncated and fully processed full-length protein. NMR studies with truncated protein (amino acids 1-169) identified a site at which compound binding stabilized the inactive conformation of KRAS. This site is located adjacent to switch-II and is similar to sites described by others. The Kd determined for this binding event is almost 3 orders of magnitude higher than the IC50 and EC50 values measured in biochemical and cellular assays. In order to understand this difference, we developed a biophysical assay using the Fortebio system which enabled binding studies in a system with full-length prenylated protein in the presence of lipids, to match the context of the biochemical and cellular assays. Micromolar binding to the full-length prenylated KRAS protein was observed in the Fortebio assay and binding was not observed in the absence of prenylation, consistent with the near millimolar Kd observed by NMR for truncated KRAS. Curiously, similar micromolar binding was seen to a peptide derived from the C-terminus of KRAS (amino acids 168-185) with and without prenyl modification while related compounds that do not bind to the full-length prenylated KRAS also do not bind to these peptides. It is still unclear whether binding to the terminal peptide in lipid context is related to the binding site adjacent to switch-II. From a drug discovery perspective, it remains to be confirmed whether current inhibitors can be optimized. Citation Format: Johanna Jansen, Wolfgang Jahnke, Susan Fong, Laura Tandeske, Charles Wartchow, Keith Pfister, Tatiana Zavorotinskaya, Anke Blechschmidt, Dirksen Bussiere, Yumin Dai, Jeff Dove, Eric Fang, David Farley, Jean-Michel Florent, John Fuller, Simona Gokhin, Alvar Gossert, Mohammad Hekmat-Nejad, Chrystele Henry, Julia Klopp, Bill Lenahan, Andreas Lingel, Arndt Meyer, Jamie Narberes, Gwynn Pardee, C Gregory Paris, Savithri Ramurthy, Paul Renhowe, Sebastien Rieffel, Kevin Shoemaker, Sharadha Subramanian, Tiffany Tsang, Stephania Widger, Armin Widmer, Isabel Zaror, Stephen Hardy. Inhibiting mutated KRAS, a broken switch of effector pathways. [abstract]. In: Proceedings of the AACR Special Conference on RAS Oncogenes: From Biology to Therapy; Feb 24-27, 2014; Lake Buena Vista, FL. Philadelphia (PA): AACR; Mol Cancer Res 2014;12(12 Suppl):Abstract nr B38. doi: 10.1158/1557-3125.RASONC14-B38