DNA damage repair enzymes are promising targets in the development of new therapeutic agents for a wide range of cancers and potentially other diseases. The enzyme poly(ADP-ribose) glycohydrolase (PARG) plays a pivotal role in the regulation of DNA repair mechanisms; however, the lack of potent drug-like inhibitors for use in cellular and in vivo models has limited the investigation of its potential as a novel therapeutic target. Using the crystal structure of human PARG in complex with the weakly active and cytotoxic anthraquinone 8a, novel quinazolinedione sulfonamides PARG inhibitors have been identified by means of structure-based virtual screening and library design. 1-Oxetan-3-ylmethyl derivatives 33d and 35d were selected for preliminary investigations in vivo. X-ray crystal structures help rationalize the observed structure−activity relationships of these novel inhibitors.
Poly(ADP-ribose) glycohydrolase (PARG) is the only enzyme known to catalyse hydrolysis of the O-glycosidic linkages of ADP-ribose polymers, thereby reversing the effects of poly(ADP-ribose) polymerases (PARPs). PARG depletion, using RNAi, results in several effects such as PAR chain persistence, progression of single- to double-strand DNA lesions and NAD+ depletion. Given these findings, inhibition of PARG with a small molecule agent offers a potential opportunity to interfere with DNA repair mechanisms and induce cell death in those cells with increased susceptibility to DNA damage, such as tumour cells. Previous efforts to develop small molecule inhibitors of PARG activity have generally been hampered by poor physicochemical properties, off-target pharmacology and a lack of cell permeability, leading some to suggest that PARG may be undruggable. In contrast, we have now developed a series of first-in-class PARG inhibitors which display drug-like properties and attractive pharmacokinetic parameters. These compounds have proved to be useful biological tool compounds. Moreover, displaying selective activity in both biochemical and, more importantly, cellular assays of PARG function, these derivatives have allowed an exploration of the phenotypes resulting from reversible, pharmacological PARG inhibition in both in vitro cell panels and in vivo models. Furthermore, our initial bioinformatic analysis suggests that deficiency of a known tumour suppressor confers sensitivity to PARG inhibition, suggesting patient populations that will potentially benefit from PARGi therapies. Citation Format: Bohdan Waszkowycz, Dominic James, Ben Acton, Emma Fairweather, Sam Fritzl, Niall Hamilton, Nicola Hamilton, Sarah Holt, James Hitchen, Colin Hutton, Stuart Jones, Allan Jordan, Alison McGonagle, Daniel Mould, Helen Small, Kate Smith, Alexandra Stowell, Ian D. Waddell, Donald Ogilvie. First-in-class inhibitors of the putatively undruggable DNA repair target Poly(ADP-ribose) glycohydrolase (PARG). [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2015 Nov 5-9; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2015;14(12 Suppl 2):Abstract nr C39.
Background: The aim of this CRUK-MI Drug Discovery project is to deliver a RET-selective inhibitor for the treatment of cancers with RET activating mutations, which include 1-2% of lung adenocarcinomas and medullary thyroid cancers (MTC). Recent data supports the hypothesis that the efficacy of vandetanib and cabozantinib, clinically approved multi-kinase inhibitors, is limited by toxicities associated with potent activity against KDR. Therefore, a RET-selective inhibitor would represent a best-in-class agent for the treatment of these cancers. Methods: We have established a robust screening cascade to develop a potent, selective RET inhibitor and developed several in vivo models to evaluate compound PKPD and antitumor efficacy. Tumor growth inhibition and PKPD studies were carried out in BaF3 mouse allograft models overexpressing KIF5B-RET or RETV804M and other disease relevant models, including an MTC xenograft (MZ-CRC-1), a KIF5B-RET lung cancer patient derived xenograft (PDX) model (CTG-0838, Champions Oncology) and a lung cancer control xenograft (Calu-6). Results: Two orally bioavailable compounds displaying nanomolar RET potency and >10 fold selectivity over KDR in cellular assays were selected from the lead series and further evaluated in our in vivo PD and efficacy models. Both compounds demonstrated efficacy in the BaF3 KIF5B-RET driven model (71% and 103% tumor growth inhibition (TGI), respectively), accompanied by reduced levels of pRET in the tumor tissue. Following further lead optimisation; a compound displaying an improved DMPK profile and additional nanomolar potency versus the gatekeeper mutation (RETV804M) was identified and accelerated through our DMPK/in vivo cascade. We consider this additional activity versus RETV804M beneficial since mutations at the gatekeeper residue in other tyrosine kinases (e.g. EGFR) have been shown to mediate acquired drug resistance in the clinic. This compound demonstrated significant TGI of 58% and 82% respectively in the BaF3 KIF5B-RET and BaF3 RETV804M allograft models. Moreover, tumor growth in the lung cancer PDX model was strongly inhibited (95% TGI) and tumor regression induced in the MTC xenograft model (109% TGI). As expected, this potent and selective RET inhibitor was not active in the Calu-6 model, which is sensitive to KDR inhibition, whereas vandetanib, a potent KDR inhibitor, significantly inhibited tumor growth (84% TGI). Additional in vitro and in vivo DMPK analyses further support the nomination of this compound as a preclinical candidate. Conclusions: The identification of selective RET inhibitors with significant in vivo activity and minimal toxicity may overcome the limitations of the currently available clinical compounds. We have made considerable progress towards this goal and show here the compelling data supporting our nomination of a preclinical development compound. Citation Format: Mandy Watson, Helen Small, Ben Acton, Habiba Begum, Samantha Hitchin, Allan Jordan, Paul Kelly, Rebecca Newton, Ian Waddell, Gina Paris, Donald Ogilvie. A potent and selective RET inhibitor with efficacy in RET-driven mouse models of medullary thyroid carcinoma and lung adenocarcinoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 2092. doi:10.1158/1538-7445.AM2017-2092
Background: Constitutive activation of RET kinase activity following mutation or rearrangement can lead to the development of cancers such as medullary thyroid carcinoma and lung adenocarcinoma. The currently approved therapeutics for these diseases are significantly compromised due to dose-limiting toxicities associated with off-target activity vs KDR (VEGFR2) and lack of potency vs anticipated secondary resistance (e.g., gatekeeper) mutations. Consequently there is considerable interest in the development of highly selective inhibitors targeting diverse RET alterations including the putative resistance mutation, V804M. Methods: We have established a robust screening cascade complemented by structure-enabled drug design and effective medicinal chemistry. Biochemical activity vs RET, KDR, and RETV804M protein was assessed using a HTRF assay. Cellular activity was quantified in BaF3 cells dependent on activity of RET, KDR, or RETV804M for proliferation. Tumor growth inhibition and supporting PK/PD studies were carried out in a number of disease-relevant models including a KIF5B-RET lung cancer patient-derived xenograft (PDX) model, a medullary thyroid carcinoma (MZ-CRC-1) xenograft model, and a lung cancer control (Calu-6) xenograft model. Results: Using this optimized, robust platform, we have identified a number of selective compounds offering a range of interesting biochemical and cellular profiles, targeting either, or both, RET and the gatekeeper mutant, RETV804M. We believe certain examples of these compounds offer the first cell-active RETV804M-selective derivatives. More importantly perhaps, we have also delivered a highly selective preclinical candidate compound demonstrating potency vs both RET fusion and RETV804M. This compound is well tolerated in vivo after oral dosing at up to 80mg/kg bid and, in a KIF5B-RET lung cancer PDX model, demonstrates efficacy at much lower doses: 50% tumor regression at 20mg/kg bid and 92% tumor growth inhibition at 10mg/kg bid. Importantly, this agent shows no efficacy in the (non-RET driven) Calu-6 xenograft model, demonstrating selective inhibition of the RET kinase domain. Conclusions: We believe that the identification of well-tolerated, selective RET inhibitors with potent activity against diverse RET alterations (including the anticipated resistance mutation, V804M) offers a clear therapeutic advantage over the present clinically approved compounds. Our most advanced compound fulfills all of these challenging criteria and has now entered preclinical development. Citation Format: Mandy Watson, Rebecca Newton, Ben Acton, Helen Small, Habiba Begum, Samantha Hitchin, Paul Kelly, Donald Ogilvie, Ian Waddell, Allan Jordan. Delivery of a potent, selective, and efficacious RET inhibitor for the treatment of RET-driven lung adenocarcinoma [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2017 Oct 26-30; Philadelphia, PA. Philadelphia (PA): AACR; Mol Cancer Ther 2018;17(1 Suppl):Abstract nr A123.
In recent years, many proteins involved in DNA repair, such as ATR, ATM and PARP, have received considerable attention as potential points of therapeutic intervention in cancer. Indeed, these efforts have recently delivered several agents into clinical evaluation or FDA regulatory approval. However, the DNA repair protein poly(ADP ribose) glycohydrolase (PARG), which plays an equally critical role in DNA single stand break repair, to successful drug discovery efforts. Through our innovative collaboration with AstraZeneca, we have discovered a novel PARG-binding pharmacophore and have employed this information to discover drug-like chemotypes, facilitating the development of potent and selective inhibitors. This poster will describe our emerging results in this area, where a novel benzimidazolone sulphonamide scaffold has been shown potently to inhibit PARG in both biochemical and cellular assays with potencies of 40 nM and 60 nM respectively. Moreover, these agents display pharmacology consistent with the anticipated mode of action, appropriate drug-like properties and are selective against PARP1 and the close glycohydrolase homologue ARH3. The medicinal chemistry optimisation of this scaffold will be described, alongside the recent biological results obtained. Ultimately, this work has helped deliver tool compounds which may help to elucidate the true pharmacology and roles of PARG in cancer and other disease settings. Citation Format: Allan Jordan, Ben Acton, Nicola Hamilton, James Hitchin, Colin Hutton, Dominic James, Cliff Jones, Stuart Jones, Alison McGonagle, Helen Small, Kate Smith, Alex Stowell, Julie Tucker, Ian Waddell, Bohdan Waszkowycz, Donald Ogilvie. Benzimidazolone sulphonamides - potent, selective and drug-like inhibitors of poly(ADP Ribose) Glycohydrolase (PARG). [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3715.
The macrodomain protein poly(ADP ribose) glycohydrolase (PARG) has been shown to be a critical component in the repair of single stand DNA breaks and counteracts the function of the ARTD family of poly(ADP ribose) polymerases, commonly known as the PARPs. As PARG exists as a single protein, it presents an attractive target for therapeutic intervention in cancer cells with enhanced dependence upon DNA repair. Inhibitors of this enzyme have proved difficult to discover and develop. Moreover, intact cell-active tool compounds which have the propensity to be used as robust chemical probes to understand PARG pharmacology, are absent from the literature. This poster will describe our work in this emerging area, optimising a series of drug-like quinazolinedione derivatives to deliver molecules with the correct physicochemical and biochemical properties to function as in vitro cell probe compounds. These unprecedented agents display potent on-target biochemical (5 nM) and cell (10 nM) activity with a significant window to acute 3-day cytotoxicity. Moreover, these agents are selective against PARP family members and the close glycohydrolase homologue ARH3. The medicinal chemistry optimisation of the scaffold will be described, alongside the outline pharmacology demonstrating on-target, selective inhibition of PARG in cells. Such tool compounds will be of value in revealing the detailed mechanisms of action of PARG in DNA repair and other PAR chain-mediated cellular processes, with the ultimate goal of delivering novel and clinically relevant therapeutic agents. Citation Format: Kate Smith, Ben Acton, Dominic James, Cliff Jones, Stuart Jones, Allan Jordan, Nicola Hamilton, Alison McGonagle, Daniel Mould, Helen Small, Alex Stowell, Julie Tucker, Ian Waddell, Bohdan Waszkowycz, Donald Ogilvie. Optimisation of quinazolinedione sulphonamides as novel inhibitors of poly(ADP Ribose) glycohydrolase (PARG). [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3714.
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