Gemma Hopkins

Toxoflavins and Deazaflavins as the First Reported Selective Small Molecule Inhibitors of Tyrosyl-DNA Phosphodiesterase II

The recently discovered enzyme tyrosyl-DNA phosphodiesterase 2 (TDP2) has been implicated in the topoisomerase-mediated repair of DNA damage. In the clinical setting, it has been hypothesized that TDP2 may mediate drug resistance to topoisomerase II (topo II) inhibition by etoposide. Therefore, selective pharmacological inhibition of TDP2 is proposed as a novel approach to overcome intrinsic or acquired resistance to topo II-targeted drug therapy. Following a high-throughput screening (HTS) campaign, toxoflavins and deazaflavins were identified as the first reported sub-micromolar and selective inhibitors of this enzyme. Toxoflavin derivatives appeared to exhibit a clear structure-activity relationship (SAR) for TDP2 enzymatic inhibition. However, we observed a key redox liability of this series, and this, alongside early in vitro drug metabolism and pharmacokinetics (DMPK) issues, precluded further exploration. The deazaflavins were developed from a singleton HTS hit. This series showed distinct SAR and did not display redox activity; however low cell permeability proved to be a challenge.

Down-Regulation of Desmosomes in Cultured Cells: The Roles of PKC, Microtubules and Lysosomal/Proteasomal Degradation

Desmosomes are intercellular adhesive junctions of major importance for tissue integrity. To allow cell motility and migration they are down-regulated in epidermal wound healing. Electron microscopy indicates that whole desmosomes are internalised by cells in tissues, but the mechanism of down-regulation is unclear. In this paper we provide an overview of the internalisation of half-desmosomes by cultured cells induced by calcium chelation. Our results show that: (i) half desmosome internalisation is dependent on conventional PKC isoforms; (ii) microtubules transport internalised half desmosomes to the region of the centrosome by a kinesin-dependent mechanism; (iii) desmosomal proteins remain colocalised after internalisation and are not recycled to the cell surface; (iv) internalised desmosomes are degraded by the combined action of lysosomes and proteasomes. We also confirm that half desmosome internalisation is dependent upon the actin cytoskeleton. These results suggest that half desmosomes are not disassembled and recycled during or after internalisation but instead are transported to the centrosomal region where they are degraded. These findings may have significance for the down-regulation of desmosomes in wounds.

The discovery of 2-substituted phenol quinazolines as potent RET kinase inhibitors with improved KDR selectivity.

Deregulation of the receptor tyrosine kinase RET has been implicated in medullary thyroid cancer, a small percentage of lung adenocarcinomas, endocrine-resistant breast cancer and pancreatic cancer. There are several clinically approved multi-kinase inhibitors that target RET as a secondary pharmacology but additional activities, most notably inhibition of KDR, lead to dose-limiting toxicities. There is, therefore, a clinical need for more specific RET kinase inhibitors. Herein we report our efforts towards identifying a potent and selective RET inhibitor using vandetanib 1 as the starting point for structure-based drug design. Phenolic anilinoquinazolines exemplified by 6 showed improved affinities towards RET but, unsurprisingly, suffered from high metabolic clearance. Efforts to mitigate the metabolic liability of the phenol led to the discovery that a flanking substituent not only improved the hepatocyte stability, but could also impart a significant gain in selectivity. This culminated in the identification of 36; a potent RET inhibitor with much improved selectivity against KDR.

Identification of selective inhibitors of RET and comparison with current clinical candidates through development and validation of a robust screening cascade

RET (REarranged during Transfection) is a receptor tyrosine kinase, which plays pivotal roles in regulating cell survival, differentiation, proliferation, migration and chemotaxis. Activation of RET is a mechanism of oncogenesis in medullary thyroid carcinomas where both germline and sporadic activating somatic mutations are prevalent. At present, there are no known specific RET inhibitors in clinical development, although many potent inhibitors of RET have been opportunistically identified through selectivity profiling of compounds initially designed to target other tyrosine kinases. Vandetanib and cabozantinib, both multi-kinase inhibitors with RET activity, are approved for use in medullary thyroid carcinoma, but additional pharmacological activities, most notably inhibition of vascular endothelial growth factor - VEGFR2 (KDR), lead to dose-limiting toxicity. The recent identification of RET fusions present in ~1% of lung adenocarcinoma patients has renewed interest in the identification and development of more selective RET inhibitors lacking the toxicities associated with the current treatments. In an earlier publication [Newton et al, 2016; 1] we reported the discovery of a series of 2-substituted phenol quinazolines as potent and selective RET kinase inhibitors. Here we describe the development of the robust screening cascade which allowed the identification and advancement of this chemical series. Furthermore we have profiled a panel of RET-active clinical compounds both to validate the cascade and to confirm that none display a RET-selective target profile.

Anilinoquinazoline inhibitors of the RET kinase domain-Elaboration of the 7-position

Graphical abstract

Desmoplakin Is Essential for Epidermal Sheet Formation

Vasioukhin et al. (2001) provided a dramatic demonstration that the desmosomal cytolinker protein desmoplakin (Dp) is essential for maintaining the integrity of epithelial cell sheets. Furthermore, they show a requirement for desmosomes in efficient maturation of adherens junctions (AJs). Dp belongs to the plakin family and contains a carboxy-terminal tail incorporating the intermediate filament (IF) binding site and a desmosome association site in the amino-terminal domain. Early embryonic lethality at E6.5 had previously demonstrated the crucial importance of Dp (Gallicano et al., 1998). Lethality was due to the breakdown in IF association with desmosomes and the failure of desmosomes to assemble and stabilize. Rescue of this lethal phenotype was achieved by fusion of knockout (KO) and wild-type embryos. This restored Dp+/+ extraembryonic tissue postponing lethality to E10 with defects in the heart, neuroepithelium and skin. The microvasculature does not contain desmosomes but was also affected because of disruptions to endothelial junctions comprising Dp, plakoglobin and VE-cadherin (Gallicano et al., 2001). The breakthrough with Dp came from the generation of mice with conditional KO of Dp in the epidermis by Vasioukhin and co-workers. The skin of newborns was very fragile and peeled off with mild mechanical stress, leading to death within a few hours. The number and size of desmosomes corresponded to wild type, but they differed ultrastructurally, lacking an inner dense plaque and attachment to the keratin cytoskeleton, which thus became detached from the cell periphery. This led to disruptions of the epidermis through loss of cell–cell adhesion. Studies on cultured KO keratinocytes unveiled additional differences, as these were incapable of sheet formation owing to inefficient clustering of desmosomal and AJ components at cell–cell borders. Rescuing with fulllength Dp restored desmosome–IF connections, but expression of only the head domain did not, supporting the need for the IF-binding site and desmosome–IF connections in epidermal sheet formation. The discovery of a patient who was compound heterozygous for Dp mutations causing severe skin fragility reinforces this Dp function (Jonkman et al., 2005). The mutations led to a truncation of Dp at the carboxyl terminus rather than complete absence of Dp. This gave rise to a loss of desmosome–IF connections and consequent severe fragility of the skin and mucous membranes, with a substantial loss in body fluids. Early postnatal death ensued. Vasioukhin et al. (2001) also revealed the interdependence of adherens junctions (AJs) and desmosomes. AJs precede and are required for desmosome formation but the ablation of Dp caused a reduction in the number of AJs. This has led to a hypothesis that desmosomes act as molecular clamps holding immature AJs in place for a second phase of maturation during epithelial sheet formation. The integrity of the epidermis is essential for survival, and Dp plays a key role in this vital function.

IncucyteDRC: An R package for the dose response analysis of live cell imaging data.

We present IncucyteDRC, an R package for the analysis of data from live cell imaging cell proliferation experiments carried out on the Essen Biosciences IncuCyte ZOOM instrument. The package provides a simple workflow for summarising data into a form that can be used to calculate dose response curves and EC50 values for small molecule inhibitors. Data from different cell lines, or cell lines grown under different conditions, can be normalised as to their doubling time. A simple graphical web interface, implemented using shiny, is provided for the benefit of non-R users. The software is potentially useful to any research group studying the impact of small molecule inhibitors on cell proliferation using the IncuCyte ZOOM.

Abstract A176: RET inhibition: Development of novel compounds and a personalized medicine strategy in lung adenocarcinoma

Background:RET is a receptor tyrosine kinase (RTK) and forms part of a macromolecular receptor complex containing dimerised RET receptor, two co-receptors and a bound ligand. Signalling networks downstream of RET play an important role in regulating cell survival, differentiation, proliferation, migration and chemotaxis. Activating mutations in RET (e.g. C634W and M918T) are known drivers in medullary thyroid carcinomas (MTC). More recently, oncogenic RET fusions (e.g. CCDC6-RET and KIF5B-RET) have been identified in 1-2% of lung adenocarcinoma patients. We are currently developing novel, selective inhibitors of RET, and at the same time, investigating a number of biomarker approaches for the stratification of RET fusion-positive lung cancer patients who might benefit from such therapy. Methods: We have undertaken collaborative studies using established techniques including immunohistochemistry (IHC) and FISH (DNA break apart and RNA). In addition, we have investigated hybrid capture DNA sequencing of both biopsy material and circulating tumour DNA in the blood. Here we, compare and contrast the benefits of each biomarker assay evaluated and consider how these approaches could be translated for use in Phase I clinical trials at The Christie. Conclusion: Our data supports the successful implementation of predictive biomarkers to identify patients who might benefit from treatment with selective RET inhibitors. Acknowledgements:This work was funded by Cancer Research UK (Grant numbers C480/A1141 and C5759/A17098). Citation Format: Mandy Watson, Helen Small, Phil Chapman, Gemma Hopkins, Habiba Begum, Ian D. Waddell, Garry Ashton, Caron Abbey, Jade Harris, Mahmood Ayub, Sumitra Mohan, Dominic Rothwell, Ged Brady, Caroline Dive, Allan Jordan, Donald Ogilvie. RET inhibition: Development of novel compounds and a personalized medicine strategy in lung adenocarcinoma. [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 A176.

Abstract 778: The identification and structure-guided optimisation of potent and selective inhibitors of oncogenes in medullary thyroid carcinoma and lung adenocarcinoma

Proceedings: AACR 106th Annual Meeting 2015; April 18-22, 2015; Philadelphia, PA RET (REarranged during Transfection) is a receptor tyrosine kinase (TK), which plays pivotal roles in regulating cell survival, differentiation, proliferation, migration and chemotaxis. Activating mutations in RET (C634W and M918T) have been identified in both familial and sporadic forms of medullary thyroid carcinoma (MTC) and correlate with aggressive disease progression, validating RET as a classical oncogene. Furthermore the recent identification of RET fusions (CCDC6-RET and KIF5B-RET) present in ∼1% of lung adenocarcinoma (LAD) patients has renewed interest in the identification and development of more selective RET inhibitors lacking the toxicities associated with the current treatments. At present, there are no known specific RET inhibitors in clinical development, although many potent inhibitors of RET have been identified opportunistically through selectivity profiling of compounds initially designed to target other TKs. Such “secondary RET inhibitors” include the clinical agents Vandetanib and Cabozantinib, both approved for use in MTC, but additional pharmacological activities (most notably inhibition of KDR) lead to dose-limiting toxicity. Using a robust screening cascade developed in house, we have measured RET and KDR inhibitory activity in vitro and in relevant cell line models to assess compound potency and selectivity. Anti-proliferative activity and off-target toxicity of these agents have also been measured. Although these competitor compounds displayed reasonable RET potency in cellular assays and this translated into anti-proliferative effects in our MTC and LAD disease models, as expected none met our target candidate criteria, clearly highlighting the need for therapeutic agents with improved selectivity. Guided by structure-based drug design, we have identified and optimised a novel series of potent and selective inhibitors of the RET kinase domain. These agents met our stringent criteria for enzyme and cell selectivity and, whilst potent in a RET-driven cell line, display little overt toxicity in a matched non-RET driven cell line. Herein, we describe the chemical optimisation of these agents and, using structural information, rationalise their improved selectivity. Citation Format: Roger J. Butlin, Rebecca Newton, Mandy Watson, Gemma Hopkins, Ben Acton, Kate Bowler, Samantha Fritzl, Kristin Goldberg, Niall Hamilton, Sarah Holt, Stuart Jones, Allan Jordan, Nikki March, Daniel Mould, Helen Small, Alexandra Stowell, Ian Waddell, Bohdan Waszkowycz, Donald Ogilvie. The identification and structure-guided optimisation of potent and selective inhibitors of oncogenes in medullary thyroid carcinoma and lung adenocarcinoma. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 778. doi:10.1158/1538-7445.AM2015-778

Abstract 3324: The discovery and optimisation of small-molecule inhibitors of human 5’-tyrosyl DNA phosphodiesterase (Tdp2).

Topoisomerases (topo) regulate DNA topology by the transient cleavage and re-ligation of DNA during transcription and replication. Topo II poisons such as etoposide can induce abortive DNA strand breaks in which topo II remains covalently bound to a 5? DNA strand terminus via a phosphotyrosyl linker. Tyrosyl DNA phosphodiesterase 2 (Tdp2, TTRAP, EAPII) is a recently discovered human 5?-tyrosyl DNA phosphodiesterase which repairs this topo-mediated DNA damage, therefore playing a central role in maintaining normal DNA topology in cells. Cellular depletion of Tdp2 has been shown to result in an increased susceptibility and sensitivity to topo II-induced DNA double strand breaks. It has therefore been proposed that selective pharmacological inhibition of Tdp2 may be a novel approach to overcome intrinsic or acquired resistance to topo II targeted drug therapy. To date, no known drug-like inhibitors of Tdp2 have been identified. We have recently reported a robust ?mix and read? HTS compatible assay and this was used to screen a diverse chemical library of approximately 92,000 compounds. From this, 2 distinct hit series have been identified. Following further chemical exploration of the original hit compounds small molecule inhibitors of Tdp2 with sub-100nM potencies have been identified. This poster will describe our preliminary results in this area.