Cellularly active N-hydroxyurea FEN1 inhibitors block substrate entry to the active site

Exell, Jack; Thompson, Mark J.; Finger, L. David; Shaw, Steven J.; Debreczeni, J.; Ward, Thomas A.; McWhirter, Claire; Siöberg, Catrine L. B.; Molina, Daniel Martinez; Abbott, W. Mark; Jones, Clifford D.; Nissink, J. Willem M.; Durant, Stephen T.; Grasby, Jane A.

doi:10.1038/nchembio.2148

Cited by 61 publications

(62 citation statements)

References 55 publications

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“…Secondly, we showed that binding of compounds 1 – 5 requires the presence of Mg 2+ ions, which bind in the active site of Caf1. This is in agreement with the proposed role of the N ‐hydroxyimide moiety in 1‐hydroxy‐xanthines and related compounds forming ion–dipole interactions with the Mg 2+ ions .…”

Section: Resultssupporting

confidence: 90%

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

et al. 2019

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In eukaryotic cells, cytoplasmic mRNA is characterised by a 3′ poly(A) tail. The shortening and removal of poly(A) tails (deadenylation) by the Ccr4‐Not nuclease complex leads to reduced translational efficiency and RNA degradation. Using recombinant human Caf1 (CNOT7) enzyme as a screening tool, we recently described the discovery and synthesis of a series of substituted 1‐hydroxy‐3,7‐dihydro‐1H‐purine‐2,6‐diones (1‐hydroxy‐xanthines) as inhibitors of the Caf1 catalytic subunit of the Ccr4‐Not complex. Here, we used a chemiluminescence‐based AMP detection assay to show that active 1‐hydroxy‐xanthines inhibit both isolated Caf1 enzyme and human Caf1‐containing complexes that also contain the second nuclease subunit Ccr4 (CNOT6L) to a similar extent, indicating that the active site of the Caf1 nuclease subunit does not undergo substantial conformational change when bound to other Ccr4‐Not subunits. Using differential scanning fluorimetry, we also show that binding of active 1‐hydroxy‐xanthines requires the presence of Mg2+ ions, which are present in the active site of Caf1.

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Section: Resultssupporting

confidence: 90%

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

et al. 2019

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“…In support of our results, other HU-based derivatives have been shown to increase human cell line sensitivity to MMS treatment (Tumey et al 2005;Exell et al 2016) and selectively impair the proliferation of HR-defective cancer cell lines (Exell et al 2016;He et al 2016;Ward et al 2017). Further, in vitro assays have demonstrated that some HU-based compounds are able to enzymatically inhibit the related endonucleases hXPG (Tumey et al 2005) and hEXO1 (Exell et al 2016), but showed species specificity upon testing with bacteriophage T5 FEN and Kluyveromyces lactis XRN1 (Exell et al 2016). These results may explain the mild off-target effects observed for the rad27D and rad52D mutants in our in vivo assays.…”

Section: Discussionsupporting

confidence: 86%

“…Further, based on synthetic lethal genetic interaction relationships, hFEN1 is a second-site target for the selective killing of homologous recombination (HR)-defective and cohesin-mutated cancer cells (McManus et al 2009;van Pel et al 2013). As such, many studies have reported the screening and development of hFEN1 inhibitors as potential anticancer therapeutics (Tumey et al 2005;Dorjsuren et al 2011;McWhirter et al 2013;van Pel et al 2013;Exell et al 2016;He et al 2016;Deshmukh et al 2017).…”

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confidence: 99%

Cross-Species Complementation of Nonessential Yeast Genes Establishes Platforms for Testing Inhibitors of Human Proteins

Hamza¹,

Driessen²,

Tammpere³

et al. 2020

Genetics

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Cross-species complementation can be used to generate humanized yeast, which is a valuable resource with which to model and study human biology. Humanized yeast can be used as an in vivo platform to screen for chemical inhibition of human protein drug targets. To this end, we report the systematic complementation of nonessential yeast genes implicated in chromosome instability (CIN) with their human homologs. We identified 20 human–yeast complementation pairs that are replaceable in 44 assays that test rescue of chemical sensitivity and/or CIN defects. We selected a human–yeast pair (hFEN1/yRAD27), which is frequently overexpressed in cancer and is an anticancer therapeutic target, to perform in vivo inhibitor assays using a humanized yeast cell-based platform. In agreement with published in vitro assays, we demonstrate that HU-based PTPD is a species-specific hFEN1 inhibitor. In contrast, another reported hFEN1 inhibitor, the arylstibonic acid derivative NSC-13755, was determined to have off-target effects resulting in a synthetic lethal phenotype with yRAD27-deficient strains. Our study expands the list of human–yeast complementation pairs to nonessential genes by defining novel cell-based assays that can be utilized as a broad resource to study human drug targets.

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“…Furthermore, the effect of the combination of ATO and FEN1-KD was also examined in vivo, using a xenograft model in mice. For this study, a previously reported FEN1 inhibitor compound 20 (C20) was used (22,23). C20 is an N-hydroxyl urea derivative that specifically inhibits FEN1 activity, which is the most potent FEN1 inhibitor tested at the time (24).…”

Section: Fen1 Inhibition Enhanced Ato-induced Cytotoxity and Growth Smentioning

confidence: 99%

Inhibition of FEN1 Increases Arsenic Trioxide-Induced ROS Accumulation and Cell Death: Novel Therapeutic Potential for Triple Negative Breast Cancer

et al. 2020

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Triple-negative breast cancer (TNBC) is an aggressive subtype of breast cancer, which is very difficult to treat and commonly develops resistance to chemotherapy. The following study investigated whether the inhibition of Flap Endonuclease 1 (FEN1) expression, the key enzyme in the base excision repair (BER) pathway, could improve the anti-tumor effect of arsenic trioxide (ATO), which is a reactive oxygen species (ROS) inducer. Our data showed that ATO could increase the expression of FEN1, and the knockdown of FEN1 could significantly enhance the sensitivity of TNBC cells to ATO both in vitro and in vivo. Further mechanism studies revealed that silencing FEN1 in combination with low doses of ATO might increase intracellular ROS and reduce glutathione (GSH) levels, by reducing the nuclear translocation of nuclear factor erythroid 2-related factor 2 (Nrf2); elevating ROS leaded to apoptosis and p38 and JNK pathway activating. In conclusion, our study suggested the combination of FEN1 knockdown and ATO could induce TNBC cell death by promoting ROS production. FEN1 knockdown can effectively decrease the application concentrations of ATO, thus providing a possibility for the treatment of TNBC with ATO.

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Cellularly active N-hydroxyurea FEN1 inhibitors block substrate entry to the active site

Cited by 61 publications

References 55 publications

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

Cross-Species Complementation of Nonessential Yeast Genes Establishes Platforms for Testing Inhibitors of Human Proteins

Inhibition of FEN1 Increases Arsenic Trioxide-Induced ROS Accumulation and Cell Death: Novel Therapeutic Potential for Triple Negative Breast Cancer

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Cellularly active N-hydroxyurea FEN1 inhibitors block substrate entry to the active site

Cited by 61 publications

References 55 publications

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg2+‐dependent binding

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg2+‐dependent binding

Cross-Species Complementation of Nonessential Yeast Genes Establishes Platforms for Testing Inhibitors of Human Proteins

Inhibition of FEN1 Increases Arsenic Trioxide-Induced ROS Accumulation and Cell Death: Novel Therapeutic Potential for Triple Negative Breast Cancer

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1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding