Project description:In recent years, several small molecule cytotoxic drugs have been identified as potential inhibitors of ribosome biogenesis (Drygin et al., 2011; Peltonen et al., 2014a; Peltonen et al., 2014b). CX-5461 is one such drug that has also demonstrated anticancer potential for a wide range of malignancies (Bywater et al., 2012; Cornelison et al., 2017; Devlin et al., 2015; Drygin et al., 2011; Hald et al., 2019; Hein et al., 2017; Ismael et al., 2019; Lawrence et al., 2018; Lee et al., 2017; Negi and Brown, 2015; Taylor et al., 2019; Xu et al., 2017; Yan et al., 2017) (Haddach et al., 2012), and is presently under phase I trials for the treatment of both hematological cancers and solid tumours (Group, 2016; Khot et al., 2019). CX-5461 was initially characterized as an inhibitor of RNA Polymerase I (RPI/PolR1/PolI) that is responsible for the synthesis of the major ribosomal RNAs and the initial step in ribosome biogenesis (Drygin et al., 2011). Since RPI and its corresponding core transcription factors are dedicated to this task alone, they present ideal molecular targets by which to modulate ribosome biogenesis. However, the specificity of CX-5461 has been questioned and it has been suggested that this drug may also act by stabilizing DNA G-quadruplexes or by “poisoning” topoisomerase II (Topo II). Thus, the primary target of this drug and its mode of action are still in doubt. Here we used Deconvolution-ChIP-Seq in NIH3T3 and HEK293T cells treated for different times with CX-5461. The data show that the primary target of CX5461 is the initiation of ribosomal RNA gene (rDNA) transcription. CX-5461 blocks transcription initiation in vitro and in vivo by arresting RNA polymerase I (RPI/Pol1) within the preinitiation complex. In contrast to previous suggestions, CX-5461 does not effect recruitment of the TBP-TAF complex SL1 to the rDNA promoter, the recruitment of the initiation competent RPI-Rrn3 complex or ongoing transcription elongation, arguing against a role for G-quadruplex stabilization or topoisomerase II poisoning. Inhibition of transcription by CX-5461 is not reversible, the RPI-Rrn3 complex remains arrested in the preinitiation complex even after drug removal. This leads to nucleolar stress, extensive DNA damage and cell senescence. Our data show that the cytotoxicity of CX-5461 is the downstream result of the highly specific inhibition of rDNA transcription. The observation that this inhibition is irreversible will be important for the future design of chemotherapeutic strategies and the avoidance of drug resistance.

Project description:The high rates of protein synthesis and processing render multiple myeloma (MM) cells vulnerable to perturbations in protein homeostasis. The induction of proteotoxic stress by targeting protein degradation with proteasome inhibitors (PI) has revolutionized the treatment of MM. However, resistance to PI is inevitable and represents an ongoing clinical challenge. Our first-in-human study of the selective inhibitor of RNA polymerase I transcription of ribosomal RNA genes, CX-5461 has demonstrated a potential signal for anti-tumor activity in three of six heavily pre-treated MM patients. Here we show that CX-5461 has potent antimyeloma activity in PI-resistant MM preclinical models in vitro and in vivo. In addition to inhibiting ribosome biogenesis, CX-5461 causes topoisomerase II trapping and replication-dependent DNA damage, leading to G2/M cell cycle arrest and apoptotic cell death. Surprisingly, the addition of PI does not enhance the therapeutic benefit of CX-5461. In contrast, CX-5461 shows synergistic interaction with the histone deacetylase inhibitor panobinostat in both the Vk*MYC and the 5T33-KaLwRij mouse models of MM by targeting ribosome biogenesis and protein synthesis through distinct mechanisms. Our findings thus provide strong evidence to facilitate the clinical development of targeting the ribosome to treat relapsed and refractory MM.

Project description:We discovered two small molecule drugs - CX-5461 and CX-3543 - with specific toxicity against BRCA deficiencies in cancer cells and xenograft models. Both CX-5461 and CX-3543 have been previously recognized as RNA pol I inhibitors. CX-5461 is in advanced phase 1 trials for treatment of lymphoma and leukemia through rDNA transcription inhibition in a p53-dependent mechanism. We have discovered a novel activity of CX-5461, as a stabilizer of G-quadruplex DNA sequences inside cells the same as CX-3543. We found that BRCA1 and BRCA2 deficiency markedly increases (one log order) sensitivity to CX-5461 and a related drug CX-3543 in human cancer cell lines and polyclonal patient derived xenograft models, providing a direct therapeutic hypothesis, including PDX tumours resistant to PARP inhibition. We show that in epithelial cells, exposure to CX-5461 and CX-3543 blocks replication forks and induces ssDNA gaps or breaks. The BRCA and NHEJ pathways are required for the repair of CX-5461 and CX-3543 induced DNA damage and failure to do so leads to lethality. RNA pol I inhibition is not a required component of the cell killing mechanism in these tumours, because BRCA2 deficient cells are not more sensitive to BMH-21, a more potent rDNA transcription inhibitor. These data strengthen the concept of G4 targeting as a therapeutic approach, specifically for targeting HR and NHEJ deficient cancers and other tumors deficient for DNA damage repair. Since CX-5461 is already in advanced phase 1 trials for other indications, this has resulted in immediately testable translational implications (Canadian trial, NCT02719977, opened May 2016) as no phase-1 eligible G4 stabilizers have been described to date.

Project description:We demonstrate that CX-5461 treatment suppresses multiple canonical pathways and transcriptions factors We used microarrays to analyze the potential mechanism by which CX-5461 regulates gene expression.

Project description:Our results confirmed that CX-5461, a Pol I inhibitor, does not significantly impact mRNA expression at 6 hrs, while I-BET151 alone, known to inhibit MYC and expression of other oncognes, resulted in widespread changes in select gene expression programs as previously demonstrated (Dawson et al., 2011). Interestingly, the combination of CX-5461 and I-BET151 demonstrated no further gene expression changes from I-BET151 alone, suggesting that their mechanism of synergy is more likely directly associated with the CX-5461-mediated DNA damage response. Further, the mRNA gene expression changes following drug combination treatment are distinct from those following doxorubicin treatment, supporting that the synergistic effects of the novel combination of CX-5461 and I-BET151 do not rely on global DNA damage.

Project description:To reveal the effect of CX-5461 (a small-molecule inhibitor of ribosome biogenesis)on the proteome of Pancreatic Ductal Adenocarcinoma (PDAC) cells, we carried out two quantitative proteomics analyses, using tumour cells isolated from an inducible mouse model of PDAC (iKras PDAC) (Ying et al., 2012). In this model, oncogenic Kras (G12D) expression can be controlled by administration of doxycycline (Dox). In the first experiment, Tandem Mass Tagging (TMT) was employed for quantitative analysis of mock vs. CX-5461 (100nM) treated iKras cells for 48 hrs, in presence of Dox (Kras on). In the second experiment, TMT was used to quantitatively analyse the proteomics changes induced by Dox removal (48 hrs), in presence or absence of CX-5461. For this purpose, iKras PDAC cells were seeded and grown for 48 hrs with or without Dox, in the background of mock vs. CX-5461 (100nM) co-treatments. TMT labelling was done using the TMT 6plex labelling kit from Thermo Fisher.

Project description:P. falciparum is the deadliest causative agent of human malaria. This parasite has historically developed resistance to many drugs, including the current frontline treatments, so new therapeutic targets are needed Our previous work on guanine quadruplexes (G4s) in the parasite’s DNA and RNA has highlighted their influence on parasite biology, and also revealed G4 stabilising compounds as promising candidates for drug repositioning. In particular, quarfloxin, a former anticancer agent, kills blood-stage parasites at all developmental stages, with fast rates of kill and nanomolar potency. Here we explored the molecular mechanism of quarfloxin and its related derivative CX-5461. In vitro, both compounds bound to P. falciparum-encoded G4 sequences. In cellulo, quarfloxin was more potent than CX-5461, and could prevent establishment of blood-stage malaria in vivo in a murine model. CX-5461 showed clear DNA damaging activity, as reported in human cells, while quarfloxin caused weaker signatures of DNA damage. Both compounds caused transcriptional dysregulation in the parasite, but the affected genes were largely different, again suggesting different modes of action. Therefore, CX-5461 may act primarily as a DNA damaging agent in both Plasmodium parasites and mammalian cells, whereas the complete anti-malarial mode of action of quarfloxin may be parasite-specific, and remains elusive.

Project description:In all domains of life, the rate of protein synthesis is directly linked to the rates of cell growth and proliferation. Consequently, highly proliferative cancer cells are especially sensitive to perturbations in ribosome biogenesis. While ribosome synthesis and cancer have a well-established relationship, only recently has ribosome biogenesis drawn interest as a cancer therapeutic target. Here, we have exploited the relationship between ribosome biogenesis and cancer cell proliferation by using a potent ribosome biogenesis inhibitor: RBI2 (Ribosome Biogenesis Inhibitor 2) to perturb cancer cell growth and viability.  We demonstrate that RBI2 significantly decreases cell viability in malignant melanoma cells and breast cancer cell lines. Treatment with RBI2 dramatically and rapidly decreases ribosomal RNA (rRNA) synthesis, without affecting the occupancy of RNA polymerase I (Pol I) on the ribosomal DNA template. Next-generation RNA sequencing (RNA-seq) reveals that RBI2 and previously described ribosome biogenesis inhibitor CX-5461 induce distinct changes in the transcriptome. Investigation of the content of the pre-rRNAs through RT-qPCR reveals an increase in polyadenylation of cellular rRNA after treatment with RBI2, a known pathway by which rRNA degradation occurs. Northern blotting revealed that RBI2 does not appear to impair or alter rRNA processing.  Collectively, these data suggest that RBI2 inhibits rRNA synthesis distinctly from other previously described ribosome biogenesis inhibitors, potentially through a novel pathway that upregulates turnover of premature rRNAs.

Project description:Sequencing files from TRAP-seq samples isolated from DHPG-stimulated WT and Fmr1-/y hippocampal slices incubated with vehicle or 200 nM CX-5461

Project description:Transcription of the >200 rRNA genes (rDNA) by RNA Polymerase I (RPI) determines as much as 35% of total nuclear RNA synthesis and is a major determinant of cell growth implicated in a range of hypertrophic and developmental disorders. Activation of the rDNA involves the formation of an extended nucleosome free region (NFR) by the multi-HMGbox factor UBTF, which is also implicated with the RPI specific TBP-TAFI factor SL1 in preinitiation complex formation. However, neither factor alone displays significant DNA sequence binding specificity. Here we show that in cell cooperation between SL1 and the UBTF1 splice variant creates the sequence specificity required for promoter recognition. While both UBTF1 and UBTF2 splice variants bind throughout the rDNA NFR, only UBTF1 binds at the rDNA promoters. Conditional deletion of the Taf1b subunit of SL1 depleted UBTF1 from the rDNA promoters but not from elsewhere across the rDNA NFR. We show RPI promoters are particularly poor binding sites for UBTF and suggest an induced-fit model in which promoter-specific remodelling by UBTF1 creates high affinity sites for SL1 binding. A mouse model of the UBTF-E210K pediatric neurodegeneration syndrome suggests this mutation affects cooperativity of UBTF-SL1 promoter recruitment and further supports the induced-fit model.