BML-257, a small molecule that protects against drug induced liver injury in zebrafish

The use of many essential drugs is restricted due to their deleterious effects on the liver. Molecules that can prevent or protect the liver from drug induced liver injury (DILI) would be valuable in such situations. We used hepatocyte-specific expression of bacterial nitroreductase in zebrafish to cause temporally controlled liver damage. This transgenic line was used to run a whole organism based chemical screen in zebrafish larvae. In this screen we identified BML-257, a potent small molecule AKT inhibitor, that protected the liver against metronidazole-induced liver injury. BML-257 also showed potent prophylactic and pro-regenerative activity in this liver damage model. BML-257 also showed remarkable protective action in two independent toxicological models of liver injury caused by acetaminophen and Isoniazid. This suggests that BML-257 may have the potential to protect against multiple kinds of drug induced liver injury.

A chemical screen based on an interruption of zebrafish gastrulation identifies the HTR2C inhibitor Pizotifen as a suppressor of EMT-mediated metastasis

Metastasis is responsible for approximately 90% of cancer-associated mortality but few models exist that allow for rapid and effective screening of anti-metastasis drugs. Current mouse models of metastasis are too expensive and time consuming to use for rapid and high-throughput screening. Therefore, we created a unique screening concept utilizing conserved mechanisms between zebrafish gastrulation and cancer metastasis for identification of potential anti-metastatic drugs. We hypothesized that small chemicals that interrupt zebrafish gastrulation might also suppress metastatic progression of cancer cells and developed a phenotype-based chemical screen to test the hypothesis. The screen used epiboly, the first morphogenetic movement in gastrulation, as a marker and enabled 100 chemicals to be tested in five hours. The screen tested 1280 FDA-approved drugs and identified Pizotifen, an antagonist for serotonin receptor 2C (HTR2C) as an epiboly-interrupting drug. Pharmacologic and genetic inhibition of HTR2C suppressed metastatic progression in a mouse model. Blocking HTR2C with Pizotifen restored epithelial properties to metastatic cells through inhibition of Wnt-signaling. In contrast, HTR2C induced epithelial to mesenchymal transition (EMT) through activation of Wnt-signaling and promoted metastatic dissemination of human cancer cells in a zebrafish xenotransplantation model. Taken together, our concept offers a novel platform for discovery of anti-metastasis drugs.

A ROS-Ca2+ signalling pathway identified from a chemical screen for modifiers of sugar-activated circadian gene expression.

Sugars are essential metabolites for energy and anabolism that can also act as signals to regulate plant physiology and development. Experimental tools to disrupt major sugar signalling pathways are limited. We have performed a chemical screen for modifiers of activation of circadian gene expression by sugars to discover pharmacological tools to investigate and manipulate plant sugar signalling. Using a library of commercially available bioactive compounds, we identified 75 confident hits that modified the response of a circadian luciferase reporter to sucrose in dark-adapted seedlings. We validated the transcriptional effect on a subset of the hits and measured their effects on a range of sugar-dependent phenotypes for 13 of these chemicals. Chemicals were identified that appear to influence known and unknown sugar signalling pathways. Pentamidine isethionate (PI) was identified as a modifier of a sugar-activated Ca2+ signal that acts downstream of superoxide in a metabolic signalling pathway affecting circadian rhythms, primary metabolism and plant growth. Our data provide a resource of new experimental tools to manipulate plant sugar signalling and identify novel components of these pathways.

A chemical screen for suppressors of dioxygenase inhibition in a yeast model of familial paraganglioma

A fascinating class of familial paraganglioma (PGL) neuroendocrine tumors is driven by loss of the tricarboxylic acid (TCA) cycle enzyme succinate dehydrogenase (SDH) resulting in succinate accumulation as an oncometabolite, and other metabolic derangements. Here we exploit a S. cerevisiae yeast model of SDH loss where accumulating succinate, and possibly reactive oxygen species, poison a dioxygenase enzyme required for sulfur scavenging. Using this model we performed a chemical suppression screen for compounds that relieve dioxygenase inhibition. After testing 1280 pharmaceutically-active compounds we identified meclofenoxate HCL, and its hydrolysis product, dimethylaminoethanol (DMAE), as suppressors of dioxygenase intoxication in SDH-loss cells. We show that DMAE acts to alter metabolism so as to normalize the succinate:2-ketoglutarate ratio, improving dioxygenase function. This work raises the possibility that oncometabolite effects might be therapeutically suppressed by drugs that rewire metabolism to reduce the flux of carbon into pathological metabolic pathways.

High-Throughput Chemical Screen on Acute Myeloid Leukemia Stem Cells Identifies Novel Anti-LSC Compounds

Acute myeloid leukemia (AML) is an aggressive form of blood cancer defined by the uncontrolled proliferation and clonal expansion of immature myeloblast cells in the blood and bone marrow, leading to hematopoietic failure. Despite the use of aggressive and cytotoxic standard-of-care drugs, patients often relapse and succumb to the disease partially due to the inability of medically unfit patients to withstand the cytotoxic treatments, regrowth from minimal residual disease and the chemo-resistant nature of leukemic stem cells (LSCs) which can remain in a quiescent state and reside in a protective bone marrow niche. Hence, novel therapies targeting unique leukemic stem cell biology are highly needed to eliminate and avoid reoccurrence. High-throughput screens of human AML LSCs are not performed due to technical issues such as low LSC frequency within primary samples, an inability to purify LSCs, and the difficulty maintaining and expanding primary patient samples and LSCs in vitro. We were able to optimize conditions for a 4-week in vitro large-scale expansion (>600 million bulk) of the primary human AML sample 8227 (OCI-AML-8227), functionally validated to be enriched for LSCs in long-term xenotransplant assays (Eppert et al., 2011). These optimized conditions enabled the isolation and maintenance of the LSC-containing fraction for a chemical screen. We isolated the CD34+ LSC-containing fraction (>90% purity) and performed a high-throughput screen of 11,166 chemical molecules using a CellTiter Glo assay followed by a counter screen against normal CD34+ cord blood (CB) hematopoietic stem and progenitor cells. From this HT screen, a total of 61 hits had >70% inhibition on CD34+ 8227 cells and <30% inhibition on CD34+ CB cells. We also identified glucocorticoids, which were also identified in our prior small-scale anti-LSC screen where they were found to specifically drive human LSCs to terminally differentiate (Laverdière & Boileau, et al., 2018). We then performed dose response assays for each candidate compounds and confirmed 35 potent anti-LSC compounds with IC 50 < 1 μM. This refined the types of compounds to including anti-apoptotic inhibitors, GSK inhibitors, protease inhibitors, metabolism inhibitors, HDAC inhibitors, BET inhibitors, nucleic acid synthesis inhibitors, cell cycle inhibitors and Wnt/β-catenin inhibitors. This is interesting as some of the classes of these compounds (inhibitors of GSK, BET, nucleic acid synthesis, Wnt/β-catenin and metabolism) have been shown to target bulk and leukemic stem cells in AML in vitro and in vivo. We now aim to examine LSC eradication in a panel of genetically defined primary AMLs confirmed through in vitro and in vivo assays. Our goal is to be able to understand and establish the molecular mechanisms and biomarkers on primary functional LSCs. Disclosures No relevant conflicts of interest to declare.

Targeting Mycobacterium tuberculosis response to environmental cues for the development of effective antitubercular drugs

Sensing and response to environmental cues, such as pH and chloride (Cl−), is critical in enabling Mycobacterium tuberculosis (Mtb) colonization of its host. Utilizing a fluorescent reporter Mtb strain in a chemical screen, we have identified compounds that dysregulate Mtb response to high Cl− levels, with a subset of the hits also inhibiting Mtb growth in host macrophages. Structure–activity relationship studies on the hit compound “C6,” or 2-(4-((2-(ethylthio)pyrimidin-5-yl)methyl)piperazin-1-yl)benzo[d]oxazole, demonstrated a correlation between compound perturbation of Mtb Cl− response and inhibition of bacterial growth in macrophages. C6 accumulated in both bacterial and host cells, and inhibited Mtb growth in cholesterol media, but not in rich media. Subsequent examination of the Cl− response of Mtb revealed an intriguing link with bacterial growth in cholesterol, with increased transcription of several Cl−-responsive genes in the simultaneous presence of cholesterol and high external Cl− concentration, versus transcript levels observed during exposure to high external Cl− concentration alone. Strikingly, oral administration of C6 was able to inhibit Mtb growth in vivo in a C3HeB/FeJ murine infection model. Our work illustrates how Mtb response to environmental cues can intersect with its metabolism and be exploited in antitubercular drug discovery.

Towards novel herbicide modes of action by inhibiting lysine biosynthesis in plants

Weeds are becoming increasingly resistant to our current herbicides, posing a significant threat to agricultural production. Therefore, new herbicides with novel modes of action are urgently needed. In this study, we exploited a novel herbicide target, dihydrodipicolinate synthase (DHDPS), which catalyses the first and rate-limiting step in lysine biosynthesis. The first class of plant DHDPS inhibitors with micromolar potency against Arabidopsis thaliana DHDPS were identified using a high throughput chemical screen. We determined that this class of inhibitors binds to a novel and unexplored pocket within DHDPS, which is highly conserved across plant species. The inhibitors also attenuated the germination and growth of A. thaliana seedlings and confirmed their pre-emergence herbicidal activity in soil-grown plants. These results provide proof-of-concept that lysine biosynthesis represents a promising target for the development of herbicides with a novel mode of action to tackle the global rise of herbicide resistant weeds.