Yonchu Jenkins

Preclinical characterization of Aurora kinase inhibitor R763/AS703569 identified through an image-based phenotypic screen

PurposeAurora kinases play a key role in mitotic progression. Over-expression of Aurora kinases is found in several human cancers and correlated with histological malignancy and clinical outcomes. Therefore, Aurora kinase inhibitors should be useful in the treatment of cancers.MethodsCell-based screening methods have an advantage over biochemical approaches because hits can be optimized to inhibit targets in the proper intracellular context. We developed a novel Aurora kinase inhibitor R763/AS703569 using an image-based phenotypic screen. The anti-proliferative effect was examined in a panel of tumor cell lines and primary cells. The efficacy was determined in a broad panel of xenograft models.ResultsR763/AS703569 inhibits Aurora kinases, along with a limited number of other kinases including FMS-related tyrosine kinase 3 (FLT3), and has potent anti-proliferative activity against many cell types accompanying unique phenotypic changes such as enlarged cell size, endoreduplication and apoptosis. The endoreduplication cycle induced by R763/AS703569 was irreversible even after the compound was withdrawn from the culture. Oral administration of R763/AS703569 demonstrated marked inhibition of tumor growth in xenograft models of pancreatic, breast, colon, ovarian, and lung tumors and leukemia. An acute myeloid leukemia cell line MV4-11, which carries a FLT3 internal tandem duplication mutation, is particularly sensitive to R763/AS703569 in vivo.ConclusionsR763/AS703569 is a potent inhibitor of Aurora kinases and exhibited significant anti-proliferative activity against a wide range of tumor cells both in vitro and in vivo. Inhibition of Aurora kinases has the potential to be a new addition to the treatment of cancers.

The AMPK activator R419 improves exercise capacity and skeletal muscle insulin sensitivity in obese mice

Objective Skeletal muscle AMP-activated protein kinase (AMPK) is important for regulating glucose homeostasis, mitochondrial content and exercise capacity. R419 is a mitochondrial complex-I inhibitor that has recently been shown to acutely activate AMPK in myotubes. Our main objective was to examine whether R419 treatment improves insulin sensitivity and exercise capacity in obese insulin resistant mice and whether skeletal muscle AMPK was important for mediating potential effects. Methods Glucose homeostasis, insulin sensitivity, exercise capacity, and electron transport chain content/activity were examined in wildtype (WT) and AMPK β1β2 muscle-specific null (AMPK-MKO) mice fed a high-fat diet (HFD) with or without R419 supplementation. Results There was no change in weight gain, adiposity, glucose tolerance or insulin sensitivity between HFD-fed WT and AMPK-MKO mice. In both HFD-fed WT and AMPK-MKO mice, R419 enhanced insulin tolerance, insulin-stimulated glucose disposal, skeletal muscle 2-deoxyglucose uptake, Akt phosphorylation and glucose transporter 4 (GLUT4) content independently of alterations in body mass. In WT, but not AMPK-MKO mice, R419 improved treadmill running capacity. Treatment with R419 increased muscle electron transport chain content and activity in WT mice; effects which were blunted in AMPK-MKO mice. Conclusions Treatment of obese mice with R419 improved skeletal muscle insulin sensitivity through a mechanism that is independent of skeletal muscle AMPK. R419 also increases exercise capacity and improves mitochondrial function in obese WT mice; effects that are diminished in the absence of skeletal muscle AMPK. These findings suggest that R419 may be a promising therapy for improving whole-body glucose homeostasis and exercise capacity.

Global metabolite profiling of mice with high-fat diet-induced obesity chronically treated with AMPK activators R118 or metformin reveals tissue-selective alterations in metabolic pathways.

BackgroundThe novel small molecule R118 and the biguanide metformin, a first-line therapy for type 2 diabetes (T2D), both activate the critical cellular energy sensor 5′-AMP-activated protein kinase (AMPK) via modulation of mitochondrial complex I activity. Activation of AMPK results in both acute responses and chronic adaptations, which serve to restore energy homeostasis. Metformin is thought to elicit its beneficial effects on maintenance of glucose homeostasis primarily though impacting glucose and fat metabolism in the liver. Given the commonalities in their mechanisms of action and that R118 also improves glucose homeostasis in a murine model of T2D, the effects of both R118 and metformin on metabolic pathways in vivo were compared in order to determine whether R118 elicits its beneficial effects through similar mechanisms.ResultsGlobal metabolite profiling of tissues and plasma from mice with diet-induced obesity chronically treated with either R118 or metformin revealed tissue-selective effects of each compound. Whereas metformin treatment resulted in stronger reductions in glucose and lipid metabolites in the liver compared to R118, upregulation of skeletal muscle glycolysis and lipolysis was apparent only in skeletal muscle from R118-treated animals. Both compounds increased β-hydroxybutyrate levels, but this effect was lost after compound washout. Metformin, but not R118, increased plasma levels of metabolites involved in purine metabolism.ConclusionsR118 treatment but not metformin resulted in increased glycolysis and lipolysis in skeletal muscle. In contrast, metformin had a greater impact than R118 on glucose and fat metabolism in liver tissue.

Abstract 3021: Development of small molecule direct AMPK activators for the treatment of cancer

5’-AMP-activated protein kinase (AMPK) is a key sensor of cellular energy status and is critical for maintaining energy homeostasis under conditions of nutrient stress. During cellular transformation, metabolic reprogramming enables the aberrant growth and proliferation of tumor cells. Both positive and negative roles for AMPK in tumor cell proliferation and survival have been reported. However, only a limited number of studies addressed this question with potent direct AMPK activators. AMPK exists as heterotrimers composed of the catalytic subunit α and reguratory subunits β and γ. We expressed the full length of all three human AMPK subunits in insect cells, purified the heterotrimer complexes, and used them for biochemical screening and characterization of AMPK activators. The purified complexes displayed basal activity, which was further enhanced by AMP. The compounds we identified potently activated the complexes in vitro at AC(2X)s (the concentration that gives a twofold activation) of 0.001-0.3 μM. Importantly, the compounds up-regulated substrate phosphorylation (pS79 Acetyl-CoA Carboxylase) and/or auto-phosphorylation (pT172 AMPKα) in multiple cancer cell lines including HepG2 hepatoma cells, A549 liver kinase B1 (LKB1) null lung cancer cells, and MOLM14 myeloid leukemia cells, indicating activation was irrespective of functional status of LKB1, which is a key AMPK-activation kinase. Activation of AMPK by the compounds was also confirmed using native AMPK isolated from normal tissues and tumor cells. We further investigated anti-proliferative effects of the compounds and found that up-regulation of AMPK kinase activity was correlated with anti-proliferative effects in A549 and MOLM14, but not in HepG2, suggesting that positive effects of direct AMPK activators could be cell-type dependent. Interestingly, we identified compounds that display comparable AMPK activation in HepG2 and A549 yet possessed divergent activities on proliferation across a panel of tumor lines. Analysis of cellular signaling across several of these tumor lines with this set of the compounds revealed dose-dependent effects on mTORC1 substrates, feedback signaling to PI3K and mTORC2, and inhibition of kinases downstream of RAF. Direct activation of AMPK could be a good therapeutic strategy for the treatment of subsets of cancers. Citation Format: Yasumichi Hitoshi, Yonchu Jenkins, Yingwu Li, Elmer Sampang, Xiang Xu, Guodong Dong, Jianing Huang, Nan Lin, Dane Goff, Simon Shaw, Luke Boralsky, Rajinder Singh, Sarkiz D. Issakani, Donald G. Payan. Development of small molecule direct AMPK activators for the treatment of cancer. [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 3021.