Cell lines

AML cell line

Preparation Method

Each AML cell line was cultured in 123 nM IACS-010759 medium for 72 h.

Reaction Conditions

123nM IACS-010759 for 72 h

Applications

In most cell lines, IACS-010759 treatment modestly increased apoptosis by up to twofold.

Animal models

Mouse models of glioblastoma and/or neuroblastoma and AML

Preparation Method

To determine whether the observed in vitro and ex vivo effects predicted in vivo responses in preclinical models at tolerated doses, IACS-010759 can be evaluated in mouse models of glioblastoma and/or neuroblastoma and AML. The PK profile of IACS-010759 was determined in mice following intravenous (0.3mg/kg) and oral (1mg/kg) administration

Dosage form

IACS-010759 intravenous (0.3mg/kg) and oral (1mg/kg) administration

Applications

Changes in blood glucose level with single or repeated doses of IACS-010759 did not observe. However, at 2 h after the first or fifth dose, plasma insulin levels transiently decreased and returned to control levels by 24 h postdose.

IACS-10759 (IACS-010759) is an oxidative phosphorylation inhibitor, IACS-10759 is a potent inhibitor of complex I of oxidative phosphorylation ( OXPHOS )^[1].

IACS-010759 targets glycolysis-deficient tumor cells, In most cell lines, IACS-010759 treatment modestly increased apoptosis by up to twofold^[1]. IACS-010759, like known quinone-site inhibitors, suppresses chemical modification by the tosyl reagent AL1 of Asp160 in the 49-kDa subunit, located deep in the interior of a previously proposed quinone-access channel^[2]. IACS-010759 in complex I is the membrane-embedded ND1 subunit because amino acid substitution at Leu55 (to Phe) in this subunit, which faces the proposed ubiquinone-access channel interior^[3].Treatment of primary CLL cells with IACS-010759 greatly inhibited OxPhos but caused only minor cell death at 24 and 48 h. In the presence of stroma, the drug successfully inhibited OxPhos and diminished intracellular ribonucleotide pools^[4]. Inhibition of OxPhos(by IACS-010759) induced transfer of mitochondria derived from mesenchymal stem cells (MSCs) to AML cells via tunneling nanotubes under direct-contact coculture conditions. Inhibition of OxPhos also induced mitochondrial fission and increased functional mitochondria and mitophagy in AML cells^[5]. Systems analysis of IACS-010759-induced changes in RTS osteoblasts revealed that chemical inhibition of mitochondrial respiratory complex I impaired cell proliferation, induced senescence, and decreased MAPK signaling and cell cycle associated genes, but increased H19 and ribosomal protein genes^[8]. In vitro, the combination of AZD3965 and IACS-010759 is synergistic and induces DLBCL cell death, whereas monotherapy treatments induce a cytostatic response^[9].

IACS-010759 also suppressed tumor growth in zebrafish and mouse xenograft models of high-risk neuroblastoma^[6].Changes in blood glucose level with single or repeated doses of IACS-010759 did not observe. However, at 2 h after the first or fifth dose, plasma insulin levels transiently decreased and returned to control levels by 24 h postdose^[1]. IACS-010759 as an OXPHOS inhibitor currently in early-phase clinical trials, improved survival of mice bearing MAPK inhibitor-resistant intracranial melanoma xenografts and inhibited melanoma brain metastases (MBM) formation in the spontaneous MBM model^[7].

References:
[1]. Molina JR, Sun Y, et,al. An inhibitor of oxidative phosphorylation exploits cancer vulnerability. Nat Med. 2018 Jul;24(7):1036-1046. doi: 10.1038/s41591-018-0052-4. Epub 2018 Jun 11. PMID: 29892070.
[2]. Tsuji A, Akao T, et,al.IACS-010759, a potent inhibitor of glycolysis-deficient hypoxic tumor cells, inhibits mitochondrial respiratory complex I through a unique mechanism. J Biol Chem. 2020 May 22;295(21):7481-7491. doi: 10.1074/jbc.RA120.013366. Epub 2020 Apr 14. PMID: 32295842; PMCID: PMC7247293.
[3]. Zhu J, Vinothkumar KR, et,al. Structure of mammalian respiratory complex I. Nature. 2016 Aug 18;536(7616):354-358. doi: 10.1038/nature19095. Epub 2016 Aug 10. PMID: 27509854; PMCID: PMC5027920.
[4]. Vangapandu HV, Alston B, et,al.Biological and metabolic effects of IACS-010759, an OxPhos inhibitor, on chronic lymphocytic leukemia cells. Oncotarget. 2018 May 18;9(38):24980-24991. doi: 10.18632/oncotarget.25166. PMID: 29861847; PMCID: PMC5982765.
[5]. Saito K, Zhang Q, et,al.Exogenous mitochondrial transfer and endogenous mitochondrial fission facilitate AML resistance to OxPhos inhibition. Blood Adv. 2021 Oct 26;5(20):4233-4255. doi: 10.1182/bloodadvances.2020003661. PMID: 34507353; PMCID: PMC8945617.
[6]. Anderson NM, Qin X, et,al. Metabolic Enzyme DLST Promotes Tumor Aggression and Reveals a Vulnerability to OXPHOS Inhibition in High-Risk Neuroblastoma. Cancer Res. 2021 Sep 1;81(17):4417-4430. doi: 10.1158/0008-5472.CAN-20-2153. Epub 2021 Jul 7. PMID: 34233924; PMCID: PMC8577318.
[7]. Fischer GM, Jalali A, et,al. Molecular Profiling Reveals Unique Immune and Metabolic Features of Melanoma Brain Metastases. Cancer Discov. 2019 May;9(5):628-645. doi: 10.1158/2159-8290.CD-18-1489. Epub 2019 Feb 20. PMID: 30787016; PMCID: PMC6497554.
[8]. Jewell BE, Xu A, et,al.Patient-derived iPSCs link elevated mitochondrial respiratory complex I function to osteosarcoma in Rothmund-Thomson syndrome. PLoS Genet. 2021 Dec 29;17(12):e1009971. doi: 10.1371/journal.pgen.1009971. PMID: 34965247; PMCID: PMC8716051.
[9]. Noble RA, Thomas H, et,al.Simultaneous targeting of glycolysis and oxidative phosphorylation as a therapeutic strategy to treat diffuse large B-cell lymphoma. Br J Cancer. 2022 Sep;127(5):937-947. doi: 10.1038/s41416-022-01848-w. Epub 2022 May 26. PMID: 35618788; PMCID: PMC9428179.