Discovery of selective inhibitors of Glutaminase-2, which inhibit mTORC1, activate autophagy and inhibit proliferation in cancer cells

Lee, Yue‐Zhi; Yang, Cheng‐Wei; Chang, Hsin-Yu; Hsu, Hsing-Yu; Chen, Ih-Shen; Chang, Hsueh‐Wei; Lee, Chih‐Hao; Lee, Jinq-chyi; Kumar, Chidambaram Ramesh; Qiu, Yueming; Chao, Yu‐Sheng; Lee, Shiow‐Ju

doi:10.18632/oncotarget.2173

Cited by 63 publications

(75 citation statements)

References 41 publications

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“…While this report is at odds with previous literature and the predicted localization of either LGA isoform, no study has yet been published which either disputes or supports these findings. The N-terminal residues of the longer LGA isoform are truncated following mitochondrial localization, but it is currently unclear if a similar tr uncation occurs for the shorter LGA variant [51,58].…”

Section: Gls 5ǵmentioning

confidence: 99%

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A Tale of Two Glutaminases: Homologous Enzymes with Distinct Roles in Tumorigenesis

2017

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Many cancer cells exhibit an altered metabolic phenotype, in which glutamine consumption is upregulated relative to healthy cells. This metabolic reprogramming often depends upon mitochondrial glutaminase activity, which converts glutamine to glutamate, a key precursor for biosynthetic and bioenergetic processes. Two isozymes of glutaminase exist, a kidney-type (GLS) and a liver-type enzyme (GLS2 or LGA). While a majority of studies have focused on GLS, here we summarize key findings on both glutaminases, describing their structure and function, their roles in cancer and pharmacological approaches to inhibiting their activities.

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Section: Gls 5ǵmentioning

confidence: 99%

“…The same group later demonstrated that transfection of the same cells with LGA increases their susceptibility to alkylating agents, by downregulating the DNA repair gene MGMT [116]. However, Lee et al showed that LGA inhibition or genetic silencing inhibited the growth of both A549 lung cancer cells and HepG2 hepatoma cells [58].…”

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confidence: 99%

A Tale of Two Glutaminases: Homologous Enzymes with Distinct Roles in Tumorigenesis

2017

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“…There exist two glutaminases, GLS (kidney type KGA and GAC isoforms) and GLS2 (liver isoform (LGA) and glutaminase B (GAB)), yet GLS is the isoform upregulated in cancer, as well as the main glutaminase within the kidney(25,26). Since GSH synthesis requires glutamate in addition to glycine and cysteine, we tested the hypothesis that blocking glutamate production from glutamine by GLS inhibition will down-regulate this important antioxidant pathway, resulting in higher ROS levels, which will be selectively toxic to cancer cells due to their increased local ROS levels.…”

Section: Introductionmentioning

confidence: 99%

Glutamine Addiction in Kidney Cancer Suppresses Oxidative Stress and Can Be Exploited for Real-Time Imaging

et al. 2017

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Many cancers appear to activate intrinsic antioxidant systems as a means to counteract oxidative stress. Some cancers, such as clear cell renal cell carcinoma (ccRCC), require exogenous glutamine for growth and exhibit reprogrammed glutamine metabolism, at least in part due to the glutathione pathway, an efficient cellular buffering system that counteracts reactive oxygen species (ROS) and other oxidants. We show here that ccRCC xenograft tumors under the renal capsule exhibit enhanced oxidative stress compared to adjacent normal tissue and the contralateral kidney. Upon glutaminase inhibition with CB-839 or BPTES, the RCC cell lines SN12PM-6-1 (SN12) and 786-O exhibited decreased survival and pronounced apoptosis associated with a decreased GSH/GSSG ratio, augmented nuclear factor erythroid related factor 2 (NRF2), and increased 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxodG), a marker of DNA damage. SN12 tumor xenografts showed decreased growth when treated with CB-839. Furthermore, PET imaging confirmed that ccRCC tumors exhibited increased tumoral uptake of 18F-(2S,4R)4- fluoroglutamine (18F-FGln) compared to the kidney in the orthotopic mouse model. This technique can be utilized to follow changes in ccRCC metabolism in vivo. Further development of these paradigms will lead to new treatment options with glutaminase inhibitors and the utility of PET to identify and manage ccRCC patients who are likely to respond to glutaminase inhibitors in the clinic.

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“…Specifically, the metabolic rewiring shown by cancer cells involves not only the Warburg effect with enhanced glycolysis and high glutamine consumption, but also elevated rates of lipid biosynthesis, maintenance of redox homeostasis and limited levels of autophagy in the first steps of oncogenesis [10–12]. Recent evidence has shown that cancer cells can engage glutamine metabolism enzymes, such as PEP-carboxykinase (PCK2) [13] or pyruvate carboxylase (PC) [14], to develop metabolic adaptation and promote enhanced cell growth when even glucose is limited. In addition, they can activate autophagy when glutamine is inhibited [15].…”

Section: Introductionmentioning

confidence: 99%

“…Recent evidence has shown that cancer cells can engage glutamine metabolism enzymes, such as PEP-carboxykinase (PCK2) [13] or pyruvate carboxylase (PC) [14], to develop metabolic adaptation and promote enhanced cell growth when even glucose is limited. In addition, they can activate autophagy when glutamine is inhibited [15]. Furthermore, metabolites, such as ATP, acetyl-CoA (AcCoA), reactive oxygen species (ROS) and enzymes with key role in metabolic regulation may act on different signaling pathways controlling tumor growth [9, 16–19].…”

Section: Introductionmentioning

confidence: 99%

Divergent in vitro/in vivo responses to drug treatments of highly aggressive NIH-Ras cancer cells: a PET imaging and metabolomics-mass-spectrometry study

et al. 2016

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Oncogenic K-ras is capable to control tumor growth and progression by rewiring cancer metabolism. In vitro NIH-Ras cells convert glucose to lactate and use glutamine to sustain anabolic processes, but their in vivo environmental adaptation and multiple metabolic pathways activation ability is poorly understood. Here, we show that NIH-Ras cancer cells and tumors are able to coordinate nutrient utilization to support aggressive cell proliferation and survival. Using PET imaging and metabolomics-mass spectrometry, we identified the activation of multiple metabolic pathways such as: glycolysis, autophagy recycling mechanism, glutamine and serine/glycine metabolism, both under physiological and under stress conditions. Finally, differential responses between in vitro and in vivo systems emphasize the advantageous and uncontrolled nature of the in vivo environment, which has a pivotal role in controlling the responses to therapy.

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Discovery of selective inhibitors of Glutaminase-2, which inhibit mTORC1, activate autophagy and inhibit proliferation in cancer cells

Cited by 63 publications

References 41 publications

A Tale of Two Glutaminases: Homologous Enzymes with Distinct Roles in Tumorigenesis

A Tale of Two Glutaminases: Homologous Enzymes with Distinct Roles in Tumorigenesis

Glutamine Addiction in Kidney Cancer Suppresses Oxidative Stress and Can Be Exploited for Real-Time Imaging

Divergent in vitro/in vivo responses to drug treatments of highly aggressive NIH-Ras cancer cells: a PET imaging and metabolomics-mass-spectrometry study

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