Isocitrate dehydrogenase 1 mutant R132H sensitizes glioma cells to BCNU-induced oxidative stress and cell death

Isocitrate dehydrogenase 1 (IDH1) decarboxylates isocitrate to α-ketoglutarate (α-KG) leading to generation of NADPH, which is required to regenerate reduced glutathione (GSH), the major cellular ROS scavenger. Mutation of R132 of IDH1 abrogates generation of α-KG and leads to conversion of α-KG to 2-hydroxyglutarate. We hypothesized that glioma cells expressing mutant IDH1 have a diminished antioxidative capacity and therefore may encounter an ensuing loss of cytoprotection under conditions of oxidative stress. Our study was performed with LN229 cells stably overexpressing IDH1 R132H and wild type IDH1 or with a lentiviral IDH1 knockdown. Quantification of GSH under basal conditions and following treatment with the glutathione reductase inhibitor BCNU revealed significantly lower GSH levels in IDH1 R132H expressing cells and IDH1 KD cells compared to their respective controls. FACS analysis of cell death and ROS production also demonstrated an increased sensitivity of IDH1-R132H-expressing cells and IDH1 KD cells to BCNU, but not to temozolomide. The sensitivity of IDH1-R132H-expressing cells and IDH1 KD cells to ROS induction and cell death was further enhanced with the transaminase inhibitor aminooxyacetic acid and under glutamine free conditions, indicating that these cells were more addicted to glutaminolysis. Increased sensitivity to BCNU-induced ROS production and cell death was confirmed in HEK293 cells inducibly expressing the IDH1 mutants R132H, R132C and R132L. Based on these findings we propose that in addition to its established pro-tumorigenic effects, mutant IDH1 may also limit the resistance of gliomas to specific death stimuli, therefore opening new perspectives for therapy.     

Biochemical,Cellular, and Biophysical Characterization of a Potent Inhibitor of Mutant Isocitrate Dehydrogenase IDH1

Two mutant forms (R132H and R132C) of isocitrate dehydrogenase 1 (IDH1) have been associated with a number of cancers including glioblastoma and acute myeloid leukemia. These mutations confer a neomorphic activity of 2-hydroxyglutarate (2-HG) production, and 2-HG has previously been implicated as an oncometabolite. Inhibitors of mutant IDH1 can potentially be used to treat these diseases. In this study, we investigated the mechanism of action of a newly discovered inhibitor, ML309, using biochemical, cellular, and biophysical approaches. Substrate binding and product inhibition studies helped to further elucidate the IDH1 R132H catalytic cycle. This rapidly equilibrating inhibitor is active in both biochemical and cellular assays. The (+) isomer is active (IC₅₀ = 68 nm), whereas the (−) isomer is over 400-fold less active (IC₅₀ = 29 μm) for IDH1 R132H inhibition. IDH1 R132C was similarly inhibited by (+)-ML309. WT IDH1 was largely unaffected by (+)-ML309 (IC₅₀ >36 μm). Kinetic analyses combined with microscale thermophoresis and surface plasmon resonance indicate that this reversible inhibitor binds to IDH1 R132H competitively with respect to α-ketoglutarate and uncompetitively with respect to NADPH. A reaction scheme for IDH1 R132H inhibition by ML309 is proposed in which ML309 binds to IDH1 R132H after formation of the IDH1 R132H NADPH complex. ML309 was also able to inhibit 2-HG production in a glioblastoma cell line (IC₅₀ = 250 nm) and had minimal cytotoxicity. In the presence of racemic ML309, 2-HG levels drop rapidly. This drop was sustained until 48 h, at which point the compound was washed out and 2-HG levels recovered.     

Establishment of a novel monoclonal antibody SMab-1 specific for IDH1-R132S mutation

Isocitrate dehydrogenase 1 (IDH1) mutations, which are early and frequent genetic alterations in gliomas, are specific to a single codon in the conserved and functionally important Arginine 132 (R132) in IDH1. We earlier established a monoclonal antibody (mAb), IMab-1, which is specific for R132H-containing IDH1 (IDH1-R132H), the most frequent IDH1 mutation in gliomas. To establish IDH1-R132S-specific mAb, we immunized mice with R132S-containing IDH1 (IDH1-R132S) peptide. After cell fusion using Sendai virus envelope, IDH1-R132S-specific mAbs were screened in ELISA. One mAb, SMab-1, reacted with the IDH1-R132S peptide, but not with other IDH1 mutants. Western-blot analysis showed that SMab-1 reacted only with the IDH1-R132S protein, not with IDH1-WT protein or IDH1 mutants, indicating that SMab-1 is IDH1-R132S-specific. Furthermore, SMab-1 specifically stained the IDH1-R132S-expressing glioblastoma cells in immunocytochemistry and immunohistochemistry, but did not react with IDH1-WT or IDH1-R132H-containing glioblastoma cells. We newly established an anti-IDH1-R132S-specific mAb SMab-1 for use in diagnosis of mutation-bearing gliomas.     

Radiological and Pathological Features Associated with IDH1-R132H Mutation Status and Early Mortality in Newly Diagnosed Anaplastic Astrocytic Tumours

Background

Glioblastoma can occur either de novo or by the transformation of a low grade tumour; the majority of which harbor a mutation in isocitrate dehydrogenase (IDH1). Anaplastic tumours are high-grade gliomas that may represent the final step in the evolution of a secondary glioblastoma or the initial presentation of an early primary glioblastoma. We sought to determine whether pathological and/or radiological variables exist that can reliably distinguish IDH1-R132H-positive from IDH1-R132H-negative tumours and to identify variables associated with early mortality.

Methods

Patients diagnosed with anaplastic astrocytic tumours were included. Magnetic resonance imaging was performed and immunohistochemistry was used to identify tumours with the IDH1-R132H mutation. Survival was assessed 12 months after diagnosis. Variables associated with IDH1-R132H status were identified by univariate and ROC analysis.

Results

37 gliomas were studied; 18 were positive for the IDH1-R132H mutation. No tumours demonstrated a combined loss of chromosomes 1p/19q. Patients with IDH1-R132H-positive tumours were less likely to die within 12 months of diagnosis (17% vs. 47%; p=0.046), more likely to have tumours located in the frontal lobe (55% vs. 16%; p=0.015), and have a higher minimum apparent diffusion coefficient (1.115 x 10^-3 mm²/sec vs. 0.838 x 10^-3 mm²/sec; p=0.016), however, these variables demonstrated only moderate strength for predicting the IDH1-R132H mutation status (AUC=0.735 and 0.711, respectively). The Ki-67 index was significantly lower in IDH1-R132H-positive tumours (0.13 vs. 0.21; p=0.034). An increased risk of death was associated with contrast-enhancement ≥ 5 cm³ in patients with IDH1-R132H-positive tumours while edema ≥ 1 cm beyond the tumour margin and < 5 mitoses/mm² were associated with an increased risk of death in patients with IDH1-R132H-negative tumours.

Conclusions

IDH1-R132H-positive and -negative anaplastic tumours demonstrate unique features. Factors associated with early mortality are also dependent on IDH1-R132H status and can be used to identify patients at high risk for death.     

人脑胶质瘤中的IDH1/2突变

胶质母细胞瘤的基因组突变分析中发现的异柠檬酸脱氢酶(isocitrate dehydrogenase,IDH1)突变对胶质瘤的认识具有突破性意义。随后,在胶质瘤中发现了IDH1的R132碱基和IDH2的R172碱基突变。IDH1突变较多的发生在WHOII-III级胶质瘤和继发胶质母细胞瘤中。这种突变改变了异柠檬酸脱氢酶的结构,从而使将异柠檬酸转化为a-酮戊二酸的能力丧失,而获得将a-酮戊二酸转化为2-羟基戊二酸这一新的酶活性。在临床中,IDH1和IDH2突变已经显示对胶质瘤患者有诊断和预后意义。同时,现今也发展了一些检测方法。     

胶质瘤中的异柠檬酸脱氢酶突变

胶质母细胞瘤的基因组突变分析中发现的异柠檬酸脱氢酶（isocitrate dehydrogenase,IDH）突变对胶质瘤的认识具有突破性意义.随后,在胶质瘤中发现了IDH1的R132碱基和IDH2的R172碱基突变.IDH1突变较多的发生在WHOⅡ～Ⅲ级胶质瘤和继发胶质母细胞瘤中.这种突变改变了异柠檬酸脱氢酶的结构,从而使将异柠檬酸转化为α-酮戊二酸的能力丧失,而获得将α-酮戊二酸转化为D-2-羟基戊二酸这一新的酶活性.在临床中,IDH1和IDH2突变已经显示对胶质瘤患者有诊断和预后意义.同时,现今也发展了一些检测方法.     

Mutation Analysis of IDH1 in Paired Gliomas Revealed IDH1 Mutation Was Not Associated with Malignant Progression but Predicted Longer Survival

Recurrence and progression to higher grade lesions are characteristic behaviorsof gliomas. Though IDH1 mutation frequently occurs and is considered as an early event in gliomagenesis, little is known about its role in the recurrence and progression of gliomas. We therefore analysed IDH1 and IDH2 statusat codon 132 of IDH1 and codon 172 of IDH2 by direct sequencing and anti-IDH1-R132H immunohistochemistry in 53 paired samples and their recurrences, including 29 low- grade gliomas, 16 anaplastic gliomas and 8 Glioblastomas. IDH1/IDH2 mutation was detected in 32 primarytumors, with 25 low- grade gliomas and 6 anaplastic gliomas harboring IDH1 mutation and 1 low- grade glioma harboring IDH2 mutation. All of the paired tumors showed consistent IDH1 and IDH2 status. Patients were analyzed according to IDH1 status and tumor-related factors. Malignant progression at recurrence was noted in 22 gliomas and was not associated with IDH1 mutation. Survival analysis revealed patients with IDH1 mutated gliomas had a significantly longer progression-free survival (PFS) and overall survival (OS). In conclusion, this study demonstrated a strong tendency of IDH1/IDH2 status being consistent during progression of glioma. IDH1 mutation was not a predictive marker for malignant progression and it was a potential prognostic marker for gliomas of Chinese patients.     

Synthesis and evaluation of radiolabeled AGI-5198 analogues as candidate radiotracers for imaging mutant IDH1 expression in tumors

Mutations in the metabolic enzyme isocitrate dehydrogenase 1 (IDH1) are commonly found in gliomas. AGI-5198, a potent and selective inhibitor of the mutant IDH1 enzyme, was radiolabeled with radioiodine and fluorine-18. These radiotracers were evaluated as potential probes for imaging mutant IDH1 expression in tumors with positron emission tomography (PET). Radioiodination of AGI-5198 was achieved using a tin precursor in 79?±?6% yield (n?=?9), and ¹⁸F-labeling was accomplished by the Ugi reaction in a decay-corrected radiochemical yield of 2.6?±?1.6% (n?=?5). The inhibitory potency of the analogous nonradioactive compounds against mutant IDH1 (IDH1-R132H) was determined in enzymatic assays. Cell uptake studies using radiolabeled AGI-5198 analogues revealed somewhat higher uptake in IDH1-mutated cells than that in wild-type IDH1 cells. The radiolabeled compounds displayed favorable tissue distribution characteristics in vivo, and good initial uptake in IDH1-mutated tumor xenografts; however, tumor uptake decreased with time. Radioiodinated AGI-5198 exhibited higher tumor-to-background ratios compared with ¹⁸F-labeled AGI-5198; unfortunately, similar results were observed in wild-type IDH1 tumor xenografts as well, indicating lack of selectivity for mutant IDH1 for this tracer. These results suggest that AGI-5198 analogues are not a promising platform for radiotracer development. Nonetheless, insights gained from this study may help in design and optimization of novel chemical scaffolds for developing radiotracers for imaging the mutant IDH1 enzyme.     

The mechanisms of IDH mutations in tumorigenesis

Tumor-associated mutations in the isocitrate dehydrogenase 1 and 2 (IDH1 and IDH2) genes result in the loss of normal catalytic activity, the production of α-ketoglutarate (α-KG), and gain of a new activity, the production of an oncometabolite, R-2-hydroxylglutarate (R-2-HG). New evidence supports previous findings that R-2-HG acts as an antagonist of α-KG to competitively inhibit the activity of multiple α-KG-dependent dioxygenases, including both histones and DNA demethylases involved in epigenetic control of gene expression and cell differentiation, and also reveals an intriguing new facet of R-2-HG in tumorigenesis.The NADP⁺-dependent isocitrate dehydrogenase IDH1 and IDH2 catalyze the oxidative decarboxylation of isocitrate to α-ketoglutarate (α-KG). IDH1 and IDH2 are localized in the cytoplasm and mitochondria, respectively, and represent by far the most frequently mutated metabolic enzymes in human cancer¹. The tumor-derived mutants of both IDH1 and IDH2 lose their activity in producing α-KG^2,3, and gain a surprising new catalytic activity, the production of R-2-hydroxyglutarate (R-2-HG) by reduction of α-KG⁴. Previous studies have shown that R-2-HG acts as an antagonist of α-KG to competitively inhibit a number of α-KG-dependent dioxygenases, including the JmjC domain-containing histone demethylases (KDMs) and the TET (ten-eleven translocation) family of DNA hydroxylases that catalyze the sequential oxidation of 5-methlycytosine (5mC) to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC), leading to eventual DNA demethylation (Figure 1)^5,6. Three papers recently published in Nature provide additional evidence that α-KG-dependent dioxygenases are the pathophysiological targets of mutant IDH1/2, and further underscore the presumptive role of R-2-HG as the first oncometabolite in contributing to tumorigenesis after IDH1/2 mutations.Open in a separate windowFigure 1Summarization of reported mechanisms linking IDH mutation to tumorigensis. Regulation of α-KG-dependent dioxygenases by R-2-HG is likely to play a major role in the pathophysiology of tumors with IDH mutation.A subset of glioblastoma, known as the proneural subgroup, has previously found to display hypermethylation at a large number of loci and is enriched with IDH1 mutations⁷. In one of the three Nature papers, Turcan et al.⁸ determined whether IDH1 mutation alone is sufficient to cause the hypermethylation phenotype by ectopic expression of IDH1^R132H mutant in immortalized primary human astrocytes, a cell type from which glioblastoma is believed to develop. The authors found that introduction of mutant IDH1 induced extensive DNA hypermethylation, altered the methylation of specific histones, and reshaped the methylome in a fashion that mirrors the changes observed in IDH1-mutated low-grade gliomas. The observed hypermethylation of DNA and histones can be explained by the direct inhibition of TET methylcytosine hydroxylases and JmjC family histone demethylases by R-2-HG, respectively. In keeping with the notion that TET hydroxylases directly regulate genomic DNA methylation levels and can be inhibited by the R-2-HG accumulated in IDH1/2-mutated cells, Turcan et al. also showed that ectopic expression of TET2 in cultured astrocytes decreased 5mC and increased 5hmC, and that both changes were inhibited by the co-expression of TET2 with mutant IDH1. These results are consistent with the findings made in acute myeloid leukemia (AML) in which IDH1/2 and TET2 genes are mutated in a mutually exclusive manner⁹. Moreover, Turcan et al. found that expression of wild-type IDH1 decreased the average DNA methylation level in the genome, supporting the notion that the concentration of α-KG may be a rate-limiting factor of TET-catalyzed DNA demethylation⁵.In the second paper, Lu et al.¹⁰ reported that ectopic expression of tumor-derived mutant IDH1/2 or feeding cells with cell-permeable R-2-HG increases histone demethylation and results in blockade of the differentiation of 3T3-L1 adipoblasts to adipocytes. These results indicate that mutation of IDH1/2 and accumulation of R-2-HG can broadly impair cell differentiation beyond the cell types in which IDH1/2 mutations are found to associate with tumorigenesis. The authors further confirmed that IDH1-mutated gliomas have elevated levels of histone methylation compared with gliomas retaining the wild-type IDH1^5,6. As previously reported^5,6, multiple KDMs that are inhibited by 2-HG, including KDM4C/JMJD2C, which causes repressive histone H3K9 di- and trimethylation and, when suppressed by RNA interference, blocks the 3T3-L1 adipogenesis. It remains to be determined whether collective inhibition of multiple KDMs or a few individual ones, such as KDM4C, is responsible for altering cell differentiation in IDH1/2-mutated cells. The authors also noted that expression of mutant IDH1 increased histone methylation prior to the increase of DNA methylation, raising an intriguing possibility that histone methylation status may affect DNA methylation.In the third paper, Koivunen et al.¹¹ proposed an enantiomer-specific mechanism of 2-HG in tumorigenesis. The authors reported two surprising findings. They showed first that immortalized human astrocytes stably expressing tumor-derived IDH1^R132H mutant proliferate faster during late passages than those expressing either wild-type IDH1 or IDH1^R132H/3DN mutant that lacks 2-HG-producing activity. Ectopic expression of R132H mutant IDH1 has previously been reported to decrease the growth of D54 glioblastoma cells¹², raising an intriguing possibility that the mutation of IDH1/2 may exhibit different effects on cell growth in a cell context-dependent manner. More surprisingly, they found that R-2-HG, but not its enantiomer S-2-HG, substitutes for α-KG as a co-substrate, as opposed to an inhibitor, of EGLN, an α-KG-dependent prolylhydroxylase responsible for promoting the degradation of hypoxia inducible factor 1α (HIF-1α) (Figure 1). As the result of stimulating EGLN, accumulation of R-2-HG was found to associate with diminished, instead of increased, HIF-1α levels in cells expressing mutant IDH1/2. At first glance, these observations appear to be at odds with the generally accepted role of both enantiomers of 2-HG as inhibitors of α-KG-dependent dioxygenases, and HIF-1α as an oncogene in tumorigenesis, but may at least in part explain the apparent selection for IDH mutations to produce R-, but not S-2-HG in cancer. This data, also for the first time, reveals a qualitatively different property of two 2-HG enantiomers with respect to α-KG-dependent dioxygenases. It will be interesting to determine the strutural basis of this enantimoer-specific effect of 2-HG toward different α-KG-dependent dixoygenases. The observation that ectopic increase of R-2-HG reduces HIF-1α suggests that endogenous α-KG is limiting for HIF-1α hydroxylation by EGLN. The study by Koivunen et al. also suggests the complexity of EGLN regulation by R-2-HG and subsequent downregulation of HIF-1α. It remains to be determined genetically whether a reduction or fluctuation of HIF-1α levels contributes to gliomagenesis in IDH1/2-mutated cells, because elevated HIF-1α generally contributes to cancer development. The only piece of genetic evidece—IDH1/2 mutation occurs in a mutually exclusive manner with TET2 mutation in AML—supports the notion that epigenetic alteration plays a direct and perhaps a key role in IDH1/2 mutation-associated tumorigenesis.IDH1/2 mutation has rapidly emerged as a favorable diagnostic and prognostic marker for certain tumors, such as low-grade gliomas and benign cartilaginous tumors. While the full mechanism linking IDH mutation to tumorigenesis is incompletely understood, regulation of α-KG-dependent dioxygenases by 2-HG is likely to play a major role in the pathophysiology of tumors with IDH mutation. These recent reports also highlight the impact of altered metabolism and metabolites on the epigenetic modification of cell differentiation and tumorigenesis.     

Synthesis and biological evaluation of 3-aryl-4-indolyl-maleimides as potent mutant isocitrate dehydrogenase-1 inhibitors

A series of 3-aryl-4-indolylmaleimide IDH1/R132H inhibitors with a novel structure was obtained by high-throughput screening and structure-based optimization. Most compounds such as 7a, 7d, 7h, 7i, 7k and 7o showed high inhibitory effects on IDH1/R132H and were highly selective against IDH1/WT, IDH2/WT, GDH, GK, and FBP. Evaluation of the biological activities and function at cellular level showed that compounds 7h, 7i and 7k could effectively suppress the production of 2-hydroxyglutaric acid in U87MG cells expressing IDH1/R132H. Additionally, 7h could reversed the differentiation block of the myeloid leukemic cell line, TF-1, caused by the overexpression of IDH1/R132H. We also explore the structure-activity relationship based on the experimental data, with an attempt to pave the way for future studies.     

Single Arginine Mutation in Two Yeast Isocitrate Dehydrogenases: Biochemical Characterization and Functional Implication

Isocitrate dehydrogenase (IDH), a housekeeping gene, has drawn the attention of cancer experts. Mutation of the catalytic Arg132 residue of human IDH1 (HcIDH) eliminates the enzyme''s wild-type isocitrate oxidation activity, but confer the mutant an ability of reducing α-ketoglutarate (α-KG) to 2-hydroxyglutarate (2-HG). To examine whether an analogous mutation in IDHs of other eukaryotes could cause similar effects, two yeast mitochondrial IDHs, Saccharomyces cerevisiae NADP⁺-IDH1 (ScIDH1) and Yarrowia lipolytica NADP⁺-IDH (YlIDH), were studied. The analogous Arg residues (Arg148 of ScIDH1 and Arg141 of YlIDH) were mutated to His. The K _m values of ScIDH1 R148H and YlIDH R141H for isocitrate were determined to be 2.4-fold and 2.2-fold higher, respectively, than those of the corresponding wild-type enzymes. The catalytic efficiencies (k _cat/K _m) of ScIDH1 R148H and YlIDH R141H for isocitrate oxidation were drastically reduced by 227-fold and 460-fold, respectively, of those of the wild-type enzymes. As expected, both ScIDH1 R148H and YlIDH R141H acquired the neomorphic activity of catalyzing α-KG to 2-HG, and the generation of 2-HG was confirmed using gas chromatography/time of flight-mass spectrometry (GC/TOF-MS). Kinetic analysis showed that ScIDH1 R148H and YlIDH R141H displayed 5.2-fold and 3.3-fold higher affinities, respectively, for α-KG than the HcIDH R132H mutant. The catalytic efficiencies of ScIDH1 R148H and YlIDH R141H for α-KG were 5.5-fold and 4.5-fold, respectively, of that of the HcIDH R132H mutant. Since the HcIDH Arg132 mutation is associated with the tumorigenesis, this study provides fundamental information for further research on the physiological role of this IDH mutation in vivo using yeast.     

A lymphoblast model for IDH2 gain-of-function activity in d-2-hydroxyglutaric aciduria type II: novel avenues for biochemical and therapeutic studies

The recent discovery of heterozygous isocitrate dehydrogenase 2 (IDH2) mutations of residue Arg(140) to Gln(140) or Gly(140) (IDH2(wt/R140Q), IDH2(wt/R140G)) in d-2-hydroxyglutaric aciduria (D-2-HGA) has defined the primary genetic lesion in 50% of D-2-HGA patients, denoted type II. Overexpression studies with IDH1(R132H) and IDH2(R172K) mutations demonstrated that the enzymes acquired a new function, converting 2-ketoglutarate (2-KG) to d-2-hydroxyglutarate (D-2-HG), in lieu of the normal IDH reaction which reversibly converts isocitrate to 2-KG. To confirm the IDH2(wt/R140Q) gain-of-function in D-2-HGA type II, and to evaluate potential therapeutic strategies, we developed a specific and sensitive IDH2(wt/R140Q) enzyme assay in lymphoblasts. This assay determines gain-of-function activity which converts 2-KG to D-2-HG in homogenates of D-2-HGA type II lymphoblasts, and uses stable-isotope-labeled 2-keto[3,3,4,4-(2)H(4)]glutarate. The specificity and sensitivity of the assay are enhanced with chiral separation and detection of stable-isotope-labeled D-2-HG by ultra performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS). Eleven potential inhibitors of IDH2(wt/R140Q) enzyme activity were evaluated with this procedure. The mean reaction rate in D-2-HGA type II lymphoblasts was 8-fold higher than that of controls and D-2-HGA type I cells (14.4nmolh(-1)mgprotein(-1) vs. 1.9), with a corresponding 140-fold increase in intracellular D-2-HG level. Optimal inhibition of IDH2(wt/R140Q) activity was obtained with oxaloacetate, which competitively inhibited IDH2(wt/R140Q) activity. Lymphoblast IDH2(wt/R140Q) showed long-term cell culture stability without loss of the heterozygous IDH2(wt/R140Q) mutation, underscoring the utility of the lymphoblast model for future biochemical and therapeutic studies.     

2-Hydroxyglutarate as a Magnetic Resonance Biomarker for Glioma Subtyping

Mutations in the isocitrate dehydrogenase (IDH) genes are frequently found in gliomas and in a fraction of acute myeloid leukemia patients. This results in the production of an oncometabolite, 2-hydroxyglutarate (2-HG). Glioma patients harboring IDH mutations have a longer survival than their wild-type counterparts. 2-HG has been detected noninvasively in gliomas with IDH mutations using magnetic resonance spectroscopy (MRS), suggesting its potential clinical relevance for identifying glioma subtypes with better prognosis. In this paper, the recent developments in the MRS detection of the 2-HG in gliomas are reviewed, including the therapeutic potentials and translational values.     

Licochalcone A suppresses the proliferation of sarcoma HT-1080 cells,as a selective R132C mutant IDH1 inhibitor

IDH1 mutations are closely related to the development and progression of various human cancers, such as glioblastoma, sarcoma, and acute myeloid leukemia. By screening dozens of reported natural compounds using both wild-type and mutant IDH1 enzymatic assays, we discovered Licochalcone A is a selective inhibitor to the R132C-mutant IDH1 with an IC₅₀ value of 5.176 μM, and inhibits the proliferation of sarcoma HT-1080 cells with an IC₅₀ value of 10.75 μM. Suggested by the molecular docking results, Licochalcone A might occupy the allosteric pocket between the two monomers of IDH1 homodimer, and the R132H mutation was unfavorable for the binding of Licochalcone A with the IDH1 protein, as compared to the R132C mutation. Revealed by the RNA-Seq data analysis, the Cell Cycle pathway was the most over-represented pathway for HT-1080 cells treated with Licochalcone A. Consistent with these results, Licochalcone A induced apoptosis and cell cycle arrest of HT-1080 cells, while it showed minimal effect against the proliferation of normal RCTEC cells. The discovery of Licochalcone A as a mutation-selective IDH1 inhibitor can serve as a promising starting point for the development of mutation-selective anti-tumor lead compounds targeting IDH1.     

Treatment with a Small Molecule Mutant IDH1 Inhibitor Suppresses Tumorigenic Activity and Decreases Production of the Oncometabolite 2-Hydroxyglutarate in Human Chondrosarcoma Cells

Chondrosarcomas are malignant bone tumors that produce cartilaginous matrix. Mutations in isocitrate dehydrogenase enzymes (IDH1/2) were recently described in several cancers including chondrosarcomas. The IDH1 inhibitor AGI-5198 abrogates the ability of mutant IDH1 to produce the oncometabolite D-2 hydroxyglutarate (D-2HG) in gliomas. We sought to determine if treatment with AGI-5198 would similarly inhibit tumorigenic activity and D-2HG production in IDH1-mutant human chondrosarcoma cells. Two human chondrosarcoma cell lines, JJ012 and HT1080 with endogenous IDH1 mutations and a human chondrocyte cell line C28 with wild type IDH1 were employed in our study. Mutation analysis of IDH was performed by PCR-based DNA sequencing, and D-2HG was detected using tandem mass spectrometry. We confirmed that JJ012 and HT1080 harbor IDH1 R132G and R132C mutation, respectively, while C28 has no mutation. D-2HG was detectable in cell pellets and media of JJ012 and HT1080 cells, as well as plasma and urine from an IDH-mutant chondrosarcoma patient, which decreased after tumor resection. AGI-5198 treatment decreased D-2HG levels in JJ012 and HT1080 cells in a dose-dependent manner, and dramatically inhibited colony formation and migration, interrupted cell cycling, and induced apoptosis. In conclusion, our study demonstrates anti-tumor activity of a mutant IDH1 inhibitor in human chondrosarcoma cell lines, and suggests that D-2HG is a potential biomarker for IDH mutations in chondrosarcoma cells. Thus, clinical trials of mutant IDH inhibitors are warranted for patients with IDH-mutant chondrosarcomas.     

A monoclonal antibody IMab-1 specifically recognizes IDH1, the most common glioma-derived mutation

IDH1 (isocitrate dehydrogenase 1) mutations have been identified as early and frequent genetic alterations in astrocytomas, oligodendrogliomas, and oligoastrocytomas as well as secondary glioblastomas. In contrast, primary glioblastomas very rarely contain IDH1 mutations, although primary and secondary glioblastomas are histologically indistinguishable. The IDH1 mutations are remarkably specific to a single codon in the conserved and functionally important Arg132 in IDH1. In gliomas, the most frequent IDH1 mutations (>90%) were G395A (R132H). In this study, we immunized mice with R132H-containing IDH1 (IDH1^R132H) peptide. After cell fusion using Sendai virus envelope, the monoclonal antibodies (mAbs), which specifically reacted with IDH1^R132H, were screened in ELISA. One of the mAbs, IMab-1 reacted with the IDH1^R132H peptide, but not with wild type IDH1 (IDH1^wt) peptide in ELISA. In Western-blot analysis, IMab-1 reacted with only the IDH1^R132H protein, not IDH1^wt protein or the other IDH1 mutants, indicating that IMab-1 is IDH1^R132H-specific. Furthermore, IMab-1 specifically stained the IDH1^R132H-expressing cells in astrocytomas in immunohistochemistry, whereas it did not react with IDH1^R132H-negative primary glioblastoma sections. In conclusion, we established an anti-IDH1^R132H-specific monoclonal antibody IMab-1, which should be significantly useful for diagnosis and biological evaluation of mutation-bearing gliomas.     

Synergistic anti-tumor efficacy of mutant isocitrate dehydrogenase 1 inhibitor SYC-435 with standard therapy in patient-derived xenograft mouse models of glioma

Clinical outcomes in patients with WHO grade II/III astrocytoma, oligodendroglioma or secondary glioblastoma remain poor. Isocitrate dehydrogenase 1 (IDH1) is mutated in > 70% of these tumors, making it an attractive therapeutic target. To determine the efficacy of our newly developed mutant IDH1 inhibitor, SYC-435 (1-hydroxypyridin-2-one), we treated orthotopic glioma xenograft model (IC-BT142AOA) carrying R132H mutation and our newly established orthotopic patient-derived xenograft (PDX) model of recurrent anaplastic oligoastrocytoma (IC-V0914AOA) bearing R132C mutation. In addition to suppressing IDH1 mutant cell proliferation in vitro, SYC-435 (15 mg/kg, daily x 28 days) synergistically prolonged animal survival times with standard therapies (Temozolomide + fractionated radiation) mediated by reduction of H3K4/H3K9 methylation and expression of mitochondrial DNA (mtDNA)-encoded molecules. Furthermore, RNA-seq of the remnant tumors identified genes (MYO1F, CTC1 and BCL9) and pathways (base excision repair, TCA cycle II, sirtuin signaling, protein kinase A, eukaryotic initiation factor 2 and α-adrenergic signaling) as mediators of therapy resistance. Our data demonstrated the efficacy SYC-435 in targeting IDH1 mutant gliomas when combined with standard therapy and identified a novel set of genes that should be prioritized for future studies to overcome SYC-435 resistance.     

Selective Inhibition of Mutant Isocitrate Dehydrogenase 1 (IDH1) via Disruption of a Metal Binding Network by an Allosteric Small Molecule

Cancer-associated point mutations in isocitrate dehydrogenase 1 and 2 (IDH1 and IDH2) confer a neomorphic enzymatic activity: the reduction of α-ketoglutarate to d-2-hydroxyglutaric acid, which is proposed to act as an oncogenic metabolite by inducing hypermethylation of histones and DNA. Although selective inhibitors of mutant IDH1 and IDH2 have been identified and are currently under investigation as potential cancer therapeutics, the mechanistic basis for their selectivity is not yet well understood. A high throughput screen for selective inhibitors of IDH1 bearing the oncogenic mutation R132H identified compound 1, a bis-imidazole phenol that inhibits d-2-hydroxyglutaric acid production in cells. We investigated the mode of inhibition of compound 1 and a previously published IDH1 mutant inhibitor with a different chemical scaffold. Steady-state kinetics and biophysical studies show that both of these compounds selectively inhibit mutant IDH1 by binding to an allosteric site and that inhibition is competitive with respect to Mg²⁺. A crystal structure of compound 1 complexed with R132H IDH1 indicates that the inhibitor binds at the dimer interface and makes direct contact with a residue involved in binding of the catalytically essential divalent cation. These results show that targeting a divalent cation binding residue can enable selective inhibition of mutant IDH1 and suggest that differences in magnesium binding between wild-type and mutant enzymes may contribute to the inhibitors'' selectivity for the mutant enzyme.