Tryptophan Metabolism Contributes to Radiation-Induced Immune Checkpoint Reactivation in Glioblastoma

Kesarwani, Pravin; Prabhu, Antony; Kant, Shri; Kumar, Praveen; Graham, Stewart F.; Buelow, Katie L.; Wilson, George D.; Miller, C. Ryan; Chinnaiyan, Prakash

doi:10.1158/1078-0432.ccr-18-0041

Cited by 56 publications

(69 citation statements)

References 49 publications

(66 reference statements)

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“…Cysteine and tryptophan metabolism also have established roles in a variety of malignancies, including glioblastoma. 32,33 Our studies reinforce the clear importance that aberrant amino acid metabolism plays in gliomagenesis, with numerous amino acids contributing to diverse metabolic functions enriched in glioblastoma. This included intermediates of serine, glutathione, cysteine, tryptophan, and urea metabolism that have been implicated in many oncogenic roles, including energy production, maintenance of redox balance, protein and nucleotide synthesis, anaplerosis, and immune modulation.…”

Section: Neuro-oncologysupporting

confidence: 70%

Integrative cross-platform analyses identify enhanced heterotrophy as a metabolic hallmark in glioblastoma

et al. 2018

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Background. Although considerable progress has been made in understanding molecular alterations driving gliomagenesis, the diverse metabolic programs contributing to the aggressive phenotype of glioblastoma remain unclear. The aim of this study was to define and provide molecular context to metabolic reprogramming driving gliomagenesis. Methods. Integrative cross-platform analyses coupling global metabolomic profiling with genomics in patientderived glioma (low-grade astrocytoma [LGA; n = 28] and glioblastoma [n = 80]) were performed. Identified programs were then metabolomically, genomically, and functionally evaluated in preclinical models. Results. Clear metabolic programs were identified differentiating LGA from glioblastoma, with aberrant lipid, peptide, and amino acid metabolism representing dominant metabolic nodes associated with malignant transformation. Although the metabolomic profiles of glioblastoma and LGA appeared mutually exclusive, considerable metabolic heterogeneity was observed in glioblastoma. Surprisingly, integrative analyses demonstrated that O 6methylguanine-DNA methyltransferase methylation and isocitrate dehydrogenase mutation status were equally distributed among glioblastoma metabolic profiles. Transcriptional subtypes, on the other hand, tightly clustered by their metabolomic signature, with proneural and mesenchymal tumor profiles being mutually exclusive. Integrating these metabolic phenotypes with gene expression analyses uncovered tightly orchestrated and highly redundant transcriptional programs designed to support the observed metabolic programs by actively importing these biochemical substrates from the microenvironment, contributing to a state of enhanced metabolic heterotrophy. These findings were metabolomically, genomically, and functionally recapitulated in preclinical models. Conclusion. Despite disparate molecular pathways driving the progression of glioblastoma, metabolic programs designed to maintain its aggressive phenotype remain conserved. This contributes to a state of enhanced metabolic heterotrophy supporting survival in diverse microenvironments implicit in this malignancy. Key Points 1. Integrative analyses define and provide molecular context to metabolic reprogramming driving gliomagenesis.

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Section: Neuro-oncologysupporting

confidence: 70%

Integrative cross-platform analyses identify enhanced heterotrophy as a metabolic hallmark in glioblastoma

et al. 2018

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“…50 Although IDO1 inhibitors have not demonstrated antitumor activity as single agents in orthotopic glioma animals, a unique synergy when combined with radiotherapy, temozolomide, or anti-programmed cell death protein 1 antibody has been noted. [28][29][30][51][52][53] TDO inhibitors have not been tested in glioma animals. In this study, RY103, an IDO1/TDO dual inhibitor, showed excellent therapeutic efficacy via downregulating the IDO1/TDO-Kyn-AhR-AQP4 signal pathway in GL261 orthotopic glioma mice.…”

Section: Discussionmentioning

confidence: 99%

Both IDO1 and TDO contribute to the malignancy of gliomas via the Kyn–AhR–AQP4 signaling pathway

Xing

Tao

et al. 2020

Sig Transduct Target Ther

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Indoleamine 2,3-dioxygenase 1 (IDO1), indoleamine 2,3-dioxygenase 2 (IDO2), and tryptophan 2,3-dioxygenase (TDO) initiate the first step of the kynurenine pathway (KP), leading to the transformation of L-tryptophan (Trp) into L-kynurenine (Kyn) and other downstream metabolites. Kyn is known as an endogenous ligand of the aryl hydrocarbon receptor (AhR). Activation of AhR through TDO-derived Kyn is a novel mechanism to support tumor growth in gliomas. However, the role of IDO1 and IDO2 in this mechanism is still unknown. Herein, by using clinical samples, we found that the expression and activity of IDO1 and/or TDO (IDO1/TDO) rather than IDO2 were positively correlated with the pathologic grades of gliomas. The expression of IDO1/TDO rather than IDO2 was positively correlated with the Ki67 index and overall survival. The expression of IDO1/TDO was positively correlated with the expression of aquaporin 4 (AQP4), implying the potential involvement of IDO1/TDO in glioma cell motility. Mechanistically, we found that IDO1/TDO accounted for the release of Kyn, which activated AhR to promote cell motility via the Kyn-AhR-AQP4 signaling pathway in U87MG glioma cells. RY103, an IDO1/TDO dual inhibitor, could block the IDO1/TDO-Kyn-AhR-AQP4 signaling pathway and exert anti-glioma effects in GL261 orthotopic glioma mice. Together, our results showed that the IDO1/ TDO-Kyn-AhR-AQP4 signaling pathway is a new mechanism underlying the malignancy of gliomas, and suggest that both IDO1 and TDO might be valuable therapeutic targets for gliomas.

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“…Considering the work by our group and others in repeatedly demonstrating the remarkable pathogenic influence of IDO in subjects with GBM, the elucidation of its role and multi-variate functions may provide a path for enhancing the effectiveness of cancer immunotherapy against malignant glioma in the future. IDO mRNA is highly expressed in ≥90% of GBM patients presenting with wild-type isocitrate dehydrogenase (wtIDH) and while not normally expressed, is inducible among a majority of human GBM cell lines after exposure to proinflammatory cytokines (23,66,(107)(108)(109)(110). While TDO expression is expressed at an even higher mRNA level than IDO in patient-resected GBM (33,(109)(110)(111), IDO2 levels are negligible or undetectable at the mRNA level (65), despite an IHC-focused study suggesting high IDO2 protein levels in GBM (n = 52) (109); the latter of which likely reflects conclusions based on non-specific antibody immunostaining.…”

Section: Mouse Models For Studying Idomentioning

confidence: 99%

“…long after surgical resection of the tumor which may reflect a treatment-related effect rather than due to the malignancy itself. A recent study by Kesarwani et al provided additional insights into metabolomic profiling of newly diagnosed GBM (n = 80) and lower grade gliomas (LGG, n = 28) demonstrating that, GBM patients have increased intratumoral Trp and Kyn levels, but decreased KA as compared to LGG patients (110). Interestingly, Trp and Kyn accumulation was specific to classical and mesenchymal GBM subtypes, whereas KA accumulation was only evident in the proneural subtype.…”

Section: Mouse Models For Studying Idomentioning

confidence: 99%

Immunosuppressive IDO in Cancer: Mechanisms of Action, Animal Models, and Targeting Strategies

et al. 2020

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Tryptophan Metabolism Contributes to Radiation-Induced Immune Checkpoint Reactivation in Glioblastoma

Cited by 56 publications

References 49 publications

Integrative cross-platform analyses identify enhanced heterotrophy as a metabolic hallmark in glioblastoma

Integrative cross-platform analyses identify enhanced heterotrophy as a metabolic hallmark in glioblastoma

Both IDO1 and TDO contribute to the malignancy of gliomas via the Kyn–AhR–AQP4 signaling pathway

Immunosuppressive IDO in Cancer: Mechanisms of Action, Animal Models, and Targeting Strategies

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