Wild-Type IDH Enzymes as Actionable Targets for Cancer Therapy
Abstract
:1. Isocitrate Dehydrogenase Enzymes
2. IDHs Genetic Alterations in Cancer
3. IDHs Genetic Alterations in Genetic Diseases
4. Downregulation of Wild-Type IDH1 in Cancers
5. Overexpression of Wild-Type IDH1 in Cancers
6. Downregulation of Wild-Type IDH2 in Cancers
7. Overexpression of Wild-Type IDH2 in Cancers
8. Wild-Type IDH3 Downregulation/Overexpression in Cancer
9. IDH Inhibition in Cancer Enhances Responsiveness to Canonical Therapies
9.1. Chemotherapy
9.2. Radiotherapy
9.3. Photodynamic Therapy
9.4. Small Molecule Inhibitors
10. Concluding Remarks and Future Perspectives
Author Contributions
Acknowledgments
Conflicts of Interest
References
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IDH1 mut. | IDH2 mut. | IDH3 mut. |
---|---|---|
Ollier disease [24,47,50] | Ollier disease [24,47] | Retinitis pigmentosa [59,60] |
Maffucci syndrome [24,47,50] | Maffucci syndrome [47] | |
Spondyloenchondromatosis with D-2-hydroxyglutaric aciduria [55,57] | D-2-hydroxyglutaric aciduria [51,55] |
IDH1 Levels | ||
Downregulated | Overexpressed | Not Specified |
Early skin tumorigenesis (OS) [61] | Lung squamous cell carcinoma (OG) [62,65,66] | Acute myeloid leukemia (OG) [68] |
Lung adenocarcinoma (OG) [62,63,65,66] | ||
Primary glioblastoma (OG) [65,67] | ||
Angioimmunoblastic lymphoma [65] | ||
Anaplastic large cell lymphoma [65] | ||
Peripheral T cell lymphoma [65] | ||
Diffuse large B cell lymphoma (OG) [65] | ||
Pancreatic ductal adenocarcinoma (OG) [69] | ||
Imbalance of IDH1/2 in colorectal cancer (OG) [86] | ||
IDH2 Levels | ||
Downregulated | Overexpressed | Not Specified |
Melanoma (OS) [70] | Esophageal squamous cell cancer (OG) [78] | Lewis lung carcinoma (OS) [79] |
Kidney cancer [64] | Lung cancer (OG) [64] | Pancreatic cancer (OG) [64] |
Hepatocellular carcinoma (OS) [71,72] | Ovarian cancer [64,80] | |
Gastric cancer (OS) [64,73] | Endometroid carcinomas of the endometrium vs. endometroid carcinomas of the ovary [81] | |
Glioblastoma [75] | Prostate cancer [82] | |
Grade III glioma [75] | Testis cancer [82] | |
Mantle cell lymphoma (OS) [77] | Eye cancer [82] | |
Chronic lymphocytic leukemia [77] | Nervous cancer [82] | |
Acute lymphocytic leukemia [77] | Breast cancer (OG/OS) [64,82,83,84] | |
Burkitt’s lymphoma (OS) [77] | Infiltrating colorectal cancer (OG) [85] | |
High-risk luminal B vs. low-risk luminal A breast cancer [83] | ||
In situ colorectal cancer [85] | ||
Imbalance of IDH1/2 in colorectal cancer (OG) [86] | ||
IDH3 Levels | ||
Downregulated | Overexpressed | Not Specified |
Lung cancer (OG) [88] | ||
Breast cancer (OG) [88] | ||
Cervical adenocarcinoma (OG) [88] | ||
Embryonic carcinoma (OG) [89] |
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Bergaggio, E.; Piva, R. Wild-Type IDH Enzymes as Actionable Targets for Cancer Therapy. Cancers 2019, 11, 563. https://doi.org/10.3390/cancers11040563
Bergaggio E, Piva R. Wild-Type IDH Enzymes as Actionable Targets for Cancer Therapy. Cancers. 2019; 11(4):563. https://doi.org/10.3390/cancers11040563
Chicago/Turabian StyleBergaggio, Elisa, and Roberto Piva. 2019. "Wild-Type IDH Enzymes as Actionable Targets for Cancer Therapy" Cancers 11, no. 4: 563. https://doi.org/10.3390/cancers11040563
APA StyleBergaggio, E., & Piva, R. (2019). Wild-Type IDH Enzymes as Actionable Targets for Cancer Therapy. Cancers, 11(4), 563. https://doi.org/10.3390/cancers11040563