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Literature DB >> 29525205

The Genomic Landscape and Pharmacogenomic Interactions of Clock Genes in Cancer Chronotherapy.

Youqiong Ye¹, Yu Xiang¹, Fatma Muge Ozguc¹, Yoonjin Kim¹, Chun-Jie Liu², Peter K Park³, Qingsong Hu³, Lixia Diao⁴, Yanyan Lou⁵, Chunru Lin⁶, An-Yuan Guo⁷, Bingying Zhou⁸, Li Wang⁸, Zheng Chen¹, Joseph S Takahashi⁹, Gordon B Mills¹⁰, Seung-Hee Yoo¹¹, Leng Han¹².

Abstract

Cancer chronotherapy, treatment at specific times during circadian rhythms, endeavors to optimize anti-tumor effects and to lower toxicity. However, comprehensive characterization of clock genes and their clinical relevance in cancer is lacking. We systematically characterized the alterations of clock genes across 32 cancer types by analyzing data from The Cancer Genome Atlas, Cancer Therapeutics Response Portal, and The Genomics of Drug Sensitivity in Cancer databases. Expression alterations of clock genes are associated with key oncogenic pathways, patient survival, tumor stage, and subtype in multiple cancer types. Correlations between expression of clock genes and of other genes in the genome were altered in cancerous versus normal tissues. We identified interactions between clock genes and clinically actionable genes by analyzing co-expression, protein-protein interaction, and chromatin immunoprecipitation sequencing data and also found that clock gene expression is correlated to anti-cancer drug sensitivity in cancer cell lines. Our study provides a comprehensive analysis of the circadian clock across different cancer types and highlights potential clinical utility of cancer chronotherapy.

Entities: Chemical

Keywords: cancer; chronotherapy; circadian rhythms; clinical actionable genes; clock genes; drug; pharmacogenomics

Mesh：

Year: 2018 PMID： 29525205 PMCID： PMC6056007 DOI： 10.1016/j.cels.2018.01.013

Source DB: PubMed Journal: Cell Syst ISSN： 2405-4712 Impact factor: 10.304

76 in total

1. Mammalian Cry1 and Cry2 are essential for maintenance of circadian rhythms.

Authors: G T van der Horst; M Muijtjens; K Kobayashi; R Takano; S Kanno; M Takao; J de Wit; A Verkerk; A P Eker; D van Leenen; R Buijs; D Bootsma; J H Hoeijmakers; A Yasui
Journal: Nature Date: 1999-04-15 Impact factor: 49.962

2. A Patient-Derived, Pan-Cancer EMT Signature Identifies Global Molecular Alterations and Immune Target Enrichment Following Epithelial-to-Mesenchymal Transition.

Authors: Milena P Mak; Pan Tong; Lixia Diao; Robert J Cardnell; Don L Gibbons; William N William; Ferdinandos Skoulidis; Edwin R Parra; Jaime Rodriguez-Canales; Ignacio I Wistuba; John V Heymach; John N Weinstein; Kevin R Coombes; Jing Wang; Lauren Averett Byers
Journal: Clin Cancer Res Date: 2015-09-29 Impact factor: 12.531

3. ARNTL2 and SERPINE1: potential biomarkers for tumor aggressiveness in colorectal cancer.

Authors: Gianluigi Mazzoccoli; Valerio Pazienza; Anna Panza; Maria Rosa Valvano; Giorgia Benegiamo; Manlio Vinciguerra; Angelo Andriulli; Ada Piepoli
Journal: J Cancer Res Clin Oncol Date: 2011-12-24 Impact factor: 4.553

4. The circadian gene NPAS2, a putative tumor suppressor, is involved in DNA damage response.

Authors: Aaron E Hoffman; Tongzhang Zheng; Yue Ba; Yong Zhu
Journal: Mol Cancer Res Date: 2008-09 Impact factor: 5.852

Review 5. Circadian timing in cancer treatments.

Authors: Francis Lévi; Alper Okyar; Sandrine Dulong; Pasquale F Innominato; Jean Clairambault
Journal: Annu Rev Pharmacol Toxicol Date: 2010 Impact factor: 13.820

Review 6. Metabolism and cancer: the circadian clock connection.

Authors: Saurabh Sahar; Paolo Sassone-Corsi
Journal: Nat Rev Cancer Date: 2009-12 Impact factor: 60.716

7. Comprehensive Characterization of Alternative Polyadenylation in Human Cancer.

Authors: Yu Xiang; Youqiong Ye; Yanyan Lou; Yang Yang; Chunyan Cai; Zhao Zhang; Tingting Mills; Ning-Yuan Chen; Yoonjin Kim; Fatma Muge Ozguc; Lixia Diao; Harry Karmouty-Quintana; Yang Xia; Rodney E Kellems; Zheng Chen; Michael R Blackburn; Seung-Hee Yoo; Ann-Bin Shyu; Gordon B Mills; Leng Han
Journal: J Natl Cancer Inst Date: 2018-04-01 Impact factor: 13.506

Review 8. Molecular components of the mammalian circadian clock.

Authors: Caroline H Ko; Joseph S Takahashi
Journal: Hum Mol Genet Date: 2006-10-15 Impact factor: 6.150

9. Cell type-specific functions of period genes revealed by novel adipocyte and hepatocyte circadian clock models.

Authors: Chidambaram Ramanathan; Haiyan Xu; Sanjoy K Khan; Yang Shen; Paula J Gitis; David K Welsh; John B Hogenesch; Andrew C Liu
Journal: PLoS Genet Date: 2014-04-03 Impact factor: 5.917

10. Whole-exome sequencing and clinical interpretation of formalin-fixed, paraffin-embedded tumor samples to guide precision cancer medicine.

Authors: Eliezer M Van Allen; Nikhil Wagle; Petar Stojanov; Danielle L Perrin; Kristian Cibulskis; Sara Marlow; Judit Jane-Valbuena; Dennis C Friedrich; Gregory Kryukov; Scott L Carter; Aaron McKenna; Andrey Sivachenko; Mara Rosenberg; Adam Kiezun; Douglas Voet; Michael Lawrence; Lee T Lichtenstein; Jeff G Gentry; Franklin W Huang; Jennifer Fostel; Deborah Farlow; David Barbie; Leena Gandhi; Eric S Lander; Stacy W Gray; Steven Joffe; Pasi Janne; Judy Garber; Laura MacConaill; Neal Lindeman; Barrett Rollins; Philip Kantoff; Sheila A Fisher; Stacey Gabriel; Gad Getz; Levi A Garraway
Journal: Nat Med Date: 2014-05-18 Impact factor: 53.440

61 in total

Review 1. Interplay between Circadian Clock and Cancer: New Frontiers for Cancer Treatment.

Authors: Gabriele Sulli; Michael Tun Yin Lam; Satchidananda Panda
Journal: Trends Cancer Date: 2019-08-03

2. Targeting Glioblastoma Stem Cells through Disruption of the Circadian Clock.

Authors: Zhen Dong; Guoxin Zhang; Meng Qu; Ryan C Gimple; Qiulian Wu; Zhixin Qiu; Briana C Prager; Xiuxing Wang; Leo J Y Kim; Andrew R Morton; Deobrat Dixit; Wenchao Zhou; Haidong Huang; Bin Li; Zhe Zhu; Shideng Bao; Stephen C Mack; Lukas Chavez; Steve A Kay; Jeremy N Rich
Journal: Cancer Discov Date: 2019-08-27 Impact factor: 39.397

The Genomic Landscape and Pharmacogenomic Interactions of Clock Genes in Cancer Chronotherapy.

1. Mammalian Cry1 and Cry2 are essential for maintenance of circadian rhythms.

2. A Patient-Derived, Pan-Cancer EMT Signature Identifies Global Molecular Alterations and Immune Target Enrichment Following Epithelial-to-Mesenchymal Transition.

3. ARNTL2 and SERPINE1: potential biomarkers for tumor aggressiveness in colorectal cancer.

4. The circadian gene NPAS2, a putative tumor suppressor, is involved in DNA damage response.

Review 5. Circadian timing in cancer treatments.

Review 6. Metabolism and cancer: the circadian clock connection.

7. Comprehensive Characterization of Alternative Polyadenylation in Human Cancer.

Review 8. Molecular components of the mammalian circadian clock.

9. Cell type-specific functions of period genes revealed by novel adipocyte and hepatocyte circadian clock models.

10. Whole-exome sequencing and clinical interpretation of formalin-fixed, paraffin-embedded tumor samples to guide precision cancer medicine.

Review 1. Interplay between Circadian Clock and Cancer: New Frontiers for Cancer Treatment.

2. Targeting Glioblastoma Stem Cells through Disruption of the Circadian Clock.

3. Radiation chronotherapy-clinical impact of treatment time-of-day: a systematic review.

Review 4. The importance of determining circadian parameters in pharmacological studies.

5. tRic: a user-friendly data portal to explore the expression landscape of tRNAs in human cancers.

6. Noncoding Variants Connect Enhancer Dysregulation with Nuclear Receptor Signaling in Hematopoietic Malignancies.

Review 7. Metabolic rivalry: circadian homeostasis and tumorigenesis.

Review 8. Circadian Clocks and Cancer: Timekeeping Governs Cellular Metabolism.

Review 9. Exploring the link between chronobiology and drug delivery: effects on cancer therapy.

10. CRY2 missense mutations suppress P53 and enhance cell growth.