Literature DB >> 24097869

Loss of NAPRT1 expression by tumor-specific promoter methylation provides a novel predictive biomarker for NAMPT inhibitors.

David S Shames1, Kristi Elkins, Kimberly Walter, Thomas Holcomb, Pan Du, Dane Mohl, Yang Xiao, Thinh Pham, Peter M Haverty, Bianca Liederer, Xiaorong Liang, Robert L Yauch, Thomas O'Brien, Richard Bourgon, Hartmut Koeppen, Lisa D Belmont.   

Abstract

PURPOSE: We sought to identify predictive biomarkers for a novel nicotinamide phosphoribosyltransferase (NAMPT) inhibitor. EXPERIMENTAL
DESIGN: We use a NAMPT inhibitor, GNE-617, to evaluate nicotinic acid rescue status in a panel of more than 400 cancer cell lines. Using correlative analysis and RNA interference (RNAi), we identify a specific biomarker for nicotinic acid rescue status. We next determine the mechanism of regulation of expression of the biomarker. Finally, we develop immunohistochemical (IHC) and DNA methylation assays and evaluate cancer tissue for prevalence of the biomarker across indications.
RESULTS: Nicotinate phosphoribosyltransferase (NAPRT1) is necessary for nicotinic acid rescue and its expression is the major determinant of rescue status. We demonstrate that NAPRT1 promoter methylation accounts for NAPRT1 deficiency in cancer cells, and NAPRT1 methylation is predictive of rescue status in cancer cell lines. Bisulfite next-generation sequencing mapping of the NAPRT1 promoter identified tumor-specific sites of NAPRT1 DNA methylation and enabled the development of a quantitative methylation-specific PCR (QMSP) assay suitable for use on archival formalin-fixed paraffin-embedded tumor tissue.
CONCLUSIONS: Tumor-specific promoter hypermethylation of NAPRT1 inactivates one of two NAD salvage pathways, resulting in synthetic lethality with the coadministration of a NAMPT inhibitor. NAPRT1 expression is lost due to promoter hypermethylation in most cancer types evaluated at frequencies ranging from 5% to 65%. NAPRT1-specific immunohistochemical or DNA methylation assays can be used on archival formalin paraffin-embedded cancer tissue to identify patients likely to benefit from coadministration of a Nampt inhibitor and nicotinic acid. ©2013 AACR.

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Year:  2013        PMID: 24097869     DOI: 10.1158/1078-0432.CCR-13-1186

Source DB:  PubMed          Journal:  Clin Cancer Res        ISSN: 1078-0432            Impact factor:   12.531


  32 in total

Review 1.  Subcellular compartmentalization of NAD+ and its role in cancer: A sereNADe of metabolic melodies.

Authors:  Yi Zhu; Jiaqi Liu; Joun Park; Priyamvada Rai; Rong G Zhai
Journal:  Pharmacol Ther       Date:  2019-04-08       Impact factor: 12.310

2.  Selective targeting of NAMPT by KPT-9274 in acute myeloid leukemia.

Authors:  Shaneice R Mitchell; Karilyn Larkin; Nicole R Grieselhuber; Tzung-Huei Lai; Matthew Cannon; Shelley Orwick; Pratibha Sharma; Yerdanose Asemelash; Pu Zhang; Virginia M Goettl; Larry Beaver; Alice Mims; Vinay K Puduvalli; James S Blachly; Amy Lehman; Bonnie Harrington; Sally Henderson; Justin T Breitbach; Katie E Williams; Shuai Dong; Erkan Baloglu; William Senapedis; Karl Kirschner; Deepa Sampath; Rosa Lapalombella; John C Byrd
Journal:  Blood Adv       Date:  2019-02-12

3.  Anti-Cancer Activity of PAK4/NAMPT Inhibitor and Programmed Cell Death Protein-1 Antibody in Kidney Cancer.

Authors:  Josephine F Trott; Omran Abu Aboud; Bridget McLaughlin; Katie L Anderson; Jaime F Modiano; Kyoungmi Kim; Kuang-Yu Jen; William Senapedis; Hua Chang; Yosef Landesman; Erkan Baloglu; Roberto Pili; Robert H Weiss
Journal:  Kidney360       Date:  2020-05-28

4.  Targeting nicotinamide adenosine dinucleotide (NAD) in diffuse gliomas.

Authors:  Jing Wu
Journal:  Neuro Oncol       Date:  2022-02-01       Impact factor: 12.300

5.  Targeting the vulnerability to NAD+ depletion in B-cell acute lymphoblastic leukemia.

Authors:  S Takao; W Chien; V Madan; D-C Lin; L-W Ding; Q-Y Sun; A Mayakonda; M Sudo; L Xu; Y Chen; Y-Y Jiang; S Gery; M Lill; E Park; W Senapedis; E Baloglu; M Müschen; H P Koeffler
Journal:  Leukemia       Date:  2017-09-14       Impact factor: 11.528

6.  Extreme Vulnerability of IDH1 Mutant Cancers to NAD+ Depletion.

Authors:  Kensuke Tateishi; Hiroaki Wakimoto; A John Iafrate; Shota Tanaka; Franziska Loebel; Nina Lelic; Dmitri Wiederschain; Olivier Bedel; Gejing Deng; Bailin Zhang; Timothy He; Xu Shi; Robert E Gerszten; Yiyun Zhang; Jing-Ruey J Yeh; William T Curry; Dan Zhao; Sudhandra Sundaram; Fares Nigim; Mara V A Koerner; Quan Ho; David E Fisher; Elisabeth M Roider; Lajos V Kemeny; Yardena Samuels; Keith T Flaherty; Tracy T Batchelor; Andrew S Chi; Daniel P Cahill
Journal:  Cancer Cell       Date:  2015-12-14       Impact factor: 31.743

7.  Myc-Driven Glycolysis Is a Therapeutic Target in Glioblastoma.

Authors:  Kensuke Tateishi; A John Iafrate; Quan Ho; William T Curry; Tracy T Batchelor; Keith T Flaherty; Maristela L Onozato; Nina Lelic; Sudhandra Sundaram; Daniel P Cahill; Andrew S Chi; Hiroaki Wakimoto
Journal:  Clin Cancer Res       Date:  2016-04-13       Impact factor: 12.531

Review 8.  Advances in NAD-Lowering Agents for Cancer Treatment.

Authors:  Moustafa S Ghanem; Fiammetta Monacelli; Alessio Nencioni
Journal:  Nutrients       Date:  2021-05-14       Impact factor: 5.717

9.  Targeting the NAD Salvage Synthesis Pathway as a Novel Therapeutic Strategy for Osteosarcomas with Low NAPRT Expression.

Authors:  Natasja Franceschini; Jan Oosting; Maud Tamsma; Bertine Niessen; Inge Briaire-de Bruijn; Brendy van den Akker; Alwine B Kruisselbrink; Ieva Palubeckaitė; Judith V M G Bovée; Anne-Marie Cleton-Jansen
Journal:  Int J Mol Sci       Date:  2021-06-10       Impact factor: 5.923

10.  Anti-tumor NAMPT inhibitor, KPT-9274, mediates gender-dependent murine anemia and nephrotoxicity by regulating SIRT3-mediated SOD deacetylation.

Authors:  Shaneice Mitchell; Pu Zhang; John C Byrd; Rosa Lapalombella; Matthew Cannon; Larry Beaver; Amy Lehman; Bonnie Harrington; Deepa Sampath
Journal:  J Hematol Oncol       Date:  2021-06-29       Impact factor: 23.168
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