Literature DB >> 25832654

NUAK2 Amplification Coupled with PTEN Deficiency Promotes Melanoma Development via CDK Activation.

Takeshi Namiki1, Tomonori Yaguchi2, Kenta Nakamura3, Julio C Valencia4, Sergio G Coelho4, Lanlan Yin4, Masakazu Kawaguchi4, Wilfred D Vieira4, Yasuhiko Kaneko5, Atsushi Tanemura6, Ichiro Katayama6, Hiroo Yokozeki7, Yutaka Kawakami8, Vincent J Hearing4.   

Abstract

The AMPK-related kinase NUAK2 has been implicated in melanoma growth and survival outcomes, but its therapeutic utility has yet to be confirmed. In this study, we show how its genetic amplification in PTEN-deficient melanomas may rationalize the use of CDK2 inhibitors as a therapeutic strategy. Analysis of array-CGH data revealed that PTEN deficiency is coupled tightly with genomic amplification encompassing the NUAK2 locus, a finding strengthened by immunohistochemical evidence that phospho-Akt overexpression was correlated with NUAK2 expression in clinical specimens of acral melanoma. Functional studies in melanoma cells showed that inactivation of the PI3K pathway upregulated p21 expression and reduced the number of cells in S phase. NUAK2 silencing and inactivation of the PI3K pathway efficiently controlled CDK2 expression, whereas CDK2 inactivation specifically abrogated the growth of NUAK2-amplified and PTEN-deficient melanoma cells. Immunohistochemical analyses confirmed an association of CDK2 expression with NUAK2 amplification and p-Akt expression in melanomas. Finally, pharmacologic inhibition of CDK2 was sufficient to suppress the growth of NUAK2-amplified and PTEN-deficient melanoma cells in vitro and in vivo. Overall, our results show how CDK2 blockade may offer a promising therapy for genetically defined melanomas, where NUAK2 is amplified and PTEN is deleted. ©2015 American Association for Cancer Research.

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Year:  2015        PMID: 25832654      PMCID: PMC4490056          DOI: 10.1158/0008-5472.CAN-13-3209

Source DB:  PubMed          Journal:  Cancer Res        ISSN: 0008-5472            Impact factor:   12.701


  27 in total

1.  Distinct sets of genetic alterations in melanoma.

Authors:  John A Curtin; Jane Fridlyand; Toshiro Kageshita; Hetal N Patel; Klaus J Busam; Heinz Kutzner; Kwang-Hyun Cho; Setsuya Aiba; Eva-Bettina Bröcker; Philip E LeBoit; Dan Pinkel; Boris C Bastian
Journal:  N Engl J Med       Date:  2005-11-17       Impact factor: 91.245

2.  Integrative genomic analyses identify MITF as a lineage survival oncogene amplified in malignant melanoma.

Authors:  Levi A Garraway; Hans R Widlund; Mark A Rubin; Gad Getz; Aaron J Berger; Sridhar Ramaswamy; Rameen Beroukhim; Danny A Milner; Scott R Granter; Jinyan Du; Charles Lee; Stephan N Wagner; Cheng Li; Todd R Golub; David L Rimm; Matthew L Meyerson; David E Fisher; William R Sellers
Journal:  Nature       Date:  2005-07-07       Impact factor: 49.962

3.  Germline p16 mutations in familial melanoma.

Authors:  C J Hussussian; J P Struewing; A M Goldstein; P A Higgins; D S Ally; M D Sheahan; W H Clark; M A Tucker; N C Dracopoli
Journal:  Nat Genet       Date:  1994-09       Impact factor: 38.330

4.  Critical role of CDK2 for melanoma growth linked to its melanocyte-specific transcriptional regulation by MITF.

Authors:  Jinyan Du; Hans R Widlund; Martin A Horstmann; Sridhar Ramaswamy; Ken Ross; Wade E Huber; Emi K Nishimura; Todd R Golub; David E Fisher
Journal:  Cancer Cell       Date:  2004-12       Impact factor: 31.743

5.  Overexpression of Akt converts radial growth melanoma to vertical growth melanoma.

Authors:  Baskaran Govindarajan; James E Sligh; Bethaney J Vincent; Meiling Li; Jeffrey A Canter; Brian J Nickoloff; Richard J Rodenburg; Jan A Smeitink; Larry Oberley; Yuping Zhang; Joyce Slingerland; Rebecca S Arnold; J David Lambeth; Cynthia Cohen; Lu Hilenski; Kathy Griendling; Marta Martínez-Diez; José M Cuezva; Jack L Arbiser
Journal:  J Clin Invest       Date:  2007-02-22       Impact factor: 14.808

Review 6.  Molecular pathogenesis of malignant melanoma: a different perspective from the studies of melanocytic nevus and acral melanoma.

Authors:  Minoru Takata; Hiroshi Murata; Toshiaki Saida
Journal:  Pigment Cell Melanoma Res       Date:  2009-09-25       Impact factor: 4.693

7.  Simultaneous suppression of MITF and BRAF V600E enhanced inhibition of melanoma cell proliferation.

Authors:  Kenji Kido; Hidetoshi Sumimoto; Sakiyo Asada; Starlyn M Okada; Tomonori Yaguchi; Naoshi Kawamura; Makoto Miyagishi; Toshiaki Saida; Yutaka Kawakami
Journal:  Cancer Sci       Date:  2009-06-29       Impact factor: 6.716

8.  Notch1 is an effector of Akt and hypoxia in melanoma development.

Authors:  Barbara Bedogni; James A Warneke; Brian J Nickoloff; Amato J Giaccia; Marianne Broome Powell
Journal:  J Clin Invest       Date:  2008-10-16       Impact factor: 14.808

9.  Pathological activation of KIT in metastatic tumors of acral and mucosal melanomas.

Authors:  Atsuko Ashida; Minoru Takata; Hiroshi Murata; Kenji Kido; Toshiaki Saida
Journal:  Int J Cancer       Date:  2009-02-15       Impact factor: 7.396

10.  Frequent somatic mutations of GNAQ in uveal melanoma and blue naevi.

Authors:  Catherine D Van Raamsdonk; Vladimir Bezrookove; Gary Green; Jürgen Bauer; Lona Gaugler; Joan M O'Brien; Elizabeth M Simpson; Gregory S Barsh; Boris C Bastian
Journal:  Nature       Date:  2008-12-10       Impact factor: 49.962
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  10 in total

1.  Expression of NUAK2 in gastric cancer tissue and its effects on the proliferation of gastric cancer cells.

Authors:  Lin Tang; Shu-Juan Tong; Zhen Zhan; Qian Wang; Yuan Tian; Feng Chen
Journal:  Exp Ther Med       Date:  2016-12-19       Impact factor: 2.447

Review 2.  Melanoma: Genetic Abnormalities, Tumor Progression, Clonal Evolution and Tumor Initiating Cells.

Authors:  Ugo Testa; Germana Castelli; Elvira Pelosi
Journal:  Med Sci (Basel)       Date:  2017-11-20

3.  Anti-hepatocellular carcinoma properties of the anti-alcoholism drug disulfiram discovered to enzymatically inhibit the AMPK-related kinase SNARK in vitro.

Authors:  Kaku Goto; Naoya Kato; Raymond T Chung
Journal:  Oncotarget       Date:  2016-11-15

4.  Transforming growth factor β (TGFβ) induces NUAK kinase expression to fine-tune its signaling output.

Authors:  Constantinos Kolliopoulos; Erna Raja; Masoud Razmara; Paraskevi Heldin; Carl-Henrik Heldin; Aristidis Moustakas; Lars P van der Heide
Journal:  J Biol Chem       Date:  2019-01-08       Impact factor: 5.157

5.  NUAK2 silencing inhibits the proliferation, migration and epithelial‑to‑mesenchymal transition of cervical cancer cells via upregulating CYFIP2.

Authors:  Yuxia Li; Xiaohui Song; Liping Liu; Lei Yue
Journal:  Mol Med Rep       Date:  2021-09-24       Impact factor: 2.952

Review 6.  NUAK1 and NUAK2 Fine-Tune TGF-β Signaling.

Authors:  Reinofke A J van de Vis; Aristidis Moustakas; Lars P van der Heide
Journal:  Cancers (Basel)       Date:  2021-07-05       Impact factor: 6.639

7.  KCTD12 promotes tumorigenesis by facilitating CDC25B/CDK1/Aurora A-dependent G2/M transition.

Authors:  Y Zhong; J Yang; W W Xu; Y Wang; C-C Zheng; B Li; Q-Y He
Journal:  Oncogene       Date:  2017-09-04       Impact factor: 9.867

8.  NUAK2 is a critical YAP target in liver cancer.

Authors:  Wei-Chien Yuan; Brian Pepe-Mooney; Giorgio G Galli; Michael T Dill; Hai-Tsang Huang; Mingfeng Hao; Yumeng Wang; Han Liang; Raffaele A Calogero; Fernando D Camargo
Journal:  Nat Commun       Date:  2018-11-16       Impact factor: 14.919

9.  Rhomboid domain-containing protein 1 promotes breast cancer progression by regulating the p-Akt and CDK2 levels.

Authors:  Xin Zhang; Yuechao Zhao; Changjun Wang; Hongge Ju; Wenjie Liu; Xiaohui Zhang; Shiying Miao; Linfang Wang; Qiang Sun; Wei Song
Journal:  Cell Commun Signal       Date:  2018-10-04       Impact factor: 5.712

10.  PKA Activates AMPK Through LKB1 Signaling in Follicular Thyroid Cancer.

Authors:  Suresh Kari; Vasyl V Vasko; Shivam Priya; Lawrence S Kirschner
Journal:  Front Endocrinol (Lausanne)       Date:  2019-11-08       Impact factor: 5.555
  10 in total

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