Mutations in the <i>DDR2</i> Kinase Gene Identify a Novel Therapeutic Target in Squamous Cell Lung Cancer

Peter S. Hammerman; Martin L. Sos; Alex H. Ramos; Chunxiao Xu; Amit Dutt; Wenjun Zhou; Lear E. Brace; Brittany A. Woods; Wenchu Lin; Jianming Zhang; Xianming Deng; Sang Min Lim; Stefanie Heynck; Martin Peifer; Jeffrey R. Simard; Michael S. Lawrence; Robert C. Onofrio; Helga B. Salvesen; Danila Seidel; Thomas Zander; Johannes M. Heuckmann; Alex Soltermann; Holger Moch; Mirjam Koker; Frauke Leenders; Franziska Gabler; Silvia Querings; Sascha Ansén; Élisabeth Brambilla; Christian Brambilla; Philippe Lorimier; Odd Terje Brustugun; Åslaug Helland; Iver Petersen; Joachim H. Clement; Harry J.M. Groen; Wim Timens; Hannie Sietsma; Erich Stoelben; Jürgen Wolf; David G. Beer; Ming‐Sound Tsao; Megan Hanna; Charlie Hatton; Michael J. Eck; Pasi A. Jänne; Bruce E. Johnson; Wendy Winckler; Heidi Greulich; Adam J. Bass; Jeonghee Cho; Daniel Rauh; Nathanael S. Gray; Kwok‐Kin Wong; Eric B. Haura; Roman K. Thomas; Matthew Meyerson

doi:10.1158/2159-8274.cd-11-0005

Mutations in the <i>DDR2</i> Kinase Gene Identify a Novel Therapeutic Target in Squamous Cell Lung Cancer

Peter S. Hammerman(Max Planck Society), Martin L. Sos(Max Planck Society), Alex H. Ramos(Max Planck Society), Chunxiao Xu(Max Planck Society), Amit Dutt(Max Planck Society), Wenjun Zhou(Max Planck Society), Lear E. Brace(Max Planck Society), Brittany A. Woods(Max Planck Society), Wenchu Lin(Max Planck Society), Jianming Zhang(Max Planck Society), Xianming Deng(Max Planck Society), Sang Min Lim(Max Planck Society), Stefanie Heynck(Max Planck Society), Martin Peifer(Max Planck Society), Jeffrey R. Simard(Max Planck Society), Michael S. Lawrence(Max Planck Society), Robert C. Onofrio(Max Planck Society), Helga B. Salvesen(Max Planck Society), Danila Seidel(Max Planck Society), Thomas Zander(Max Planck Society), Johannes M. Heuckmann(Max Planck Society), Alex Soltermann(Max Planck Society), Holger Moch(Max Planck Society), Mirjam Koker(Max Planck Society), Frauke Leenders(Max Planck Society), Franziska Gabler(Max Planck Society), Silvia Querings(Max Planck Society), Sascha Ansén(Max Planck Society), Élisabeth Brambilla(Max Planck Society), Christian Brambilla(Max Planck Society), Philippe Lorimier(Max Planck Society), Odd Terje Brustugun(Max Planck Society), Åslaug Helland(Max Planck Society), Iver Petersen(Max Planck Society), Joachim H. Clement(Max Planck Society), Harry J.M. Groen(Max Planck Society), Wim Timens(Max Planck Society), Hannie Sietsma(Max Planck Society), Erich Stoelben(Max Planck Society), Jürgen Wolf(Max Planck Society), David G. Beer(Max Planck Society), Ming‐Sound Tsao(Max Planck Society), Megan Hanna(Max Planck Society), Charlie Hatton(Max Planck Society), Michael J. Eck(Max Planck Society), Pasi A. Jänne(Max Planck Society), Bruce E. Johnson(Max Planck Society), Wendy Winckler(Max Planck Society), Heidi Greulich(Max Planck Society), Adam J. Bass(Max Planck Society), Jeonghee Cho(Max Planck Society), Daniel Rauh(Max Planck Society), Nathanael S. Gray(Max Planck Society), Kwok‐Kin Wong(Max Planck Society), Eric B. Haura(Max Planck Society), Roman K. Thomas(Max Planck Society), Matthew Meyerson(Max Planck Society)

Cancer Discovery

April 8, 2011

10.1158/2159-8274.cd-11-0005

Cited by 472Open Access

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Abstract

UNLABELLED: While genomically targeted therapies have improved outcomes for patients with lung adenocarcinoma, little is known about the genomic alterations which drive squamous cell lung cancer. Sanger sequencing of the tyrosine kinome identified mutations in the DDR2 kinase gene in 3.8% of squamous cell lung cancers and cell lines. Squamous lung cancer cell lines harboring DDR2 mutations were selectively killed by knock-down of DDR2 by RNAi or by treatment with the multi-targeted kinase inhibitor dasatinib. Tumors established from a DDR2 mutant cell line were sensitive to dasatinib in xenograft models. Expression of mutated DDR2 led to cellular transformation which was blocked by dasatinib. A squamous cell lung cancer patient with a response to dasatinib and erlotinib treatment harbored a DDR2 kinase domain mutation. These data suggest that gain-of-function mutations in DDR2 are important oncogenic events and are amenable to therapy with dasatinib. As dasatinib is already approved for use, these findings could be rapidly translated into clinical trials. SIGNIFICANCE: DDR2 mutations are present in 4% of lung SCCs, and DDR2 mutations are associated with sensitivity to dasatinib. These findings provide a rationale for designing clinical trials with the FDA-approved drug dasatinib in patients with lung SCCs.

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