Literature DB >> 27620277

Genomic Amplification of CD274 (PD-L1) in Small-Cell Lung Cancer.

Julie George1, Motonobu Saito2,3, Koji Tsuta4, Reika Iwakawa2, Kouya Shiraishi2, Andreas H Scheel5, Shinsuke Uchida4, Shun-Ichi Watanabe6, Ryo Nishikawa7, Masayuki Noguchi8, Martin Peifer9, Se Jin Jang10, Iver Petersen11, Reinhard Büttner5, Curtis C Harris12, Jun Yokota2,13, Roman K Thomas14,5,15, Takashi Kohno16,17.   

Abstract

Purpose: Programmed death ligand-1 (PD-L1), encoded by the CD274 gene, is a target for immune checkpoint blockade; however, little is known about genomic CD274 alterations. A subset of small-cell lung cancer (SCLC) exhibits increased copy number of chromosome 9p24, on which CD274 resides; however, most SCLCs show low expression of PD-L1. We therefore examined whether CD274 is a target of recurrent genomic alterations.Experimental Design: We examined somatic copy number alterations in two patient cohorts by quantitative real-time PCR in 72 human SCLC cases (cohort 1) and SNP array analysis in 138 human SCLC cases (cohort 2). Whole-genome sequencing revealed the detailed genomic structure underlying focal amplification. PD-L1 expression in amplified cases from cohorts 1 and 2 was further examined by transcriptome sequencing and immunohistochemical (IHC) staining.
Results: By examining somatic copy number alterations in two cohorts of primary human SCLC specimens, we observed 9p24 copy number gains (where CD274 resides) and focal, high-level amplification of CD274 We found evidence for genomic targeting of CD274, suggesting selection during oncogenic transformation. CD274 amplification was caused by genomic rearrangements not affecting the open reading frame, thus leading to massively increased CD274 transcripts and high level expression of PD-L1.Conclusions: A subset (4/210, 1.9%) of human SCLC patient cases exhibits massive expression of PD-L1 caused by focal amplification of CD274 Such tumors may be particularly susceptible to immune checkpoint blockade. Clin Cancer Res; 23(5); 1220-6. ©2016 AACR. ©2016 American Association for Cancer Research.

Entities:  

Mesh:

Substances:

Year:  2016        PMID: 27620277      PMCID: PMC6329376          DOI: 10.1158/1078-0432.CCR-16-1069

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


  47 in total

1.  Next-Generation Sequencing-Based Assessment of JAK2, PD-L1, and PD-L2 Copy Number Alterations at 9p24.1 in Breast Cancer: Potential Implications for Clinical Management.

Authors:  Sounak Gupta; Chad M Vanderbilt; Paolo Cotzia; Javier A Arias-Stella; Jason C Chang; Ahmet Zehir; Ryma Benayed; Khedouja Nafa; Pedram Razavi; David M Hyman; José Baselga; Michael F Berger; Marc Ladanyi; Maria E Arcila; Dara S Ross
Journal:  J Mol Diagn       Date:  2018-12-18       Impact factor: 5.568

2.  EPB41L5 is Associated With the Metastatic Potential of Low-grade Pancreatic Neuroendocrine Tumors.

Authors:  James Saller; Shabnam Seydafkan; Mohammad Shahid; Manoj Gadara; Mauro Cives; Steven A Eschrich; David Boulware; Jonathan R Strosberg; Nasir Aejaz; Domenico Coppola
Journal:  Cancer Genomics Proteomics       Date:  2019 Sep-Oct       Impact factor: 4.069

3.  The local immune landscape determines tumor PD-L1 heterogeneity and sensitivity to therapy.

Authors:  Yuan Wei; Qiyi Zhao; Zhiliang Gao; Xiang-Ming Lao; Wei-Ming Lin; Dong-Ping Chen; Ming Mu; Chun-Xiang Huang; Zheng-Yu Liu; Bo Li; Limin Zheng; Dong-Ming Kuang
Journal:  J Clin Invest       Date:  2019-05-21       Impact factor: 14.808

4.  Dual Checkpoint Blockade in a Neuroendocrine Carcinoma With Dual PD-L1/PD-L2 Amplification and High Tumor Mutational Burden.

Authors:  Jun Gong; Sandip Patel; Jacob J Adashek; David Frishberg; Michelle Guan; Veronica R Placencio-Hickok; Alexandra Gangi; Gillian Gresham; Richard Tuli; Young K Chae; Razelle Kurzrock; Andrew E Hendifar
Journal:  JCO Precis Oncol       Date:  2020-05-15

5.  Identification of candidate responders for anti-PD-L1/PD-1 immunotherapy, Rova-T therapy, or EZH2 inhibitory therapy in small-cell lung cancer.

Authors:  Motonobu Saito; Katsuharu Saito; Kouya Shiraishi; Daichi Maeda; Hiroyuki Suzuki; Yoshihiro Minamiya; Koji Kono; Takashi Kohno; Akiteru Goto
Journal:  Mol Clin Oncol       Date:  2017-12-12

6.  Selective sensitivity of EZH2 inhibitors based on synthetic lethality in ARID1A-deficient gastric cancer.

Authors:  Leo Yamada; Motonobu Saito; Aung Kyi Thar Min; Katsuharu Saito; Mai Ashizawa; Koji Kase; Shotaro Nakajima; Hisashi Onozawa; Hirokazu Okayama; Hisahito Endo; Shotaro Fujita; Wataru Sakamoto; Zenichiro Saze; Tomoyuki Momma; Kosaku Mimura; Shinji Ohki; Koji Kono
Journal:  Gastric Cancer       Date:  2020-06-06       Impact factor: 7.370

7.  Oncolytic virotherapy for small-cell lung cancer induces immune infiltration and prolongs survival.

Authors:  Patrick Kellish; Daniil Shabashvili; Masmudur M Rahman; Akbar Nawab; Maria V Guijarro; Min Zhang; Chunxia Cao; Nissin Moussatche; Theresa Boyle; Scott Antonia; Mary Reinhard; Connor Hartzell; Michael Jantz; Hiren J Mehta; Grant McFadden; Frederic J Kaye; Maria Zajac-Kaye
Journal:  J Clin Invest       Date:  2019-04-29       Impact factor: 14.808

Review 8.  Genomics of High-Grade Neuroendocrine Neoplasms: Well-Differentiated Neuroendocrine Tumor with High-Grade Features (G3 NET) and Neuroendocrine Carcinomas (NEC) of Various Anatomic Sites.

Authors:  Silvia Uccella; Stefano La Rosa; Jasna Metovic; Deborah Marchiori; Jean-Yves Scoazec; Marco Volante; Ozgur Mete; Mauro Papotti
Journal:  Endocr Pathol       Date:  2021-01-12       Impact factor: 3.943

9.  Profiling targetable immune checkpoints in osteosarcoma.

Authors:  Troy A McEachron; Timothy J Triche; Laurie Sorenson; David M Parham; John D Carpten
Journal:  Oncoimmunology       Date:  2018-09-11       Impact factor: 8.110

Review 10.  Regulation and Function of the PD-L1 Checkpoint.

Authors:  Chong Sun; Riccardo Mezzadra; Ton N Schumacher
Journal:  Immunity       Date:  2018-03-20       Impact factor: 31.745
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.