Your search keyword '"Stephen J. Murphy"' showing total 2 results

1. Identification of Independent Primary Tumors and Intrapulmonary Metastases Using DNA Rearrangements in Non–Small-Cell Lung Cancer

Author

Tobias Peikert, Benjamin R. Kipp, Simone Terra, George Vasmatzis, Marie Christine Aubry, Geoffrey C. Halling, Ping Yang, Michael K. Asiedu, Travis M. Drucker, Stephen J. Murphy, Faye R. Harris, Sarah H. Johnson, Dennis A. Wigle, and Eunhee S. Yi

Subjects

Gene Rearrangement, Cancer Research, Pathology, medicine.medical_specialty, Lung Neoplasms, Gene Dosage, Laser Capture Microdissection, ORIGINAL REPORTS, Sequence Analysis, DNA, Gene rearrangement, Biology, medicine.disease, DNA sequencing, law.invention, Metastasis, genomic DNA, Oncology, law, Carcinoma, Non-Small-Cell Lung, Carcinoma, medicine, Humans, Lung cancer, Polymerase chain reaction, Laser capture microdissection

Abstract

Purpose Distinguishing independent primary tumors from intrapulmonary metastases in non–small-cell carcinoma remains a clinical dilemma with significant clinical implications. Using next-generation DNA sequencing, we developed a chromosomal rearrangement–based approach to differentiate multiple primary tumors from metastasis. Methods Tumor specimens from patients with known independent primary tumors and metastatic lesions were used for lineage test development, which was then applied to multifocal tumors. Laser capture microdissection was performed separately for each tumor. Genomic DNA was isolated using direct in situ whole-genome amplification methodology, and next-generation sequencing was performed using an Illumina mate-pair library protocol. Sequence reads were mapped to the human genome, and primers spanning the fusion junctions were used for validation polymerase chain reaction. Results A total of 41 tumor samples were sequenced (33 adenocarcinomas [ADs] and eight squamous cell carcinomas [SQCCs]), with a range of three to 276 breakpoints per tumor identified. Lung tumors predicted to be independent primary tumors based on different histologic subtype did not share any genomic rearrangements. In patients with lung primary tumors and paired distant metastases, shared rearrangements were identified in all tumor pairs, emphasizing the patient specificity of identified breakpoints. Multifocal AD and SQCC samples were reviewed independently by two pulmonary pathologists. Concordance between histology and genomic data occurred in the majority of samples. Discrepant tumor samples were resolved by genome sequencing. Conclusion A diagnostic lineage test based on genomic rearrangements from mate-pair sequencing demonstrates promise for distinguishing independent primary from metastatic disease in lung cancer.

Published

2014

2. Genomic rearrangements in lung adenocarcinoma: Lineage relationships between the in situ and invasive components

Author

Ping Yang, Dennis A. Wigle, Faye R. Harris, Stephen J. Murphy, Bruce W. Eckloff, Sarah H. Johnson, Marie-Christine Aubry, Joema Felipe Lima, Tobias Peikert, Charlie T. Seto, George Vasmatzis, and Michael K. Asiedu

Subjects

In situ, Cancer Research, Lung, medicine.anatomical_structure, Lineage (genetic), Oncology, business.industry, medicine, Cancer research, Adenocarcinoma, medicine.disease, business

Abstract

7568 Background: The molecular events in the initiation and progression of invasive lung adenocarcinoma remain poorly characterized. These tumors are thought to develop through an adenocarcinoma in situ (AIS), minimally invasive adenocarcinoma (MIA), invasive adenocarcinoma (AD) sequence. The goal of our study was to assess lineage relationships between in situ and invasive components within adenocarcinomas with prominent lepidic growth patterns. Methods: Frozen tissue from fourteen lung adenocarcinomas with mixtures of AD together with an adjacent in situ component (AIS), varying in ratio between 40 to 80%, were selected from our Lung Specimen Registry. Laser capture microdissection (LCM) of each component was performed separately for each tumor. Genomic DNA was isolated using a direct in situ whole genome amplification (WGA) methodology, and Next Generation Sequencing performed using an Illumina Mate Pair (MP) library protocol. MP sequence reads were mapped to the human genome and primers spanning the fusion junctions were used in validation PCRs. Results: Genomic break points identical and unique to a specific patient were identified between the AIS and AD components in 13 (of 14) cases. The total number of events per case ranged from 4-215, and the number of identical events shared between the AIS and AD components ranged from 30 to 90%. Recurrent genomic breakpoints between cases were also observed, with the 2 most common involving 8q24.3 in 5 cases and FAM19A2 on chromosome 12 in 4 cases. PCR validation of selected genomic alterations confirmed the genomic break points identified from sequencing in both the AIS and AD in all cases. Interestingly, we also observed a limited number of genomic alterations present in a zonal distribution of surrounding normal lung around the tumor mass. Conclusions: Our study demonstrates unique chromosomal alterations present in both the AIS and AD components of individual lung tumors with features of lepidic growth. These data provide evidence for lineage relationship and clonal relatedness between the two components, and provide genomic evidence for a model of stepwise progression from AIS to invasive AD in this subset of lung adenocarcinomas.

Published

2013