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V.A. Miller
Author of
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MA04 - HER2, P53, KRAS and Other Targets in Advanced NSCLC (ID 380)
- Event: WCLC 2016
- Type: Mini Oral Session
- Track: Advanced NSCLC
- Presentations: 1
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MA04.09 - RICTOR Amplification in Non-Small Cell Lung Cancer: An Emerging Therapy Target (ID 6177)
17:00 - 17:06 | Author(s): V.A. Miller
- Abstract
- Presentation
Background:
Comprehensive genomic profiling (CGP) can discover novel therapy targets in NSCLC. Amplification of RICTOR, encoding a component of the MTORC2 complex, has recently been identified as a targetable alteration leading to clinical benefit.
Methods:
CGP was performed on hybridization-captured, adaptor ligation-based libraries for up to 315 cancer-related genes plus select introns from 28 genes frequently rearranged in cancer on 14,698 consecutive cases of NSCLC, comprising lung adenocarcinoma, squamous cell carcinoma (SCC) or NSCLC not otherwise specified (NOS). Tumor mutational burden (TMB) was determined on 1.1 Mb of sequenced DNA. All classes of genomic alterations (GA) were assessed simultaneously, including base substitutions, indels, rearrangements/fusions, and copy number changes.
Results:
747 (5.0%) NSCLC featured RICTOR amplification (amp). There were 380 (51%) male and 367 (49%) female patients with a mean age of 64.1 years (range 18-88 years). The primary tumor was analyzed in 333 (45%) cases and a metastasis biopsy in 414 (55%) cases. Genes most frequently co-altered with RICTOR amp included TP53 (79.5%) and FGF10 (64.6%), which is located close to RICTOR on chromosome 5 and is frequently co-amplified. Several known oncogenes in NSCLC were mutated at significantly higher rates in tumors with RICTOR amp, including EGFR (22%), MET (8.4%), ERBB2 (7%), as well as FGFR1 (5%), FGFR3 (1.4%), and FGFR4 (1.6%). 42.2% of tumors with RICTOR amp did not harbor additional alterations in KRAS or genes indicated in the NCCN guidelines. KRAS GA were identified in 19.6% of RICTOR amp tumors, compared with 29.8% of all NSCLC, but this difference was not statistically significant. Mean TMB in RICTOR amp tumors was intermediate (14.9 mut/Mb), and is higher than the overall average for NSCLC (9.2 mut/Mb). The number of RICTOR-amplified tumors with high TMB (>20 mut/Mb) was 23%, higher than the rate for non-RICTOR amp NSCLC (12.9%). Examples of patients with RICTOR amplification within late stage NSCLC responding to MTOR inhibitors will be presented.
Conclusion:
RICTOR amplification, when compared to other non-EGFR known drivers of NSCLC, is a relatively frequent clinically relevant GA that has been shown to respond to MTOR inhibitors. The co-occurrence of RICTOR amplification with mutation of known oncogenic drivers suggests a possible mechanism of acquired resistance to therapy that should be explored further. Tumors with RICTOR amp more often have higher levels of TMB than other NSCLC. Further study of RICTOR amp as a therapy target NSCLC in a clinical trial setting appears warranted.
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