Yang W. Shao

Circulating Tumor DNA Mutation Profiling by Targeted Next Generation Sequencing Provides Guidance for Personalized Treatments in Multiple Cancer Types

Cancer is a disease of complex genetic alterations, and comprehensive genetic diagnosis is beneficial to match each patient to appropriate therapy. However, acquisition of representative tumor samples is invasive and sometimes impossible. Circulating tumor DNA (ctDNA) is a promising tool to use as a non-invasive biomarker for cancer mutation profiling. Here we implemented targeted next generation sequencing (NGS) with a customized gene panel of 382 cancer-relevant genes on 605 ctDNA samples in multiple cancer types. Overall, tumor-specific mutations were identified in 87% of ctDNA samples, with mutation spectra highly concordant with their matched tumor tissues. 71% of patients had at least one clinically-actionable mutation, 76% of which have suggested drugs approved or in clinical trials. In particular, our study reveals a unique mutation spectrum in Chinese lung cancer patients which could be used to guide treatment decisions and monitor drug-resistant mutations. Taken together, our study demonstrated the feasibility of clinically-useful targeted NGS-based ctDNA mutation profiling to guide treatment decisions in cancer.

Novel Mutations on EGFR Leu792 Potentially Correlate to Acquired Resistance to Osimertinib in Advanced NSCLC

Abstract Osimertinib is an irreversible third generation EGFR tyrosine kinase inhibitor (TKI) and has shown outstanding performances in treating EGFR T790M-positive advanced non-small cell lung cancer (NSCLC) patients, but acquired resistance is inevitable. EGFR C797S is the most notable resistance mechanism to this drug, but other EGFR mutations may also exist. In three lung adenocarcinoma patients resistant to osimertinib, we identified recurrent novel mutations at EGFR Leu792 codon by targeted next generation sequencing (NGS) of cell free DNA (cfDNA) from plasma or pleural effusion. In two cases with pre-treatment tumor samples tested, mutations at Leu792 were absent, indicating that they were newly acquired during the therapy. Interestingly, all Leu792 mutations are localized at the same gene allele as T790M, but different from C797S. Structural prediction suggests that Leu792 mutations could interrupt the binding of osimerbinib to EGFR and potentially cause drug resistance.

Cell-Free DNA Provides a Good Representation of the Tumor Genome Despite Its Biased Fragmentation Patterns

Cell-free DNA (cfDNA) is short, extracellular, fragmented double-stranded DNA found in plasma. Plasma of patients with solid tumor has been found to show significantly increased quantities of cfDNA. Although currently poorly understood, the mechanism of cfDNA generation is speculated to be a product of genomic DNA fragmentation during cellular apoptosis and necrosis. Sequencing of cfDNA with tumor origin has identified tumor biomarkers, elucidating molecular pathology and assisting in accurate diagnosis. In this study, we performed whole-genome sequencing ofcfDNA samples with matching tumor and whole blood samples from five patients diagnosed with stage IV gastric or lung cancer. We analyzed the coverage spectrum of the human genome in our cfDNA samples. cfDNA exhibited no large regions with significant under-coverage, although we observed unbalanced coverage depth in cfDNA at transcription start sites and exon boundaries as a consequence of biased fragmentation due to ordered nucleosome positioning. We also analyzed the copy number variant status based on the whole-genome sequencing results and found high similarity between copy number profile constructed from tumor samples and cfDNA samples. Overall, we conclude that cfDNA comprises a good representation of the tumor genome in late stage gastric and lung cancer.

Circulating tumor DNA profiling by next generation sequencing reveals heterogeneity of crizotinib resistance mechanisms in a gastric cancer patient with MET amplification

Crizotinib has been used to counter MET gene amplification in a number of different human malignancies. Transient response to crizotinib in MET-amplified gastric cancer has been reported, but the mechanisms of resistance are not well studied. Here, we reported a stage IV gastric cancer patient with high levels of MET amplification. The implementation of crizotinib treatment led to significant symptomatic improvement in the first 2 months, but was followed by rapid disease progression. Periodic mutation profiling of patients circulating tumor DNA (ctDNA) by next generation sequencing (NGS) revealed a number of genetic alterations including re-occurrence of MET amplification, multiple secondary MET mutations, a dramatic increase of FGFR2 gene relative copy number as well as mutations in other downstream and bypassing elements, which may collectively related to the patients cancer progression. Our results illustrate the complex and heterogeneous molecular mechanisms for crizotinib resistance in this patient, and demonstrate the great potential of ctDNA profiling for treatment decision-making and prognosis in clinical practice.

JAK2 variations and functions in lung adenocarcinoma

Lung cancer ranks as the first most common cancer and the first leading cause of cancer-related death in China and worldwide. Due to the difficulty in early diagnosis and the onset of cancer metastasis, the 5-year survival rate of lung cancer remains low. JAK2 has emerged as pivotal participant in biological processes, often dysregulated in a range of cancers. Recently our study found that JAK2 might play an important role in lung cancer pathogenesis. While our understanding of JAK2 in the onset and progression of lung cancer is still in its infancy, there is no doubt that understanding the variations and functions of JAK2 will certainly secure strong biomarkers and improve treatment options for lung cancer patients. The expression level of JAK2 mRNA was assayed using RT-PCR. JAK2 mutations and amplification were detected using next-generation sequencing (NGS). The shRNA and overexpression plasmids of JAK2 were conducted. MTT (3-(4, 5-dimethylthiazol-2-yl)-2, 5-diphenyl-tetrazoliumbromide) assay, Trans-well migration and Matrigel invasion assay were conducted to study the proliferation, migration and invasion abilities of lung adenocarcinoma cells independently. We found that JAK2 mRNA was up-regulated in lung adenocarcinoma tissues when compared with their adjacent non-tumor tissues, and was associated with lymph node metastasis (p < 0.05). JAK2 V617F and N30S mutations and JAK2 amplification were detected by NGS in plasmid samples in patients with lung adenocarcinoma. Downregulation of JAK2 inhibited the proliferation, migration and invasion abilities of lung adenocarcinoma A549 cells. Moreover, overexpression of JAK2 induced the proliferation, migration and invasion abilities of A549 cells. Thus, the up-regulation, mutation and amplification of JAK2 detected in lung adenocarcinoma may participate in lung cancer progression by regulating cancer cells’ proliferation, migration and invasion.

Genetic and clonal dissection of osteosarcoma progression and lung metastasis: Genetic and clonal dissection of osteosarcoma

Osteosarcoma is a primary malignant bone tumor that has a high potential to metastasize to lungs. Little is known about the mechanisms underlying the dissemination of OS cancer cells to lungs. We performed whole exome sequencing of 13 OS primary tumors, with matched lung metastases and normal tissues. Phylogenetic analyses revealed that lung metastatic tumors often harbor clones that are nonexistent or rare in the matched primary OS tumors. Spatially and temporally separated lung metastases were from parallel seeding events with a polyphyletic pattern. Loss of TP53 or RB1 is among the early events during OS tumorigenesis, while loss of PTEN is involved at the later stages associated with lung metastases. Finally, KEAP1 was identified as a novel biomarker for increased metastatic risk. Patients whose primary tumors harbored KEAP1 amplification have significantly poorer lung‐metastasis free survival. This finding was validated in two independent datasets. Further, in vitro experiments exhibited that KEAP1 depletion suppressed the invasion of OS cells. Our findings uncover the patterns of clonal evolution during OS progression and highlight KEAP1 as a novel candidate associated with the risk of lung metastasis in OS patients.

Short-Term Responders of Non-Small Cell Lung Cancer Patients to EGFR Tyrosine Kinase Inhibitors Display High Prevalence of TP53 Mutations and Primary Resistance Mechanisms.

Non–small cell lung cancer (NSCLC) with activating EGFR mutations in exon 19 and 21 typically responds to EGFR tyrosine kinase inhibitors (TKI); however, for some patients, responses last only a few months. The underlying mechanisms of such short responses have not been fully elucidated. Here, we sequenced the genomes of 16 short-term responders (SR) that had progression-free survival (PFS) of less than 6 months on the first-generation EGFR TKI and compared them to 12 long-term responders (LR) that had more than 24 months of PFS. All patients were diagnosed with advanced lung adenocarcinoma and harbored EGFR 19del or L858R mutations before treatment. Paired tumor samples collected before treatment and after relapse (or at the last follow-up) were subjected to targeted next-generation sequencing of 416 cancer-related genes. SR patients were significantly younger than LR patients (P < .001). Collectively, 88% of SR patients had TP53 variations compared to 13% of LR patients (P < .001). Additionally, 37.5% of SR patients carried EGFR amplifications compared to 8% of LR patients. Other potential primary resistance factors were also identified in the pretreatment samples of 12 SR patients (75%), including PTEN loss; BIM deletion polymorphism; and amplifications of EGFR, ERBB2, MET, HRAS, and AKT2. Comparatively, only three LR patients (25%) were detected with EGFR or AKT1 amplifications that could possibly exert resistance. The diverse preexisting resistance mechanisms in SR patients revealed the complexity of defining treatment strategies even for EGFR-sensitive mutations.

Acquired EGFR L718V mutation mediates resistance to osimertinib in non-small cell lung cancer but retains sensitivity to afatinib

OBJECTIVES Epidermal growth factor receptor (EGFR) tyrosine kinase inhibitors (TKIs) are promising targeted therapies for EGFR-mutated non-small-cell lung cancer (NSCLC) patients. However, acquired resistance inevitably develops. Comprehensive and dynamic companion genomic diagnosis can gain insights into underlying resistance mechanisms, thereby help oncologists and patients to make informed decision on the potential benefit of the treatment. MATERIALS AND METHODS A 67-year-old male who was initially diagnosed of EGFR L858R-mediated NSCLC received multiple lines of chemotherapy and EGFR TKI therapies after surgery. The EGFR mutational status of individual metastatic lesion was determined by genetic testing of the tumor tissue biopsies using next generation sequencing (NGS) throughout the patients clinical course. An acquired potentially drug-resistant EGFR mutation was functionally validated in vitro and its sensitivity to different EGFR TKIs was assessed simultaneously. RESULTS We have identified distinct resistance mechanisms to EGFR blockade in different metastatic lung lesions. Acquired EGFR T790M was first detected that leads to the resistance to the gefitinib treatment. Consequently, osimertinib was administrated and the response lasted until disease progressed. We identified a newly acquired EGFR L718V mutation in one lesion in conjunction with L858R, but not T790M, which showed stable disease on the following erlotinib treatment, while EGFR C797S together with L858R/T790M was detected in the other lesion that continuously progressed. In vitro functional studies demonstrated that EGFR-L858R/L718V confers resistance to osimertinib, but retains sensitivity to the second generation TKI afatinib. CONCLUSION We reported that distinct resistance mechanisms could arise in different metastases within the same patient in response to EGFR blockade. We also demonstrated in vitro that EGFR L718V mutation mediates resistance to osimertinib, but retains sensitivity to afatinib. We evidenced that dynamic companion genomic diagnosis offers valuable information to help define the mechanisms of drug resistance and to guide the selection of subsequent treatment.

Case Report: Osimertinib achieved remarkable and sustained disease control in an advanced non-small-cell lung cancer harboring EGFR H773L/V774M mutation complex

Missense mutations in EGFR exon 20 are rare in non-small-cell lung cancer (NSCLC), and mostly insensitive to the first generation tyrosine kinase inhibitors (TKIs) of EGFR. However, their responses to the third generation TKI are unclear. Here, we reported a patient with advanced NSCLC harboring a rare EGFR H773L/V774M mutation complex. Although he was irresponsive to the first generation TKI gefitinib, he demonstrated sustained disease control to osimertinib, suggesting that this complex is an activating mutation of EGFR and can be suppressed by osimertinib. The follow-up genetic profiling revealed multiple acquired new mutations that might be related to his resistance to osimertinib. This finding would provide valuable experience for future treatment of the same mutations.

Mechanisms of primary resistance to EGFR targeted therapy in advanced lung adenocarcinomas

INTRODUCTION Increasing evidence leads to a ratiocination that genetic heterogeneity of the lung adenocarcinoma with EGFR mutations may impact clinical responses and outcomes to EGFR tyrosine kinase inhibitor (TKI) treatments. METHODS We performed genetic profiling of pre-treatment samples of 69 lung adenocarcinoma patients, including tumor FFPE and cell-free DNA (cfDNA), targeting 416 cancer-related genes using next generation sequencing. We analyzed mutation concordance across sample types and investigated potential mechanisms that confer primary resistance to EGFR-TKIs in patients with short progression-free survival (PFS) versus those with long PFS. RESULTS We detected a total of 200 actionable genetic alterations (mean: 2.9 variants/patient, range: 1-7 variants) in tumor FFPE and 140 actionable genetic alterations (mean: 2.0 variants/patient, range: 0-5 variants) in matched cfDNA, respectively. All patients had EGFR TKI-sensitizing mutations, including EGFR Ex19del, L858R, G719S/C, and L861Q. Concurrent TP53 mutations were most commonly observed in 72.5% of patients, followed by EGFR amplification (20.3%), RB1 (10.1%), PIK3CA (7.2%), and MYC (5.8%). For EGFR activating mutations, the concordance rate was 88.2% between cfDNA and FFPE samples. Furthermore, we identified genes that potentially confer primary resistance to EGFR-TKIs including CDC73, SMAD4, RB1 and PIK3CA. We also report signaling pathways enriched in patients with TKI primary resistance. CONCLUSIONS We note the genetic complexity and heterogeneity of EGFR-mutated lung adenocarcinoma and underscore that mutation status is highly concordant between tumor FFPE and cfDNA samples. This study also highlights the alterations that potentially confer primary resistance to EGFR TKI treatments in patients who demonstrated short PFS.