Abstract
Multiple primary lung cancers (MPLCs) harbour various genetic profiles among the tumours, even from individuals with same non-intrinsic risk factors. Paired mutational analyses were performed to obtain a census of mutational events in MPLC and assess their relationship with non-intrinsic risk factors. Thirty-eight surgical specimens from 17 patients diagnosed as MPLC were used. Extracted DNAs were sequenced for somatic mutations in 409 cancer-associated genes from a comprehensive cancer panel. We statistically analysed the correlation between each driver mutation frequency and non-intrinsic risk factors using Fisher's exact test, and whether genetic mutations occurred concomitantly or randomly in MPLC using an exact test. Comprehensive genetic analyses suggested different mutation profiles in tumours within the same individuals, with some exceptions. EGFR, KRAS, TP53, or PARP1 mutations were concomitantly detected in some MPLC cases. EGFR mutations were significantly more frequent in never or light smokers and females. Concomitant EGFR or KRAS mutations in MPLCs were significantly more frequent than expected by chance (Pā=ā.0023 and .0049, respectively) suggesting a more prominent role of non-intrinsic risk factors in EGFR and KRAS mutations than other mutations, which occurred more randomly. Concomitant EGFR or KRAS mutations were particularly prominent in never or light smokers and males.
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Introduction
Lung cancer is the leading cause of cancer-related death worldwide1. Cancer risk factors include intrinsic and non-intrinsic factors. The majority of cancer risk factors (60ā90%) are non-intrinsic2,3. Intrinsic risk has been defined as intrinsic DNA replication errors which are unmodifiable and occur in the process of normal human cells division. Non-intrinsic risk is defined as factors that consist of modifiable exogenous factors such as lifestyle, radiation, chemical carcinogens, tumour causing viruses, and partially modifiable endogenous factors such as biological aging, inflammation, immune responses, hormones, and metabolisms. Epidemiological studies of lung cancer have revealed multiple risk factors that comprise a combination of genetic and external factors (environmental and occupational). In particular, smoking is the main cause of the development and progression of lung cancer4,5.
The development of a variety of reliable and powerful molecular tools has led to the discovery of driver mutations associated with the development of lung cancer and revealed differences in the frequency of genetic mutations due to non-intrinsic factors. For example, epidermal growth factor receptor (EGFR) mutations are more frequently found in female patients who are never smokers and who have adenocarcinoma histology, whereas KRAS mutations are more common in adenocarcinoma patients who are smokers6,7,8. Furthermore, fusions of canonical oncogenes are reportedly often acquired in the early decades of life9. The authors suggested that these events likely take place in normal cells with competent DNA damage response9. Another study suggested that the majority of cancer risk is due to bad luck, with random mutations arising during DNA replication in normal, noncancerous stem cells10. These previous studies analysed patients with different molecular and clinical backgrounds, and so were hindered by the problem that various factors are intricately intertwined. Therefore, we focused on multiple primary lung cancers (MPLCs), which occur in a patient exposed to the identical risk factors and systemic reactions, including the immune response. This focus allowed us to elucidate the relationships between genetic mutations and non-intrinsic factors.
It is reported that MPLCs occur in 0.2 to 20% of all primary lung cancer cases, and the incidence rate has risen because of the incorporation of high-resolution computed tomography (CT) and positron emission tomography/CT (PET/CT) into clinical practice11,12. The initial criteria published in 197513 defined MPLCs based on histology and tumour locations. However, in some cases, it is difficult to differentiate MPLCs from metastases in accordance with these criteria. In particular, bronchioloalveolar carcinomas appearing as multiple pure ground-glass opacity lesions are commonly defined as MPLC without pathological confirmation for every lesion14. Therefore, differentiation of MPLC from intrapulmonary metastasis is often a problem. Array comparative genomic hybridisation (CGH), histological subtyping, and imaging features are powerful tools to differentiate MPLC from intrapulmonary metastasis15,16,17.
Although next generation sequencing (NGS) enables comprehensive gene mutation analysis, in MPLC the difference of mutation profiling among multiple lesions is unclear. Therefore, we assumed that genetic mutations that are strongly influenced by non-intrinsic risk factors would occur concomitantly in multiple tumours within the same individuals, whereas the mutations that are not influenced by non-intrinsic risk factors would occur randomly.
In this study, we performed comprehensive mutational analyses for MPLC patients to clarify whether genetic mutations can occur concomitantly or randomly in multiple tumours within the same individuals. In addition, we researched if non-intrinsic factors, mainly smoking status, obesity, age, and sex, can change the occurrence of mutations.
Methods
Patients and sample preparation
This study involved 34 patients who underwent surgery at Osaka City University Hospital for early stage non-small cell lung cancer (NSCLC) between October 2007 and March 2019. The patients were diagnosed with MPLC based on the criteria mentioned in previous studies13,18. Multiple tumours in the same lobe were included only if the tumours were located within different segments, classified as origin from carcinoma in situ, exhibited different histologic features (for example, adenocarcinoma and squamous cell carcinoma), or demonstrated the same histologic features but different subtyping (for example, acinar and papillary growth patterns). All available information was carefully reviewed and considered, including radiological and pathological findings from a multidisciplinary tumour board, which included radiologists, thoracic surgeons, and medical oncologists. Pathological staging was performed using the eighth edition of the TNM Classification of Malignant Tumours. The patients provided written informed consent for the genetic research studies, which were performed in accordance with protocols approved by the Institutional Review Board at Osaka City University Hospital and Wakayama Medical University Hospital. The specimens were reviewed to ensure tissue adequacy (>ā10% tumour nuclei) before testing. DNA was extracted from unstrained formalin-fixed paraffin-embedded (FFPE) resections using the QIAamp DNA FFPE Tissue Kit following the manufacturerās instructions (Qiagen). Genomic DNA concentration was measured using a Qubit fluorometer (Thermo Fisher Scientific). We checked the degree of DNA decomposition using TapeStation (Agilent) and excluded samples that were clearly undergoing DNA degradation. Finally, we analysed 38 surgical specimens from 17 patients (see Supplementary Fig. S1 online).
Targeted sequencing and data analysis
Next-generation sequencing for the detection of actionable somatic mutations was carried out as previously described19. Briefly, Ion AmpliSeq Library Kit Plus (Thermo Fisher Scientific) was used for library construction followed by barcode ligation using the Ion Xpress Barcode Adapters Kit (Thermo Fisher Scientific). Then, library samples were purified (Agencourt AMPure XP reagent, Beckman Coulter) and quantified (Ion Library Quantitation Kit, Thermo Fisher Scientific). The libraries were templated using Ion 540 Kit-Chef (Thermo Fisher Scientific) and sequencing was carried out on the Ion GeneStudio S5 (Thermo Fisher Scientific) for somatic mutations in 409 cancer-associated genes (Ion AmpliSeq Comprehensive Cancer Panel)Ā (see Supplementary Fig. S2 online). Data analysis was conducted using the Ion Reporter Server System (Thermo Fisher Scientific) and CLC Genomics Workbench version 9 (CLC bio, Aarhus, Denmark). Visual inspection was performed to confirm the sequence data using the Integrative Genomics Viewer.
Single Nucleotide Polymorphisms (SNPs) registered in the COSMIC database20 or Japanese Multi Omics Reference Panel21 were excluded. Nonsynonymous variants with coverage ofā<ā250 and allele frequency (AF)ā<ā3% were excluded. And then considering about base substitution by the FFPE sample, regarding Cā>āT/Gā>āA base substitution, those with AF of less than 5% and those with no reported lung cancer in the COSMIC and TCGA databases were excluded.
ALK immunohistochemistry (IHC)
Patients lacking EGFR and KRAS mutations were examined for ALK fusions. FFPE specimens were used for IHC with the Histofine ALK iAEP kit (Nichirei Bioscience, Tokyo, Japan). ALK IHC results were classified into positive (positive tumour cellsā>ā0%) and negative (0%).
ROS1 fusion gene detection
Patients lacking EGFR and KRAS mutations were examined for ROS1 fusions. Using haematoxylin and eosin-stained tissue slides as a guide, the corresponding areas of tumours on six sections of 5-Ī¼m-thick FFPE specimens were marked and scraped off the slide for macrodissection. Real-time reverse transcription-polymerase chain reaction was performed using RNA extracted from macrodissected specimens at LSI Medience (Osaka, Japan).
Array CGH
In cases where NGS showed the same mutation profiling or the same driver mutations (EGFR or KRAS mutations, or ALK or ROS1 rearrangements), array CGH was performed at DNA Chip Research Inc. (Tokyo, Japan). FFPE DNA samples (20Ā ng) were amplified using the GenomePlex Complete Whole Genome Amplification Kit (WGA2; Sigma-Aldrich, St. Louis MO, USA), according to the manufacturer's instructions. Each amplified sample (250Ā ng) was labelled with SureTag Complete DNA Labelling Kit (Agilent Technologies). In brief, Cy3- and Cy5-labelled DNA were combined with Cot-1 DNA (Thermo Fisher Scientific) and CGH blocking agent (Agilent Technologies), and then denatured and hybridised to the arrays (SurePrint G3 Human CGH Microarray 8āĆā60Ā K; Agilent Technologies) for 24Ā h in a rotating oven at 67Ā Ā°C and 20Ā rpm (Agilent Technologies). After hybridisation and washing, the microarray was scanned using a model G4900DA SureScan Microarray Scanner System (Agilent Technologies). Images were analysed with Feature Extraction Software 12.1.1.1 (Agilent Technologies) with the CGH_1201_Sep17 protocol for background subtraction and normalisation. Data analysis of the microarray experiments was conducted using the Aberration Detection Method-2 statistical algorithm (Agilent Technologies) on the basis of the combined log2 ratios at a threshold of 6.0, as was done in a previous study22. The data were centralised and calls with average log2 ratios ofā<ā0.3219 were filtered to exclude false positives.
Statistical analysis
The correlation between the frequency of tumours carrying each driver mutation and non-intrinsic risk factor was analysed using Fisherās exact test. Statistical analyses were performed to determine whether genetic mutations would occur concomitantly or randomly in multiple tumours using an exact test. At first, we assumed genetic mutations occurred by chance and calculated the frequency of each mutation in both, either, or neither lesions based on the Japan Molecular Epidemiology for lung cancer (JME) study, which was a prospective and multicentre molecular epidemiology study for Japanese NSCLC patients7. The frequency of mutations not analysed in the JME study was calculated from the number of samples in this study. Supplementary Table S1 online shows the frequency of each mutation. The assumed frequency of mutations was compared with the actual data to statistically analyse the difference in how the mutations occurred. If there was a significant difference, the mutations would occur concomitantly in the multiple tumours within the same individuals. Cases that had more than three lesions were considered discrepant if all lesions did not share the same mutation for purposes of this analysis. Statistical significance was assumed for a two-tailed p-valueā<ā0.05.
Results
Patient characteristics
We obtained 78 surgical specimens from 34 patients who were pathologically diagnosed as MPLC. Among them, 38 specimens from 17 patients were eligible for sequencing (see Supplementary Fig. S1 online). In addition to the clinicopathological features, patientsā age, sex, smoking history, body mass index (BMI), radiologic features, and surgical procedures were reviewed. We defined light smokers as Brinkman Index (BI)ā<ā200, medium smokers as BI 200 to 600, and heavy smokers as BIā>ā600 in accordance with a previous report7. Seventeen patients were divided into groups by the following characteristics (Table 1): 12 males, 5 females; 11 ever smokers, 6 never smokers. Age ranged between 50 and 83Ā years (mean age 73Ā years). Data concerning tumour location, pathological stage, maximum diameter of the tumours, histology, and operative procedure are presented in Table 2.
Targeted sequencing identifies somatic mutations in lung cancers
Targeted sequencing was performed for 38 surgically resected tumours from 17 patients. Deep sequencing was successfully performed in all of the specimens. The mean coverage depth was 846-fold for tumour samples (range: 540ā2061) (see Supplementary Table S2 online). In 38 specimens, sequencing analysis of 409 genes identified 21 mutations (0ā7 mutations per tumour) based on the defined filter criteria (Figs.Ā 1, 2). ALK and ROS1 rearrangements were examined in 16 samples lacking EGFR or KRAS mutations. These rearrangements were not detected in any of the samples (Fig.Ā 2).
In each patient, with a few exceptions, the gene mutations and amino acid substitutions within the individual tumours constituting the multiple lung cancers showed different mutation profiling (Fig.Ā 1). Case 5, 13, 14, and 16 showed the same mutation profiling.
Array CGH was performed for these four cases with the same mutation profiling among paired tumours by NGS and for three cases (Cases 3, 15 and 17) with the same driver mutations that included EGFR or KRAS mutations. The results of array CGH for each of the seven cases are shown in Supplementary Fig. S3 online. Case 14 displayed a gain of chromosome 22 in one tumour. Case 16 displayed losses of chromosomes 5 and 19 in one tumour. These results would be equivocal to conclude they represented MPLCs, nonetheless, Case 14 did not share all components of pathological subtypes and their proportions and morphological features were different, and one tumour in Case 16 was AIS. Therefore, the two cases were conclusively diagnosed as MPLCs. The other cases showed the typical array CGH results, which were amplifications or deletions in one of the tumours. In Case 5, the second cancer developed more than 3Ā years after the first cancer, so it was consistent with metachronous MPLC. In Case 13, radiographic findings of both tumours showed ground-glass opacity with no recurrence (see Supplementary Fig. S4 online). These clinical courses also supported the diagnoses of these cases as MPLCs.
We assessed whether non-intrinsic risk factors including age, sex, and smoking status were correlated with specific mutations. We could not assess the correlation between obesity and mutation profile, because none of the patients had a BMIā>ā25. In patients with MPLC, EGFR mutations occurred significantly more frequently in females and in never or light smokers, as well as the single primary lung cancers reported previously7 (Fig.Ā 3). The other mutations had no significant correlation with non-intrinsic risk factors in patients with MPLC. Heat mapping showed that each mutation occurred in all tumours, in either tumour, or in no tumour in multiple tumours within the same individuals (Fig.Ā 2). The EGFR, KRAS, TP53, and PARP1 mutations occurred concomitantly in some cases, but the other mutations were not detected concomitantly. We set each mutation frequency of single primary lung carcinoma in each characteristic based on the JME study and the data of the present study (see Supplementary Table S1 online). We assumed the mutations occurred by chance even in MPLC. Comparing the assumed frequency of mutations with the actual data, we statistically performed paired mutational analyses using the exact test to clarify the nature of the occurrence of mutations in MPLC. The results are shown in Table 3 and Supplementary Table S3 online. EGFR mutations were detected in 8 of 17 patients (all lesions in 5 patients, either lesions in 3 patients, no lesion in 9 patients). The occurrence of concomitant EGFR mutations in multiple tumours within the same individuals was significantly more frequent than expected by chance (Pā=ā0.0023). KRAS mutations were detected in 5 of 17 patients (all lesions in 2 patients, either lesions in 3 patients, no lesion in 12 patients).
The occurrence of concomitant KRAS mutations in multiple tumours within the same individuals was significantly more frequent than expected by chance, although there were few cases of KRAS mutated lung cancers (Pā=ā0.0049). In contrast, TP53 mutations were detected in 9 of 17 patients (all lesions in 2 patients, either lesion in 7 patients, no lesion in 8 patients). There was no significant difference in occurrence of TP53 mutations between the calculated frequency and the present data (Pā>ā0.05). Therefore, TP53 could occur randomly, even in the same individuals. Concomitant PARP1 mutations were also significantly more frequent than expected by chance. The likely reason is that the frequency of PARP1 mutation in lung cancer was very low and that only one patient with PARP1 mutated lung cancer had concomitant PARP1 mutations in MPLC. Regarding the other mutation, there was no significant difference between the calculated frequency and the present results (Pā>ā0.05). When we analysed whether smoking status, BMI, age, and sex were concomitantly or randomly associated with occurrence of gene mutations, concomitant EGFR or KRAS mutations occurred significantly more frequently in males and never or light smokers (see Supplementary Table S3 online). Younger patients (<ā70Ā years old) also had significantly more concomitant EGFR mutations than those in older patients (ā„ā70Ā years old). Three interesting cases are detailed below.
Case presentations
Case I: A 72-year-old male who was a light smoker had triple primary adenocarcinomas in S8, S9, and S10 of the right lobe. Right basal segmentectomy was performed. The results of mutation profiling using NGS showed that the S8 tumour had EGFR deletion 19, whereas the S9 and S10 tumours had EGFR L858R. The three tumours displayed different mutation profiling patterns (Fig.Ā 1). Pathologically, the tumours in right S8 and S10 were classified as adenocarcinoma in situ (AIS), and the right S9 tumour was classified as predominantly papillary adenocarcinoma (Fig.Ā 4a). The patient has had no recurrence for the 12Ā months that have elapsed since surgery. Thus, this case was consistent with MPLC. This case suggests that some populations are prone to EGFR mutations, although there is the difference of amino acid substitutions.
Case II: A 73-year-old male never smoker came to our department after abnormalities in the right S6 were detected on a chest CT performed as a screening procedure before surgery for pancreatic cancer (Fig.Ā 4b). During follow-up after resection of the right S6 lesion, multiple tumours in right S7, S9, and S10 lesions developed. Clinical distinction between the primary and metastatic tumours was difficult for the three tumours, therefore, right lower lobectomy was performed. Pathological findings showed AIS in all four tumours. Two new tumours subsequently developed in right S5 and left S8 lesions. We clinically diagnosed these tumours as MPLC and resected them. Pathologically, the right S5 tumour was classified as AIS and the left S8 tumour was classified predominantly papillary adenocarcinoma. They were also consistent with MPLC (Fig.Ā 4b). Although tumours including abundant tumour ratio involved only two lesions (right S6 and left S8), EGFR mutations were clinically examined in all lesions. All displayed the EGFR wild type. While the possibility of the influence of passive smoke cannot be denied, this case suggests that some cases are unlikely to have EGFR mutation, even in never smokers.
Case III: A 83-year-old male heavy smoker came to our department after CT detected two masses adjacent to each other in the left S10 (Fig.Ā 4c). There were no significant lymphadenopathy and metastases, so left lower lobectomy was performed. Pathologically, both tumours were classified as predominantly papillary adenocarcinomas. There were some differences between them. One tumour included lepidic construction and the other included relatively large amounts of acinar components without a lepidic component (Fig.Ā 4c). Morphological features were also not completely similar between the two groups. Therefore, these tumours were diagnosed as double primary lung cancers. EGFR L858R mutation was detected in one tumour (left 10A) but not in the other tumour (left 10B) (Fig.Ā 1). Even if EGFR mutations were detected in all lesions, it would be difficult to distinguish between MPLC and pulmonary metastasis. However, an EGFR mutation in only one lesion would support a diagnose as MPLC.
Discussion
Our study analysing mutation profiling of MPLCs using NGS showed that concomitant EGFR or KRAS mutations in MPLCs were significantly more frequent than expected by chance, whereas the other most mutations occurred randomly. Non-intrinsic factors such as smoking status, sex, and age were considered to be factors contributing to concomitant EGFR or KRAS mutations in MPLCs.
Non-intrinsic risk factors including inherited predispositions are carcinogenic risks, and exposure to tobacco smoke is the primary etiologic factor responsible for lung cancer. However, lung cancer in never smokers comprises an estimated 15 to 20% of cases in men and over 50% in women globally23. The mechanisms of the occurrence of lung cancer in never smokers are unclear. Random mutations arising during DNA replication in normal, noncancerous stem cells are also considered to be carcinogenic risks10, although this conclusion is very controversial2,3. Little is known of the cause of carcinogenesis and occurrence of mutations, using multiple tumours within the same individuals and also within the same organs. MPLC is considered an appropriate model for elucidate these unknowns.
In a case with two tumours with the same matching mutations, we assume that the tumours are a consequence of metastasis because, theoretically, metastatic lesions inherit genomic characteristics10. Along with the development of sequencing technology, it has been suggested that genetic mutational profiling using NGS might be useful to distinguish between MPLC and intrapulmonary metastasis24,25. However, matched mutations may occur in double primary tumours, while additional mutations may occur in metastasis26. Several studies have reported intratumor heterogeneity of EGFR mutations27,28,29. Therefore, multiple tumours within the same patients may harbour various genetic profiling patterns, regardless of MPLC or intrapulmonary metastasis. Owing to tumour heterogeneity and insufficient understanding of their clinicopathological characteristics, there are currently no golden diagnostic criteria for MPLCs. Array CGH has been confirmed as a powerful method for the study of DNA copy number alterations in a variety of cancer types30. Comparing paired tumours in the somatic allelic gains and losses across the genome using array copy number data has provided evidence to classify tumour pairs as clonal metastases or as independent multiple primary tumours15. Additionally, comprehensive histological subtyping and morphological features, including nuclear pleomorphism, cell size, acinus formation, nucleolar size, mitotic rate, nuclear inclusions, intraalveolar clusters and necrosis, are tools to differentiate MPLC from intrapulmonary metastasis17,31.
We therefore checked for histologic subtypes and morphologic features in pathological findings as well as CT findings suspected of intrapulmonary metastasis, such as well circumscribed, rounded lesions, feeding vessel sign, and lymphadenopathy common in multiple lesions. We then carefully excluded cases of intrapulmonary metastasis from our analysis, regardless of the sequencing data, and confirmed the absence of paired tumours with strikingly similar morphologic features, especially in cases with similar patterns of histologic subtypes, such as Cases 1, 2, 5, 9 and 10. Furthermore, we verified that the diagnosis was consistent with MPLC using array CGH in some cases.
Presently, EGFR mutations significantly occurred concomitant with MPLC. This finding suggests that the existence or absence of EGFR mutations will not impact on diagnosis of MPLC, intrapulmonary metastasis, or recurrence tumours. One of the reasons why the mutations occurred concomitantly may be the association with germline mutations and SNPs. Previous reports have identified germline mutations in driver oncogenes that are associated with lung cancers, such as EGFR32,33,34,35,36 and human epidermal growth factor receptor 2 (HER2)37, which suggests that a heritable predisposition to lung cancer is a contributor in some cases. EGFR V769M was demonstrated to be a germline related to MPLC and that harbours co-occurring somatic mutations in EGFR35. Presently, EGFR V769M was detected in a patient (Case 12) and a co-occurring somatic variant in exon 21 (L861Q or L858R) was found (Fig.Ā 1). And then, it was reported that Six loci, represented by seven SNPs (rs2736100 at 5p15.33, rs2853677 at 5p15.33, rs2179920 at 6p21.32, rs3817963 at 6p21.3, rs7636839 at 3q28, rs7216064 at 17q24.3, and rs2495239 at 6p21.1) have been associated with the risk of lung adenocarcinomas with EGFR mutation38. There were no significant differences in the association of these seven SNPs with gender or smoking status, suggesting that these loci likely affected the risk for EGFR-mutated lung adenocarcinomas, irrespective of gender and smoking status38. The sequencing panel used in this study targeted only on the somatic mutations and we were unable to examine these SNPs. However, some patients with EGFR-mutated lung cancer would be strongly associated with non-intrinsic factors, including SNPs. KRAS mutations also occurred concomitantly in MPLC in this study. Although SNPs related with KRAS have been reported39, the importance is unclear since other studies did not find such a relationship40. KRAS mutations were also presently detected in never or light smokers. This finding could reflect the small number of KRAS mutated cases, ambiguous information concerning smoking status because of patientās self-reporting, and a lack of information of passive smoking history. Further validation is needed. The present finding that TP53 mutations occurred randomly in multiple tumours within the same individuals suggests that TP53 mutations are not commonly associated with non-intrinsic factors. There were few cases with the other mutations, which hindered evaluation. However, the present finding is consistent with the previous report of the extreme rarity of these mutations in single lung cancers. Thus, it is considered they were less affected by non-intrinsic factors, and that the rare mutations occurred by chance.
This study has several limitations. First, our sample size was relatively small, and the retrospective nature of the study might have induced a selection bias. Thus, further studies using a larger cohort is warranted to confirm the results and to reveal more detailed genetic features and complexities of MPLC. However, MPLC is a relatively rare disease, and our assessment involved unique statistical analysis and datasets of samples from patients with MPLC. Secondly, most Cā>āT/Gā>āA transitions were associated with a low variant allelic frequency, suggesting that this mutational pattern was an artefact related to formalin fixation. A lack of normal tissue reference made difficult to assess the SNPs, germline mutations, and somatic mutations. Therefore, we used relatively strict filtering criteria. Finally, array CGH using WGA methods potentially had an amplification bias.
Although a larger prospective study is needed to assess these results, they are important as they are the first assessment of whether genetic mutations can occur concomitantly or randomly in multiple tumours within the same individuals. Validation of the existence of concomitant mutations would be useful for accurate diagnosis, staging, and therapeutic strategy. The findings of the present MPLC study confirms that some cases with EGFR- or KRAS- mutated tumours are strongly related to non-intrinsic factors and suggests that the other most mutations may occur by chance.
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Acknowledgements
This work was supported by JSPS KAKENHI Grant Number JP17K07176 (Y.K. and T.K.).
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M.I., Y.K., and T.K. designed the project. M.I., J.O., K.S., and Y.M. conducted experiments. M.I. and M.F. did the statistical analysis. M.O. performed the pathological diagnosis. M.I. produced the first draft of the paper. J.O., K.S, K.O., Y.M., Y.T., T.S., T.W., H.K., S.M., K.A., N.Y, Y.K, and T.K. contributed to data interpretation, drafting, and editing of the manuscript. All authors read and approved the final manuscript.
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Y. Koh has received honoraria from Thermo Fisher Scientific. All other authors declare that they have no competing interests.
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Izumi, M., Oyanagi, J., Sawa, K. et al. Mutational landscape of multiple primary lung cancers and its correlation with non-intrinsic risk factors. Sci Rep 11, 5680 (2021). https://doi.org/10.1038/s41598-021-83609-y
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DOI: https://doi.org/10.1038/s41598-021-83609-y
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