The present study was approved by the Institutional Review Boards of Shanghai Chest Hospital, Shanghai Jiao Tong University (Shanghai, China), and Chongqing Cancer Institute (Chongqing, China). All participants underwent lung resection and needle aspiration, and provided written informed consent. Samples were snap-frozen with liquid nitrogen at the time of resection and stored at −80°C until required. All cases were independently reviewed by two pathologists during disease diagnosis. Patients were considered never-smokers if they had never smoked or had smoked <100 cigarettes in their lifetime (15).

Genomic DNA was extracted with the QIAamp DNA formalin-fixed paraffin-embedded (FFPE) kit (Qiagen, Inc., Valencia, CA, USA) according to the manufacturer's protocols. EGFR, KRAS and BRAF mutations were detected by amplification refractory mutation system in multiple quantitative polymerase chain reaction (ARMS-multi-qPCR) analysis with the Human EGFR Mutation Detection kit (YuanQi Bio-Pharmaceutical Co., Ltd., Shanghai, China) and the Human KRAS and BRAF Mutation Detection kit (YuanQi Bio-Pharmaceutical Co., Ltd.), respectively. The PCR conditions used were as follows: 42°C for 5 min, 94°C for 3 min, followed by 40 cycles at 94°C for 15 sec and 60°C for 1 min on the 7500 Real-Time PCR System (Applied Biosystems; Thermo Fisher Scientific, Inc., Waltham, MA, USA). The following primers were used: EGFR-exon (E)18 forward, 5′-CAAGTGCCGTGTCCTGG-3′ and reverse, 5′-CCTTACCTTATACACCGTGCC-3′; EGFR-E19 forward, 5′-CGGTGCATCGCTGGTAACAT-3′ and reverse, 5′-ATGGACCCCCACACAGC-3′; EGFR-E20 forward, 5′-CTGGCCACCATGCGAAG-3′ and reverse, 5′-TCCTGGCTCCTTATCTCCC-3′; EGFR-E21 forward, 5′-GCTTCTTCCCATGATGATCTG-3′ and reverse, 5′-CTGGTCCCTGGTGTCAGG-3′; KRAS forward, 5′-TTTGTATTAAAAGGTACTGGTGG-3′ and reverse, 5′-CCTCTATTGTTGGATCATATTCG-3′; and BRAF forward, 5′-ACTCTTCATAATGCTTGCTCTG-3′ and reverse, 5′-TGAATACTGGGAACTATGAAAATAC-3′. All PCR products were subjected to direct sequencing to verify mutations in EGFR, KRAS and BRAF. The following probes were used: for EGFR-E18, 5′-GGTGACCCTTGTCTCTGTGTTC-3′; EGFR-E19, 5′-ATCACTGGGCAGCATGTG-3′; EGFR-E20, 5′-CCCTGATTACCTTTGCGAT-3′; EGFR-E21, 5′-TGATCTGTCCCTCACAGCAG-3′; KRAS, 5′-TGTATTAAAAGGTACTGGTGGAG-3′; and BRAF 5′-TGAGACCTTCAATGACTTTCTAG-3′. All primers and probes were purchased from Sangon Biotech Co., Ltd., Shanghai, China.

Multiplex one-step reverse transcription (RT)-PCR was performed to detect ALK fusion gene variants. The Human Lung Cancer Related Fusion Gene Detection kit (YuanQi Bio-Pharmaceutical Co., Ltd.) was used according to the manufacturer's protocols. In brief, the mixture for each reaction contained 3 µl total RNA extracted from the tumor specimen, 12 µl Multiplex RT-PCR buffer, 2.5 µl Multiplex Enzyme mix and 300 nmol/l primers in a total volume of 25 µl. The PCR conditions used were as follows: 42°C for 30 min, 94°C for 5 min, followed by 40 cycles at 94°C for 15 sec and 60°C for 1 min on the 7500 Real Time PCR System. A total of two experiments were performed separately to detect echinoderm microtubule-associated protein-like 4 (EML4)-ALK fusion or alternative ALK fusions [transforming growth factor (TGF)-ALK, kinesin light chain 1 (KLC1)-ALK and kinesin family member 5B (KIF5B)-ALK]. The following forward primers were used for detecting EML4-ALK variants: EML4-E2 (V5a and 5b) forward, 5′-GTGGCCTCAGTGAAAAAATC-3′; EML4-E6 (V3a and 3b) forward, 5′-TAAAGATGTCATCATCAACCAAG-3′; EML4-E13 (V1 and 6) forward, 5′-CCTGGGAAAGGACCTAAAG-3′; EML4-E14 (V4b and 7) forward, 5′-GGGAAAGGACCTAAAGGTG-3′; EML4-E15 (V4a) forward, 5′-TGATGGCTTCCAAATAGAAGTAC-3′; EML4-E17 (V9) forward, 5′-ACGGGAATGAACAGCTCTCT-3′; and EML4-E20 (V2) forward, 5′-CGGGAGACTATGAAATATTGTACT-3′. The primers for alternative ALK fusion variants included: TGF-E3 forward, 5′-GAGAACCAGGACCTTCCACC-3′; KLC1-E9 forward, 5′-ATTCTCACTCGTGCACATGAAA-3′; KIF5B-E15 forward, 5′-AAAAGACCTTGCAGAAATAGGAA-3′; KIF5B-E17 forward, 5′-TCTGTCGATGCCCTCAGTG-3′; and KIF5B-E24 forward, 5′-TCAGGTCAAAGAATATGGCCA-3′. The common reverse primer for all ALK fusion variants was 5′-GCTTGTACTCAGGGCTCTGC-3′. Multiplex One-step RT-PCR was additionally used to detect RET fusion variants, including KIF5B-RET and coiled-coil domain containing 6 (CCDC6)-RET. RET Fusion Gene Detection kit (YuanQi Bio-Pharmaceutical Co., Ltd.) was used according to the manufacturer's protocols. All PCR products were subjected to DNA sequencing with the probe 5′-AGCTCCTGGTGCTTCCGGCG-3′ for all ALK fusion products. The expression of ALK tyrosine kinase was examined by immunohistochemistry using the ALK (D5F3) CDx Assay kit (Ventana Medical Systems, Inc., Tucson, AZ, USA) containing the rabbit monoclonal antibody against ALK (clone D5F3; catalog no., 790–4796; dilution, 1:250), which detected endogenous levels of total ALK protein, as well as ALK fusion proteins. The experiments were performed on FFPE sections, as described previously (20).

P-values were determined by Fisher's exact test or χ² test using Prism 6 analysis software (GraphPad Software, Inc., La Jolla, CA, USA). P<0.05 and P<0.01 were considered to indicate a statistically significant and highly significant difference, respectively.

Between January 2012 and June 2013, resected lung adenocarcinoma samples were collected from a total of 358 patients who had been diagnosed with NSCLC at Shanghai Chest Hospital or Chongqing Cancer Institute. The cohort consisted of 274 female patients (76.5%) and 84 male patients (23.5%) (Table I). The median age of the patient cohort was 57.1 years. While ~36.3% of patients were 50–59 years old, and 41.6% were ≥60 years, only 22.1% of patients were <50 years old (Table I). All specimens were selected based on the following criteria: i) Re-review confirmed a pathological diagnosis of lung adenocarcinoma; ii) the tumor specimen contained a minimum of 70% tumor cells; iii) sufficient tissue was available for comprehensive analysis; iv) the patient was a never-smoker; and v) the patient did not receive any neoadjuvant treatment. Based on the differentiation level of cancer cells, the specimens could be divided into three groups, which comprised poorly-, moderately- or well-differentiated carcinoma. The number of specimens was similar among these groups, ranging from 32.1 to 35.8% (Table I).

Out of a total of 358 NSCLC patents, genetic alterations were detected in 217 carcinoma specimens. Among these positive cases, there were 171 patients carrying EGFR mutations, accounting for 47.8% of all patients (Fig. 1). A total of 27 patients were detected as exhibiting EML4-ALK fusion genes, 13 with KRAS mutations, 5 with KIF5B-RET fusion variants and 1 with BRAF mutations, accounting for 7.5, 3.6, 1.4 and 0.3%, respectively (Fig. 1). No KIF5B-ALK or TFG-ALK fusion variants were detected in the samples. These results were confirmed by immunohistochemistry. Representative images revealed that ALK was absent in EML4-ALK-negative carcinoma cases (Fig. 2A), but was highly expressed in EML4-ALK-positive samples (Fig. 2B). None of the specimens carried mutations in >1 gene. However, there was one patient (>60 years old) who carried two EGFR mutations (E19 and E21) in their tumor specimen. These results supported the observation that mutations in the investigated tumorigenic genes are typically mutually exclusive (21).

EGFR mutations were most prevalent in E19, with 102 cases, accounting for 28.5% of all patients and 59.6% of patients exhibiting EGFR mutations (Table II). EGFR mutations were additionally identified frequently in E21, with 63 cases, accounting for 17.6% of all patients and 36.8% of patients with EGFR mutations (Table II). Markedly fewer cases were detected with mutations in E18 (3 cases; 0.8% of all patients) or E20 (4 cases; 1.1% of all patients), accounting for <5% of combined patients exhibiting EGFR mutations (Table II). Detailed data is listed in Table II according to gender, age, differentiation and histology.

Subgroup analysis was performed in order to uncover clinical features that were associated with the identified genetic mutations in the present study (Table III). In order to determine whether gender affected the frequency of investigated tumorigenic mutations in the present patient cohort, subtype analysis was performed according to patient gender, as shown in Table III. The percentage of patients who possessed EGFR mutations was 35.7% (30/84) of male patients and 51.5% (141/274) of female patients. The difference in the number of patients with or without EGFR mutations between male (30 vs. 54) and female (141 vs. 133) patients was markedly significant (P<0.01), suggesting that gender is an important factor that may affect EGFR mutations in NSCLC in never-smokers. Thus, EGFR mutations were more likely to be detected in female patients compared with male patients in the subset of NSCLC exhibited by never-smokers. Using an identical analysis method, a significant difference was observed (P<0.05) in the prevalence of KRAS mutations between male and female patients. The frequency of KRAS mutations was 7.1% in male patients and 2.6% in female patients. No significant difference was observed in the prevalence of mutations for ALK, RET and BRAF genes between male and female patients, suggesting that gender may have no significant effect on these mutations in NSCLC in never-smokers.

Subsequently, the effect of ageing on the occurrence of oncogenic mutations was determined. Consistent with previous reports (22,23), in the present study, EGFR mutations were more likely to be identified in older patients compared with younger patients. This was determined by comparing the distribution in four age subgroups between patients with and without EGFR mutations (P<0.04; Table III). By contrast, mutations in KIF5B-RET and EML4-ALK were more likely to be detected in younger patients compared with older patients, as there was a significant difference in the distribution of patients in four distinct age groups between wild-type and mutated KIF5B-RET or EML4-ALK, respectively (P<0.001; Table III). The median age was 42.8±1.6 years in KIF5B-RET-positive patients or 54.4±0.6 years in EML4-ALK-positive patients, compared with 57.9±0.8 years in mutation-negative patients (Table III). These results suggested a potential early onset of the disease in the patients exhibiting KIF5B-RET or EML4-ALK mutations. No evidence suggested that ageing was a significant factor in the occurrence of mutations in KRAS and BRAF, as determined by Fisher's exact test (Table III).

The differentiation level of carcinoma cases was examined, and it was identified that those expressing EML4-ALK were more likely to be poorly- or moderately-differentiated, but not well-differentiated, compared with mutation-negative patients (P<0.01; Table III). By comparing the differentiation level between tumors with and without EGFR mutations, the cancer cells were more likely to be well-differentiated in carcinoma exhibiting EGFR mutations compared with wild-type carcinoma (P<0.05; Table III). The differentiation level of carcinoma carrying alternative types of gene mutation was not significantly different from the remaining patients. These results suggested that ALK fusions activated cancer types that were less differentiated, but that possessed a more rapid rate of growth and were more resistant to conventional treatment. By contrast, EGFR mutations demonstrated the opposite properties for these aspects. The tumors were well-differentiated, with a slower rate of growth and possessed an improved response to conventional treatment (3,10). Therefore, screening for genetic mutations and determining cell differentiation levels may be important steps for improving the efficiency of targeted treatments in NSCLC.