Prevalence and Associations of Co-occurrence of NFE2L2 Mutations and Chromosome 3q26 Amplification in Lung Cancer

Jinfeng Liu; Sijie Liu; Dan Li; Hongbin Li; Fan Zhang

doi:10.1055/s-0044-1786004

Global Medical Genetics, Table of Contents

CC BY 4.0 · Glob Med Genet 2024; 11(02): 150-158
DOI: 10.1055/s-0044-1786004

Original Article

Prevalence and Associations of Co-occurrence of NFE2L2 Mutations and Chromosome 3q26 Amplification in Lung Cancer

Jinfeng Liu

¹Department of Thoracic Surgery, The First Hospital of Hebei Medical University, Shijiazhuang, China

,

Sijie Liu

²Department of Thoracic Surgery, Beijing Aerospace General Hospital, Beijing, China

,

Dan Li

³Department of General Surgery, Jingxing County Hospital of Hebei Province, Shijiazhuang, China

,

Hongbin Li

⁴Department of Oncology, Rongcheng County People's Hospital, Baoding, China

,

Fan Zhang

⁵Department of Thoracic Surgery, National Cancer Center/National Clinical Research Center for Cancer/Cancer Hospital, Chinese Academy of Medical Science and Peking Union Medical College, Beijing, China

› Author Affiliations

Abstract

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Keywords

NFE2L2 - lung cancer - 3q36 amplification - co-occurrence mutations - next-generation sequencing

Introduction

NFE2L2 (nuclear factor erythroid-2-related factor-2), encoding NRF2, is a crucial transcription factor responsible for regulating the expression of genes involved in various cellular processes, such as the antioxidant metabolism, lipid and iron catabolism, and proteostasis.[1] The Cancer Genome Atlas (TCGA) data reveal that NFE2L2 mutations occur in approximately 20% of squamous cell carcinoma (SCC).[2] Activation of the NRF2 pathway can provide a significant advantage in shielding tumor cells from the detrimental effects of oxidative stress.[3] Cancer cells that exhibit sustained activation of NRF2 often acquire a reliance on this pathway and contribute to the development of malignant phenotypes, ultimately leading to unfavorable prognoses in cancer patients.[4] Accumulating evidence indicates the functional involvement of NRF2 in the progression and development of nonsmall cell lung carcinoma (NSCLC).[5] [6] Satoh et al demonstrated a relative decrease in the number of tumors with more malignant characteristics in NRF2 knockout mice, underscoring the importance of NRF2 in the initiation and progression of lung cancer.[7] Furthermore, NRF2 activation has been associated with poor treatment response and prognosis in clinical patients.[8] The unfavorable prognosis observed in NFE2L2-mutant NSCLC has been partially attributed to the inadequate response to radiotherapy[9] as well as second- and third-line chemotherapy.[10] This diminished responsiveness is primarily associated with resistance mediated by the mutant Nrf2 pathway.[11] Through bioinformatics analysis of NRF2 transcripts in NSCLC cells, a recurring loss of exon 2 or exons 2/3 in NRF2 mRNA was observed as a result of alternative splicing.[12] The deletion of exon 2 presents a sophisticated mechanism for tumors to enhance NRF2 stability by eliminating its interaction sites—specifically, the DLG and ETGE motifs—with KEAP1. Additionally, oncogenic signals like KRAS, BRAF, and MYC activate NRF2 transcription.[13]

The signaling pathway of NRF2 is tightly regulated by KEAP1, which acts as a substrate adapter protein for the E3 ubiquitin ligase complex CUL3/RBX1 consisting of human cullin-3 and human RING box protein 1.[14] Extensive research has demonstrated that the KEAP1-NRF2 pathway exhibits bidirectional regulatory effects in carcinogenesis. On one hand, it possesses tumor preventive properties, whereas on the other hand, it can promote tumor progression.[15] Mutations in NFE2L2/KEAP1 have been linked to increased tumor mutational burden (TMB) and PD-L1 expression, resulting in improved clinical responses to immunotherapy and favorable patient outcomes.[16] Additionally, lung adenocarcinoma patients with co-occurring mutations in NFE2L2 and KEAP1 have shown poorer survival outcomes compared with those with a single mutation in either gene.[17]

The PIK3CA gene, located on the q26 region of the long arm of chromosome 3 (3q26), frequently undergoes activating mutations or copy number amplifications in lung cancer.[18] [19] [20] [21] PIK3CA is responsible for regulating the phosphatidylinositol 3-kinase (PI3K)/Akt signaling pathway, crucial in governing cell proliferation, adhesion, differentiation, and motility.[22] Activated PI3K signaling leads to increased NRF2 accumulation in the nucleus,[23] thereby enhancing various biological processes, including de novo purine nucleotide synthesis, glutamine metabolism, and the pentose phosphate pathway. The PI3K inhibitor NVP-BKM120 reduces NRF2 expression in squamous lung cancer cells.[24] Diosmetin selectively induces apoptosis and enhances paclitaxel efficacy in NSCLC cells by accumulating reactive oxygen species through disrupting the PI3K/Akt/GSK-3β/Nrf2 pathway.[25] Recent studies have revealed the involvement of NFE2L2 in DNA repair. There exists a significant association between NFE2L2 mutations and ATR gene expression.[26] NRF2 interacts with ATR at DNA damage sites, promoting ATR activation through its AAD-like domain and thereby facilitating G2 cell cycle arrest.[27] Notably, the ATR gene, a key regulator of the DNA damage response (DDR), is also located on 3q26.

Indeed, the genetic fitness of tumors is influenced by the nonadditive contributions of multiple genes within cancer pathways, underscoring the importance of interactions between mutations that may signify genetic epistasis.[28] In the context of lung cancer, the concept of epistatic mutation interactions has garnered substantial support. For example, in the realm of targeted therapy, the presence of TP53 mutations has been linked to diminished responsiveness to tyrosine kinase inhibitors and a poorer prognosis in patients with EGFR-mutated NSCLC.[29] Additionally, early studies have demonstrated the mutually exclusive nature of EGFR and KRAS mutations, delineating two subtypes of NSCLC patients with distinct clinical outcomes.[30] [31] Regarding immunotherapy, patients harboring concurrent TP53 and KRAS mutations may potentially derive greater benefits from PD-L1 inhibitors compared with those with a single mutation.[32] [33] Furthermore, the presence of STK11/LKB1 mutations has been shown to facilitate resistance to PD-1/PD-L1 inhibitors in KRAS-mutant lung adenocarcinoma (LUAD).[34]

In this comprehensive investigation, we employed targeted next-generation sequencing analysis on a robust cohort comprising 1,103 individuals diagnosed with lung cancer. Our principal objective centered on the meticulous exploration of potential deleterious co-occurrences associated with the NFE2L2 gene within the context of lung cancer.

Patients and Methods

Patients and Specimens

We collected blood and tumor tissue specimens from a cohort of 1,103 individuals diagnosed with lung cancer. These patients received treatment at multiple clinical centers from January 2020 to July 2022. Prior to specimen collection, all participants provided written informed consent. The study protocol was approved by the Ethics Committee of the First Hospital of Hebei Medical University, ensuring compliance with ethical guidelines for research involving human subjects. During the selection process, patients with histopathological evidence of either lung adenocarcinoma (LUAD) or lung squamous cell carcinoma (LUSC) and who underwent standard treatment were included. Patients with other types of cancers showing multiple malignant tumor cell components (such as adenosquamous carcinoma) were excluded.

Data Collection

High-quality total DNA was extracted from tissues using a commercial Universal Columnar Genome Extraction Kit (Kangwei, China). Sample Purification Beads (Illumina) were employed to purify fragmented DNA. To generate DNA fragments of 180 to 280 bp, hydrodynamic shearing was conducted using the M220 Focused-ultrasonicator (Covaris) on 0.6 g of genomic DNA. Subsequently, adapter-ligated libraries were generated using the TruSeq Nano DNA Sample Prep Kits (Illumina). For target enrichment, the constructed libraries were hybridized to custom-designed biotinylated oligonucleotide probes (Roche NimbleGen) covering 364 cancer-related genes ([Supplementary Table S1], available in online version only). Subsequently, the index-coded library samples were clustered on an Illumina cBot Cluster Generation System, and the DNA libraries were sequenced using an Illumina HiSeq 2000 system. Genomic alterations, including single-nucleotide variants, small insertions and deletions (Indels), copy number alterations, and gene fusions/rearrangements, were detected with GATK, MuTect (version 1.1.4) and BreakDancer, respectively. For quality control, tumor tissue somatic mutations were refined using the following criteria: (1) variants with a frequency of <1% in the 1000 Genomes Project (https://www.internationalgenome.org/) and the Exome Aggregation Consortium; (2) not present in paired germline DNA from peripheral blood lymphocytes; and (3) detected in five or more high-quality reads and without paired-end reads bias.

Data related to the TCGA cohorts were downloaded from cBioPortal (http://cbioportal.org). In addition, the data access period was June 2022. Briefly, we collected data on patients with lung cancer from this online database, including molecular characteristics (somatic mutations, copy number variation [CNV], and TMB), clinical information (gender, age, pathology, and smoking history), and overall survival (OS).

Statistical Analysis

The Kaplan–Meier curves were used to estimate OS, and statistical significance was calculated using the log-rank test. Multivariate Cox analysis was used to examine the association between OS and genomic features, as well as clinical phenotypes. The related estimates were reported as hazard ratio and 95% confidence interval. For all the analysis, a p-value below 0.05 was considered significant. Statistical analyses were carried out using R software.

Results

The Prevalence and Distribution of NFE2L2 Mutations with Lung Cancer

We conducted a retrospective analysis of sequencing data from 1,103 lung cancer patients between 2020 and 2022. The clinical characteristics of these patients were listed in [Table 1]. Among the cohort of patients, a total of 33 individuals with NFE2L2 mutations were identified. Notably, all of these individuals were male, with a median age of 66 years (range: 38–87) ([Supplementary Table S2], available in online version only). In comparison to patients with wild-type NFE2L2, those carrying NFE2L2 mutations exhibited a slightly higher average age (p = 0.029). The prevalence of NFE2L2 mutations is summarized in [Fig. 1A], indicating a relatively high mutation frequency of 16% in LUSC. Unexpectedly, a lower mutation frequency of 3% was observed in LUAD, which is still relatively high when compared with previous reports.[16] [35] Furthermore, NFE2L2 mutations showed no significant correlation with disease stage (I/II vs. III/IV, p = 0.681), primary lesion location (left lung vs. right lung, p = 0.944), or smoking history (ever vs. never, p = 0.164). Aberrations in NFE2L2 commonly arise from somatic mutations or CNVs. In our study, we identified a total of 34 NFE2L2 variations, with 27 located in exon 2, 4 in exon 5, 2 in exon 3, and 1 in exon 4 ([Fig. 1B]). Most of them occur in DLG or ETGE motifs, and the majority of them lead to the activation of the NRF2 pathway in cancer.[36] Additionally, we identified three cases of copy number amplification variant of NFE2L2 in LUSC, which also resulted in activation of the NRF2 pathway. Our investigation further revealed the presence of several previously unreported mutations within exon 2 of the NFE2L2 gene. These novel mutations include D21H, V36_E45del, F37_E45del, R42P, E67Q, and L76_E78delinsQ.

Table 1
Clinical characteristics of nonsmall cell lung carcinoma patients with NFE2L2 mutations and NFE2L2 wild type
Patient characteristics	NFE2L2 mutated (N = 33)	NFE2L2 wild-type (N = 1,070)
Age (mean ± SD)	65.97 ± 9.61	61.93 ± 10.51
Gender
Male	33	560
Female	0	510
Type
LUSC	18	93
LUAD	15	977
Smoking status
Ever	14	316
Never	19	752
NA	0	2
Stage
I	9	393
II	9	227
III	14	287
IV	1	132
NA	0	31
Site
Left lung	13	444
Right lung	20	624
NA	0	2

Abbreviations: LUAD, lung adenocarcinoma; LUSC, lung squamous cell carcinoma; NA, not applicable; SD, standard deviation.

Fig. 1 The prevalence and distribution of NFE2L2 mutations in Chinese NSCLC. (A) The prevalence of NFE2L2 mutations in patients with LUAD and LUSC. (B) The distribution of NFE2L2 mutations are shown on protein schematics. Symbols indicate the mutation type and location. LUAD, lung adenocarcinoma; LUSC, lung squamous cell carcinoma; NSCLC, nonsmall cell lung carcinoma.

Identification of NFE2L2 Co-occurring Mutations

Based on the genomic data obtained from the cohort of 33 patients, we further elucidated the comprehensive landscape of NFE2L2 gene alterations ([Fig. 2A]). Our findings indicated that individuals harboring NFE2L2 mutations also exhibited other actionable or driver mutations, with TP53 being the most frequently mutated gene (84.8%), followed by CDKN2A (33.3%), KMT2B (33.3%), LRP1B (33.3%), and PIK3CA (27.3%). Subsequently, a set of genes whose alterations showed the most pronounced co-occurrence with NFE2L2 were identified ([Fig. 2B]). This gene set (IRF2, TERC, ATR, ZMAT3, and SOX2) exhibited significant co-occurrence with NFE2L2 (p < 0.001). Remarkably, a majority of these genes are situated in the q26 region of the long arm of chromosome 3 (3q26), which is frequently amplified in TCGA LUSC cohort ([Fig. 2C]). Furthermore, our study revealed that the amplification of four genes (PIK3CA, SOX2, TERC, ZMAT3) located on chromosome 3q26 was also found to co-occur with NFE2L2 ([Fig. 2D]). Previous studies have suggested that NFE2L2 is a poor prognosis marker in lung cancer.[8] [37] Thus, we further investigated whether the co-occurrence of NFE2L2 and 3q26 amplification defines a molecular subset of lung cancer with unique clinical outcomes.

Fig. 2 Characteristics of co-occurring gene mutations with NFE2L2. (A) Co-mutation genes of NFE2L2 in patients with NSCLC. (B) Volcano plot indicating key co-occurring and mutually exclusive alterations associated with NFE2L2 status in the Chinese NSCLC. (C) Co-occurrence pattern of TERC, ZMAT3, and SOX2 in the TCGA cohort. (D) Heatmap illustrating the co-occurrence pattern of NFE2L2 and genes located at chromosome 3q26. *p < 0.1, ** p < 0.05, ***p < 0.01. NSCLC, nonsmall cell lung carcinoma; TCGA, The Cancer Genome Atlas.

Overall Survival Features of Lung Cancer Carrying Co-mutations

In order to determine whether the co-occurrence of NFE2L2 mutations and 3q26 amplification has a different impact on the prognosis of lung cancer patients than what has been previously reported, we conducted an analysis of the TCGA Pan-Lung Cancer database (http://cbioportal.org/msk-impact). [23] This database includes data from 1,144 patients with various types of lung cancer. After excluding patients without survival data, we ultimately analyzed 982 patients to assess survival. Our analysis revealed that in the cohort of patients with NFE2L2 mutations, those who carried 3q26 amplification had significantly longer survival than those who did not carry the amplification ([Fig. 3A], median overall survival: 55.23 vs. 32.04, p = 0.0166). However, within the subgroup of patients lacking NFE2L2 mutations, our analysis did not identify any noteworthy disparity in survival outcomes between individuals with and without 3q26 amplification ([Fig. 3B]).

Fig. 3 Survival analyses in the TCGA cohort. (A) Comparison of overall survival between chromosome 3q26 amplification (3q26 amp) versus non-3q26 amplification (non-3q26 amp) tumors in NFE2L2 mutated (NFE2L2 mut) subcohort. (B) Comparison of overall survival between chromosome 3q26 amplification (3q26 amp) versus non-3q26 amplification (non-3q26 amp) tumors in NFE2L2 wild-type (NFE2L2 wt) subcohort. TCGA, The Cancer Genome Atlas.

Risk of Death of Lung Cancer Carrying Co-mutations

Given the variable prevalence of NFE2L2 mutations in LUSC and LUAD, it is essential to investigate whether the difference in prognosis associated with the presence or absence of 3q26 amplification in NFE2L2-mutated patients is caused by distinct clinical features. Multivariate Cox regression analyses were conducted to identify potential predictors of survival in the TCGA Pan-Lung Cancer cohort. Among the molecular characteristics and clinical information examined, the presence or absence of NFE2L2 mutations co-occurring with 3q26 amplification was the only significant predictor of OS ([Fig. 4A]). In addition, considering that previous studies have mostly reported NFE2L2 as a marker of poor prognosis in pan-cancer or LUAD,[8] [37] [38] we separately analyzed OS in TCGA LUSC patients with only NFE2L2 mutations versus those with coexisting mutations. Our findings suggest that the synergistic effect of 3q26 amplification on NFE2L2 still holds true, as patients carrying coexisting mutations (CoMut) had better prognoses than those with only NFE2L2 mutations ([Fig. 4B]). These results confirmed that the co-occurrence of NFE2L2 and 3q26 defined a molecular subset of lung cancer with better clinical outcomes compared with NFE2L2 alone, and this difference is not related to clinical features.

Fig. 4 Multivariate Cox regression analysis of overall survival (OS). (A) Multivariate Cox regression analysis for OS in the TCGA Pan-Lung Cancer cohort. (B) Comparison of OS in the TCGA LUSC subcohort, including coexisting mutations (CoMut), chromosome 3q26 amplification only (3q26 amp), NFE2L2 mutation only (NFE2L2 mut), and both wild-type (WT) cases. LUSC, lung squamous cell carcinoma; TCGA, The Cancer Genome Atlas.

Discussion

NFE2L2 mutations commonly coincide with additional driver mutations across diverse cancer types, such as LUSC, head and neck cancer, bladder cancer, and esophageal cancer. Consequently, the inhibition of the NRF2 pathway may exert an epistatic interaction with other driving variants, resulting in the suppression of cancer growth.[39] The primary objective of our investigation was to examine NFE2L2, given its high frequency of genetic alterations in lung cancer and its established correlation with adverse clinical outcomes. Furthermore, NFE2L2-mutated cancers often display concurrent alterations, and ongoing clinical trials (NCT05275673, NCT04518137) are evaluating NFE2L2 as a potential therapeutic target. This offers a unique opportunity to identify key prognostic markers and potential targets for future clinical interventions. Furthermore, our investigation unveiled a significant co-occurrence of NFE2L2 with the amplification of four genes (PIK3CA, SOX2, TERC, ZMAT3) located on chromosome 3q26, as indicated by the examination of co-mutation correlation patterns.

CNVs represent recurrent genetic alterations commonly identified in human tumors. The amplification of the long arm of chromosome 3 (3q) was initially documented nearly two decades ago in head and neck squamous cell carcinoma (HNSCC).[40] Subsequent evidence has demonstrated that 3q26 amplification is a frequent occurrence in malignant tumors and is potentially associated with tumor invasiveness. This suggests that 3q26 amplification plays a substantial functional role in the transition from premalignancy to malignancy in several tumor types, including laryngeal squamous cell carcinoma, HNSCC, and cervical cancer. These tumor types have been consistently observed to exhibit 3q26 amplification.[41] [42] [43]

The SOX2 protein is a transcription factor that plays a crucial role in regulating the pluripotency of embryonic stem cells as well as in the morphogenesis and homoeostasis of tracheobronchial epithelia. The current hypothesis suggests that SOX2 is involved in various stages of invasive carcinoma development from normal epithelium, driving the expression of squamous histology markers such as P63. Studies have demonstrated that silencing SOX2 expression results in apoptosis, reduced tumorigenicity, and decreased stemness in lung cancer cells.[44] [45] [46] Amplification of the SOX2 gene has been identified as a driver of its expression in various SCCs, such as lung and esophageal cancers.[47] [48] Researchers have demonstrated a correlation between heightened levels of SOX2 expression and an unfavorable prognosis in both lung adenocarcinoma[49] and small cell lung cancer.[46] Paradoxically, in NSCLC patients, SOX2 expression has been linked to better clinical outcomes, indicating that complex multigenic interactions are involved in driving aggressive behavior and unfavorable clinical outcomes in tumors with 3q26 amplification.[50]

Another gene that has robust evidence supporting its driving role in 3q26 amplification tumors and other tumor types is PIK3CA. It is located on the 3q26 genomic region, downstream of SOX2, and encodes the p110α protein, which is the catalytic subunit of PI3K. PIK3CA is responsible for regulating the PI3K/Akt signaling pathway, which is critical for cell survival in human cancer.[22] Notably, there is a higher prevalence of genetic alterations in PIK3CA in LUSC compared with LUAD.[18] [19] Okudela and colleagues demonstrated PIK3CA copy number gains by FISH in 43% of Japanese LUSC patients. Similarly, Ji and coworkers noted amplification by PCR in 42% of Chinese LUSC patients.[20] [21] Furthermore, a study conducted by Best et al elucidated the synergistic interplay between the KEAP1/NRF2 and PI3K pathways, which contributes to the development of NSCLC with an altered immune microenvironment.[51] The researchers observed that NRF2 exhibits oncogenic activity downstream of the PI3K pathway. Intriguingly, they also discovered that prolonged activation of NRF2 under homeostatic conditions does not trigger the development of malignant pathologies. Moreover, our investigation revealed a notable co-occurrence between NFE2L2 and the amplification of PIK3CA, which is located on chromosome 3q26. However, further large-scale follow-up studies are warranted to determine whether this co-mutation has an impact on the prognosis of lung cancer patients.

ATR serves as a key regulator of the DDR in mammary cells, exerting a master control over this process. In cells experiencing DNA double-strand breaks, crosslinks, or replication stress, the replication protein A (RPA) envelops the single-stranded DNA (ssDNA) present at the sites of DNA damage. ATR effectively detects and recognizes this ssDNA coated with RPA through its interaction with the protein ATRIP.[52] Recruiting ATR/ATRIP to RPA-coated ssDNA alone is insufficient to achieve optimal activation; additional proteins are required as activators. NRF2 has emerged as a potential activator of ATR, playing a crucial role in maintaining genomic stability by facilitating ATR activation and promoting G2 cell cycle arrest.[27] We found that alterations of ATR also showed significant co-occurrence with NFE2L2. Further investigation is required to describe whether the abnormal activation of NFE2L2 can compensate for the impairment of homologous recombination repair caused by ATR deficiency and effectively preserve genome stability.

TERC encodes the human telomerase RNA, and its increased gene expression is frequently detected in various human cancers.[53] The expression of TERC was differentially regulated during the oncogenesis process in the histological subtypes of lung carcinoma, with higher TERC expression observed in LUSC.[54] Recent studies have reported a positive feedback regulation between TERC and the PI3K/Akt pathway, operating independently of telomerase activity in human fibroblasts to control cell proliferation.[55] The amplification of TERC and its co-occurrence with NFE2L2 in our study suggests a potential mutual synergistic effect between TERC and NFE2L2 through the PI3K/Akt pathways. ZMAT3 (Zinc Finger Matrin 3), encoding a zinc finger RNA-binding protein, is a crucial downstream tumor suppressor of the tumor protein p53. Its expression is highly dependent on p53 in KRAS ^G12D-driven LUAD, and similar to p53, ZMAT3 inhibits LUAD growth by impeding proliferation without inducing apoptosis.[56] Interestingly, we observed that ZMAT3 amplification is associated with a better prognosis in patients with NFE2L2 mutations. However, no such difference was observed in patients with wild-type NFE2L2. We speculate that ZMAT3 may play a positive tumor-suppressive role in the progression of NFE2L2-mutated tumors. Nevertheless, these speculations need validation in future in vitro or in vivo studies.

A notable observation in our study is that all 33 patients with NFE2L2 mutations were male. Consistent with previous investigations, where among 262 patients, all 6 individuals with NFE2L2 mutations were also male.[35] In this study, all 6 patients were smokers with LUSC. Prolonged and repetitive exposure of the respiratory tract to cigarette smoke typically triggers the activation of cellular defense mechanisms, while the substances deposited induce a multifaceted adaptive response aimed at restoring tissue homeostasis. A previous study suggests that the activation of the transcription factor NRF2 is considered a prominent characteristic of this defense system, acting as the master regulator of the cellular antioxidant response.[57] Besides NFE2L2's involvement in antioxidant metabolism related to smoking, the precise mechanism underlying the higher propensity for NFE2L2 mutations in males remains currently unclear.

This study reveals a notable disparity in the frequency of NFE2L2 gene alterations between lung adenocarcinoma and SCC, offering crucial insights into the molecular characteristics of distinct lung cancer subtypes. This contributes to a better comprehension of the molecular classification of lung cancer, providing valuable guidance for personalized therapeutic approaches. In the TCGA Pulmonary Squamous Carcinoma project, patients harboring NFE2L2 mutations along with 3q26 amplification exhibit prolonged median survival and superior OS. This preliminary evidence underscores the potential prognostic value of NFE2L2 mutations in assessing the outcomes of lung cancer patients. For individuals concurrently carrying NFE2L2 mutations and 3q26 amplification, further exploration of the prospective clinical applications within this subset is warranted. This may involve the development of more personalized treatment strategies tailored to the unique characteristics of this subgroup. In summary, this study not only sheds light on the role of NFE2L2 mutations in lung cancer but also provides a novel perspective and insights into their potential therapeutic applications. Our study has several limitations that need to be acknowledged. Firstly, the compared subgroups had different sizes, which could introduce a potential bias in the analysis. Additionally, the lack of follow-up data limited our ability to assess long-term outcomes. To address these limitations, we utilized the TCGA survival database to complement our analysis and examine the association between genetic mutations and prognosis. However, it is important to note that discrepancies between our dataset and the TCGA database could introduce bias and restrict the generalizability of our findings to the Chinese population. Furthermore, due to the low occurrence rate of the co-occurrence in LUAD, our study may have had insufficient statistical power to fully evaluate the potential impact of this co-occurrence on prognosis in LUAD patients.

Conclusions

Our findings demonstrate that the co-occurrence of NFE2L2 and 3q26 is observed in approximately 3% of NSCLC cases. Notably, patients with NFE2L2/3q26 mutations show a more favorable prognosis compared with those with sole NFE2L2 mutations without 3q26 amplification. As a result, further investigations should focus on elucidating whether patients with NFE2L2 mutations may benefit from more aggressive upfront therapy when compared with individuals harboring NFE2L2/3q26 mutations.

References

References
1 Cuadrado A, Manda G, Hassan A. et al. Transcription factor NRF2 as a therapeutic target for chronic diseases: a systems medicine approach. Pharmacol Rev 2018; 70 (02) 348-383
2 Cancer Genome Atlas Research Network. Comprehensive genomic characterization of squamous cell lung cancers. Nature 2012; 489 (7417) 519-525
3 DeBlasi JM, DeNicola GM. Dissecting the crosstalk between NRF2 signaling and metabolic processes in cancer. Cancers (Basel) 2020; 12 (10) 3023
4 Kitamura H, Motohashi H. NRF2 addiction in cancer cells. Cancer Sci 2018; 109 (04) 900-911
5 Colburn NH, Kensler TW. Targeting transcription factors for cancer prevention–the case of Nrf2. Cancer Prev Res (Phila) 2008; 1 (03) 153-155
6 Singh A, Misra V, Thimmulappa RK. et al. Dysfunctional KEAP1-NRF2 interaction in non-small-cell lung cancer. PLoS Med 2006; 3 (10) e420
7 Satoh H, Moriguchi T, Takai J, Ebina M, Yamamoto M. Nrf2 prevents initiation but accelerates progression through the Kras signaling pathway during lung carcinogenesis. Cancer Res 2013; 73 (13) 4158-4168
8 Yang H, Wang W, Zhang Y. et al. The role of NF-E2-related factor 2 in predicting chemoresistance and prognosis in advanced non-small-cell lung cancer. Clin Lung Cancer 2011; 12 (03) 166-171
9 Binkley MS, Jeon YJ, Nesselbush M. et al. KEAP1/NFE2L2 mutations predict lung cancer radiation resistance that can be targeted by glutaminase inhibition. Cancer Discov 2020; 10 (12) 1826-1841
10 Frank R, Scheffler M, Merkelbach-Bruse S. et al. Clinical and pathological characteristics of KEAP1- and NFE2L2-mutated non-small cell lung carcinoma (NSCLC). Clin Cancer Res 2018; 24 (13) 3087-3096
11 Barrera-Rodríguez R. Importance of the Keap1-Nrf2 pathway in NSCLC: is it a possible biomarker?. Biomed Rep 2018; 9 (05) 375-382
12 Goldstein LD, Lee J, Gnad F. et al. Recurrent loss of NFE2L2 exon 2 is a mechanism for Nrf2 pathway activation in human cancers. Cell Rep 2016; 16 (10) 2605-2617
13 DeNicola GM, Karreth FA, Humpton TJ. et al. Oncogene-induced Nrf2 transcription promotes ROS detoxification and tumorigenesis. Nature 2011; 475 (7354) 106-109
14 Bauer AK, Hill III T, Alexander CM. The involvement of NRF2 in lung cancer. Oxid Med Cell Longev 2013; 2013: 746432
15 Rojo de la Vega M, Chapman E, Zhang DD. NRF2 and the hallmarks of cancer. Cancer Cell 2018; 34 (01) 21-43
16 Xu X, Yang Y, Liu X. et al. NFE2L2/KEAP1 mutations correlate with higher tumor mutational burden value/PD-L1 expression and potentiate improved clinical outcome with immunotherapy. Oncologist 2020; 25 (06) e955-e963
17 Marinelli D, Mazzotta M, Scalera S. et al. KEAP1-driven co-mutations in lung adenocarcinoma unresponsive to immunotherapy despite high tumor mutational burden. Ann Oncol 2020; 31 (12) 1746-1754
18 Massion PP, Kuo WL, Stokoe D. et al. Genomic copy number analysis of non-small cell lung cancer using array comparative genomic hybridization: implications of the phosphatidylinositol 3-kinase pathway. Cancer Res 2002; 62 (13) 3636-3640
19 Kawano O, Sasaki H, Endo K. et al. PIK3CA mutation status in Japanese lung cancer patients. Lung Cancer 2006; 54 (02) 209-215
20 Okudela K, Suzuki M, Kageyama S. et al. PIK3CA mutation and amplification in human lung cancer. Pathol Int 2007; 57 (10) 664-671
21 Ji M, Guan H, Gao C, Shi B, Hou P. Highly frequent promoter methylation and PIK3CA amplification in non-small cell lung cancer (NSCLC). BMC Cancer 2011; 11: 147
22 Karakas B, Bachman KE, Park BH. Mutation of the PIK3CA oncogene in human cancers. Br J Cancer 2006; 94 (04) 455-459
23 Mitsuishi Y, Taguchi K, Kawatani Y. et al. Nrf2 redirects glucose and glutamine into anabolic pathways in metabolic reprogramming. Cancer Cell 2012; 22 (01) 66-79
24 Abazeed ME, Adams DJ, Hurov KE. et al. Integrative radiogenomic profiling of squamous cell lung cancer. Cancer Res 2013; 73 (20) 6289-6298
25 Chen X, Wu Q, Chen Y. et al. Diosmetin induces apoptosis and enhances the chemotherapeutic efficacy of paclitaxel in non-small cell lung cancer cells via Nrf2 inhibition. Br J Pharmacol 2019; 176 (12) 2079-2094
26 Goeman F, De Nicola F, Scalera S. et al. Mutations in the KEAP1-NFE2L2 pathway define a molecular subset of rapidly progressing lung adenocarcinoma. J Thorac Oncol 2019; 14 (11) 1924-1934
27 Sun X, Wang Y, Ji K. et al. NRF2 preserves genomic integrity by facilitating ATR activation and G2 cell cycle arrest. Nucleic Acids Res 2020; 48 (16) 9109-9123
28 van de Haar J, Canisius S, Yu MK, Voest EE, Wessels LFA, Ideker T. Identifying epistasis in cancer genomes: a delicate affair. Cell 2019; 177 (06) 1375-1383
29 Canale M, Petracci E, Delmonte A. et al. Impact of TP53 mutations on outcome in EGFR-mutated patients treated with first-line tyrosine kinase inhibitors. Clin Cancer Res 2017; 23 (09) 2195-2202
30 Pao W, Wang TY, Riely GJ. et al. KRAS mutations and primary resistance of lung adenocarcinomas to gefitinib or erlotinib. PLoS Med 2005; 2 (01) e17
31 Marchetti A, Martella C, Felicioni L. et al. EGFR mutations in non-small-cell lung cancer: analysis of a large series of cases and development of a rapid and sensitive method for diagnostic screening with potential implications on pharmacologic treatment. J Clin Oncol 2005; 23 (04) 857-865
32 Zhang C, Wang K, Lin J, Wang H. Non-small-cell lung cancer patients harboring TP53/KRAS co-mutation could benefit from a PD-L1 inhibitor. Future Oncol 2022; 18 (27) 3031-3041
33 Gu M, Xu T, Chang P. KRAS/LKB1 and KRAS/TP53 co-mutations create divergent immune signatures in lung adenocarcinomas. Ther Adv Med Oncol 2021; 13: 17 588359211006950
34 Skoulidis F, Goldberg ME, Greenawalt DM. et al. STK11/LKB1 mutations and PD-1 inhibitor resistance in KRAS-mutant lung adenocarcinoma. Cancer Discov 2018; 8 (07) 822-835
35 Sasaki H, Suzuki A, Shitara M. et al. Genotype analysis of the NRF2 gene mutation in lung cancer. Int J Mol Med 2013; 31 (05) 1135-1138
36 Kerins MJ, Ooi A. A catalogue of somatic NRF2 gain-of-function mutations in cancer. Sci Rep 2018; 8 (01) 12846
37 Inoue D, Suzuki T, Mitsuishi Y. et al. Accumulation of p62/SQSTM1 is associated with poor prognosis in patients with lung adenocarcinoma. Cancer Sci 2012; 103 (04) 760-766
38 Campbell JD, Alexandrov A, Kim J. et al; Cancer Genome Atlas Research Network. Distinct patterns of somatic genome alterations in lung adenocarcinomas and squamous cell carcinomas. Nat Genet 2016; 48 (06) 607-616
39 Klein MI, Cannataro VL, Townsend JP, Newman S, Stern DF, Zhao H. Identifying modules of cooperating cancer drivers. Mol Syst Biol 2021; 17 (03) e9810
40 Speicher MR, Howe C, Crotty P, du Manoir S, Costa J, Ward DC. Comparative genomic hybridization detects novel deletions and amplifications in head and neck squamous cell carcinomas. Cancer Res 1995; 55 (05) 1010-1013
41 Pelosi G, Del Curto B, Trubia M. et al. 3q26 Amplification and polysomy of chromosome 3 in squamous cell lesions of the lung: a fluorescence in situ hybridization study. Clin Cancer Res 2007; 13 (07) 1995-2004
42 Heselmeyer K, Schröck E, du Manoir S. et al. Gain of chromosome 3q defines the transition from severe dysplasia to invasive carcinoma of the uterine cervix. Proc Natl Acad Sci U S A 1996; 93 (01) 479-484
43 Singh B, Stoffel A, Gogineni S. et al. Amplification of the 3q26.3 locus is associated with progression to invasive cancer and is a negative prognostic factor in head and neck squamous cell carcinomas. Am J Pathol 2002; 161 (02) 365-371
44 Chen S, Li X, Lu D. et al. SOX2 regulates apoptosis through MAP4K4-survivin signaling pathway in human lung cancer cells. Carcinogenesis 2014; 35 (03) 613-623
45 Lee SH, Oh SY, Do SI. et al. SOX2 regulates self-renewal and tumorigenicity of stem-like cells of head and neck squamous cell carcinoma. Br J Cancer 2014; 111 (11) 2122-2130
46 Xiang R, Liao D, Cheng T. et al. Downregulation of transcription factor SOX2 in cancer stem cells suppresses growth and metastasis of lung cancer. Br J Cancer 2011; 104 (09) 1410-1417
47 Bass AJ, Watanabe H, Mermel CH. et al. SOX2 is an amplified lineage-survival oncogene in lung and esophageal squamous cell carcinomas. Nat Genet 2009; 41 (11) 1238-1242
48 Justilien V, Walsh MP, Ali SA, Thompson EA, Murray NR, Fields AP. The PRKCI and SOX2 oncogenes are coamplified and cooperate to activate Hedgehog signaling in lung squamous cell carcinoma. Cancer Cell 2014; 25 (02) 139-151
49 Sholl LM, Barletta JA, Yeap BY, Chirieac LR, Hornick JL. Sox2 protein expression is an independent poor prognostic indicator in stage I lung adenocarcinoma. Am J Surg Pathol 2010; 34 (08) 1193-1198
50 Iijima Y, Seike M, Noro R. et al. Prognostic significance of PIK3CA and SOX2 in Asian patients with lung squamous cell carcinoma. Int J Oncol 2015; 46 (02) 505-512
51 Best SA, De Souza DP, Kersbergen A. et al. Synergy between the KEAP1/NRF2 and PI3K pathways drives non-small-cell lung cancer with an altered immune microenvironment. Cell Metab 2018; 27 (04) 935-943.e4
52 Cimprich KA, Cortez D. ATR: an essential regulator of genome integrity. Nat Rev Mol Cell Biol 2008; 9 (08) 616-627
53 Cao Y, Bryan TM, Reddel RR. Increased copy number of the TERT and TERC telomerase subunit genes in cancer cells. Cancer Sci 2008; 99 (06) 1092-1099
54 Storti CB, de Oliveira RA, de Carvalho M. et al. Telomere-associated genes and telomeric lncRNAs are biomarker candidates in lung squamous cell carcinoma (LUSC). Exp Mol Pathol 2020; 112: 104354
55 Wu S, Ge Y, Lin K. et al. Telomerase RNA TERC and the PI3K-AKT pathway form a positive feedback loop to regulate cell proliferation independent of telomerase activity. Nucleic Acids Res 2022; 50 (07) 3764-3776
56 Bieging-Rolett KT, Kaiser AM, Morgens DW. et al. Zmat3 is a key splicing regulator in the p53 tumor suppression program. Mol Cell 2020; 80 (03) 452-469.e9
57 Müller T, Hengstermann A. Nrf2: friend and foe in preventing cigarette smoking-dependent lung disease. Chem Res Toxicol 2012; 25 (09) 1805-1824

Figures

Fig. 1 The prevalence and distribution of NFE2L2 mutations in Chinese NSCLC. (A) The prevalence of NFE2L2 mutations in patients with LUAD and LUSC. (B) The distribution of NFE2L2 mutations are shown on protein schematics. Symbols indicate the mutation type and location. LUAD, lung adenocarcinoma; LUSC, lung squamous cell carcinoma; NSCLC, nonsmall cell lung carcinoma.

Fig. 2 Characteristics of co-occurring gene mutations with NFE2L2. (A) Co-mutation genes of NFE2L2 in patients with NSCLC. (B) Volcano plot indicating key co-occurring and mutually exclusive alterations associated with NFE2L2 status in the Chinese NSCLC. (C) Co-occurrence pattern of TERC, ZMAT3, and SOX2 in the TCGA cohort. (D) Heatmap illustrating the co-occurrence pattern of NFE2L2 and genes located at chromosome 3q26. *p < 0.1, ** p < 0.05, ***p < 0.01. NSCLC, nonsmall cell lung carcinoma; TCGA, The Cancer Genome Atlas.

Fig. 3 Survival analyses in the TCGA cohort. (A) Comparison of overall survival between chromosome 3q26 amplification (3q26 amp) versus non-3q26 amplification (non-3q26 amp) tumors in NFE2L2 mutated (NFE2L2 mut) subcohort. (B) Comparison of overall survival between chromosome 3q26 amplification (3q26 amp) versus non-3q26 amplification (non-3q26 amp) tumors in NFE2L2 wild-type (NFE2L2 wt) subcohort. TCGA, The Cancer Genome Atlas.

Fig. 4 Multivariate Cox regression analysis of overall survival (OS). (A) Multivariate Cox regression analysis for OS in the TCGA Pan-Lung Cancer cohort. (B) Comparison of OS in the TCGA LUSC subcohort, including coexisting mutations (CoMut), chromosome 3q26 amplification only (3q26 amp), NFE2L2 mutation only (NFE2L2 mut), and both wild-type (WT) cases. LUSC, lung squamous cell carcinoma; TCGA, The Cancer Genome Atlas.

Supplementary Material

Supplementary Material