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. 2020 Aug 5;8(10):e1395. doi: 10.1002/mgg3.1395

Oncogenic mutations within the β3‐αC loop of EGFR/ERBB2/BRAF/MAP2K1 predict response to therapies

Biao Zhang 1, Yongsheng Chen 2,3, Pingping Dai 2,3, Haoda Yu 4, Jianhui Ma 2, Chen Chen 2,3, Yan Zhang 2,3, Yanfang Guan 2,3, Rongrong Chen 2, Tao Liu 2,3, Jiayin Wang 3, Ling Yang 2, Xin Yi 2, Xuefeng Xia 2, Haitao Ma 1,
PMCID: PMC7549570  PMID: 32757330

Abstract

Background

β3‐αC loop is a highly conserved structural domain across oncogene families, which is a switch for kinase activity. There have been numerous researches on mutations within β3‐αC loop in EGFR, but relatively less in ERBB2, BRAF, and MAP2K1. In addition, previous studies mainly focus on β3‐αC deletion in EGFR, which is the most common type affecting kinase activity and driving lung cancer. Other mutation types are not well studied.

Methods

Here we analyzed the profile of β3‐αC loop mutations in a total of 10,000 tumor biopsy and/or ctDNA patient samples using hybridization capture‐based next‐generation sequencing.

Results

We identified 1616 mutations within β3‐αC loop in this cohort. Most mutations were located in EGFR, with less percentage in ERBB2, BRAF, and MAP2K1. EGFR β3‐αC deletions occurred at a high percentage of 96.7% and were all drug‐relevant. We also detected rare EGFR β3‐αC insertions and point mutations, most of which were related to EGFR TKIs resistance. ERBB2 β3‐αC deletions were only found in breast cancers and sensitive to EGFR/ERBB2 inhibitor. Moreover, BRAF and MAP2K1 mutations within β3‐αC loop also demonstrated drugs relevance.

Conclusion

Our study showed that oncogenic mutations within the β3‐αC loop of ERBB2, MAP2K1, and BRAF are analogous to that of EGFR, which have profound effect on drug response. Understanding the mutation profile within the β3‐αC loop is critical for targeted therapies.

Keywords: BRAF, EGFR, ERBB2, MAP2K1, Oncogenic mutations, β3‐αC loop

Oncogenic alterations within the kinase domain β3‐αC loop, which is highly conserved across oncogene families, are very common in human cancers. Therefore, understanding the spectrum of β3‐αC loop mutations within these genes is critical for target therapies. Motivated by this, we analyzed tumor biopsy and/or ctDNA samples of a large cohort of patients (10,000) using hybridization capture‐based next‐generation sequencing and summarized different alterations in this region and the possible response to target therapy. Our findings provided a comprehensive instruction for target therapies for cancer patients.

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1. INTRODUCTION

Protein kinases usually have a structurally conserved domain and the way that the structural elements tend to fold determines the activation status of the kinases (Scheeff & Bourne, 2005). The structure will change in response to upstream signaling and thus lead to activation or inactivation of the kinases, which then regulates different biological activities. Mutations in this region or mutations that lead to the structure change will affect kinase activity and the downstream signaling. In one study, they analyzed somatic mutations across the kinome. They mapped significantly mutated positions (SMPs) of protein kinases and identified 23 SMPs. These SMPs are located at certain structural regions, such as activation loop (A‐loop), nucleotide binding P‐loop, the αC‐helix, the N‐ or C‐terminal to the αC‐helix (the β3‐αC loop and the αC‐β4 loop, respectively), and the catalytic loop (C‐loop; Kumar & Bose, 2017). β3‐αC loop in kinase domain is highly conserved across oncogene families. Deletions in the β3‐αC loop of HER2 and BRAF have been shown to resemble EGFR exon 19 deletions (Foster et al., 2016). Exon 19 deletion within EGFR β3‐αC loop affecting kinase activity and driving lung cancer has been described (Chung et al., 2012).

Since kinase signaling pathways are involved in regulating multiple cellular processes, including proliferation, survival, motility, differentiation, and metabolism, activation of these signaling is frequently found in all kinds of tumors (Gross, Rahal, Stransky, Lengauer, & Hoeflich, 2015; Hanahan & Weinberg, 2011). Kinase activation can be caused by different mechanisms, such as point mutations, in‐frame deletions or insertions, and gene fusions (Foster et al., 2016).

There are a variety of anticancer drugs designed for targeting oncogenically activated kinases. The efficacy of some drugs could be affected by structure changes in the kinase domain. For example, drugs that target kinase activation in BRAF‐mutant cancers depend on structural variations in the BRAF kinase domain. BRAF exon 12 deletions within the β3‐αC loop, which is required for kinase activation, make the tumors resistant to “first‐generation” BRAF‐V600E inhibitors (Chakraborty et al., 2016). Recently, two new activating mutations of BRAF involving the β3‐αC loop in anaplastic pleomorphic xanthoastrocytoma were identified and patients with these mutations were predicted to be resistant to kinase inhibitors (Pratt et al., 2018). On the other hand, BRAF V600E mutation is often sensitive to small molecular kinase inhibitors (Cantwell‐Dorris, O'Leary, & Sheils, 2011; Holderfield, Deuker, McCormick, & McMahon, 2014).

Although β3‐αC loop widely exists in kinds of oncogenes, researches on mutations within this structure mainly focus on EGFR exon 19 deletions. Other mutation types and mutations in other oncogenes accommodating β3‐αC loop were not well understood. Here we analyze the profile of β3‐αC loop mutations within important oncogenes, EGFR, ERBB2, BRAF, and MAP2K1, and the potential implications on sensitivity to therapeutic drugs in Chinese patients.

2. MATERIALS AND METHODS

2.1. Patients and sample collection

Between October 2015 and July 2018, 10,000 patients with advanced cancer from China received next‐generation sequencing (NGS) testing in Geneplus‐Beijing Institute. For each patient, signed consent form was obtained before starting the test. Tissue including fresh, formalin‐fixed, paraffin‐embedded samples, or plasma samples was obtained. Tumor specimens were reviewed by qualified pathologists to confirm the diagnosis of tumor types and ensure > 20% tumor content. At the same time, peripheral blood was collected using EDTA Vacutainer tubes (BD Diagnostics) as a source of matched normal (germline) sample. As for plasma testing, 10‐ml peripheral blood was collected from each patient in cell‐free DNA BCT tubes (Streck) and processed within 72 hr of sample collection.

2.2. Sample processing and DNA extraction

Extraction of DNA was performed as previously described (Nong et al., 2018). Genomic DNA was extracted from FFPE samples using Maxwell® RSC DNA FFPE Kit (Promega). Plasma was separated by centrifugation at 1,600 g for 10 min, transferred to new microcentrifuge tubes, and centrifuged at 16,000 g for 10 min to remove remaining cell debris. Peripheral blood lymphocytes (PBLs) from the initial spin were used for isolation of germline genomic DNA. PBL DNA was extracted using the DNeasy Blood & Tissue Kit (Qiagen). Cell‐free circulating DNA was isolated from plasma using QIAamp Circulating Nucleic Acid Kit (Qiagen). DNA concentration was measured using a Qubit fluorometer and the Qubit dsDNA HS (High Sensitivity) Assay Kit (Invitrogen, Carlsbad). With that, the size distribution of plasma DNA was assessed using an Agilent 2100 BioAnalyzer and the DNA HS kit (Agilent Technologies).

2.3. Sequencing library construction and target enrichment

Before library construction, genomic DNA extracted from PBL or FFPE specimen was sheared to 300 bp fragments with a Covaris S2 ultrasonicator (Covaris). KAPA Library Preparation Kit (Kapa Biosystems) was adopted to prepare indexed Illumina NGS libraries from PBL DNA, tumor DNA, and plasma DNA. Target enrichment was performed with a custom SeqCap EZ Library (Roche NimbleGen). The capture probe designed based on cancer genomic regions of 59 genes or 1021 genes was used in this study to explore the comprehensive genetic properties of advanced solid tumors. Capture hybridization was carried out according to the manufacturer's protocol. Following hybrid selection, the captured DNA fragments were amplified and then pooled to generate several multiplex libraries.

2.4. NGS Sequencing and data analysis

Sequencing was carried out using Illumina 2 × 75 bp paired‐end sequencing on Illumina HiSeq 3000 instruments, using TruSeq PE Cluster Generation Kit v3 and the TruSeq SBS Kit v3 (Illumina) according to the manufacturers’ recommendations. After removal of terminal adaptor sequences and low‐quality data, reads were mapped to the reference human genome (hg19) and aligned using BWA (0.7.12‐r1039; Li & Durbin, 2009).

GATK (https://www.broadinstitute.org/gatk/, The Genome Analysis Toolkit), MuTect2 (3.4‐46‐gbc02625; Cibulskis et al., 2013), and in‐house algorithm NChot (Yang et al., 2017) were employed to call somatic small insertions and deletions (indel), and single nucleotide variants (SNV) by filtering PBL sequencing data. Contra (2.0.8) was used to detect copy number variations (Li et al., 2012). For structure variations (SV), an in‐house algorithm NCSV was used to identify split‐read and discordant read‐pair to identify SVs (Yang et al., 2020).

For the sequence variant nomenclature, we followed the Human Genome Variation Society (HGVS) recommendations and used the transcript references as below: EGFR NM_005228.3, ERBB2 NM_004448.2, BRAF NM_004333.4, MAP2K1 NM_002755.3.

2.5. Actionable mutation assessment

Sequence mutations were annotated according to in‐house database, a curated knowledge base of the oncogenic effects and treatment implications of somatic mutations. According to the level of evidence that the mutation is a predictive biomarker of drug response, mutations were classified in a tumor type‐specific manner.

3. RESULTS

3.1. Key genetic alterations identified in patients

Total of 10,000 patients diagnosed with advanced cancer between October 2015 and July 2018 were included in this study, with 65.5% of all patients were lung cancer, 7.3% were breast cancer, 1.4% were pancreatic cancer, 7.6% were colorectal, and 18.1% were other cancer types. All patients received NGS testing. We identified 1616 mutations within β3‐αC loop of protein kinases EGFR, ERBB2, BRAF, and MAP2K1 in the cohort. Of these mutations, 97.8% (1583/1616) were found in lung cancer, with 96.71% (1530/1583) of the mutations in lung cancer were located in EGFR, 1.1% (17/1583) located in ERBB2, 0.7% (12/1583) located in BRAF, and 1.4% (23/1583) in MAP2K1 (Table 1 and Figure 1a). Of all mutations identified here, 1.2% (20/1617), 0.25% (4/1617), 0.19% (3/1617), and 0.49% (8/1617) were found in breast cancer, colorectal cancer, pancreatic cancer, and others, respectively. Hundred percent of the mutations found in breast cancer were located in ERBB2 and similarly, BRAF accounts for all mutations in colorectal cancer and MAP2K1 in pancreatic cancers. The kinase domain β3‐αC loop is highly conserved across oncogenes and also resides in ERBB2, BRAF, and MAP2K1 (Figure 1b). Interestingly, we found that mutations in this region of EGFR, BRAF, ERBB2, and MAP2K1 were mutually exclusive (Figure 1c), which is consistent with a previous report (Arcila et al., 2015) that suggested one driver mutation is sufficient cancer initiation or development.

Table 1.

Distribution of identified mutations in different cancer types

Total mutation Genes Lung cancer Breast cancer Colorectal cancer Pancreatic cancer Other cancers
1530 EGFR 1,530 (96.7%)
38 ERBB2 17 (1.07%) 20 (100%) 1 (14%)
18 BRAF 12 (0.70%) 3 (100%) 3 (43%)
30 MAP2K1 23 (1.45%) 4 (100%) 3 (43%)
Total 1616 1583 (97.8%) 20 (1.2%) 4 (0.25%) 3 (0.19%) 7 (0.43%)
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Number in brackets indicates the percentage of certain type of cancer that harbors the corresponding gene mutation. The transcript references are as below: EGFR NM_005228.3, ERBB2 NM_004448.2, BRAF NM_004333.4, MAP2K1 NM_002755.3.

Figure 1.

Figure 1

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Distribution of key mutations within β3‐αC loop of protein kinases EGFR, ERBB2, BRAF, and MAP2K1. (a) Percentage of each mutation in lung cancer samples. (b) Amino acid sequence of β3‐αC loop of protein kinases EGFR, ERBB2, BRAF, and MAP2K1. (c) Mutations in β3‐αC loop of protein kinases EGFR, ERBB2, BRAF, and MAP2K1 in lung cancer are mutually exclusive. The transcript references are as below: EGFR NM_005228.3, ERBB2 NM_004448.2, BRAF NM_004333.4, MAP2K1 NM_002755.3

3.2. Characteristics of EGFR mutations and clinical indication

All EGFR β3‐αC alterations were found in lung cancer patients and EGFR β3‐αC deletions were present in a very high frequency of 96.7% (1479/1530), with the most frequent deletion of amino acids glutamic acid‐leucine‐arginine‐glutamic acid‐alanine (also referred to as ΔELREA), followed by lower frequencies of ∆LREATS, P753S, and ∆LREAT. We also found 12 patients harboring rare EGFR β3‐αC insertion (I740_K745dup, also referred to as K745_E746insIPVAIK), which was reported as tyrosine kinase inhibitor (TKI)‐sensitive mutation (Kobayashi & Mitsudomi, 2016). Although the therapeutic response of patients with EGFR β3‐αC deletions to different EGFR TKIs was slightly different, all the patients with the deletions were sensitive to EGFR TKI treatment. This is consistent with previous study that patients with LRE deletions were associated with better response to TKIs than those with non‐LRE deletions in exon 19 (Chung et al., 2012). We were also able to identify 38 (24.8%, 38/1530) missense mutations within β3‐αC region and among these, 34% (13/38), that is p.L747P and 3 p.L747S (Table 2), showed influence on kinase activities and were found to be resistant to EGFR TKI treatment according to previous studies (Liu, Wu, Zhong, Hui, & Fang, 2013; Wang, Ning, Li, & Huang, 2016; Wu et al., 2011; Yamaguchi et al., 2014; Yamaguchi, Kugawa, Tateno, Kokubu, & Fukuchi, 2012; Yu et al., 2015).

Table 2.

Major alterations in β3‐αC region of EGFR, ERBB2, BRAF, and MAP2K1 genes in lung cancer

EGFR_mis EGFR β3‐αC delins ERBB2 MAP2K1 BRAF mutations
p.L747P (10) p.E746_A750del (978) p.L755P (5) p.E102_I103del (15) p.N486_P490del (2)
p.V742I (6) p.L747_P753delinsS (131) p.D769Y (2) p.P105_A106del (4) p.K483E (3)
p.V742L (5) p.L747_T751del (79) p.K753E (2) p.Y134F (1) p.D479N (2)
p.D761Y (4) p.L747_A750delinsP (66) p.I767M (1) p.A106T (1) p.L485F (1)
p.L747S (3) p.E746_T751delinsA (31) p.D769H (1) p.V127M (1) p.E501K (1)
p.I744M (2) p.E746_S752delinsV (28) p.I740M (1) p.I99V (1) p.K483Q (1)
p.I759M (2) p.L747_S752del (22) p.L607Q (1) p.Q496* (1)
p.K757M (2) p.L747_T751delinsP (16) p.L755V (1) p.N486_A489delinsK (1)
p.E734D (1) p.L747_E749del (12) p.S760del (1)
p.I759N (1) p.I740_K745dup (12) p.I767F (1)
p.K757L (1) Others together (117) p.L755S (1)
p.L747C (1)
DR 34% (13/38) a 100% a 59% (10/17) 70% (16/23)§ 50% (6/12)
Total 38 1,492 17 23 12
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DR, percentage of drug‐relevant mutations; Red color indicates the drug‐relevant mutations. The transcript references are as below: EGFR NM_005228.3, ERBB2 NM_004448.2, BRAF NM_004333.4, MAP2K1 NM_002755.3.

a

Sensitive to EGFR TKI.

b

Related to the efficacy of HER2 target therapy.

c

Related to MEK target therapy.

d

Related to BRAF/MEK target therapy.

3.3. Characteristics of ERBB2, BRAF, and MAP2K1 mutations and clinical indication

ERBB2 β3‐αC deletions (ΔLRENT) were only detected in breast cancers, which were sensitive to EGFR/ERBB2 inhibitor neratinib and resistant to lapatinib. In lung cancer, most of the ERBB2 β3‐αC mutations are point mutations and the percentage of drug‐relevant mutations was 59% (10/17; Table 2, red). Sixty‐one percent (11/18) of BRAF mutations were found in lung cancers and 16.7% (3/18) in pancreatic cancers. About 45.5% (5/11) of lung cancer patients with BRAF β3‐αC loop mutations demonstrated drug relevance. We detected 23 (23/30 = 76.7%) MAP2K1 mutations in lung cancer patients and four (4/30 = 13.3%) in colorectal cancer patients. In contrast to ERBB2, most of MAP2K1 mutations found in lung cancer are β3‐αC deletions. Seventy percent (15/23) of the mutations in this region were drug‐relevant.

4. DISCUSSION

In this study, we analyzed a large number of 10,000 patients with advanced cancers for oncogenic mutations in EGFR, ERBB2, BRAF, and MAP2K1, especially for those located within the kinase domain β3‐αC loop. In addition, we summarized the effect of these mutations on the sensitivity to target therapy, that is TKIs. These data not only refined our understanding of the mutation profile within β3‐αC loop of these kinase domain but also provided a comprehensive instruction for target therapies.

Most kinase domain β3‐αC loop deletions/insertions or point mutations are activating mutations as shown in a previous study (Foster et al., 2016). We found an interesting phenomenon that mutations in this region of EGFR, BRAF, ERBB2, and MAP2K1 were mutually exclusive, indicating changes in this region of these kinases function similarly to drive tumorigenesis. This finding supports the opinion that single driver mutation is required for oncogene addiction in lung tumors (Gazdar, Shigematsu, Herz, & Minna, 2004). EGFR is one of the most frequently altered genes in lung cancer, especially in Asian adenocarcinoma subgroup (Dearden, Stevens, Wu, & Blowers, 2013). Most EGFR gene mutations can be targeted for therapy and thus is considered the most common “actionable” mutation in lung cancer patients (Castellanos, Feld, & Horn, 2017). In our study, most of the kinase β3‐αC loop alterations found in lung cancer were from EGFR with all β3‐αC indels, and 34% of point mutations in this region were drug‐relevant alterations. About 59% ERBB2 mutations, 65% MAP2K1 mutations, and 50% BRAF mutations in this region were drug‐relevant, confirming the importance of β3‐αC loop for kinase functions.

Genetic alterations in MAPK/ERK pathway are very common in non‐small cell lung cancer (NSCLC), especially mutations found in the upstream members, EGFR and KRAS, which account for 70% or more of all known driver mutations (Ladanyi & Pao, 2008; Riely et al., 2008). Alterations in BRAF and MAP2K1 (MEK1) are less common, with BRAF mutations well studied and MAP2K1 mutation remaining relatively undefined with a close association with smoking (Arcila et al., 2015; Marks et al., 2008; Paik et al., 2011). In our study, we found similar genetic alterations in kinase β3‐αC loop and that the majority of them are localized in EGFR gene. Human epidermal growth factor receptor 2 (HER2; ERBB2) is tyrosine kinase receptor and the mutation or amplification of which have been linked with human cancers, with lung cancer and breast cancer the most common (Connell & Doherty, 2017). We found about 52.6% (20/38) of ERBB2 mutations were from breast cancer patients and 44.7% (17/38) were from lung cancer patients, with 59% of all mutations in β3‐αC loop were druggable.

In conclusion, based on a large cohort of cancer patients, our study analyzed mutations in β3‐αC loop in kinase domain of EGFR, ERBB2, MAP2K1, and BRAF, and summarized the drug‐relevant mutations of each gene. These results highlighted the significance of β3‐αC loop in kinase domain and generated valuable mutation profiles of this region, thus providing insight into the target therapies that rely on these mutations.

CONFLICT OF INTEREST

The authors declare that there is no conflict of interest regarding the publication of this paper.

AUTHOR CONTRIBUTIONS

Collection of clinical data: Haoda Yu, Jiayin Wang, Ling Yang, and Xin Yi; Data analyzed and interpreted: Yongsheng Chen, Yan Zhang, Yanfang Guan, Rongrong Chen, and Tao Liu; Writing and review of original draft of the manuscript: Biao Zhang, Jianhui Ma, Pingping Dai, ChenChen, Xuefeng Xia, and Haitao Ma.

Zhang B, Chen Y, Dai P, et al. Oncogenic mutations within the β3-αC loop of EGFR/ERBB2/BRAF/MAP2K1 predict response to therapies. Mol Genet Genomic Med. 2020;8:e1395 10.1002/mgg3.1395

Biao Zhang, Yongsheng Chen, Pingping Dai authors contribute equally to this work.

Funding information

This study was supported by the National Natural Science Foundation of China (No. 81672281), and Natural Science Foundation of Jiangsu Province (No. B:K20191174); Grants LCZX201402; National Science Foundation of China (Grant No: 31701150), the Fundamental Research Funds for the Central Universities (CXTD2017003), and Liaoning Province Natural Science Foundation Grant (20180550161).

DATA AVAILABILITY STATEMENT

The data that support the findings of this study are available from the corresponding author upon reasonable request.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

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