Rapid detection of epidermal growth factor receptor mutations with multiplex PCR and primer extension in lung cancer.

Epidermal growth factor receptor (EGFR) kinase domain mutations hyperactivate the kinase and confer kinase addiction of the non-small-cell lung cancer (NSCLC) tumor cells. Almost all of these mutations are located within exons 18-21. The -216 single nucleotide polymorphism in the promoter region is associated with increased EGFR production. We present a method for detecting these common mutations in 81 cases of NSCLC. The protocol is based on the multiplex amplification of promoter region and exons 18-21 of the EGFR genes in a single tube, followed by primer extension of the PCR products using various sizes of primers to detect base changes at -216 promoter region and codons 719, 746-750, 790, 858 of the EGFR gene. We compared the results with that from direct sequencing for detecting EGFR mutations in 81 cases of NSCLC. The two methods identified the same 26 mutations, but our method is superior to direct sequencing in terms of the amount of work and time required. We presented a simple and fast method to detect mutations of EGFR genes in NSCLC.

Background

Lung cancer is one of the most common cancers in the world and is responsible for one third of all cancer-related death. Treatment of lung cancer mainly depends on the type of the cells that make up the cancer. Small-cell lung cancer (SCLC) which comprises about 20% of lung cancers originates from neuroendocrine cells in the bronchus. SCLC responds well to chemotherapy initially, but resistance occurs commonly. Non-small-cell lung cancer (NSCLC), comprising 80% of lung cancers, arises from lung epithelial cells, and comprises diverse histological subtypes that includes adenocarcinoma, bronchioloalveolar, squamous, anaplastic and large-cell carcinomas [1]. NSCLC is often treated with combination cytotoxic chemotherapy, but the treatment only results in a modest increase in survival. The receptor tyrosine kinases (RTKs) serve as cell signalling mediators by receptor-specific ligands. Epidermal growth factor receptor (EGFR) is a member of the ErbB family of RTKs expressed in many cases of NSCLC, and its expression is correlated with a poor prognosis [2-5]. Two EGFR small molecule inhibitors, gefitinib and erlotinib, which target the tyrosine kinase domain of EGFR have been approved for the treatment of advanced NSCLC. Females, Asians, nonsmokers, and those with bronchioloalveolar carcinoma appear to derive the most benefit from gefitinib or erlotinib [6-10]. Molecular analysis showed that the majority of responders harbored specific mutations in the gene that encodes EGFR [8,10-12]. EGFR kinase domain mutations occur primarily in exons 18-21 which encode part of the tyrosine kinase (TK) domain [13-15]. Besides these EGFR kinase domain mutations, a common single nucleotide polymorphisms (SNP) located -216 bp upstream from the initiator ATG in the promoter region also has been identified. The SNP occurs at an important binding site for the transcription factor SP1 that is necessary for activation of EGFR promoter activity and correlates with increased promoter activity and expression of EGFR mRNA [16].

In this study, we performed multiplex amplification of exons 18-21 and promoter of EGFR using five pair of primers followed by primer extension to detect base changes or deletions in codons 719, 746-750, 790, 858, and -216 promoter to analyze the mutational frequency in 81 cases of lung cancer, and compared the results to that obtained by direct sequencing.

Methods

Tissue Procurement

Tumor specimens, obtained from patients on protocols approved by the Institutional Review Board of Changhua Christian Hospital, were collected from eighty-one patients with NSCLC at the time of surgical resection before systemic treatment. All specimens were frozen immediately and stored in liquid nitrogen until DNA was extracted.

DNA extraction, PCR and direct sequencing of the EGFR gene

DNA extraction was performed as previously described [17]. Five separate PCR reactions, each with the corresponding pair of primers, were used to amplify the promoter region and exons 18-21 of the EGFR genes (Table 1). PCR amplification of 0.2 μg DNA was performed with a denaturing step at 94°C for 5 min, then 30 sec at 94°C, 1 min at 58°C, and 1 min at 72°C for 35 cycles, followed by a final 5 min at 72°C. The PCR products were visualized on a 2.5% agarose gel. These PCR products were then subjected to direct sequencing using the same primers, and all mutations were confirmed by sequences originating from both the upstream and downstream primers. Direct sequencing was performed on a Beckman Coulter CEQ 8000 Series Genetic Analysis System (Beckman Coulter Inc., Fullerton, CA, USA) according to manufacturer instructions.

Table 1

PCR Primers used to amplify promoter region and exons 18, 19, 20, and 21 of the EGFR genes

EGFR gene	Sequence
E18-5'	5'-CTGGCACTGCTTTCCAGCAT-3'
E18-3'	5'-GCTTGCAAGGACTCTGGGCT-3'
E19-5'	5'-GCATCGCTGGTAACATCCAC-3'
E19-3'	5'-AGATGAGCAGGGTCTAGAGC-3'
E20-5'	5'-ATCGCATTCATGCGTCTTCA-3'
E20-3'	5'-AGACCGCATGTGAGGATCCT-3'
E21-5'	5'-TGACCCTGAATTCGGATGCA-3'
E21-3'	5'-ATACAGCTAGTGGGAAGGCA-3'
Promoter 5'	5'-CCTCCTCTGCTCCTCCCGAT-3'
Promoter 3'	5'-CGGGGCTAGCTCGGGACT-3'

Multiplex PCR and primer extension analysis of mutations in EGFR-216 promoter region and exons 18, 19, 20, and 21

Multiplex PCR was used to amplify the promoter region and exons 18-21 of the EGFR genes in a single tube. The primers and conditions used for the multiplex PCR were the same as the PCR described above. After multiplex PCR amplification, the PCR products were purified to remove the remaining primers and unincorporated deoxynucleotide triphosphates, using the PCR-M™ Clean Up System (Viogene-biotek Co., Sunnyvale, CA, USA). After removing the primers, the products were subjected to primer extension analysis. Various concentrations of probe for -216 promoter region and exons 18-21 were added to the tube containing 1.5 μl of purified PCR products (Table 2), as well as 4 μl of ABI PRISM SNaPshot Multiplex Kit (Applied Biosystems, Foster City, CA) containing AmpliTaq® DNA polymerase and fluorescently labeled dideoxynucleotide triphosphates (ddNTPs) (RGG-labeled dideoxyadenosine triphosphate, TAMRA-labeled dideoxycytidine triphosphate, ROX-labeled dideoxythymidine triphosphate, and R110-labeled dideoxyguanosine triphosphate). Each 10-μl mixture was subjected to 25 single-base extension cycles consisting of a denaturing step at 96°C for 10 sec, and primer annealing and extension at 60°C for 35 sec. After cycle extension, unincorporated fluorescent ddNTPs were incubated with 1 μl of shrimp alkaline phosphatase (SAP) (United States Biochemical Co., Cleveland, USA), at 37°C for 1 hour, followed by enzyme deactivation at 75°C for 15 min.

Table 2

Primer extension mutation analysis probes for -216 promoter region and codons 719, 746-750, 790, and 858 of the EGFR genes

Nucleotide number and sequence	Amino acid change	Sequence	Size
2155 G>T, 2155 G>A	G719C, G719S	5'-TGAATTCAAAAAGATCAAAGTGCTG-3'	25 mer
2156 G>C	G719A	5'-AAACTGAATTCAAAAAGATCAAAGTGCTGG-3'	30 mer
2235-2249 del	E746-A750 del	5'-GAAGGTGAGAAAGTTAAAATTCCCGTCGCTATCAA-3'	35 mer
2236-2250 del	E746-A750 del	5'-TCCCAGAAGGTGAGAAAGTTAAAATTCCCGTCGCTATCAAG-3'	41 mer
2237-2254 del	E746-T751 del	5'-(T)20AGTTAAAATTCCCGTCGCTATCAAGG-3'	46 mer
2240-2257 del	L747-S752 del	5'-(T)23AGTTAAAATTCCCGTCGCTATCAAGGAAT-3	52 mer
2573 T>G	L858R	5'-(T)26ACCGCAGCATGTCAAGATCACAGATTTTGGGC-3'	58 mer
2369 C>T	T790M	5'-CTCCACCGTGCAGCTCATCA-3'	20 mer
-216 G/T		5'-GGCCGCAGCAGCCTCC-3'	16 mer

The primer extension reaction products were resolved by automated capillary electrophoresis on a capillary electrophoresis platform. Briefly, 14 μl of Hi-Di™ Formamide (Applied Biosystems) and 0.28 μl of GeneScan™ -120LIZ® Size Standard (Applied Biosystems) were added to 6 μl of primer extension products. All samples were loaded and run on an ABI Prism 310 DNA Genetic Analyzer (Applied Biosystems) following the manufacturer's recommendations. Following the run, samples were analyzed using GeneScan™ 3.1 application software (Applied Biosystems).

Results

Patients

We used multiplex PCR plus primer extension method to detect EGFR -216 promoter region and exons 18-21 mutations in 81 cases of NSCLC (Figure 1). Histologically, there were 26 adenocarcinomas, 6 bronchioloaveolar carcinomas, 33 squamous cell carcinomas, 5 adenosquamous carcinomas, and 11 other types of NSCLCs.

Figure 1

Detection of wild-type and mutant . NSCLC DNA samples of wild-type EGFR and ones containing the following mutations: -216 G/T, 2235-2249 del, 2236-2250 del, 2240-2257 del, and 2573 T>G.

Multiplex PCR and primer extension

For mutation analysis of codons 719 in exon 18, we used different-sized primers to recognize the change of the first and second base separately. In-frame deletion between codon 746 and 752 in codon 19 was analyzed with primers made to be different in size either by adding different lengths of poly(dT) tails to the 5'-end or extending the primer sequence to allow separation based on the differences in size. SNP at -216 promoter region and missense mutations which result in L858R change in exon 21 and T790M in exon 20 were each analyzed with a single probe.

The overall mutation (in EGFR TK domain and -216 promoter) rate was 32% (26 of 81).

Mutations in exons 18-21 of EGFR TK domain were detected in 19 (23%) of the 81 NSCLCs in which there were 12 adenocarcinomas, three bronchioloaveolar carcinomas, two squamous cell carcinomas, one adenosquamous carcinoma, and one other type of NSCLC. No mutation was detected at codon 719 in exon 18 and codon 790 in codon 20. Seven tumors had in-frame deletions within exon 19, resulting in the loss of codons 746 through 750 in six tumors, and loss of codon 747 through 752 in one tumor. 12 cases had a 2573 T>G mutation resulted in L858R change. SNP -216 in the promoter region were detected in seven (8.6%) cases that include three adenocarcinomas, one bronchioloaveolar carcinoma, three squamous cell carcinomas. Three patients with SNP -216 in the promoter region had another mutation in exon 21 (L858R). Results of the multiplex PCR and primer extension mutation analysis of the EGFR gene are listed in Table 3.

Table 3

Mutation analysis of the EGFR gene by multiplex PCR and primer extension.

	Case(s) with EGFR mutation(s)
NSCLC subtype		E746-A750 del		L747-S752 del	L858R
	-216 G/T	2235-2249 del	2236-2250 del	2240-2257 del	2573 T>G
Adenocarcinoma (n = 26)	3	1	3	0	8
Bronchioloalveolar carcinoma (n = 6)	1	2	0	0	1
Squamous cell carcinoma (n = 33)	3	0	0	0	2
Adenosquamous carcinoma (n = 5)	0	0	0	1	0
Others (n = 11)	0	0	0	0	1
Total (n = 81)	7	3	3	1	12

Direct Sequencing

We also used direct sequencing to analyze the -216 promoter region and exons 18-21 of the EGFR gene. The results of sequencing analysis were identical to the results of multiplex PCR with primer extension analysis. No other mutation was identified by direct sequencing. We can therefore conclude that our method was very accurate in profiling the most common EGFR mutations in NSCLC.

Discussion

EGFR proteins control essential signaling pathways that regulate cell proliferation [18]. Increased levels of EGFR gene expression are observed in many cancers, including NSCLC, and its expression is correlated with an adverse prognosis [2-4,19]. Clinical responsiveness to gefitinib and erlotinib in NSCLC have been shown to correlate with somatic mutations in the EGFR gene, which result in increased sensitivity to inhibition of growth by the drugs [8,10-12]. EGFR mutations have been found more frequently in non-smoking East Asian women with adenocarcinoma with bronchioalvelar features [14,20-26].

A protocol based on mutant-enriched PCR followed by primer extension of the PCR products was used to detect EGFR T790M mutation in NSCLC [27]. We recently demonstrated a simple and fast way to identify K-RAS mutation [17]. In this study, we extend the application to detect -216 promoter region and exons 18-21 mutations of EGFR gene simultaneously and apply this method to investigate the mutation status in 81 cases of NSCLC. We compared the results with that from direct sequencing for detecting EGFR mutations in 81 cases of NSCLC. The two protocols identified the same 26 mutations, but the new method is superior to direct sequencing in terms of the amount of work and time required. With this method, -216 promoter region and exons 18-21 of the EGFR gene were amplified with multiplex PCR in a single tube and the detection of mutations in the EGFR promoter and four key exons can be combined into one assay. This allows a sample to be screened for all common EGFR mutations simultaneously. We previously reported that that as little as 10 ng of DNA was enough for the multiplex PCR reaction and we also showed that this method can detect mutations against a background of up to at least 23 wild-type alleles [3]. Moreover, because the technique is a sequencing-based approach, additional sequencing is not necessary.

Distinguishing sequence variants with primer extension is based on the high accuracy of nucleotide incorporation catalyzed by a DNA polymerase. Current products of the thermostable enzymes used in primer extension have very low error rates and are specific for ddNTPs [28]. These characteristics provide negligible primer misincorporation and excellent discrimination between wild, heterozygous and homozygous genotypes. Another advantage of the primer extension reaction is its multiplexing capability, with several mutations being detected in a single reaction tube. Multiplex PCR-SSCP- or PCR-ARMS-based methods can also simultaneously detect several mutations. However, PCR-SSCP require further confirmation by direct sequencing, and PCR-ARMS require more primers than are possible in a single reaction to detect all mutations at -216 promoter region and exons 18-21 of the EGFR gene. The primer extension reaction is a less time-consuming assay because automated fluorescent capillary electrophoresis of the products requires only 25 minutes in comparison with capillary electrophoresis required for standard sequencing that takes more than an hour.

Conclusions

The method that we demonstrated in this report provides a rapid way to identify common EGFR mutations for the purpose of clinical evaluation in NSCLC. The method can also be applied in the detection of other mutations in the EGFR gene.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

CHL performed PCR and primer extension and draft the manuscript, KTY participated in the design of the study, YSC performed direct sequencing, NCH participated in the analysis and helped to draft the manuscript, JGC designed the study.