EGFR copy number alterations in primary tumors, metastatic lymph nodes, and recurrent and multiple primary tumors in oral cavity squamous cell carcinoma
The EGFR and downstream signaling pathways play an important role in tumorigenesis in oral squamous cell carcinoma (OSCC). Gene copy number alteration is one mechanism for overexpressing the EGFR protein and was also demonstrated to be related to lymph node metastasis, tumor invasiveness and perineural invasion. Therefore, we hypothesized that EGFR gene copy number alteration in the primary tumor could predict amplification in recurrent tumors, lymph node metastatic foci or secondary primary tumors.
Methods
We recruited a group of newly diagnosed OSCC patients (n = 170) between Mar 1997 and Jul 2004. Metastatic lymph nodes were identified from neck dissection specimens (n = 57). During follow-up, recurrent lesions (n = 41) and secondary primary tumors (SPTs, n = 17) were identified and biopsied. The EGFR gene amplifications were evaluated by fluorescence in situ hybridization (FISH) assay in primary tumors, metastatic lymph nodes, recurrences and SPTs.
Results
Of the 170 primary OSCCs, FISH showed low EGFR amplification/polysomy in 19 (11.4%) patients and amplification in 33 (19.8%) patients. EGFR gene amplification was related to lymph node metastasis (χ2 trend test: p = 0.018). Of 57 metastatic lymph nodes, nine (15.8%) had EGFR polysomy and 14 (24.6%) had EGFR gene amplification. The concordance rate of EGFR gene copy number in primary tumors and lymph node metastasis was 68.4% (McNemar test: p = 0.389). Of 41 recurrent tumors, five (12.2%) had EGFR polysomy and five (12.2%) had gene amplification. The concordance rate of EGFR gene copy number between primary tumors and recurring tumors was 65.9% (McNemar test: p = 0.510). The concordance rate between primary tumors and SPTs was 70.6%. EGFR amplification in either primary tumors, metastatic lymph nodes or recurrent tumors had no influence on patient survival.
Conclusion
We can predict two-thirds of the EGFR gene copy number alterations in lymph node metastasis or recurrent tumors from the analysis of primary tumors. For OSCC patients who are unable to provide lymph node or recurrent tumor samples for EGFR gene copy number analysis, examining primary tumors could provide EGFR clonal information in metastatic, recurrent or SPT lesions.
The online version of this article (10.1186/s12885-017-3586-9) contains supplementary material, which is available to authorized users.
Abkürzungen
AQ
Areca-quid
DFS
Disease-free survival
FISH
Fluorescence in situ hybridization
LA/Poly
Low amplification/polysomy
NSCLC
Non-small cell lung cancer
OS
Overall survival
OSCC
Oral squamous cell carcinoma
SPT
Secondary primary tumor
Background
In Taiwan, oral cancer is the 4th most common cancer in men [1]. The consumption of areca-quid (AQ), tobacco and alcohol among Taiwanese men results in an increase in oral cancer risks about ten-fold higher than women and its incidence is rising [2]. The primary treatment for oral cavity squamous cell carcinoma (OSCC) is radical surgery with or without post-operative adjuvant radio−/chemotherapy and this treatment approach can result in good loco-regional control [3]. Some patients have recurrence and/or distant metastasis after these radical treatments. Among the poor prognostic factors for OSCC discussed by O’Brien et al., cervical lymph node metastasis is just as important as tumor stage, the extent of the tumor invasion, and perineural/lympho-vascular invasion in adversely influencing tumor control [4‐6]. We previously demonstrated that lymph node metastasis, tumor cell differentiation and perineural invasion and tumor stage are correlated with EGFR gene amplification [7]. Those previous findings indicate that tumor cells with EGFR amplification are invasive. These tumor cells are more likely to proliferate in recurrent tumors and metastasize to the lymph nodes. It is therefore worthwhile to investigate tumor cells with increased EGFR amplification because the number of EGFR copies plays an important role in metastasis, recurrence or development of secondary primary tumors (SPTs).
Regarding the concordance between the number of EGFR gene copies and primary tumor and metastatic lesions in non-small cell lung cancer, the discordant rate ranges from 27 to 32% [8‐11]. Due to mucosal “field cancerization”, OSCC patients carry a higher risk of developing SPTs in their head and neck region [12, 13]. The genetic alterations between the primary lesion and secondary primaries are more complex and reflected in markers such as TP53, microsatellite markers or the D-loop region in mitochondria [14, 15]. However, the concordance rate varies depending on the markers used. Our aim in this study was therefore to determine the clonality of EGFR from the primary tumor, metastatic lesion, recurrence and SPT lesions in OSCCs.
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We hypothesized that the number of EGFR gene copy alterations in the primary tumor can predict whether tumors will reoccur or whether patients will be at risk for lymph node metastasis. Current knowledge how tumor cells with EGFR gene copy number alterations in the primary tumor are related to metastases and recurrences in OSCC is limited. More specifically, until now no investigations had been conducted in an oral cavity cancer. Therefore, in our study, the status of EGFR gene copy number was investigated in paired samples from a series of primary OSCC lesions and corresponding lymph node metastases, recurrent tumors and even multiple primary tumors. By clarifying the clonality of the EGFR gene status in paired tumor specimens, we can determine whether EGFR amplified cells bear the invasive characters in metastasis or recurrence in oral cavity cancer.
Methods
Patients, tissue specimens and clinical diagnosis
This study was approved by the Institutional Review Board of Chang Gung Memorial Hospital. One hundred and seventy oral cancer patients treated at Chang Gung Memorial Hospital, Lin-Kuo, were recruited for participation in this study. All patients gave informed consent for participation and were interviewed uniformly before surgery by a well-trained interviewer. The questionnaire used in the interview sought detailed information on general demographic data, current and past cigarette smoking, alcohol consumption, areca-quid (AQ) chewing, and a history of family disease (Additional file 1). All patients received curative intent surgery as an initial treatment. In the surgeries, the primary tumors were excised with safety margins greater than or equal to 1 cm (for both peripheral and deep margins). The tumor margin tissue was cryosectioned to ensure that the margin was free of tumor. For each patient, clinical histological parameters were scored according to the recommendations for the reporting of specimens containing oral cavity and oropharynx neoplasms by the Association of Directors of Anatomic and Surgical Pathology (ADASP) [16].
Metastatic lymph nodes
For patients who received radical surgeries, neck dissection was performed according to the tumor stage of the patients. Two types of neck dissections were used in our patients: one was a dissection of level I-III lymph nodes (supraomohyoid neck dissection) for nodal negative patients; and the other was a dissection of level I-V lymph nodes (usually a modified radical neck dissection) for nodal positive patients. We selected pathologically proven metastatic lymph nodes from the neck dissection specimens.
Patients with advanced tumor status (T3 or T4), lymph node extracapsular spread, tumor depth ≥ 10 mm or poor differentiation, adjuvant radiotherapy or cisplatin-based concomitant chemoradiotherapy would be given after surgery.
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Recurrence and secondary primary lesions
After radical surgeries with or without adjuvant chemo-radiotherapy, the patients received regular follow-up visits. For tumors growing nearby the primary tumor, in the neck or distant sites, the lesions were recorded as recurrences. In the head and neck region, the mucosa carries similar risks for developing malignancies. Lesions that were located in different tumor subsites from the primary tumor or a 2 cm distance from the primary lesion in the mucosa were recorded as secondary primary lesions [17]. The secondary lesions could occur simultaneously with the primary lesion (synchronous) or be found during regular follow-up appointments in the clinic after surgeries (metachronous).
FISH assay and analysis
EGFR gene copies were investigated with FISH using the LSI EGFR SpectrumOrange/CEP 7 SpectrumGreen probe (Vysis; Abbott Laboratories, Downers Grove, IL) according to the manufacturer’s instructions and our previous report [7]. In brief, section slides were incubated at 56 °C overnight, deparaffinized, dehydrated, treated with 0.2 N HCl (pH 2.5) for 20 min, and treated with 1 M sodium thiocyanate (Sigma-Aldrich Corp., St. Louis, MO) in 1 M Tris (pH 8.0) at 82 °C for 20 min. Then the specimens were digested with 0.4% pepsin (Sigma-Aldrich Corp., St. Louis, MO) in 0.9% NaCl (pH 2.35) for 15 min. The samples were briefly rinsed in ddH2O and 2 × SSC between steps. After fixation in 4% formaldehyde for 5 min, each slide had the probe set applied to a selected area, and the hybridization area was covered with a plastic coverslip and sealed with a glue gun before the slides were heated at 75 °C for 10 min with OmniGene (Hybaid Ltd., Middlesex, United Kingdom) to promote co-denaturation of chromosomal and probe DNAs. Hybridization was carried out in a humidified oven at 37 °C for 18 h, followed by post-washing in 0.3% Nonidet P40 (BDH, England) in 2 × SSC at 45 °C for 4 min, in 2 × SSC at 45 °C for 5 min, and finally twice in 2 × SSC at room temperature for 5 min. After being counterstained with DAPI for 5 min, the slides were mounted with Vectashield mounting medium (Vector Laboratories, Burlingame, CA) and scored under an fluorescent microscope using a Plan Neofluar 100× objective (Axiophot, Zeiss, Germany) with dual and triple pass filters (Chroma Technology Corp., Rockingham, VT). At least 100 non-overlapping nuclei per case were scored independently by two independent observers who followed strict scoring guidelines and used constant adjustment of the microscope’s focus because signals were located in different focal planes. In each nucleus, the number of EGFR copies and chromosome 7 probes were assessed independently.
FISH patterns were classified into 3 strata based on the number of copies of the EGFR gene per cell as described in previous studies [7, 18, 19]. The strata were normal disomy, ≤ two copies in more than 90% of analyzed cells (Fig. 1a); and low amplification/polysomy (LA/Poly), ≥ three copies in more than 40% of analyzed cells. Gene amplification was defined as the presence of tight EGFR gene clusters, a ratio of gene/chromosome per cell ≥2, or ≥15 copies of EGFR per cell in ≥ 10% of analyzed cells (Fig. 1b). Tumors with LA/Poly or gene amplification were considered to be FISH positive.
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Statistical analysis
Statistical analysis was performed using the SPSS statistical package (SPSS, Chicago, IL). Correlations between the frequency of EGFR FISH status and age, TNM stage, cigarette smoking, alcohol consumption, and AQ chewing were examined with the χ2 test or Fisher’s exact test. The concordance of EGFR gene copy alterations between primary tumors, metastatic lesions, recurrences and SPTs was analyzed with the McNemar test. Disease-free survival (DFS) was defined as the time from diagnosis to recurrence or metastasis. Overall survival (OS) was defined as the time from diagnosis to death. Survival curves were constructed using the Kaplan-Meier method, and the curves were compared using the log-rank test. A two-sided value of p < 0.05 was considered to be statistically significant.
Results
Patient characteristics
The clinicopathological features of the 170 OSCC male patients between Mar 1997 and Jul 2004 who took part in this study are listed in Table 1. The major primary sites were the bucca (39.4%, 67/170) and the tongue (34.1%, 58/170). Overall, 90.6% (154/170) of the patients were cigarette smokers, 68.2% (116/170) were alcohol drinkers and 91.2% (155/170) were AQ chewers. All 170 patients received surgery as their initial treatment, and 88 (51.8%) and 30 (17.6%) patients underwent additional radiation therapy and chemoradiotherapy, respectively. The median follow-up was 57.50 months.
Table 1
Characteristics of the 170 oral cavity squamous cell carcinoma patients
Characteristic
[No. of patients (%)]
Age (yrs)
Mean
49.55
Range
29.0–78.0
Site of primary tumor [No. of patients (%)]
Tongue
58 (34.1)
Mouth floor
8 (4.7)
Lip
6 (3.5)
Buccal mucosa
67 (39.4)
Alveolar ridge
19 (11.2)
Hard palate
4 (2.4)
Retromolar trigone
8 (4.7)
Pathologic tumor status
T1
30 (17.6)
T2
58 (34.1)
T3
20 (11.8)
T4
62 (36.5)
Pathologic N stage
N0
101 (59.4)
N1
19 (11.2)
N2b
45 (26.5)
N2c
5 (2.9)
Pathologic stage
Stage I
22 (12.9)
Stage II
32 (18.8)
Stage III
24 (14.1)
Stage IV
92 (54.1)
Of 170 primary OSCCs, FISH results showed EGFR LA/polysomy in 19 (11.4%) patients and amplification in 33 (19.8%) patients. EGFR gene amplification was related to lymph node metastasis (χ2 trend test: p = 0.018). Of 57 metastatic lymph nodes, nine (15.8%) had EGFR polysomy and 14 (24.6%) had EGFR gene amplification.
In our patients, 69 had lymph node metastasis identified in neck dissection specimens and 57 positive lymph nodes from neck dissection specimens were available for FISH assays. Fourteen patients had gene copy number amplification (24.6%, 14/57) and nine (15.8%, 9/57) patients had EGFR gene polysomy. During follow-up, 87 patients had recurrence and 41 recurrence tissues were used for analyzing the EGFR gene copy number. Five (12.2%, 5/41) had EGFR gene amplification and five (12.2%, 5/41) had increased gene copy number (LA/polysomy). Twenty-six patients had secondary primary tumors. A total of 17 secondary primary lesions were suitable for FISH analysis. The results showed that two (11.8%, 2/17) had gene amplification and three (17.6%, 3/17) had an increase in gene copy number. The concordance rate of EGFR gene copy number in primary tumors and lymph node metastasis was 68.4% (McNemar test: p = 0.389). The concordance rate between primary tumors and recurrence tumors was 65.9% (McNemar test: p = 0.510), and the concordance rate between primary tumors and SPTs was 70.6% (Table 2).
Table 2
EGFR gene amplification in primary cancer with recurrence, multiple primaries, and neck metastasis
EGFR gene copies number
EGFR gene copies
Disomy
[n (%)]
Polysomy
[n(%)]
Amplification
[n (%)]
Discordance
P value
Recurrent tumor
Disomy (n = 31)
24 (77.4)
4 (12.9)
3 (9.7)
14/41 (34.1%)
0.261
Polysomy (n = 5)
5 (100.0)
0 (0.0)
0 (0.0)
0.510*
Amplificaiton (n = 5)
2 (40.0)
2 (40.0)
1 (20.0)
Second primary tumor
Disomy (n = 12)
11 (91.7)
1 (8.3)
0 (0.0)
5/17 (29.4%)
0.264
Polysomy (n = 3)
2 (66.7)
1 (33.3)
0 (0.0)
*NA
Amplificaiton (n = 2)
1 (50.0)
1 (50.0)
0 (0.0)
Lymph node metastasis
Disomy (n = 34)
25 (73.5)
2 (5.9)
7 (20.6)
18/57 (31.6%)
<0.001
Polysomy (n = 9)
3 (33.3)
4 (44.4)
2 (22.2)
*0.389
Amplificaiton (n = 14)
4 (28.6)
0 (0.0)
10 (71.4)
*McNemar test
In four patients with multiple primary cancers, the concordance rate of EGFR gene copy number was 100% (Table 3). In one patient (No. 2) with multiple recurrences, the EGFR copy number increased in the recurring tumor. The EGFR gene polysomy was maintained in the second recurrence.
Table 3
Summary for EGFR gene copy number alterations in multiple primary OSCC patients
Case
Primary cancer site
EGFR gene copy number
Second cancer site
EGFR gene copy number
Third cancer site
EGFR gene copy number
1
OR147
Left alveolus
Polysomy
Right tongue
Trisomy with Focal amplification
Left tongue
Polysomy
2
OR218
Left alveolus
Disomy
Recurrence
Trisomy or polysomy
2nd recurrence
Polysomy
3
OR276
Left bucca
Disomy
Right hard palate
Disomy
Right alveolus
Polysomy
4
OR295
Right tongue
Disomy
Left tongue
Disomy
Hard palate (3rd primary)
Disomy
5
OR325
Right mouth floor
Disomy
Soft palatal
Disomy
Recur from 2nd primary
Disomy
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Prognostic implications of EGFR gene copy number in metastatic lymph nodes and tumor recurrence
As shown in Table 4, EGFR gene amplification was significantly more prevalent in tumors at an advanced stage than tumors at early stages. Younger patients had a higher risk of EGFR gene amplification. Tumors with high levels of tumor invasion, lymph node metastasis, bone invasion and perineural invasion had a significantly higher frequency of EGFR gene amplification than tumors without those characteristics. However, EGFR gene amplification was not associated with subsites, skin invasion, AQ chewing, cigarette smoking, and alcohol consumption. We analyzed other factors that may predict EGFR gene amplification in metastatic lymph node and found no clinicopathological factors related to amplification.
Table 4
The associations between EGFR gene copies and clinicopathological parameters in recurrent tumor (N = 41)
EGFR Gene Copies Number
Disomy
[N (%)]
Polysomy
[N (%)]
Amplification
[N (%)]
p value
Subsites
Local (n = 31)
22 (71.0)
4 (80.0)
5 (100.0)
0.643
Regional (n = 3)
2 (6.5)
1 (20.0)
0 (0.0)
Distant metastasis (n = 7)
7 (22.5)
0 (0.0)
0 (0.0)
Tumor status
T nulla (n = 10)
9 (29.0)
1 (20.0)
0 (0.0)
0.644
Earlyb (n = 30)
21 (67.7)
4 (80.0)
5 (100.0)
Advancedc (n = 1)
1 (3.2)
0 (0.0)
0 (0.0)
Lymph node metastasis
Yes (n = 12)
10 (32.3)
2 (40.0)
0 (0.0)
0.289
No (n = 29)
21 (67.7)
3 (60.0)
5 (100.0)
Radiation therapy
Yes (n = 29)
22 (71.0)
4 (80.0)
3 (60.0)
0.936
No (n = 12)
9 (29.0)
1 (20.0)
2 (40.0)
Chemotherapy
Yes (n = 7)
7 (22.6)
0 (0.0)
0 (0.0)
0.256
No (n = 34)
24 (77.4)
5 (100.0)
5 (100.0)
ano primary tumor recurrence, but with either lymph node or distant metastasis
bEarly: T1/T2 lesions
cAdvanced: T3/T4 lesions
The Kaplan-Meier survival curves for patients with different EGFR gene copy numbers are shown in Fig. 2. Patients showing an EGFR FISH pattern were not significantly associated with either DFS or OS (Fig. 2a, p = 0.692 and Fig. 2b, p = 0.444). The EGFR gene amplification in metastatic lymph nodes was not associated with patient survival (DFS and OS, Fig. 3a, p = 0.872, and Fig. 3b, p = 0.618, respectively). Furthermore, the EGFR FISH pattern in recurrence tumors did not predict patient survival from recurrence to death (Fig. 4, p = 0.868).
×
×
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Discussion
For loco-regional advanced head and neck squamous cell carcinoma, concomitant radiotherapy with anti-EGFR target therapy such as Cetuximab (C225, Erbitux™) has been shown to improve locoregional control and reduce mortality [20]. A significant improvement in OS/DFS and response rate were also observed in the EXTREME clinical trial [21]. In non-small cell lung cancer (NSCLC), several reports have also shown that EGFR-specific tyrosine kinase inhibitors, such as gefitinib and erlotinib, are capable of reducing brain and adrenal metastases [22, 23]. EGFR mutations, amplifications or gene gains have been associated with clinical responses to those inhibitors [18, 24]. A previous study demonstrated that EGFR FISH analysis may be used as an alternative to gene mutation analysis as the primary laboratory test [25]. Additionally, in our previous study, the EGFR mutation rate in areca-quid-related OSCC was as low as 0.58% [26]. Gene amplification is one of the important mechanisms that influence EGFR proteins expression. We sought to better understand the clonal change of EGFR gene between primary tumors, metastatic lesions and recurrence tumors in OSCC.
The tumors examined in our experiments were heterogeneous and polyclonal. Park et al. demonstrated that EGFR mutations are not always identical in disseminated cancer cells and cells from the primary tumors in NSCLC [27]. The differences could originate from intratumoral molecular heterogeneity or the consequences of genetic instability during metastatic spread of tumor cells. In our study, we hypothesized that tumor cells with EGFR amplification were prone to recur or metastasize. Our EGFR copy number comparison analyzed primary and metastatic lesions in OSCC, and we found the concordance rate was approximately 60%. In the literature, studies on clonal changes between primary tumors and metastatic lesions in EGFR in OSCC were few and most related studies focused on lung cancer. Matsumoto et al. reported a 100% concordance for EGFR mutation status in six NSCLC patients of Asian ethnicity [28]. In a study by Kalikaki et al., the authors demonstrated significant discordance between EGFR and K-RAS mutations occurring in primary tumors and the corresponding metastases in patients with NSCLC [29]. The discordance in EGFR mutation status was 28% and the discordance for K-RAS was 24%. Similarly, two other studies of paired NSCLC tumors showed discordance rates of 32 and 27% for the EGFR gene copy number [8, 10]. The concordance rate of EGFR copy number in metastatic lymph nodes or recurrent OSCC from our study were within the range of concordance rates for lung cancer.
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In a meta-analysis by Wang and Wang, primary NSCLC had a lower EGFR copy number rate (29.3%, 39/133) than corresponding metastases (39.8%, 53/133), but there was no significant difference [30]. In our study, the EGFR copy number in metastatic lymph node samples was higher (40.35%) than samples from primary tumors (30.59%). Although the result was statistically insignificant, tumor cells with EGFR gene amplification carried a higher propensity for lymph node metastasis. In OSCC, an increased EGFR copy number was identified in 24.39% of recurrent tumors and 29.41% of SPTs. We intended to identify the factors that would lead to a higher risk of EGFR gene amplification in patients. In Table 4, no clinical factors, such as primary tumor stage, lymph node metastasis, radiation therapy or chemotherapy, were related to increased EGFR gene copy number. To minimize the heterogeneity of our study population, none had received neo-adjuvant chemotherapy, neoadjuvant bio-chemotherapy or adjuvant bio-CCRT. Adjuvant chemo-radiotherapy for locoregional advanced OSCCs consists of cisplatin-based regimen in our patients. In the patients with tumor recurrence, 70.73% had previous radiation therapy after primary surgery and 17.07% received adjuvant chemotherapy concomitantly with radiation therapy. Interestingly, none of the recurrences had EGFR amplification if the patients had chemotherapy included in the initial treatment of OSCC. The tumor clones of increased EGFR copy number could potentially have been eliminated during the process of recurrence.
Conclusions
In OSCC, the concordance rates between primary tumors and metastatic lymph nodes, recurrence tumors or SPTs were 65.9, 68.4 and 70.6%, respectively. We could predict two-thirds of the EGFR gene copy number alterations for the lymph node metastasis group or the recurrence tumor group from analysis of the primary tumor. For OSCC patients, in whom the lymph nodes or recurrence tumors were unavailable for EGFR gene copy number analysis, studies of the primary tumor could provide part of the EGFR clonal information to predict metastatic or recurrent lesions.
Acknowledgements
The authors thank all the members of the Cancer Center and the Tissue Bank at Chang Gung Memorial Hospital, Linkou, for their invaluable assistance.
Funding
This study was supported by grants CMRPG3F0671, CMRPG3F2221 and CMRPB53 from Chang Gung Memorial Hospital in the writing of the manuscript and publication fee, and grants MOST 103–2314-B-182A-057-MY2 and MOST106–2314-B-182-025-MY3 from the National Science Council, Executive Yuan, Taiwan, ROC, in the design of the study, experiments, analysis and interpretation of data.
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Availability of data and materials
The datasets used and analyzed during the current study are available from the corresponding author on reasonable request.
Competing interest
The authors declare that they have no competing interests.
Ethics approval and consent to participate
All patients signed informed consent for participation of this study. This study had ethics approval and consent by the ethic committee in Chang Gung Memorial Hospital (Institutional Review Board of Chang Gung Medical Foundation, IRB No. 97-1593A3), Taiwan, R.O.C..
Consent for publication
Not applicable.
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EGFR copy number alterations in primary tumors, metastatic lymph nodes, and recurrent and multiple primary tumors in oral cavity squamous cell carcinoma