Abstract
Testicular cancer is the most common cancer in young male patients. The combination of cisplatin-based chemotherapy and surgery has resulted in high cure rates. However, a small percentage of patients have cancers that are refractory to chemotherapy; treatment options for these patients are limited, and their prognosis is generally poor. Further studies are needed to explore the molecular pathogenesis pathways and potential targets of therapy for this group of highly aggressive tumors. We analyzed 21 patients who presented with metastatic embryonal carcinoma, were treated with chemotherapy, and subsequently underwent retroperitoneal lymph node dissection. Immunostaining for epidermal growth factor receptor (EGFR) was performed on paraffin-embedded tissue sections containing tumor from these specimens, using the avidin–biotin–peroxidase method. EGFR gene amplification was performed by interphase fluorescence in situ hybridization (FISH). Immunohistochemically, 9 of 21 cases (43%) demonstrated positive EGFR staining; 12 of 21 cases (57%) had absent or very limited EGFR expression. FISH revealed EGFR amplification in 1 case (5%), polysomy in 15 of 21 cases (71%), and normal disomy pattern in 5 of 21 cases (24%). A significant correlation between EGFR protein expression level and its chromosome polysomy/amplification was established (P=0.02). Our study showed that EGFR protein is frequently expressed in a subset of patients with chemorefractory metastatic embryonal carcinoma. EGFR chromosomal polysomy/amplification may be one of the mechanisms that cause increased EGFR protein expression, and could potentially be used as indication for anti-EGFR therapy.
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Main
Testicular cancer is the most common cancer in male patients between 15 and 35 years of age.1 Germ cell tumors are divided into seminoma and nonseminomatous germ cell tumors based on histological, biological, and clinical features. Several histological factors have been shown to predict the risk of metastasis or relapse of disease, including vascular invasion, presence or volume of embryonal carcinoma component, and absence of yolk sac tumor. The combination of surgery- and cisplatin-based chemotherapy has resulted in cure rates of 70 to >95% in nonseminomatous germ cell tumors, depending on the stage of the tumor.2, 3 However, a small group of patients who have late relapse or are refractory to chemotherapy have few treatment options and are faced with a poor prognosis.
Epidermal growth factor receptor (EFGR) gene, one of the oncogenes on chromosome 7, has been implicated in the pathogenesis and progression of many malignancies.4 However, its role in the pathogenesis of germ cell tumors has not been extensively investigated. Overexpression of EGFR in various types of carcinoma has prompted the development of agents directed against EGFR.5 Targeted therapies against EGFR have been successfully used in the treatment of some advanced colorectal and non-small-cell lung cancers.6, 7, 8 In this study, we examined EGFR protein expression by immunohistochemical staining and assessed gene amplification by fluorescence in situ hybridization (FISH) in tumorous tissue from 21 patients with metastatic chemorefractory embryonal carcinoma, and also investigated correlations between EGFR protein expression and gene amplification in this tumor. Our study was designed to provide further insights into the molecular pathogenesis of metastatic germ cell tumor and to help define potential therapies for this uncommon malignancy.
Materials and methods
Patients
A retrospective review of Indiana University Medical Center testis cancer database of 1990–2002 was performed to identify patients who presented with metastatic nonseminomatous germ cell tumor, were treated with three or four courses of cisplatin-based chemotherapy, and subsequently underwent retroperitoneal lymph node dissection (RPLND) at the Indiana University Medical Center. A total of 21 patients (age range: 19–40 years, mean age: 32 years) with residual metastatic embryonal carcinoma in their RPLND specimens were identified, and tumor tissue from their specimens was evaluated in this study. Formalin-fixed, paraffin-embedded tissue from RPLND was available for all cases.
Formalin-fixed, paraffin-embedded tissue was available in only two cases of primary testicular tumors, including one teratoma and one embryonal carcinoma. We were not able to retrieve other primary testicular tumors for analysis as most orchiectomies were performed at the outside institutions during the period of 1979–1996.
Immunohistochemical Analysis
Immunohistochemical staining for EGFR was performed on formalin-fixed and paraffin-embedded tissue sections using the peroxidase-labeled streptavidin–biotin method. Tissue sections (5 μm) from each patient were used for EGFR immunohistochemical staining. Sections were deparaffinized in xylene for 5 min and then rehydrated through graded ethanol to distilled water. Antigen retrievel was performed by heating sections for 15 min (Target Retrievel; Dako, Carpinteria, CA, USA). Endogenous peroxidase was blocked by incubation in 3% H2O2 for 5 min. Tissue sections were incubated with primary antibodies against EGFR (Dako) for 10 min, followed by biotinylated secondary antibody (Dako) and peroxidase-labeled streptavidin (Dako). 3,3-Diaminobenzidine was used as the chromogen. The extent of staining was evaluated by visual examination microscopically. Each section was scanned at low magnification for membranous staining and was scored by evaluating the percentage of tumor cells staining positively. According to the scoring system recommended by Tsao et al,9 results were recorded as positive expression (≥10% of cells staining) or negative expression (<10% of cells staining).
Tissue Preparations and FISH
Sections (4-μm-thick) were cut from paraffin blocks from each patient. The slides were deparaffinized with two washes of xylene, 15 min each, and subsequently washed twice with absolute ethanol, 10 min each and then air-dried in the hood. Next, the slides were treated in 0.1 mM citric acid (pH 6.0) (Zymed, CA, USA) at 95°C for 10 min, rinsed in distilled water for 3 min followed by a wash of 2 × SSC (standard saline citrate) for 5 min. Digestion of the tissue was performed by applying 0.4 ml of pepsin (5 mg/ml in 0.1 N HCl with 0.9% NaCl) (Sigma, St Louis, MO, USA) at 37°C for 40 min. The slides were rinsed with distilled water for 3 min, and then washed with 2 × SSC for 5 min and air-dried.
EGFR gene chromosomal alterations was detected by interphase FISH using LSI EGFR/CEP 7 Dual Color Probe containing centromere chromosome 7 (Centromeric Enumeration Probe, CEP 7, Spectrum Green) and EGFR located at 7p12 (EGFR, Spectrum Orange) (Vysis, Downers Grove, IL, USA). The probe was diluted with tDenHyb2 (Insitus, Albuquerque, NM, USA) in a ratio of 1:50. Diluted probe (5 μl) were applied to each slide in reduced light conditions; the slides were then covered with a 22 × 22 mm coverslip and sealed with rubber cement. Denaturation was achieved by incubating the slides at 80°C for 10 min in a humidified box, followed by hybridization at 37°C over night. The coverslip was removed and the slides were washed extensively with two 45°C prewarmed 0.1 × SSC/1.5 M urea, 20 min for each, followed by a wash with 2 × SSC for 20 min and a 2 × SSC/0.1% NP40 for 10 min at 45°C. The slides were further washed with room temperature 2 × SSC for 5 min and air-dried. The slides were counterstained with 10 μl 4-6-diamidino-2-phenylindole (DAPI; Insitus), covered with coverslips and sealed with nail polish.
The slides were examined using a Zeiss Axioplan 2 microscope (Zeiss, Göttingen, Germany) with the following filters: SP-100 DAPI, FITC MF-101 for Spectrum Green (CEP 7) and Gold 31003 for Spectrum orange (EGFR) from Chroma (Chroma, Brattleboro, VT, USA). The images were acquired with a CCD camera and analyzed with MetaSystem Isis Software (MetaSystem, Belmont, MA, USA). Four sequential focus stacks with 0.4-μm intervals were acquired and then integrated into a single image to reduce thickness-related artifacts.
FISH Analysis
The method of analysis was as previously described in detail.10, 11 In brief, for each slide, 100 neoplastic nuclei were scored for signals from both CEP7 and EGFR probes under the fluorescence microscope with × 1000 magnification. Signals from nonoverlapping nuclei were enumerated. Two signals of the same size in close proximity, not connected by a link, were counted as two signals. A diffuse signal was regarded as a signal if it was contiguous and within an acceptable boundary. Two small signals connected by a visible link were counted as one signal. Overlapping nuclei and nuclei with uncertain signal were not included. In accordance with the criteria of Alvarez et al,12 EGFR amplification was considered to be present if >10% of the nuclei contained multiple EGFR signals and the EGFR/CEP7 ratio was >2.10, 11 Polysomy for an individual tumor was defined as follows: >10% of the nuclei contained >2 signals of CEP7 or EGFR and the EGFR/CEP7 ratio was <2. Individual tumors were considered to show disomy if the percentage of disomic cells (with two copies of EGFR and CEP7) fell into the range of summarized average±three standard deviations of the normal control cells and did not meet the criteria for amplification or polysomy. For each FISH preparation, known positive and negative cells were used as controls. Preparations were considered valid if >90% of the cells showed bright signals.10, 11
Statistical Analysis
Data were analyzed using SAS version 9.1 (SAS Institute, Cary, NC, USA). Correlations between EGFR protein expression and gene amplification were evaluated by using Cochran–Mantel–Hanszel. A P-value <0.05 was considered significant, and all P-value tests were two sided.
Results
Clinical and Pathological Features
In all, 21 patients (age range: 19–40 years, mean age: 32 years) were found to have residual metastatic embryonal carcinoma in their RPLND specimens, despite prior treatment with cisplatin-based chemotherapy. In 6 cases, the residual tumor was pure embryonal carcinoma; in the other 15 cases, the residual tumors contained two or more different histological elements. The percentage of each component in these 21 tumors was as follows: embryonal carcinoma (present in 21 of 21 tumors, 100%), teratoma (7 of 21, 33%), yolk sac tumor (7 of 21, 33%) and choriocarcinoma (3 of 21, 14%).
Immunohistochemical Study of EGFR Protein Expression
Immunohistochemical evidence of EGFR protein expression was evaluated in the metastatic embryonal components of all 21 cases. Positive immunohistochemical expression of EGFR was observed in tissue sections from 9 of 21 patients (43%), 1 with 10–25% staining, 4 with 25–50% staining, 1 with 50–75% staining, and 3 with 75–100% staining (Figure 1). By contrast, immunohistochemical expression of EGFR was absent or very limited in 12 of 21 cases (57%), 11 with no staining, and 1 with 1–10% staining.
We also performed EGFR immunostaining on two primary testicular tumors available (one teratoma and one embryonal carcinoma). Both primary tumors showed negative immunostainings for EGFR. Corresponding retroperitoneal metastatic embryonal carcinoma showed 10–25% of EGFR staining and 25–50% of EGFR staining, respectively.
FISH Study for EGFR Gene Amplification
EGFR gene amplification was performed on the metastatic embryonal components of all 21 cases. EGFR gene amplification was observed in one case (5%). Polysomy (more than two copies of CEP7 and EGFR/CEP7 ratio <2) of chromosome 7 was observed in 15 of 21 cases (71%) (Figure 1); the remaining 5 cases (24%) exhibited a normal disomic FISH pattern.
Similarly, EGFR gene amplification was also evaluated on two primary testicular tumors available (one teratoma and one embryonal carcinoma). Both primary tumors showed EGFR polysomy, which is identical to retroperitoneal metastatic embryonal carcinoma component.
Correlation between EGFR Protein Expression and Gene Amplification
EGFR gene amplification status and protein expression level were compared in the metastatic embryonal components of all 21 cases. (Table 1) Positive EGFR protein expression was present in 9 of 21 cases (1 case had EGFR amplification, 7 cases had polysomy and 1 cases had disomy). EGFR protein expression was absent or very limited in 12 of 21 cases (8 patients had polysomy and 4 case had disomy). By contrast, EGFR gene amplification was observed in 1 of these 21 cases, with positive EGFR protein expression. Of 21 cases, 15 had polysomy (7 patients had positive EGFR protein expression, 8 cases had no protein expression). The remaining five cases had disomy (one case had EGFR protein expression and four cases had no EGFR protein expression). The results indicated a significant correlation between elevated EGFR protein expression level and EGFR gene polysomy/amplification (P=0.02).
Discussion
Testicular neoplasms account for <1% of all malignancies in male patients. About 95% of testicular cancers consist of germ cell tumors, with an estimated 7920 new cases and 380 deaths expected annually in the United States. On the basis of histological, biological, and clinical features, germ cell tumors are categorized into two groups: seminoma and nonseminomatous germ cell tumors. Nonseminomatous germ cell tumors are histologically heterogeneous and include one or more of the following components: teratoma (mature and/or immature), embryonal carcinoma, yolk sac tumor, and choriocarcinoma. Seminoma can coexist with other components in nonseminomatous germ cell tumors.
Germ cell tumors are typically managed initially by radical orchiectomy to establish the histological type of tumor and local tumor stage. Depending on clinical and pathological findings, subsequent management may include clinical observation, radiation therapy, RPLND, or cisplatin-based chemotherapy, and these treatments are curative in the great majority of patients. However, 30% of patients with disseminated disease at the time of initial diagnosis fail to achieve complete remission or subsequently relapse and require further salvage treatments, which may include high-dose chemotherapy with stem cell rescue. Approximately half of patients who suffer relapse eventually die of the disease.13
Chemotherapy resistance is an important biological and clinical issue in the management of germ cell tumors. The genetic pathways that determine chemotherapy sensitivity in germ cell tumors remain largely unknown. Patients who are chemotherapy resistant may have different genetic alterations. Chemoresistance has been linked to P53 gene mutations by some investigators14 but not others.15 By comparative genomic hybridization analysis, Rao et al16 identified possible amplified regions involving multiple chromosomes (1q, 2p, 7q, 9q, 9q, 15q, and 20q) in cisplatin-resistant germ cell tumors. Identification of amplified/overexpressed genes may elucidate genetic pathways of chemotherapy resistance in germ cell tumors and may help in the development of novel treatments targeted at the molecular level.
The EGFR superfamily (EGFR/erB-1, HER2/erB-2, HER3/erb-3, and HER4/erb-4) consists of different transmembrane growth factor tyrosine kinases that share similarities in structure and function and are important in cell survival and proliferation. EGFR (EGFR, HER-1, c-erbB-1) is expressed in many human epithelial malignancies. Overexpression of EGFR correlates with a poor prognosis and decreased survival in EGFR in some of these malignancies.17 The EGFR gene is located on chromosome 7p12–p22 and encodes a 170 kDa glycoprotein. Structurally, EGFR is composed of an extracellular EGF ligand-binding domain, a transmembrane lipophilic segment, and an intracellular tyrosine kinase domain. Two ligands can activate EGFR: epidermal growth factor and transforming growth factor. After the ligand binds EGFR, the receptors homodimerize or heterodimerize. Subsequently, tyrosine kinase of the receptor's intracytoplasmic domain is activated and signal pathways are triggered that may induce cellular growth, differentiation and proliferation, invasion, and increased metastatic potential of the tumor cells.
Currently, data concerning EGFR expression at the protein level or molecular level in metastatic embryonal carcinoma is very limited and available data are inconclusive. In a series of 88 testicular germ cell tumors, Hechelhammer et al18 observed EGFR reactivity only in the stromal cells of embryonal carcinoma (29%), in the epithelial components of teratoma (71%), and in syncytiotrophoblastic cells of other components. Moroni et al19 investigated 24 testicular tumors and detected EGFR staining in the β-HCG-positive components present in 16 of 18 nonseminomatous germ cell tumors, but observed no staining in the β-HCG-negative components of these tumors. In addition, they detected expression of EGFR activation (phosphorylated EGFR) in 27% of the EGFR-positive tumors; their overall findings led them to suggest that active EGFR-targeted pharmaceutical agents may be clinically relevant in the management of mixed germ cell tumors with β-HCG expression.19 Kollmannsberger et al20 also demonstrated the presence of EGFR expression restricted to trophoblastic cells in 4 of 22 cisplatin-resistant germ cell tumors and in 3 of 12 chemosensitive germ cell tumors. In this study, only 4 of 22 chemoresistant tumors and 6 of 12 chemotherapy-responsive tumors included elements of embryonal carcinoma. In current study, we found EGFR gene amplification in only 1 of 21 cases. However, we did demonstrate frequent polysomy, possibly representative of ‘low level’ gene amplification, in 15 of 21 cases (71%). We also observed significant correlation between EGFR protein overexpression by immunohistochemical studies and gene amplification/polysomy by FISH.
The mechanisms underlying EGFR protein overexpression are not well understood and appear to differ markedly among various tumor types. Proposed mechanisms included gene amplification, activating mutations, increasing EGFR transcription or translation causing increased mRNA and protein production, decreased protein destruction, overexpression of receptor ligands, and others. Our results suggested that EGFR gene amplification/polysomy appears to induce protein overexpression; however, EGFR protein expression may be influenced by other regulatory pathways, and further studies are needed to clarify this process. Significantly, our demonstration of frequent expression of EGFR in a subset of cases of metastatic chemorefractory embryonal carcinomas suggested that targeted therapy against EGFR (such as cetuximab or gefitinib) may be beneficial in such cases; this hypothesis is worthy of further investigation.
In summary, we found in our series of 21 patients with chemorefractory metastatic embryonal carcinoma that EGFR was expressed in 9 cases (43%). EGFR gene polysomy/amplification were identified in 16 of 21 cases (76%). To our knowledge, our study is the first to demonstrate EGFR gene amplification/polysomy at the molecular level and the first to show a significant correlation between EGFR overexpression and gene amplification/polysomy in metastatic chemorefractory embryonal carcinoma. Our observation of EGFR expression in 43% of cases of chemorefractory metastatic embryonal carcinoma suggests that anti-EGFR therapy might be useful in the management of this subset of patients with such aggressive cancers. Further studies of larger sample focusing on specific histological subtypes as well as primary testicular tumors, including chemosensitive and chemorefractory tumors, are needed to define more clearly the prevalence and significance of EGFR expression in chemorefractory germ cell tumors.
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Wang, X., Zhang, S., MacLennan, G. et al. Epidermal growth factor receptor protein expression and gene amplification in the chemorefractory metastatic embryonal carcinoma. Mod Pathol 22, 7–12 (2009). https://doi.org/10.1038/modpathol.2008.133
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DOI: https://doi.org/10.1038/modpathol.2008.133
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