Main

Epidermal growth factor receptor (EGFR) is a 170-kDa transmembrane glycoprotein/cell surface receptor composed of an extracellular ligand-binding domain, a transmembrane lipophilic segment and an intracellular tyrosine kinase (Grant et al, 2002). Epidermal growth factor receptor belongs to the ErbB tyrosine kinase receptor family, which includes four proteins encoded by the c-erb B proto-oncogene, namely ErbB1 (EGFR), ErbB2 (HER2/neu), ErbB3 (HER3) and ErbB4 (HER4) (Yarden and Sliwkowski, 2001; Baselga, 2002). Ligand binding produces dimerisation of the receptor and activation of intrinsic protein tyrosine kinase activity leading to the transduction of signalling pathways involved in proliferation, cell division and differentiation (Herbst, 2004). The MAP kinase and AKT signalling pathways have been found to mediate intracellular EGFR signalling (Herbst, 2004). The biologic responses to MAP kinase induction result in increased expression of proteins governing cell-cycle regulation. AKT, an anti-apoptotic kinase, is implicated in cell survival and promotion of angiogenesis and has also been linked to activation of matrix metalloproteinase protein facilitating tumour growth and promotion (Kainulainen et al, 2000; Thant et al, 2000).

Expression of EGFR is linked to poor survival in a variety of malignancies (Neal et al, 1990; Tateishi et al, 1990; Nicholson et al, 1991; Chua et al, 1996; Jonjic et al, 1997; Gamboa-Dominguez et al, 2004). In colorectal cancer (CRC), it is well documented that EGFR expression may be associated with an advanced disease stage (Gross et al, 1991; Radinsky, 1995; Radinsky et al, 1995; Prewett et al, 2002). However, these results remain controversial because an association between EGFR expression and Dukes stage or length of survival in CRC has not been detected in other studies (Yasui et al, 1988; Moorghen et al, 1990; Koenders et al, 1992; Saeki et al, 1995; McKay et al, 2002).

Among the standard techniques such as protein expression, RNA transcript and DNA assays used to detect EGFR expression in tumours, immunohistochemistry (IHC) is the most commonly used in CRC (Italiano, 2006). EGFR expression had been reported in 25–82% of CRCs (Wan et al, 1988; Radinsky et al, 1995; Goldstein and Armin, 2001; Yarden and Sliwkowski, 2001; McKay et al, 2002; Cunningham et al, 2004; Spano et al, 2005a).

It has been recognised that the wide range of methods for interpreting EGFR expression as determined by IHC considerably hinders a meta-analysis of the predictive or prognostic value of the protein in CRC (Italiano, 2006). Despite its subjective nature, staining intensity has become an integral component of many EGFR scoring systems (Goldstein and Armin, 2001; Resnick et al, 2004; Italiano et al, 2005; Spano et al, 2005b). It has recently been shown, however, that the degree of staining intensity may be affected by varying fixation methods and laboratory procedures and is reduced dramatically with increased storage time of the tissue samples (Atkins et al, 2004; Italiano et al, 2006). Scoring methods for EGFR include those evaluating only the degree of staining intensity (Resnick et al, 2004), those for which positive or negative expression of EGFR are based on a predetermined and often arbitrarily set cutoff score (Goldstein and Armin, 2001; Umemura et al, 2004; Azria et al, 2005; Italiano et al, 2005; Bibeau et al, 2006) and those with composite systems incorporating both the extent of positivity and staining intensity (Spano et al, 2005b). Rarely is the choice of scoring method, in particular the selection of cutoff scores for positivity, addressed and many remain unvalidated.

The aim of this study was to determine the predictive value of EGFR in rectal cancer treated with a novel preoperative radiotherapy protocol, namely high-dose rate endorectal brachytherapy (HDREB) and its prognostic value in 1197 mismatch-repair (MMR)-proficient CRCs using the tissue microarray (TMA) technique. In pursuing this aim, we propose and validate the application of receiver operating characteristic (ROC) curve analysis to the selection of cutoff scores for EGFR overexpression for the end points under investigation.

Materials and methods

Study Group 1

This study was approved by the Institutional Review Board and informed written consent was obtained from 82 patients with rectal adenocarcinoma undergoing preoperative HDREB (Vuong et al, 2002; Vuong et al, 2005). Clinical staging according to the International Union against Cancer Classification was carried out by both endorectal ultrasonography and MRI. In cases of discrepancy, the higher T stage was assigned. Patients with abdominal nodal disease were excluded from the study, as were patients with distant metastases. Radiation was delivered preoperatively with an eight-channel endorectal catheter using a high-dose rate remote after-loading system. A daily fraction of 6.5 Gy was administered over 4 consecutive days to a total of 26 Gy. Treatment was planned using a CT simulator to obtain optimal conformal dosimetry. The dose was prescribed to a clinical target volume that included the gross tumour volume and any intra-mesorectal deposits visible at MRI. Patients underwent cancer-directed surgery 4–8 weeks following radiotherapy regardless of tumour response.

Tumours were considered completely responsive to preoperative HDREB when no histologic evidence of residual carcinoma could be pathologically determined from postoperative surgical resections (ypT0). Partial response was characterised by the presence of microfoci or foci of residual carcinoma measuring 0.3–0.9 cm in diameter, whereas no response was defined by large areas of residual carcinoma that could be identified macroscopically and ranged in size from 2 to 6 cm following irradiation.

Study Group 2

A TMA of 1420 unselected, nonconsecutive CRCs was constructed (Sauter et al, 2003). Briefly, formalin-fixed, paraffin-embedded tissue blocks of CRC resections were obtained. One tissue cylinder with a diameter of 0.6 mm was punched from morphologically representative tissue areas of each donor tissue block and brought into one recipient paraffin block (3 × 2.5 cm) using a homemade semiautomated tissue arrayer.

The clinicopathological data for 1420 patients included T stage (T1, T2, T3 and T4), N stage (N0, N1 and N2), tumour grade (G1, G2 and G3), vascular invasion (presence or absence) and 10-year survival. The distribution of these features has been described previously (Lugli et al, 2006b).

IHC

The 1420 CRCs were dewaxed and rehydrated in dH2O. Endogenous peroxidase activity was blocked using 0.5% H2O2. The sections were incubated with 10% normal goat serum (Dako Cytomation, Carpinteria, CA, USA) for 20 min. To determine MMR status, the 1420 CRCs were incubated with primary antibody for MLH1 (MLH1 clone MLH-1, BD Biosciences Pharmingen, San Jose, CA, USA), MSH2 (clone MSH-2, BD Biosciences Pharmingen, San Jose, CA, USA), and MSH6 (clone 44, Transduction Laboratories, San Diego, CA, USA) for 2 h at room temperature. Subsequently, sections were incubated with HRP-conjugated secondary antibody (K4005, EnVision+ System-HRP (AEC); DakoCytomation, Carpinteria, CA, USA) for 30 min at room temperature. For visualisation of the antigen, the sections were immersed in 3-amino-9-ethylcarbazole+substrate-chromogen (DakoCytomation) for 30 min, and counterstained with Gill's haematoxylin.

IHC for EGFR (clone 3C6, 3 mg ml−1, Ventana Medical Systems, Tucson, USA) was performed on the 82 pretreatment rectal tumour biopsies as well as on all 1420 CRCs using an autostainer according to the manufacturer's recommendations. Positive controls consisted of normal oral mucosa. Negative controls were treated identically with the primary antibody omitted.

Evaluation of IHC

EGFR immunoreactivity was evaluated as either membranous or cytoplasmic in a semiquantitative manner using the proportion of EGFR-positive tumour cells over the total number of tumour cells ranging from 0 to 100%. Scores were based on 5% intervals (0, 5, 10%, etc). The rectal tumour biopsies were evaluated by three experienced pathologists (AL, JJ, SH) as were the TMA CRCs (AL, JJ, DH). For the 1420 CRCs, MLH1, MSH2 and MSH6 were scored as negative (0% staining) or positive (>0% staining). Staining intensity was not evaluated.

MMR status

The 1420 CRCs were stratified according to DNA MMR status and consisted of 1197 MMR-proficient tumours expressing MLH1, MSH2 and MSH6, 141 MLH1-negative tumours and 82 presumed HNPCC cases demonstrating loss of MSH2 and/or MSH6 at any age, or loss of MLH1 at <55 years (Hampel et al, 2005). Only MMR-proficient tumours were included in this study to ensure a uniform population (N=1197, 84.4%).

Randomisation of MMR-proficient CRCs

The 1197 MMR-proficient CRCs were randomly assigned into two groups, Study Group 2A (N=599) and Study Group 2B (N=598). Study Group 2A was used to determine the most relevant cutoff scores above which a tumour should be considered to overexpress EGFR for each clinicopathological feature. The associations of EGFR expression at the proposed cutoff scores with T stage, N stage, tumour grade, vascular invasion and survival were investigated on Study Group 2B.

Statistical analysis

Inter-observer reliability of the scoring method

The reproducibility of the semiquantitative scoring method in both rectal tumour biopsies and TMA CRC punches was assessed among three pathologists and analysed using the intraclass correlation coefficient (ICC) (Shrout and Fleiss, 1979; Zlobec et al, 2006a). The ICC is defined as the ratio of the between-subject variance over the between-subject+within subject variances and has previously been used to assess agreement of IHC scores (Kirkegaard et al, 2006).

Selecting the cutoff scores for EGFR ‘positivity’

The selection of cutoff scores for EGFR expression in both Study group 1 and 2A were based on ROC curve analysis (Zlobec et al, 2006b). At each score, the sensitivity and specificity for the outcome being studied were plotted thus generating a ROC curve. The score located closest to the point with both maximum sensitivity and specificity, that is, the point (0.0, 1.0) on the curve, was selected as the cutoff score leading to the greatest number of tumours which were correctly classified as having or not having the outcome. To use ROC curve analysis, the clinical and tumour characteristics must be binary and were therefore dichotomized. For Study group 1 two analyses were performed, the first to predict complete pathological response (complete response vs partial or no response) and any response (complete or partial response vs no response). For Study group 2, T stage was dichotomized as early (T1+T2) or late (T3+T4), N stage as N0 (no lymph node involvement) or >N0 (any lymph node involvement), tumour grade as low (G1+G2) or high (G3), vascular invasion as absent or present and survival as death due to CRC or other (censored, alive or death from other causes).

Reproducibility of ROC curve analysis

To determine whether ROC curve analysis was a reproducible method for selecting the cutoff scores for EGFR, ROC curves were generated for each independent pathologist and clinicopathological feature. In addition, 100-bootstrapped replications were performed to resample the data and determine the reliability of the cutoff scores obtained by each scorer. With bootstrapping, 100 resamples of equal size are created and ROC curve analysis is performed for each subgroup. Finally, the cutoff scores from each pathologist were averaged and subsequently used to determine the association of EGFR overexpression and the clinicopathological features on Study Group 2B. The most frequently obtained cutoff score over the 100 resamples the area under the ROC curve (AUC) and 95% CI were acquired for each analysis. Area under the ROC curves summarise the discriminatory power of EGFR for the outcome with values of 0.5 indicating low power and those closer to 1.0 higher power.

Association with clinicopathological features at the respective cutoffs

To determine the association of EGFR expression and tumour response, logistic regression analysis was performed. The odds ratio (OR) and 95% CI were obtained. The χ2 test was used to evaluate EGFR expression with T stage, N stage, tumour grade and vascular invasion. Survival analysis was carried out using the Kaplan–Meier method and log-rank test. Cox proportional hazards regression was used in multivariate survival analysis to identify the prognostic value of EGFR independently of T stage, N stage, tumour grade, vascular invasion and age. All analyses were carried out using SAS (The SAS Institute, Cary, NC, USA). Receiver operating characteristic curves were plotted using SPSS.

Results

Tumour characteristics

Study Group 1

Twenty-seven tumours (32.9%) were completely responsive to preoperative HDREB whereas 29 (35.4%) were non-responsive and 30 (36.6%) were partially responsive to therapy. Fifteen tumours (18.3%) showed no immunoreactivity (0% staining) for EGFR whereas 67 (81.7%) displayed either membranous or cytoplasmic positivity (Figure 1A and B). More than 90% of patients were staged as cT3.

Figure 1
figure 1

Predominantly membranous (A) and cytoplasmic (B) EGFR expression in rectal adenocarcinoma (× 40). Membranous (C) and cytoplasmic (D) EGFR staining in TMA punches of moderately differentiated MMR-proficient CRCs (× 40).

Study Group 2

EGFR immunoreactivity was evaluated in 1032 MMR-proficient CRCs. One hundred and sixty-five cases were not assessed owing to the absence of tissue or tumour. Absence of staining was found in 367 (35.6%) cases whereas membranous and/or cytoplasmic staining was described in 64.4% (Figure 1C and D).

Inter-observer agreement

The ICCs obtained by analysing the rectal tumour biopsies and TMA CRC punches were 0.71 and 0.86, respectively.

ROC curve analysis

The cutoff values for EGFR positivity or overexpression were determined by ROC curve analysis. For the three pathologists, a cutoff score was obtained (Table 1) for each clinicopathological feature. Values were highly consistent between pathologists. The average EGFR cutoff scores were obtained and included 18% for predicting complete response, 15% for predicting complete or partial response, 85% for T stage, and 10-year survival, 75% for N stage, 82% for tumour grade and 80% for vascular invasion. The ROC curves for each outcome are shown in Figure 2.

Table 1 Most frequently obtained cutoff score (mode), and area under the ROC curve (AUC (95% CI)) for each pathologist and clinicopathological feature
Figure 2
figure 2

ROC curves plotted for each clinicopathological feature using scores from one of the three pathologists (A) complete tumour response, (B) complete or partial tumour response, (C) T stage, (D) N stage, (E) tumour grade, (F) vascular invasion and (G) 10-year survival. Arrows indicate the closest point on the ROC curves to the point (0.0, 1.0), which correspond to the selected cut-off score.

Association of EGFR and clinicopathological features (Table 2)

Table 2 Association of EGFR expression and clinicopathological features

Positive EGFR expression (>18% tumour cell staining) was significantly associated with complete pathological response to preoperative HDREB (P-value <0.001; OR (95% CI)=7.12 (2.3–21.7)). Complete or partial tumour response was more frequently associated with positive EGFR expression (>15% tumour cell staining) (P-value=0.008; OR (95% CI)=3.59 (1.37–9.43)).

Overexpression of EGFR (>85% tumour cell staining) was more frequently found in tumours with late T stage, although this difference was only marginally significant (P=0.069). No association between EGFR overexpression and N stage (P-value=0.792) or vascular invasion (P=0.753) was found. A marginally significant difference in tumour grade with EGFR overexpression was observed (P=0.051).

Tumours with <85% EGFR staining had a significantly better survival time (87.0 months (69.0–103.0)) (P<0.001) compared to tumours overexpressing the protein (35.0 months (23.0–58.0)) (Figure 3). In a multivariate survival analysis adjusting for T stage, N stage, tumour grade, vascular invasion and age, EGFR overexpression was independently associated with worse survival time (P<0.001) (HR (95% CI)=1.93 (1.44–2.57)).

Figure 3
figure 3

Kaplan–Meier survival curve for MMR-proficient CRCs with (1) <85% EGFR staining, (2) 85% EGFR staining.

Discussion

The predictive and prognostic value of EGFR in CRC varies significantly in the literature. Several reasons have been suggested for this discrepancy such as non-comparable study populations (Spano et al, 2005a), variability in protocols, fixation and antibodies (Atkins et al, 2004) and the lack of a uniform scoring system (Penault-Llorca et al, 2005; Italiano, 2006; Walker, 2006).

The aim of this study was to determine the predictive and prognostic value of EGFR in CRC based on cutoff scores selected to maximise the clinical utility of EGFR findings by IHC. EGFR expression and tumour response to a novel preoperative radiation protocol, namely HDREB, was evaluated on whole tumour biopsy specimens. In addition, 1197 CRCs from TMA punches were randomised into two subgroups, the first used to select the cutoff scores for EGFR overexpression, the second to analyse EGFR overexpression and its association with tumour progression and survival. The TMA approach is an accepted tool of investigation, in particular with large sample sizes (Moch et al, 1999; Barlund et al, 2000; Nocito et al, 2001; Simon et al, 2001; Torhorst et al, 2001; Sauter et al, 2003; Goethals et al, 2006).

The evaluation of immunoreactivity was carried out semiquantitatively by scoring the percentage of positive tumour cells in both rectal tumour biopsy specimens and TMA punches. We have previously shown that this scoring method leads to a more complete assessment of the prognostic value of several tumour markers in CRC when compared to an evaluation system based on arbitrarily determined ‘positive’ or ‘negative’ scores (Lugli et al, 2006a, 2006b, 2006c, 2006d). We have also shown that this scoring method is reproducible among pathologists in rectal cancer using the ICC which has recently been proposed as a method for determining inter-observer variation of semicontinuous immunohistochemical scores (Kirkegaard et al, 2006; Zlobec et al, 2006a). An ICC greater than 0.7 should be regarded as the acceptable minimum standard for declaring reliability (Kirkegaard et al, 2006). In this study, we again validate this scoring method for EGFR among three independent pathologists in rectal cancer biopsies (ICC=0.71) and TMA punches of CRC (ICC=0.86).

ROC curves are commonly used in clinical oncology to determine the threshold value above which a test result should be considered positive for some outcome (Hanley, 1989; Al-Homoud et al, 2004; Carpelan-Holmstrom et al, 2004; Chen et al, 2005; Reid et al, 2005; Lind et al, 2006; Linke et al, 2006; Punglia et al, 2006). We applied the same principle in this study to determine the cutoff scores above which EGFR should be considered overexpressed (Zlobec et al, 2006b). The reproducibility of this method was validated by generating ROC curves for each of the three pathologist's scores in addition to resampling of the data. The results of this study demonstrate that the selected cutoff scores for each clinicopathological feature were highly consistent among pathologists.

To obtain the best estimate of the EGFR expression in each tumour, the three cutoff scores from each pathologist were averaged. The cutoff score varied with the end point under investigation. EGFR was considered to be overexpressed when more than 15% of cells were stained when evaluating rectal tumour response to HDREB but was significantly greater when analysing features related to tumour progression and survival (75% staining). This difference in cutoff scores may be due to the selection of patients into each Study Group. The rectal cancer patients in Study Group 1 had predominantly cT3 tumours whereas those in Study Group 2 were unselected and included tumours of all T stages. The distribution of EGFR scores in both study groups varied considerably with those in Study group 1 ranging from 0 to 90% with only 5% of tumours expressing EGFR in more than 80% of tumour cells.

The findings of this study underline the fact that the selection of cutoff scores for positivity should be performed for the specific end point under investigation. The cutoff score of 15% is therefore specific for predicting complete response in patients undergoing treatment with preoperative HDREB and may not be generalisable to other forms of radiotherapy for which cutoff scores can be established.

When investigating outcomes, such as response to anti-EGFR therapy, it may be more beneficial to choose a cutoff score leading to high sensitivity rather than specificity for tumour response to select the greatest number of potentially responsive candidates for treatment. In this study, the cutoff score was selected such that it maximised the number of correctly classified tumours with and without the end point being under evaluation (maximum sensitivity with minimal loss of specificity).

At the selected cutoff scores, EGFR overexpression was significantly associated with improved response to preoperative HDREB. Complete pathological response was more than seven times more likely to occur in tumours overexpressing EGFR whereas complete or partial response was found to occur nearly four times more often in these cases. These results are in line with reports in head and neck squamous cell carcinoma investigating the predictive value of EGFR using a high-dose rate approach (Eriksen et al, 2004; Bentzen et al, 2005).

EGFR overexpression in MMR-proficient CRC was not associated with N stage or vascular invasion and led to marginally significant associations with T stage and tumour grade. These results are supported by similar findings by other groups that have shown no relationship between EGFR overexpression and disease evolution (Yasui et al, 1988; Moorghen et al, 1990; Koenders et al, 1992; Saeki et al, 1995; Goldstein and Armin, 2001; Yarden and Sliwkowski, 2001; McKay et al, 2002; Spano et al, 2005b). However, patients with EGFR overexpressing tumours (85% tumour cell staining) demonstrated a significantly worse prognosis (35.0 months (23.0–58.0)) than those with no overexpression (87.0 months (69.0–103.0)). Previous reports also support these findings (Gross et al, 1991; Mayer et al, 1993; Khorana et al, 2003; Resnick et al, 2004; Galizia et al, 2006). Moreover, EGFR in this study was found to predict worse survival in a multivariate analysis independently of known adverse prognostic factors including T stage, N stage and vascular invasion. These results indicate that EGFR expression evaluated at a cutoff of 85% could be used as a prognostic marker in addition to pathological staging.

In conclusion, EGFR is a predictive marker of response to preoperative HDREB in rectal cancers and an independent adverse prognostic factor in MMR-proficient CRC. The combination of semiquantitative evaluation of EGFR expression and ROC curve analysis which was validated in this study proves to be a reproducible method for selecting the cutoff scores for EGFR overexpression in CRC.