Comparison of the IHC, FISH, SISH and qPCR methods for the molecular diagnosis of breast cancer
- D. Tvrdík
- L. Staněk
- H. Skálová
- P. Dundr
- Z. Velenská
- C. Povýšil
- Published online on: May 17, 2012 https://doi.org/10.3892/mmr.2012.919
- Pages: 439-443
Her2 proto-oncogene amplification and protein overexpression is observed in 20–40% of patients with breast cancer (1), and plays a crucial role in the biological behavior and pathogenesis of invasive breast cancer and its treatment. Both node-positive and node-negative breast cancer patients whose tumors exhibit Her2 amplification have a poor prognosis, increased risk of recurrence and high risk of disease-related mortality, demonstrating an overall shorter survival time (2–6).
The Her2 gene [also known as ERBB2 or epidermal growth factor receptor (EGFR)2] encodes a 185 kDa transmembrane glycoprotein with tyrosine kinase activity. Her2 has high sequence homology with other members of the EGFR family (7). The function of these receptors is the regulation of cell growth, differentiation and survival. Receptor activation requires 3 components: a ligand, a receptor and a dimerization partner. When a specific ligand binds to a Her2 receptor, it must combine with another receptor of similar structure and undergo dimerization. This initiates a cascade of phosphorylation and signal transduction events that affect the transcription of specific genes involved in cell proliferation and survival (8).
However, Her2 status does predict a favorable response to chemotherapy and anti-Her2 antibody treatment (9), since the humanized anti-Her2 antibody binds to the Her2 receptor, thereby preventing heterodimerization and interrupting the downstream signaling pathway. Moreover, the bound antibody induces FcR-mediated cytotoxicity (8). Therefore, it is extremely important to determine the status of Her2 when considering biological therapy.
In the present study, we investigated samples from 131 patients with invasive breast carcinoma. The expression/amplification level of Her2 was evaluated using manual and/or automatic immunohistochemistry (IHC), fluorescence in situ hybridization (FISH), silver in situ hybridization (SISH) and quantitative polymerase chain reaction (qPCR).
Patients and methods
Our study included 131 female patients, aged 55±14 years (mean ± standard deviation), treated for breast carcinoma at the General Faculty Hospital (Prague, Czech Republic) between 2005 and 2011. In all cases, tumor tissue was obtained from a diagnostic core needle biopsy or from a specimen removed during final surgery (lumpectomy or mastectomy).
The specimens obtained from the core needle biopsy and surgery were fixed in 10% formalin and embedded in paraffin wax. Histological evaluation was performed on slides routinely stained with hematoxylin and eosin (H&E). Tumor stage was determined according to WHO guidelines (2003) regarding the use of clinical data.
Immunohistochemistry included the assessment of Her2 by manual and automatic procedures.
The manual evaluation of Her2 was conducted using HerceptTest (DakoCytomation, Glostrup, Denmark) according to the manufacturer's instructions. The slides were immersed in a pre-heated epitope retrieval solution (95–99°C) in a water bath for 40 min, cooled at room temperature for 20 min and then rinsed using a washing buffer. A peroxidase-blocking reagent, a primary antibody, a visualization reagent and a substrate-chromogen solution were applied; the slides were incubated and after each step they were rinsed with a washing buffer. The evaluation of Her2 overexpression was performed as defined by the HercepTest scoring guidelines: 0, no staining or membrane staining in less than 10% of the tumor cells; 1+, partial faint membrane staining in more than 10% of the tumor cells; 2+, weak to moderate complete membrane staining in more than 10% of the tumor cells; 3+, strong complete membrane staining in more than 10% of the tumor cells. The HercepTest results were interpreted as negative (score 0 and 1+), weakly positive (2+) and strongly positive (3+) for Her2 protein overexpression.
Automatic Her2 staining was performed using Ventana anti-Her2/neu rabbit monoclonal antibody (Roche Diagnostics, Mannheim, Germany) using a Ventana Benchmark XT instrument (Roche Diagnostics) according to the manufacturer's instructions. Briefly, primary antibody incubation was carried out at 37°C for 16 min, then with UV HRP UNIV MULT for 8 min, UV DAB and UV DAB H2O2 for 8 min, UV COPPER for 4 min, hematoxylin for 8 min and bluing reagent for 8 min. The interpretation of Ventana staining was the same as that for the HercepTest.
Fluorescence in situ hybridization
Sections (5 μm) of paraffin-embedded tissue were processed for FISH using the PathVysion HER-2 DNA Probe kit from Abbott Vysis (Downers Grove, IL, USA). The assay procedure was conducted according to the manufacturer's instructions. Firstly, the slides were deparaffinized in xylene, then pre-treated in 0.2N HCl and subsequently in an NaSCN solution at 80°C; the next step was proteolytic treatment. The protease digestion was performed to obtain readable and conclusive FISH results. Protease II (25 mg; Abbott Vysis) in a 50 ml saline solution at pH 2.0 was used with a digestion time of 45 min for the core needle biopsy and 60 min for the final surgery samples. Next, the sections were fixed in buffered formalin. We then applied the FISH probe, sealed it with liquid rubber cement, co-denatured the specimen and the DNA probe for 1 min at 85°C and then hybridized it overnight in a ThermoBrite system (Abbott Vysis) at 37°C. After hybridization, the unbound probe was removed in 0.4xSSC/0.3% NP-40 washing solution at 74°C, and the slides were dehydrated and counterstained with 4,6-diamidino-2-phenylindol (DAPI).
For each sample, a minimum of 20 cells was evaluated using an Olympus Provis AX70 microscope (Olympus, Tokyo, Japan) for the presence of amplification signals. A positive result was defined as the ratio, Her2:CEP17 >2.
Silver in situ hybridization
The automatic silver in situ hybridization of Her2 was conducted using a Ventana Inform Her2 Dual ISH DNA Probe Cocktail assay (Roche) according to the manufacturer's instructions. The SISH conditions for the Ventana Benchmark XT (Roche Diagnostics) instrument were: cell conditioner 2 for 8 min, protease 3 for 16 min, hybridization for 6 h, washing at 72°C, silver staining for 8 min, red staining for 8 min, hematoxylin staining for 8 min and bluing reagent for 4 min. The interpretation of Ventana SISH staining was the same as that for manual FISH.
DNA isolation and qPCR analysis
Deparaffinized slides of formalin-fixed, paraffin-embedded tissue and isolation of DNA were performed using standard procedures. First, the slides were deparaffinized in xylene and the DNA was then extracted using a QIAamp DNA mini kit (Qiagen, Hamburg, Germany).
Her2 amplification levels were quantified by using a LightCycler 480 (Roche Diagnostics) and the LightMix Her2/neu kit (Tib MolBiol GmbH, Berlin, Germany) according to manufacturer's instructions. The kit contained a DNA calibrator provided to generate a calibration curve.
The PCR conditions were: initial denaturation for 10 min at 95°C, followed by 50 cycles of denaturation for 10 sec at 95°C, annealing for 10 sec at 60°C and extension for 10 sec at 72°C.
The level of Her2 DNA was normalized to the level of the housekeeping gene, ribosomal protein L23 (RPL23). PCR amplification of each transcript was performed twice. The normalized ratio, Her2:RPL23 >2, was considered positive for Her2 gene amplification.
Initially, we determined the Her2 status of 29 patients by immunohistochemistry and qPCR analysis (Table I). The patients included 12 Her2-negative patients (score 0 or 1+), 2 patients with weak positivity (score 2+) and 15 patients with a strong membrane positivity (3+). We found a positive correlation (R=0.57) between immunohistochemically detected membrane protein expression and molecular biologically analyzed Her2 gene amplification using qPCR. In a group of 11 patients, we determined Her2 status by using qPCR and FISH methods; this group included 1 Her2-negative patient (score 0), 1 patient with weak positivity (score 2+) and 9 patients with 3+ positivity. We found a positive correlation (R=0.51) between the results obtained from these 2 methods.
In the following step, we performed analysis of Her2 status by manual and automatic IHC and FISH in another group of 35 patients (Table II). This group included 16 Her2-negative patients (score 0 or 1+), 8 patients with weak positivity (score 2+) and 11 patients with a strong membrane positivity 3+. We found a significant correlation between the results obtained from manual and automatic IHC (R=0.9) and between those obtained from manual IHC and FISH (R=0.81).
Finally, we analyzed another group of 67 patients using automatic IHC and SISH (Table III). This group included 51 Her2-negative patients (score 0 or 1+), 10 patients with weak positivity (score 2+) and 6 patients with a strong membrane positivity 3+. We found a positive correlation (R=0.72) between the results obtained from automatic IHC and SISH.
However, the correlation co-efficient (R) calculated from these methods was, in some cases, low, as qPCR enables a wide range of real-time applications compared to other methods that score from 0 to 3+.
We can conclude that our proposed method of detecting the amplification/overexpression Her2 using the qPCR appears to be sufficiently specific with good reproducibility. Moreover, our data demonstrated that all methods investigated were highly comparable for the detection of Her2 overexpression/amplification.
Clinicians have long recognized the heterogeneity of human breast cancers, not only in terms of their diverse natural histories, despite identical morphological features, but also in their varied responses to treatment (10).
With the development of tailored therapies targeting specific molecules, Her2, ER and other molecular markers have become important predictive factors. For example, Her2 positivity predicts a response to trastuzumab, and estrogen receptor positivity predicts response to hormonal therapy (11).
Her2 protein overexpression is also indicative of a more aggressive tumor phenotype, an increased number of lymph node metastases, a shorter time to treatment failure and a shorter overall survival time (1,3–6). Moreover, through unknown mechanisms, it correlates with grade and type of breast cancer and is associated with a poor prognosis (12).
The most common methods for examining Her2 status are IHC, for the detection of gene expression at the protein level, and FISH, for the detection of gene amplification on the DNA level.
Immunohistochemical evaluation can be affected by variations among antibodies, fixatives and subjective interpretation. No significant difference was identified between the manual Herceptest and the automatic Ventana method. However, the automatic Ventana method stained a little more intensely than the HercepTest method; this would not be a problem for an experienced pathologist.
In situ hybridization techniques allow the analysis of individual cells, and can detect whether amplification is the result of chromosome duplication or gene amplification. However, FISH is expensive, time-consuming and requires several hours for hybridization (often overnight) and considerable time to count amplification in individual cells. Moreover, FISH/SISH cannot identify cases in which the gene product is overexpressed in the absence of gene amplification.
Again, no significant difference was identified between the manual FISH and the automatic SISH methods. However, in cases of strong amplification, the overlapping SISH signals may aggregate in clusters that cannot be individually counted. Although this is not a problem for clinical use, it may cause problems with strict external quality assessment.
qPCR techniques allow the detection of Her2 on DNA and RNA (13) levels, and may provide alternatives to these methods (14,15). In the future, PCR methods are likely to become more widely used as they are more sensitive, faster, easy to perform and allow the screening of multiple samples at the same time. On the other hand, the use of formalin-fixed paraffin-embedded tissue for this purpose on the RNA level may be problematic since the RNA often becomes degraded in this material (16).
In conclusion, we determined Her2 status using several methods including manual and automatic IHC, SISH/FISH and qPCR. We verified that these methods produce mutual results and are therefore interchangeable.
We conclude that in order to devise effective rational treatments for Her2-positive tumors, a reliable tool for determining Her2 status is required. This study demonstrates that qPCR is a valuable tool for the evaluation of Her2 gene overexpression. The results from qPCR analysis positively correlated with the results obtained from IHC and FISH analysis. Moreover, the results obtained by qPCR are not encumbered with any subjective error on the part of the evaluator.
This study was supported by grant IGA MZ ČR NS/10575-3. We wish to thank Lenka Matiášková, Jana Šídlová and Blanka Véghová for their precise laboratory technician work.