Willem E. Corver

Specificity of seven monoclonal antibodies against p53 evaluated with Western blotting, immunohistochemistry, confocal laser scanning microscopy, and flow cytometry

p53 immunostaining of histological sections shows inter- and intratumor variability in distribution and staining intensity which are usually scored semiquantitatively. In order to investigate the variation in p53 expression more accurately and its possible relation to other cellular parameters (e.g., DNA content), we have studied the possibility to measure p53 accumulation by multiparameter flow cytometry. To this end we have evaluated seven, commercially available, monoclonal antibodies (MAbs) against p53 (MAbs 1801, 240, 246, 421, 1620, Do1, and Do7) on five tumor cell lines with known p53 gene status: MCF-7 (wild-type p53 gene), COV362.cl4 and T47d (mutated p53 genes), and SAOS-2 and HL60 (no p53 mRNA). Localization of immunofluorescence was investigated with confocal laser scanning microscopy, immunofluorescence signal intensity with flow cytometry, and antibody specificity with Western blotting. Subsequently, single cell suspensions from two breast carcinomas were flow cytometrically analyzed after triple staining for p53, cytokeratin 8/18, and DNA, and compared to immunohistochemical staining. MAbs Do1 and Do7, and to a lesser extent MAb 421, accurately discriminated p53 positive from p53 negative cell lines. Even at high concentrations these MAbs yielded nuclear immunofluorescence, whereas with MAbs 1801, 240, and 246 strong cytoplasmic signals in both the p53 accumulating and p53 negative cell lines were seen. By using lower antibody concentrations the cytoplasmic immunofluorescence disappeared, but simultaneously the nuclear p53 immunostaining intensity in p53 accumulating cell lines decreased, resulting in false negative nuclei. With MAb 1620 only weak intranuclear spots were obtained in all cell lines tested. Western blotting yielded results with MAbs 1801, Do1, and Do7 in the 53 kD region of the p53 accumulating cell lines. The signal intensity obtained with MAb 1801 was much less compared to MAbs Do1 and Do7. Although all three MAbs are also described as wild-type p53 specific, only MAbs, Do1 and Do7 showed bands in the 53 kD region of cell line MCF-7. With MAb 1801 ascites and MAb 1801 supernatant an additional approximately 80 kD band was present in all cell lines tested, including SAOS-2, indicating cross reactivity of this MAb. Immunohistochemical staining of two clinical breast carcinomas confirmed the results obtained in the cell lines. Multiparameter flow cytometric analysis of these breast carcinomas with MAbs Do1 and Do7 showed intratumor heterogeneity for p53 accumulation, which was independent of DNA index heterogeneity. We conclude that MAbs Do1 and Do7 enable quantitative analysis of p53 accumulation in a multiparameter flow cytometric analysis.

High human papillomavirus oncogene mRNA expression and not viral DNA load is associated with poor prognosis in cervical cancer patients

Purpose: Cervical cancer is now known to be caused by infection with an oncogenic type of the human papillomavirus (HPV). However, little is known about the continued role of HPV once cancer has been established. Here, we describe the quantitative relation between HPV DNA copy number and mRNA expression of the viral oncogenes (E6 and E7) and the prognostic value of both measures in cervical cancer patients. Experimental Design: We studied the number of viral DNA copies and the level of HPV E6/E7 mRNA expression in 75 HPV 16–positive or HPV 18–positive International Federation of Gynecology and Obstetrics stage Ib and IIa cervical cancer patients. Measurements were done with quantitative PCR. DNA copy number analysis was done on pure tumor cell samples enriched with flow sorting. mRNA expression data were compensated for the percentage of tumor cells included. Results: The number of viral DNA copies was not predictive of survival in cervical cancer patients. In contrast, high HPV E6/E7 mRNA expression was strongly related to an unfavorable prognosis (P = 0.006). In a multivariate Cox model for overall survival, including all known prognostic variables and stratified for HPV type, the level of E6/E7 mRNA expression was an independent prognostic indicator, second only to lymph node status. No correlation was observed between DNA copy number and the level of HPV E6/E7 mRNA expression, which reflects that not all DNA copies are equally transcriptionally active. Conclusions: Cervical cancer patients with high HPV E6/E7 oncogene mRNA expression have a worse survival independently from established prognostic factors.

Single nucleotide polymorphisms in antigen processing machinery component ERAP1 significantly associate with clinical outcome in cervical carcinoma

Genetic variation of the antigen processing machinery (APM) components TAP2, LMP7, and ERAP1 is related to cervical carcinoma risk, although the relation with expression and clinical outcome remains unknown. We have investigated the occurrence of APM component single nucleotide polymorphisms (SNPs) in cervical carcinoma. Twelve nonsynonymous, coding SNPs in the TAP1, TAP2, LMP2, LMP7, and ERAP1 genes were genotyped in 75 cervical carcinoma patients with known APM component and HLA class I expression levels. Individual genotype distributions were assessed for association with APM component expression, various histopathological parameters and survival. Genotype distributions at the ERAP1‐56 and ERAP1‐127 loci were significantly associated with overall survival (OS); haplotype construction spanning these two SNPs revealed that the combination of a major allele at ERAP1‐56 and a minor allele at ERAP1‐127 was significantly associated with survival, homozygosity for this haplotype being associated with decreased OS (5‐year survival 50% vs. 70 and 81% for complete absence or heterozygosity for this haplotype, respectively; P = 0.021). Heterozygosity for this haplotype was an independent predictor for better OS in multivariate analysis (HR = 0.219; P = 0.014). These data indicate that genetic variation in APM component genes, particularly ERAP1, is an important contributing factor in cervical carcinogenesis, progressive tumor growth and survival. The location of the ERAP1‐127 SNP in the peptidase M1 domain of the ERAP1 aminopeptidase suggests the possibility of direct functional consequences of variation at this locus.

Genetic variation of antigen processing machinery components and association with cervical carcinoma

The antigen processing machinery (APM) plays an important role in immune recognition of virally infected and transformed cells. Defective expression of several APM components is associated with progression and clinical outcome in cervical carcinoma. Genetic variation in the genes encoding APM components is known to be associated with risk of occurrence of several malignancies. However, only limited evidence exists supporting the role of single nucleotide polymorphisms (SNPs) in APM components in cervical carcinoma. We have therefore investigated the occurrence of APM component SNP genotypes and haplotypes in cervical carcinoma. Thirteen coding SNPs in the LMP2, LMP7, TAP1, TAP2, and ERAP1 genes were genotyped in 127 cervical carcinoma patients and 124 controls. Individual genotype and allele distributions were assessed by single‐marker analysis. Effects of various SNP combinations were estimated by haplotype construction and subsequent haplotype interaction analysis. Significant haplotypes were modeled on disease risk. Allele distributions at the LMP7‐145, TAP2‐651, ERAP1‐127, and ERAP1‐730 loci differed significantly between cases and controls with the major allele at the LMP7 and TAP2 loci and the minor allele at both ERAP1 loci associated with increased cervical carcinoma risk. A combination of the two haplotypes spanning these loci was associated with a three‐fold increased risk (OR = 3.024; P << 0.001); approximately 12% of all cervical carcinoma occurrences were attributable to this combination. Our data indicate that combined genetic variation in the TAP2, LMP7, and ERAP1 genes is associated with increased cervical carcinoma risk.

Allelotype analysis of flow‐sorted breast cancer cells demonstrates genetically related diploid and aneuploid subpopulations in primary tumors and lymph node metastases

Flow cytometric DNA content measurements have demonstrated extensive DNA ploidy heterogeneity in primary breast carcinomas. However, little is known at the molecular level about the clonal relationship between these tumor cell subpopulations, or about the molecular genetic changes associated with aneuploidization. We have used flow cytometric cell sorting to dissect some of this complexity by isolating clonal subpopulations in breast carcinomas for comparative molecular genetic analysis. Clonal subpopulations were isolated from 12 primary breast carcinomas and 5 lymph node metastases from 4 cases based on DNA content and cytokeratin 8/18 labeling. DNA from these clones was screened for allelic imbalances with 92 polymorphic microsatellite markers mapped to 39 different chromosome arms. Diploid and aneuploid populations were concurrently present in 11 out of 12 primary tumors. The DNA ploidy status of primary tumors was identical to that of the related lymph node metastases. Allelic imbalance was present in 10 out of 11 diploid clones (mean, 3.4 ± 4.2). All allelic imbalances observed in the diploid clones recurred in the cognate aneuploid clones, but were, in the latter, accompanied by additional allelic imbalances at other loci and/or chromosome arms (mean, 10.9 ± 5.8). In only two of the four metastatic cases did the allelotypes of metastatic clones show small differences relative to their cognate primary tumors. The primary diploid tumor clone recurred in all lymph node metastases. This study indicates that the majority of allelic imbalances in breast carcinomas are established during generation of DNA ploidy diversity. Recurrence of the allelic imbalances in diploid clones in the aneuploid clones suggests linear tumor progression, whereas the simultaneous presence of early diploid and advanced aneuploid clones in both primary and metastatic tumor sites suggests that acquisition of metastatic propensity can be an early event in the genetic progression of breast cancer. Genes Chromosomes Cancer 28:173–183, 2000.

High-resolution multi-parameter DNA flow cytometry enables detection of tumour and stromal cell subpopulations in paraffin-embedded tissues

The accuracy of DNA ploidy measurements of paraffin‐embedded tissues is limited by the lack of resolution and the inability to identify the DNA diploid population unequivocally in bimodal DNA histograms. A multi‐parameter DNA flow cytometric method has been developed that enables the simultaneous detection of neoplastic and stromal cells in samples from dewaxed 50 µm sections or 2 mm diameter punches of archival tissue blocks. The method combines heat pretreatment in sodium citrate buffer and subsequent enzymatic dissociation with a collagenase/dispase mixture. Cells were simultaneously stained for keratin (FITC), vimentin (R‐PE), and DNA (PI) before flow cytometric analysis. The method was applied to 12 paraffin‐embedded cervical carcinomas and four colorectal carcinomas. In all cervical cancers, distinct keratin‐positive and vimentin‐positive cell populations were observed. While the exclusive vimentin‐positive cell fractions always yielded unimodal DNA content distributions, bimodal distributions were observed for the keratin‐positive cell fractions in nine cervical carcinomas, whereas one cervical carcinoma showed three distinct G0G1 populations. Coefficients of variation of the G0G1 peaks ranged from 1.70% to 4.79%. Average background, aggregate, and debris values were 14.7% (vimentin‐positive fraction) and 33.8% (keratin‐positive fraction). Flow sorting confirmed that the exclusively vimentin‐positive cell fractions represent different normal stromal and infiltrate cells that can serve as an internal ploidy reference enabling discrimination between DNA hypo‐diploid and DNA hyper‐diploid tumour cell subpopulations. The neoplastic origin of the keratin–vimentin co‐expressing cells from two cervical carcinomas was confirmed by genotyping of flow‐sorted samples revealing loss of heterozygosity (LOH) of 6p. This improved method obviates the need for fresh/frozen tumour tissue for high‐resolution DNA ploidy measurements and enables the isolation of highly purified tumour subpopulations for subsequent genotyping. Copyright

Expression of Smad2 and Smad4 in cervical cancer: absent nuclear Smad4 expression correlates with poor survival.

Alterations in transforming growth factor-β signaling, due to a decrease in Smad2 and especially Smad4 expression, has primarily been reported in pancreatic and colorectal cancers, although loss of the chromosomal region 18q21.1, containing the loci of Smad2 and Smad4, is among the most frequent molecular alterations in cervical cancer. The aim of our study was to investigate whether decreased Smad2 and Smad4 protein expression in primary cervical cancers is associated with molecular alterations at 18q21.1, mutations in the functional domains of Smad2 and Smad4 or hypermethylation, and to assess the biological relevance of decreased Smad2 and Smad4 expression. Subsequently, Smad2, Smad4 and p21 protein expression was determined by immunohistochemistry in 117 primary cervical carcinomas, assembled in a tissue array. Smad signaling was shown to be associated with p21 mRNA expression. All the tumors expressed Smad2 or Smad4. Weak cytoplasmic Smad2 or weak cytoplasmic Smad4 expression could not be attributed to loss of heterozygosity at 18q21.1. Despite weak/moderate Smad2 expression and absent nuclear Smad4 expression, the coding regions of the functional MH1 and MH2 domains of Smad2 and Smad4 were unchanged, as assessed by sequence analysis. The Smad4 promoter region was unmethylated in tumor samples with weak/moderate cytoplasmic Smad4 expression. Remarkably, both weak cytoplasmic Smad4 expression and absent nuclear Smad4 expression significantly correlated with poor disease-free (P=0.003 and P=0.003, respectively) and overall 5-year survival (P=0.003 and P=0.010, respectively). Our findings support the hypothesis that Smad4 is a target molecule for functional inactivation in cervical cancer.

Genome-wide Allelic State Analysis on Flow-Sorted Tumor Fractions Provides an Accurate Measure of Chromosomal Aberrations

Chromosomal aberrations are a common characteristic of cancer and are associated with copy number abnormalities and loss of heterozygosity (LOH). Tumor heterogeneity, low tumor cell percentage, and lack of knowledge of the DNA content impair the identification of these alterations especially in aneuploid tumors. To accurately detect allelic changes in carcinomas, we combined flow-sorting and single nucleotide polymorphism arrays. Cells derived from archival cervical and colon cancers were flow-sorted based on differential vimentin and keratin expression and DNA content and analyzed on single nucleotide polymorphism arrays. A new algorithm, the lesser allele intensity ratio, was used to generate a molecular measure of chromosomal aberrations for each case. Flow-sorting significantly improved the detection of copy number abnormalities; 31.8% showed an increase in amplitude and 23.2% were missed in the unsorted fraction, whereas 15.9% were detected but interpreted differently. Integration of the DNA index in the analysis enabled the identification of the allelic state of chromosomal aberrations, such as LOH ([A]), copy-neutral LOH ([AA]), balanced amplifications ([AABB]), and allelic imbalances ([AAB] or [AAAB], etc.). Chromosomal segments were sharply defined. Fluorescence in situ hybridization copy numbers, as well as the high similarity between the DNA index and the allelic state index, which is the average of the allelic states across the genome, validated the method. This new approach provides an individual molecular measure of chromosomal aberrations and will likely have repercussions for preoperative molecular staging, classification, and prognostic profiling of tumors, particularly for heterogeneous aneuploid tumors, and allows the study of the underlying molecular genetic mechanisms and clonal evolution of tumor subpopulations.

Four-Color Multiparameter DNA Flow Cytometric Method to Study Phenotypic Intratumor Heterogeneity in Cervical Cancer

BACKGROUND Multiparameter DNA flow cytometry using a one-laser bench-top flow cytometer has been restricted to three different colors. The two laser FACSCalibur has recently been introduced, allowing four-color analysis. Therefore, we optimized and extended our three-color method (Corver et al., 1994, Corver et al. 1996) to a four-color analysis of phenotypic intra-tumor heterogeneity using a bench-top flow cytometer. METHODS First, the effect of a range of different propidium iodide (PI) and TO-PRO-3 iodide (TP3) concentrations on the coefficient of variation (CV) of the DNA histograms was measured using paraformaldehyde-fixed lysolecithin-permeabilized peripheral blood lymphocytes (PBLs) and SiHa and HeLa cervical cancer cells. Second, labeling freshly isolated cervical cancers from solid tumors was optimized with a mixture of anti-keratin antibodies. Third, the FACSCalibur hardware was modified, thereby allowing the simultaneous measurement of allophycocyanin (APC) fluorescence (FL4) in combination with FL3 pulse processing (FL3-W vs. FL3-A). The optimized procedure was then applied to cell suspensions from four different human cervical cancers to study phenotypic intratumor heterogeneity. Cell suspensions were simultaneously stained for DNA (PI, fluorescence) and three cellular antigens: (a) the epithelial cell-adhesion molecule (Ep-CAM; APC fluorescence), (b) keratin (R-phycoerythrin [RPE] fluorescence) to identify the epithelial fraction, and (c) vimentin (fluorescein-isothiocyanate [FITC] fluorescence) to label stromal cells. RESULTS Overall, PI produced better CVs than did TP3. The optimal concentration of PI was 50-100 microM for all cells tested. Average CVs were 1.76% (PBL), 3.16% (HeLa), and 2.50% (SiHa). Optimal TP3 concentrations were 0.25-2.0 microM. Average CVs were 2. 58% (PBL), 5.16% (HeLa), and 3.96% (SiHa). Inter- or intra-DNA stem line heterogeneity of Ep-CAM expression was observed in the keratin-positive fractions. Vimentin-positive, keratin-negative cells were restricted to the DNA diploid fraction. CONCLUSIONS PI is a superior DNA stain to TP3 when using intact normal PBL and human cancer cells. Four-color high-resolution multiparameter DNA flow cytometry allows the identification of intratumor subpopulations using PI as DNA stain and FITC, RPE, and APC as reporter molecules. The FACSCalibur bench-top flow cytometer can be used for this purpose, allowing the application of this technique in clinical laboratories.

Multiparameter DNA flow-sorting demonstrates diploidy and SDHD wild-type gene retention in the sustentacular cell compartment of head and neck paragangliomas: chief cells are the only neoplastic component.

Head and neck paragangliomas are considered to be biphasic tumours, composed of two distinct cell types: chief cells and sustentacular cells. A substantial number of these tumours show mutations in the SDHD gene located at chromosome 11q23. Although there is general agreement that paragangliomas are a neoplastic proliferation of chief cells, the nature of sustentacular cells is still a matter of debate. To clarify the nature of sustentacular cells further, multiparameter DNA flow cytometry was performed utilizing S‐100 labelling as a selective marker of the sustentacular fraction simultaneously with DNA content measurement in six head and neck paragangliomas. S‐100‐positive fractions and other tumour‐cell populations were flow‐sorted and restriction digestion analysis of SDHD mutations was performed on each fraction. Flow cytometry demonstrated that the S‐100 labelled cells were diploid. Restriction digestion analysis in informative cases revealed retention of the wild‐type SDHD allele in S‐100‐positive fractions and loss of the wild‐type allele in S‐100‐negative fractions. These data strongly suggest that sustentacular cells should be regarded as a non‐neoplastic cell population that may be induced as a tumour‐specific stromal component by chief cells. Copyright