Marius Nap

Immunocytochemical detection and mapping of a cytokeratin 18 neo-epitope exposed during early apoptosis

A neo‐epitope in cytokeratin 18 (CK18) that becomes available at an early caspase cleavage event during apoptosis and is not detectable in vital epithelial cells is characterized. The monoclonal antibody M30, specific for this site, can be utilized specifically to recognize apoptotic cells, which show cytoplasmic cytokeratin filaments and aggregates after immunohistochemistry with M30, while viable and necrotic cells are negative. The number of cells recognized by the antibody increases after induction of apoptosis in exponentially growing epithelial cell lines and immunoreactivity is independent of the phosphorylation state of the cytokeratins. The generation of the M30 neo‐epitope occurs early in the apoptotic cascade, before annexin V reactivity or positive DNA nick end labelling. In a flow cytometric assay, the majority of the M30‐positive cells appear in the ‘apoptotic’ subG1 peak. Tests with synthetic peptides define positions 387–396 of CK18, with a liberated C‐terminus at the caspase cleavage site DALD‐S, as the ten‐residue epitope of M30. This epitope starts at the end of coil 2 of the predicted CK18 structure, at a probable hinge region, compatible with the sensitivity to proteolytic cleavage. The definition of a specific caspase cleavage site in CK18 as a neo‐epitope can be used for quantification of apoptotic epithelial cells with immunocytochemical techniques and is applicable to both fresh and formalin‐fixed material. Copyright

Simultaneous detection of apoptosis and proliferation in colorectal carcinoma by multiparameter flow cytometry allows separation of high and low‐turnover tumors with distinct clinical outcome

Dukes C colorectal carcinoma is treated with adjuvant chemotherapy. Adjuvant treatment is not standard for patients with Dukes B tumors, even though about 20% of patients within this tumor stage die of recurrent disease. The authors investigated whether a novel method of simultaneous detection of apoptosis and proliferation would improve the assessment of prognosis in colorectal carcinoma patients, with the ultimate goal of accurately identifying patients eligible for adjuvant therapy.

Evaluation of the membrane attack complex of complement for the detection of a recent myocardial infarction in man

The diagnosis of an acute myocardial infarction (MI) can be cumbersome for pathologists. Even with a positive nitroblue tetrazolium (NBT) reaction, haematoxylin and eosin (H&E) evaluation of the myocardial tissue can remain inconclusive. Early signs presumed diagnostic for myocardial infarction, such as hypereosinophilia, waviness, and contraction band necrosis, have to be considered non‐specific and are probably reversible signs of ischaemia. Several studies implicate the complement system, and especially complement factor C9, as part of the membrane attack factor (MAC), in cardiomyocyte damage during MI. In a post‐mortem study on well‐documented cardiological autopsies, we evaluated the use of complement factor C9 immunostaining as a marker for the detection of very recent MI. Forty‐three tissue samples from 40 patients were obtained from the left ventricular free wall only, a region that can be specifically attributed to one corresponding coronary artery. As some patients presented with MIs of various stages in that perfusion area, in total 57 observations were possible. C9 immunostaining specifically detected irreversibly damaged (=infarcted) cardiomyocytes, as is implied by the lytic activity of C9/MAC binding to cell membranes. Most interesting was the group of clinically suspected, NBT‐positive MIs resulting from very recent myocardial ischaemia. In this population, where H&E evaluation by (cardio‐) experienced pathologists was not conclusive, C9 immunostaining clearly pointed towards myocardial infarction in 47% of the cases. In conclusion, C9 immunostaining, routinely practicable in the pathology laboratory, has an additional value in discriminating between reversible ischaemia and infarcted cardiomyocytes in very early MIs. Copyright

Activated macrophages containing tumor marker in colon carcinoma: immunohistochemical proof of a concept.

The presence of carcinoembryonic antigen (CEA)-containing activated macrophages has been demonstrated in peripheral blood from patients with colorectal carcinoma. Macrophages migrate from the circulation into the tissue, phagocytose debris, and return to the bloodstream. Hence it seems likely that activated macrophages containing tumor debris, i.e., tumor marker, are present in the stroma of colorectal carcinoma. After phagocytosis, they could follow a hematogenic or lymphogenic route to the peripheral blood. The aim of this study is to assess the presence of tumor marker-containing activated macrophages in the stroma of colon carcinoma and in regional lymph nodes. From 10 cases of colon carcinoma, samples of tumor tissue and metastasis-free lymph nodes were cut in serial sections and stained for CD68 to identify macrophages and for CEA, cytokeratin, or M30 presence. Slides were digitalised and visually inspected using two monitors, comparing the CD68 stain to the tumor marker stain to evaluate the presence of tumor marker-positive macrophages. Macrophages containing tumor marker could be identified in tumor stroma and in metastasis-free regional lymph nodes. The distribution varied for the different markers, CEA-positive macrophages being most abundant. The presence of macrophages containing tumor marker in the tumor stroma and lymph nodes from patients with colon carcinoma could be confirmed in this series using serial immunohistochemistry. This finding supports the concept of activated macrophages, after phagocytosing cell debris, being transported or migrating through the lymphatic system. These results support the potential of tumor marker-containing macrophages to serve as a marker for diagnosis and follow-up of colon cancer patients.

Flow cytometric DNA and phenotype analysis in pathology

Abstract. This meeting report summarizes the presentations of three different groups that are active in the field of flow cytometry (FCM) in relation to diagnosing and classification of proliferative disorders. The report starts with the contribution from Regensburg about the developments in DNA FCM, the progression to dual parameter determinations, and combination of immunophenotyping in combination with DNA. In the second part, the use of FCM for the detection of isolated tumor cells in the peripheral blood from patients with prostate or breast cancer is discussed in a contribution from Münster. In the third part, from Heerlen, the use of multi-parameter FCM on formalin-fixed paraffin-embedded tissues from solid tumors is discussed as a new development and application in routine surgical pathology.

Reproducibility studies for experimental epitope detection in macrophages (EDIM)

INTRODUCTION We have recently described epitope detection in macrophages (EDIM) by flow cytometry. This is a promising tool for the diagnosis and follow-up of malignancies. However, biological and technical validation is warranted before clinical applicability can be explored. METHODS The pre-analytic and analytic phases were investigated. Five different aspects were assessed: blood sample stability, intra-individual variability in healthy persons, intra-assay variation, inter-assay variation and assay transferability. The post-analytic phase was already partly standardized and described in an earlier study. RESULTS The outcomes in the pre-analytic phase showed that samples are stable for 24h after venipuncture. Biological variation over time was similar to that of serum tumor marker assays; each patient has a baseline value. Intra-assay variation showed good reproducibility, while inter-assay variation showed reproducibility similar to that of to established serum tumor marker assays. Furthermore, the assay showed excellent transferability between analyzers. CONCLUSION Under optimal analytic conditions the EDIM method is technically stable, reproducible and transferable. Biological variation over time needs further assessment in future work.

Early apoptotic responses in transgenic mouse mammary carcinoma for photodynamic therapy.

BACKGROUND Male transgenic mice expressing the human RAS gene on an FVB strain background develop adenocarcinoma of the breast between 7 and 8 weeks of age. We have utilized this mammary tumour model to investigate apoptotic responses following photodynamic therapy (PDT) with a chlorin-based, water-soluble photosensitizer. METHODS Detection of apoptosis was accomplished by use of the antibody M30 against a neo-epitope of caspase-cleaved cytokeratin 18 that becomes available at an early stage of the apoptotic cascade. Mice bearing multiple tumours were injected with the photosensitizer intraperitoneally, and following a drug-light interval of 96h, 40J/cm(2) of 652nm laser light was applied to one tumour per animal, while the other tumours were protected from light to serve as host controls. The M30 antibody was used for standard immunohistochemistry of tumour sections and flow cytometric detection of epitope expression coupled to cell cycle analysis in tumour cell populations retrieved from paraffin blocks. RESULTS M30 staining was significantly increased within 2h following light treatment and persisted until 96h after treatment. Flow cytometric analysis for the S-phase fraction (SPF) of tumour cells post-PDT showed a substantial decrease in SPF at 2h post PDT, and recovery of SPF within 96h. CONCLUSIONS Cytokeratin 18 cleavage seems to be both an early and ongoing event during the cellular response to PDT. Calculating the M30/SPF ratio at both 2h and 96h suggested distinct cellular dynamics at early and late time points, and we propose the M30/SPF ratio as a tumour dynamic index (TDI) to monitor events post PDT.

9 Clinical flow cytometry of solid tumors

Publisher Summary Immunophenotyping by multiparameter flow cytometric (FCM) can provide a rapid accurate method for both identifying unique cell populations and describing their functional status. This can be achieved because antibodies to cellular proteins can be conjugated or labeled with different-colored fluorochromes and combined in panels for staining heterogeneous cell populations. Traditionally, FCM has never been the core business of surgical pathology. However, immunohistochemistry as an additional tool for the surgical pathologist is not always satisfactory—for example, clonality assessment in B-cell lymphomas is still difficult to perform with immunohistochemistry because of lack of staining contrast between surface immunoglobulins and extracellular immunoglobulins. In addition, solid tumors are heterogeneous of composition, and they consist of a mixture of normal stromal, inflammatory, and malignant cells. This heterogeneous cell composition is one of the limiting factors for reproducible quantification—for example, of steroid hormone receptor expression in breast carcinomas. Immunohistochemistry is sensitive to many external factors interfering with accurate quantification of receptor content. Staining intensity is influenced by the kind and duration of fixation, thickness of the tissue section, incubation conditions of the primary antibodies, choice and concentration of the chromogens, and subjective scoring by the investigators.