A novel monoclonal antibody to cytokeratin 18 with reactivity toward lung squamous cell carcinomas and adenocarcinomas of various sites.

Antibodies to cytokeratins (CKs) have found extensive application in the differential diagnosis of epithelial tumors. The chain-specific anti-CK reagents appear to be of practical value for further subtyping of carcinomas. The authors have produced a novel anti-CK 18 monoclonal antibody (ACK-156) using a modified immunization procedure that included sequential injections of human epidermal keratin, cyclophosphamide, and enriched cytoskeletal extracts from a human lung carcinoma cell line. This protocol effectively amplified clones with reactivity toward CK epitopes not present in epidermal keratin. Monospecificity of the antibody was confirmed by immunoblot analysis using both total cell lysates and cytoskeletal extracts as antigens. Immunoperoxidase staining of adenocarcinomas from a variety of sites, including lung, was strongly positive. Squamous cell carcinomas of lung were also strongly stained whereas squamous cell carcinomas of head and neck origin were stained focally or not at all. In contrast, several commercially available anti-CK 18 monoclonal antibodies did not distinguish squamous cell carcinomas of lung from those of head and neck origin. Immunoblot analysis of tumor lysates corroborated the tissue staining results and revealed that the commercially available antibodies that were tested recognize at least one other low molecular weight peptide in addition to the CK 18 peptide recognized by ACK-156.     

Utility of 123C3 monoclonal antibody against CD56 (NCAM) for the diagnosis of small cell carcinomas on paraffin sections

CD56 is immunohistochemically detectable in virtually all small cell carcinomas on frozen sections. The authors retrospectively tested the usefulness of the monoclonal antibody 123C3 against CD56 to differentiate pulmonary and extrapulmonary small cell carcinomas from nonneuroendocrine non—small cell carcinomas by paraffin-section immunohistochemistry after antigen retrieval. The study included 70 small cell carcinomas and 344 primary and metastatic nonneuroendocrine carcinomas of various primary sites. The staining results were compared with specific neuroendocrine markers (CD57, Chromogranin A, Synaptophysin). The monoclonal antibody 123C3 diffusely stained most small cell carcinomas with a strong membranous pattern (sensitivity: 0.99). The staining intensity was not diminished in areas with crush artifacts or after decalcification. The neuroendocrine markers had a combined sensitivity of only 0. 44 for small cell carcinomas. With regard to nonneuroendocrine carcinomas, the 123C3 antibody stained 7 of 28 ovarian carcinomas, 6 of 30 renal cell carcinomas, 2 of 10 endometrial carcinomas, two of three nonneuroendocrine large cell carcinomas of the lung, 1 of 38 adenocarcinomas, and 4 of 52 squamous cell carcinomas of the lung. Urothelial carcinomas, hepatocellular carcinomas, squamous carcinomas of the head/neck and cervix uteri, as well as adenocarcinomas of the breast, stomach, colon, pancreas, and prostate, showed no immunoreactivity for CD56. The specificities of 123C3 and the combined neuroendocrine markers for small cell carcinomas were 0. 94 and 0. 95, respectively. The authors conclude that monoclonal antibody 123C3 might be useful for the immunohistochemical differentiation of small cell carcinomas from nonneuroendocrine carcinomas on paraffin sections, especially in small and crushed biopsy specimens.     

An assessment of MAC 387 antibody as a diagnostically useful marker of L1 epithelial antigen expression by lung tumours.

A recent report describing the distribution of L1 epithelial antigen in lung tumours in relation to the histological type claimed that this antigen was a highly reliable marker of squamous cell carcinoma. Our study was designed to test this claim and to examine the potential of this antigen in the typing of lung tumours in biopsy specimens. A total of 143 lung tumours were typed according to the WHO classification and examined immunohistochemically for L1 epithelial antigen expression using commercially available monoclonal mouse anti-human myeloid/histiocyte antigen (MAC 387). Positivity was found in 46 of 55 squamous cell carcinomas (84 per cent), 12 of 27 adenocarcinomas (44 per cent), 15 of 16 adenosquamous carcinomas (93 per cent), 10 of 15 large cell carcinomas (67 per cent), none of 20 small cell carcinomas, and none of 10 carcinoid tumours. Of those tumours expressing L1 epithelial antigen, most showed a patchy pattern of positivity. From this study it is clear that detection of L1 epithelial antigen by MAC 387 antibody is not specific for squamous cell carcinomas, but it may have a limited use in the diagnosis of small cell carcinomas and carcinoid tumours as these are consistently negative.     

Expression of the embryonal neural cell adhesion molecule N-CAM in lung carcinoma. Diagnostic usefulness of monoclonal antibody 735 for the distinction between small cell lung cancer and non-small cell lung cancer

Paraffin sections of 19 surgically resected small cell lung carcinomas (SCLC), 33 non-small cell lung carcinomas (NSCLC) of various types, and four bronchial carcinoids were immunostained with monoclonal antibodies (MoAbs) 735 and anti-Leu 7, both recognizing some sugar epitopes present on the neural cell adhesion molecule N-CAM. With MoAb 735, all SCLC were stained focally or diffusely, and one carcinoid was stained focally. Only three of the 33 NSCLC were faintly and focally positive with MoAb 735; these three tumours showed relatively small tumour cells and small, oval nuclei. Anti-Leu 7 stained all the carcinoids, only eight SCLC, sometimes focally, and eight NSCLC. MoAb 735 was thus superior to anti-Leu 7 in distinguishing between SCLC and NSCLE. Since MoAb 735 stained all SCLC strongly and is applicable on paraffin sections, it provides a well-needed addition to the immunomarkers used in the diagnostic distinction of SCLC and NSCLC.     

Expression and localization of thrombomodulin in preneoplastic bronchial lesions and in lung cancer

Thrombomodulin (TM) is an endothelial surface glycoprotein that acts as a natural anticoagulant. It inhibits thrombin and accelerates the activation of the anticoagulant protein C. TM has been detected in dermal keratinocytes, where it is associated with terminal differentiation. It can also be detected in various types of squamous malignant neoplasms and in malignancies of endothelial and mesothelial origin, such as Kaposi's sarcoma or malignant mesothelioma, but is absent in pulmonary adenocarcinomas (AC). Seventy-two lung tumour specimens [33 squamous cell carcinomas (SQCC), 23 AC, 1 large cell carcinoma, 8 small cell lung cancers (SCLC) and 7 multidifferentiated tumours (MT)] were analysed immunohistochemically by staining with an anti-TM antibody in order to assess TM expression. All of the SQCC stained positively for TM. In contrast, only 9 AC and 4 MT and none of the SCLC showed positive anti-TM staining. Seven hyperplastic bronchial epithelial specimens and eight preneoplastic bronchial lesions (five cases of moderate dysplasia, two cases of severe dysplasia and one case of carcinoma in situ) were used as controls.Normal or hyperplastic areas of bronchial epithelium revealed no positive reaction. However, a distinct positive anti-TM staining pattern related to the degree of keratiniziation of dysplastic lesions was seen. The present results suggest that anti-TM immunostaining is a useful marker for squamous cell carcinoma in the differential diagnosis of pulmonary carcinoma, also indicating keratinocyte differentiation in dysplastic bronchial epithelium.     

Ber EP4 and epithelial membrane antigen aid distinction of basal cell, squamous cell and basosquamous carcinomas of the skin

AIMS: Seventy-five skin tumours were studied to investigate the value of immunohistochemistry in differentiating basal cell, squamous cell and basosquamous carcinomas of the skin. METHODS AND RESULTS: Archived paraffin-embedded tissue samples of basal cell carcinomas (n = 39), squamous cell carcinomas (n = 23) and basosquamous carcinomas (n = 13) were stained immunohistochemically using a panel of antibodies. All of the basal cell carcinomas stained positively for Ber EP4, in contrast to the group of squamous cell carcinomas, that showed no staining. Basosquamous carcinomas all showed at least some areas of Ber EP4 positivity. None of the basal cell carcinomas, but most of the squamous cell carcinomas (22 of 23) expressed epithelial membrane antigen (EMA). Only one of the basosquamous carcinomas expressed EMA positivity focally. CAM 5.2, carcinoembryonic antigen (CEA) and 34betaE12 antibodies lacked specificity in relation to the different tumour types. CONCLUSION: Distinction of basal and squamous cell carcinomas of the skin can be readily achieved with routine immunohistochemistry using Ber EP4 and EMA. Identification of basosquamous carcinoma is also facilitated with this method.     

Growth fraction in lung tumours determined by Ki67 immunostaining and comparison with AgNOR scores

Estimation of the growth fraction with the use of monoclonal antibody Ki67, which recognizes a nuclear antigen in proliferating cells, was compared with the nucleolar organizer region staining in 95 lung tumours. There was nuclear staining in most tumours; 12 tumours were negative. Cytoplasmic staining was observed in another seven tumours. The small cell carcinoma group had the highest mean Ki67 index (23.75); squamous carcinomas had a mean value of 15.71, adenocarcinomas 10.99, and large cell anaplastic 20.76. Carcinoids had few stained cells. Nucleolar organizer regions were demonstrated by the argyrophilic method (AgNOR). No correlation was found between Ki67 indices and AgNOR scores. Kinetic data obtained by the AgNOR technique were less discriminating in view of the overlap between scores of various groups including carcinoids. We conclude that use of the monoclonal antibody Ki67 is a more reliable method of assessing proliferative activity in lung tumours. This antibody may be effective in identifying slowly proliferating tumours which are less sensitive to chemotherapeutic agents.     

Comparison of immunoreactivity between two different monoclonal antibodies recognizing peptide and polysialic acid chain epitopes on the neural cell adhesion molecule in normal tissues and lung tumors.

A comparative immunohistochemical study of two different monoctonal antibodies against different epitopes on the neural cell adhesion molecule (N-CAM) was performed. Various normal tissues and lung tumors were examined for reactivity with NCC-LU-243, a monoclonal antibody which recognizes a peptide epitope on N-CAM, and monoclonal antibody 735 (MoAb 735), which reacts with a polysialic acid chain epitope on N-CAM. When acetone-fixed normal tissues were used, the immunoreactivities of MoAb 735 and NCC-LU-243 were not identical. In lung tumors, almost all small cell cancers (SCLC) and carcinoid tumors, and some non-SCLC were stained by both monoclonal antibodies. NCC-LU-243 stained the cell membrane only of almost all SCLC cells and clusters of non-SCLC cells. MoAb 735 stained the cell membrane of SCLC in a patchy manner and not only the cell membrane but also the cytoplasm of some non-SCLC. However cytoplasmic staining was evaluated as ‘not positive’. The number of positive cases and the size of the positive tumor cell population determined by cell membrane staining with MoAb 735 were smaller than those determined with NCC-LU-243 in both SCLC and non-SCLC cases. In routinely formalin-fixed materials, the immunoreactivity of both monoclonal antibodies, especially of NCC-LU-243, decreased after prolonged fixation as in surgically resected and autopsy materials. However, both monoclonal antibodies were found to be useful when materials were fixed for a short period of time as in biopsy specimens.     

Protein 1 and Clara cell 10-kDa protein distribution in normal and neoplastic tissues with emphasis on the respiratory system

Thirty-six different normal tissues and 13 different malignant epithelial tumours, were examined immunohistochemically for the presence of protein 1 (P1) and Clara cell 10-kDa protein (CC10). Adenocarcinomas of the lung were also examined for the expression of pulmonary surfactant apoprotein using a monoclonal antibody (PE-10). The staining results of P1 and CC10 were almost identical both in normal tissues and in malignant tumours. In normal lung, Clara cells were strongly positive for both P1 and CC10. In addition, some goblet cells and non-ciliated non-mucus cells in the upper airways were moderately positive for both proteins. In the malignant tumours, some lung cancers were positive for P1 and CC10, both of which were positive in the same tumour cells on sequential sections. In 117 lung cancers, P1 and CC10 were positive in 10.2% of adenocarcinomas, 20.5% of squamous cell carcinomas, and 12.5% of large cell carcinomas. PE-10 stained positively in 65.3% of adenocarcinomas, a frequency significantly higher than that of P1 and CC10 (P<0.01). These results suggest that P1 and CC10 are nearly identical proteins, that both are useful markers of Clara cells, and that many pulmonary adenocarcinomas express surfactant apoprotein rather than Clara cell proteins.     

The L1 antigen and squamous metaplasia in the bladder

The L1 antigen was investigated as a marker of squamous differentiation in urothelium using a monoclonal antibody Mac387, and the results were compared with the expression of high molecular weight cytokeratins. L1 antigen was consistently demonstrated in all instances of partial and complete squamous metaplasia and in squamous carcinomas. In contrast, pure transitional cell carcinomas (except one with minor focal staining), adenocarcinomas and normal and hyperplastic urothelium did not label. In a few squamous carcinomas in situ, the pattern of labelling obtained with Mac387 was different from that seen in invasive squamous carcinomas and metaplasias. Compared with high molecular weight cytokeratins, the expression of L1 was more intense in areas of squamous differentiation. L1 expression, as identified by antibody Mac387, may therefore serve as a useful marker of squamous differentiation in urothelial lesions.     

Immunohistochemical reactivity of a monoclonal antibody prepared against human breast carcinoma

Summary The reactivity profile of an IgM monoclonal antibody, MBR1, raised against the human breast cancer cell line MCF7, was studied in a variety of human tumours and non-neoplastic tissues by light microscopic immunohistochemistry. The range of reactivity included specific types of non-neoplastic epithelial cells and a number of epithelial tumours. Most mammary carcinomas reacted with MBR1, but adenocarcinomas and squamous carcinomas from different sites were also strongly positive. Different patterns of immunoreactivity were apparent in microscopically normal tissues, in tissues with inflammatory changes and in carcinomas. Heterogeneous staining, despite morphological similarities, was documented in neoplastic and non-neoplastic epithelial cells. The reactivity of MBR1 was different from that reported for other monoclonal antibodies, but revealed similarities to that of monoclonal antibodies and polyclonal sera against human milk fat globule membrane.     

A monoclonal antibody, NCRC-11, raised to human breast carcinoma. 1. Production and immunohistological characterization

The production of a mouse monoclonal IgM antibody, NCRC-11, raised against human breast carcinoma is described. It has been characterized immunohistologically. The antigen recognised has a wide but highly specific distribution in normal tissues, being virtually confined to the surface of certain epithelial cell types. It is found in some forms of epithelial metaplasia and most epithelial malignancies, particularly adenocarcinomas. The heterogeneity of staining in mammary carcinomas is outlined and is of particular interest. The immunohistological staining distribution of NCRC-11 is similar to other antibodies, including anti-epithelial membrane antigen, which were raised against human milk fat globule membrane. A competition experiment with some of these antibodies, using a flow cytofluorimeter, showed competition with one antibody, LICR LON/M8.     

CD68 reactivity of non-macrophage derived tumours in cytological specimens.

AIMS--To investigate the presence of the macrophage associated antigen CD68 in non-haematopoietic tumours. METHODS--Cytological specimens from non-macrophage derived tumours were stained using the alkaline phosphatase anti-alkaline phosphatase immunocytochemical method (APAAP) and three monoclonal anti-CD68 antibodies, Y1/82A, EBM11, and KP1. RESULTS--Reactivity of malignant cells with one or more of the antibodies was seen in 11 out of 40 adenocarcinomas and in one of seven poorly differentiated carcinomas; other neoplasms, including 10 cases of squamous carcinoma, three of malignant melanoma, and four of oat cell carcinoma were negative. Monoclonal antibody KP1 gave the strongest staining and reacted with the highest proportion of neoplastic cells. CONCLUSIONS--CD68 is expressed in a proportion of epithelial tumours although the labelling is usually less intense than in macrophages. Anti-CD68 antibodies should therefore be used as part of a panel in the diagnosis of poorly differentiated neoplasms in cytological material.     

Distribution of the cytoskeletal protein β-tubulin in normal lung, cryptogenic fibrosing alveolitis and lung tumours

Tubulin is the major protein of microtubules. The immunocytochemical distribution of tubulin within the human respiratory tract has not been investigated in detail and no analysis of diseased lung or lung tumours has been undertaken. We therefore studied the distribution of beta-tubulin in formalin-fixed normal lung (n = 6), cryptogenic fibrosing alveolitis (n = 10) and lung tumours (n = 66), using a monoclonal antibody to beta-tubulin. In normal lung positive immunostaining was observed in all ciliated epithelium from the trachea down to bronchiolar level; blood vessel endothelium, vascular smooth muscle and nerve bundles were also strongly positive; pneumocytes, cartilage and airway smooth muscle gave weak staining. A similar distribution of beta-tubulin was seen in cryptogenic fibrosing alveolitis, but with strong tubulin immunostaining of fibroblasts in the interstitium and of the cytoplasm of ciliated respiratory epithelial cells. In lung tumours, six of 17 (35%) adenocarcinomas, one of two adenosquamous and one of 17 (5%) squamous cell carcinomas gave strong immunostaining. All six large cell carcinomas gave strong immunostaining for tubulin. In neuroendocrine tumours, two of seven (28%) carcinoids, two of seven (28%) atypical carcinoids and seven of 10 (70%) small cell carcinomas were strongly positive for tubulin. beta-Tubulin is widely distributed in the normal and diseased respiratory tract and is found in many lung tumours, particularly in large cell and small cell carcinomas which are highly aggressive in behaviour.     

An analysis of the sensitivity and specificity of the cytokeratin marker CAM 5.2 for epithelial tumours. Results of a study of 203 sarcomas, 50 carcinomas and 28 malignant melanomas

Two hundred and three sarcomas, 40 carcinomas, 10 carcinomas with spindle cell features, 27 malignant melanomas and one spindle cell melanoma were examined using CAM 5.2, a monoclonal antibody to cytokeratin. This antibody which was prepared against colorectal carcinoma cells and which identifies low molecular weight intermediate filament cytokeratin proteins is suitable for use in formalin fixed, paraffin embedded material. Seventeen of the 203 sarcomas showed positive staining. These included 15/21 synovial sarcomas, 1/5 epithelioid sarcomas and 1/18 malignant neural tumours. Five carcinosarcomas showed positive staining of their epithelial components but negative staining of their spindle cell components; three out of four pure spindle cell carcinomas stained positively; a metastasis from a spindle cell renal carcinoma was negative. A spindle cell thymoma also stained positively. Thirty-seven of the 40 carcinomas stained positively; the three negative carcinomas were a squamous cell carcinoma, a renal cell carcinoma and an oat cell carcinoma. All malignant melanomas were negative. These results are compared with those of other workers and the sensitivity and specificity of CAM 5.2 as an epithelial marker is assessed.     

Preservation of cluster 1 small cell lung cancer antigen in zinc-formalin fixative and its application to immunohistological diagnosis

Monoclonal antibodies reactive with cluster 1 small cell lung cancer antigen have been shown to be useful for the distinction of small cell from non-small cell tumours. In previous studies the antibodies have been applied to frozen sections and cold acetone-fixed tissues. However, one of three monoclonal antibodies that we produced, NCC-LU-243, reacted with some small cell lung carcinomas fixed in formalin solution and embedded in paraffin. The addition of zinc sulphate to the formalin solution at a concentration of 2% (v/w) greatly improved antigen immunoreactivity, and reactivity was retained even after prolonged fixation. Occasionally, immunoreactivity was present in a poorly differentiated adenocarcinoma with rosette-like structures. The monoclonal antibody NCC-LU-243 is thus of considerable potential value in the immunohistochemical diagnosis of small cell lung cancers.     

Immunocytochemical localization of neuron specific enolase in small cell carcinomas and carcinoid tumours of the lung

Carcinoid tumours and small cell carcinomas of the lung share many characteristics with normal neuroendocrine cells. While carcinoid tumours contain many dense-cored neurosecretory granules and are frequently argyrophil, small cell carcinomas are poorly granulated and rarely argyrophil, which casts doubt on their neuroendocrine nature. Immunostaining of the enzyme neuron specific enolase (NSE) was recently used to demonstrate the neuroendocrine components of the lung including nerves and neuroendocrine cells. We therefore used NSE immunostaining to investigate neuroendocrine differentiation in 79 lung tumours, including 18 bronchial carcinoids and 31 small cell carcinomas, and compared these results with those obtained with silver stains. Thirteen of the 18 carcinoids were reactive to silver, all other types being negative. NSE-immunoreactivity occurred in 16 carcinoids and 18 small cell carcinomas. None of the squamous cell carcinomas, large cell anaplastic carcinomas and adenocarcinomas examined showed NSE-immunoreactivity. Radioimmunoassay of extractable NSE from 10 fresh lung tumours correlated well with the immunostaining results, demonstrating large amounts in two small cell carcinomas (334 and 517 ng/mg protein) and three carcinoids (152, 908, and 1143 ng/mg protein). Values were much lower for four squamous cell carcinomas (31-44 ng/mg protein) and one large cell anaplastic carcinoma (30 ng/mg protein) and were accounted for by the presence of NSE-positive nerves and neuroendocrine cells in the surrounding lung. NSE immunostaining is a useful marker of neuroendocrine differentiation in lung tumours and should prove particularly valuable in the diagnosis of small cell anaplastic tumours and their metastases.     

Monoclonal antibody JC1: new reagent for studying cell proliferation.

AIM: To characterise a newly developed mouse monoclonal antibody JC1 which recognises a nuclear antigen present in proliferating cells in normal tissues and neoplastic lesions, and which is absent in resting cells. METHODS: The methodology was established using a representative range of frozen sections from normal tissues and from certain tumours which were immunostained with antibodies Ki67 and JC1. The molecular weight of the antigen recognised by JC1 was obtained by western blot analysis and this was compared with that of Ki67. IM-9 cell lysates containing Ki67 derived plasmids were also tested with JC1 antibody. RESULTS: Biochemical investigation indicated that the antigen recognised by JC1 gives two molecular weight bands of 212 and 123 kilodaltons, which is distinct from the well characterised anti-proliferation monoclonal antibody Ki67 (395-345 kilodaltons). In addition recombinant Ki67 protein is not recognised by JC1. Immunohistological reactivity was seen in areas known to contain numerous proliferating cells such as lymphoid germinal centres, splenic white matter, cortical thymocytes and undifferentiated spermatogonia. In tumours many cells from adenocarcinomas, oat cell carcinomas, squamous cell carcinomas of lung, and seminomas were labelled by JC1 with a distribution and proportion similar to that seen with Ki67. In normal tissues the only apparent difference was in testis where JC1 stained a considerably greater number of cells than Ki67. In all cases studied the new antibody showed nuclear reactivity only. JC1 did not show any cytoplasmic crossreactivity with squamous cells as is frequently seen with Ki67. CONCLUSION: Antibody JC1, which recognises a nuclear antigen present in proliferating cells, should provide a useful adjunct to Ki67 as a marker of proliferation especially in those cases such as squamous cell carcinomas where a Ki67 index cannot be determined.     

High-level expression of CD109 is frequently detected in lung squamous cell carcinomas

CD109 is a glycosylphosphatidylinositol (GPI)-anchored cell surface protein, which is a member of the alpha2-macroglobulin/C3, C4, C5 family of thioester-containing proteins. It has been reported that CD109 is expressed in a subset of hematopoietic cells, endothelial cells and several kinds of human tumors. Herein it is reported that the CD109 protein is preferentially expressed in lung squamous cell carcinomas compared with other types of lung carcinoma including adenocarcinomas, large cell carcinomas and small cell carcinomas. Immunohistochemical staining of surgically resected lung specimens using an anti-CD109 antibody detected CD109 expression in basal cells of bronchial and bronchiolar epithelia and myoepithelial cells of bronchial secretary glands, but not in bronchial and bronchiolar apical epithelial cells and alveolar epithelial cells. Furthermore, the CD109 immunoreactivity was observed in squamous cell carcinomas at a high frequency compared with other types of lung carcinoma. Although the detailed function of CD109 protein is unclear, these results suggest that CD109 expression may play a role in the development of lung squamous cell carcinoma.