Patterns of keratin polypeptides in 110 biphasic, monophasic, and poorly differentiated synovial sarcomas

Synovial sarcoma is a mesenchymal neoplasm of unknown histogenesis that shows various degrees of epithelial differentiation. It is known to contain simple epithelial keratins, and the possibility of complex epithelial keratin expression has been suggested. In this study, we immunohistochemically examined 110 well-documented synovial sarcomas including 44 biphasic, 48 monophasic, and 18 poorly differentiated (undifferentiated, highly mitotically active) tumors for 11 different keratin (K) polypeptides of the Moll catalogue. The epithelia of biphasic synovial sarcomas showed consistent, extensive reactivity for K7, K8, K14, K18, and K19. Other keratins seen in the epithelia of biphasic tumors included K17 (variable, in 77%), K13 (25%), K16 (23%), and K6 (24%) in the minority of biphasic tumors, predominantly in stratified-appearing epithelia. K10 was detected only focally in one case that showed keratinizing squamous differentiation. Focal expression of K20 was seen in 27% of cases. Monophasic synovial sarcomas had a more limited keratin repertory. Simple epithelial keratin positivity was detected, usually focally for K7 (79%), K19 (60%), K8 (45%), and K18 (46%). Two cases showed more extensive keratin positivity in the spindle cells. The monophasic tumors showed limited positivity for complex epithelial keratins: K14 (28%) and K17 (10%). K20 was detected focally in 6% of the monophasic tumors; other keratins were not detected. The poorly differentiated synovial sarcomas showed limited simple epithelial keratin reactivity, usually limited to scattered cells: K19 (61%), K7 (50%), K18 (47%), K8 (33%), but five cases showed more extensive positivity. Complex epithelial keratins were scant: K14 in one case and K17 in two cases. The immunoreactivity of capillary endothelia seen for K7 and K18 (but not for K8 and K19 with the antibodies used) is a potential diagnostic pitfall, and may cause overdiagnosis of synovial sarcoma if not properly recognized. In summary, we show complex patterns of keratins in synovial sarcoma, especially in the biphasic tumors. Such patterns establish a baseline in differential diagnostic considerations, and give an insight into the complex epithelial differentiation of this enigmatic mesenchymal tumor. Received: 17 February 2000 / Accepted: 3 April 2000     

Distribution of keratins in normal endothelial cells and a spectrum of vascular tumors: implications in tumor diagnosis

Vascular endothelial cells are specialized mesenchyme-derived epithelial-like lining cells which are the essential participants in benign and malignant vascular tumors. Although endothelia in lower animals often express keratins (K), human endothelia are generally K negative and vimentin-positive. However, K expression has been noted in some endothelia and in some epithelioid vascular tumors. In this study, we systematically examined normal human vascular endothelia and a spectrum of human vascular tumors (n = minimum of 137 tumors with each marker) for simple epithelial keratin polypeptides of the Moll catalogue (K7, K8, K18, and K19). Selected vascular tumors were also evaluated with antibodies to K14 and the monoclonal antibody 34betaE12 that recognizes several keratins of stratified epithelia. Endothelia of normal veins, venules, and lymphatics commonly exhibited focal positivity for K7 and K18, whereas K8, K14, and K19 were not seen in non-neoplastic endothelia with the antibodies used. Lymphangiomas (6 of 7) and venous hemangiomas (6 of 13) often showed K7-positive endothelial cells; K18 was detected less commonly, whereas K8 and K19 were not detected. Epithelioid hemangioendotheliomas (EHEs) showed K7 and K18 expression in the majority of cases (50% and 100%, respectively), while K8 was seen in 10% cases and K14 and K19 in none. In contrast, epithelioid angiosarcomas (EAs) were often positive for K8 and K18 (approximately 50%), whereas they less commonly showed K7 and only occasionally K19; all tumors were negative for K14 and with the antibody 34betaE12. Nonepithelioid angiosarcomas (AS) less commonly showed keratin expression with K7, K8, and K18 being positive in 20% of cases, and K14 and K19 in none of the cases. Epithelial membrane antigen (EMA) was occasionally detectable in EHE (2/19) but was present in 4 of 16 (25%) EAs and 17 of 48 (35%) nonepithelioid AS. These findings document the common presence of focal reactivity for K7 and K18 in subsets of normal endothelia and also the frequent presence of simple epithelial keratins in malignant vascular tumors, while such expression is uncommon in nonepithelioid angiosarcomas. K- and EMA-positivity in neoplastic endothelia needs to be considered in the evaluation of human tumors. K antibodies such as those specific to K19 or AE1 that do not react with K8 and K18 should be used in the differential diagnosis of epithelioid vascular tumors and carcinomas.     

Immunohistochemical investigation of different cytokeratins and vimentin in the prostate from the fetal period up to adulthood and in prostate carcinoma

From the fetal period up to puberty the immature epithelium of the prostate glands, the prostatic ducts, the ejaculatory ducts and the seminal vesicles as well as the urothelium of the prostatic urethra are extensively positive for different keratin antibodies (antibody against keratins from human stratum corneum, broadly reacting antibody "AE1 and AE" and antibodies against the keratins 7, 8, 18 and 19) immunohistochemically. The epithelium of the ejaculatory ducts and seminal vesicles in addition regularly exprimates vimentin which is found in the epithelium of the prostate glands focally. During puberty, the immature epithelium of the prostate glands differentiates into the two cell types basal cell and secretory epithelium which differ immunohistochemically: Keratins from human stratum corneum are exclusively demonstrable in the basal cells, the keratins 8 and 18 only in the secretory epithelium. For keratin 7, 19 and the antibody "AE1 and AE3" both cell types are positive. Keratin 7 is demonstrable only focally. The secretory epithelium partly co-exprimates keratins and vimentin. Prostatic carcinomas of different grades virtually contain no keratins from stratum corneum. All other keratins are found in variable extension in the vast majority of the tumors independent of the differentiation. Vimentin is positive mostly focally in about 50% of the tumors. Prostatic carcinoma and the secretory epithelium of the prostate glands share identical immunohistochemical features and differ from the basal cell by several markers. This indicates that prostatic carcinoma rather derives directly from the secretory epithelium than from the basal cell.     

Keratin subsets in spindle cell sarcomas. Keratins are widespread but synovial sarcoma contains a distinctive keratin polypeptide pattern and desmoplakins.

The presence of individual keratin polypeptides and desmoplakins was immunohistochemically studied in 25 spindle cell sarcomas of different types using acetone-fixed frozen sections. Results revealed that keratins 8 and 18 were present in a high number of tumors: 9 of 9 synovial sarcomas, 5 of 7 leiomyosarcomas, 5 of 5 malignant schwannomas, and 1 of 4 undifferentiated spindle cell sarcomas. In addition to keratins 8 and 18, the glandular component of synovial sarcoma showed prominent reactivity with antibodies to keratins 7 and 19. Also the glandular epithelial cells in synovial sarcoma showed desmoplakin immunoreactivity preferentially in a luminal distribution, but desmoplakin was absent in other spindle cell sarcomas. Furthermore keratin 13 was seen focally in 4 of 9 synovial sarcomas. In contrast, keratins 7, 13, and 19 were practically absent in leiomyosarcomas, malignant schwannomas, and undifferentiated spindle cell sarcomas. The widespread presence of keratins 8 and 18 in various spindle cell sarcomas may reflect aberrant keratin expression in mesenchymal cells, previously described in cultured transformed fibroblasts. The presence of keratins 7 and 19 and desmoplakin is highly associated with morphologically observable epithelial differentiation restricted to synovial sarcoma among spindle cell sarcomas.     

Keratin expression in cervical cancer.

Using a panel of 21 monoclonal and 2 polyclonal keratin antibodies, capable of detecting separately 11 subtypes of their epithelial intermediate filament proteins at the single cell level, we investigated keratin expression in 16 squamous cell carcinomas, 9 adenocarcinomas, and 3 adenosquamous carcinomas of the human uterine cervix. The keratin phenotype of the keratinizing squamous cell carcinoma was found to be most complex comprising keratins 4, 5, 6, 8, 13, 14, 16, 17, 18, 19, and usually keratin 10. The nonkeratinizing variety of the squamous cell carcinoma expressed keratins 6, 14, 17, and 19 in all cases, usually 4, 5, 7, 8, and 18, and sometimes keratins 10, 13, and 16. Adenocarcinomas displayed a less complex keratin expression pattern comprising keratins 7, 8, 17, 18, and 19, while keratin 14 was often present and keratins 4, 5, 10 and 13 were sporadically found in individual cells in a few cases. These keratin phenotypes may be useful in differential diagnostic considerations when distinguishing between keratinizing and nonkeratinizing carcinomas (using keratin 10, 13, and 16 antibodies), and also in the distinction between nonkeratinizing carcinomas and poorly differentiated adenocarcinomas, which do not express keratins 5 and 6. Keratin 17 may also be useful in distinguishing carcinomas of the cervix from those of the colon and also from mesotheliomas. Furthermore the presence of keratin 17 in a CIN I, II, or III lesion may indicate progressive potential while its absence could be indicative of a regressive behavior. Because most carcinomas express keratins 8, 14, 17, 18, and 19, we propose that this expression pattern reflects the origin of cervical cancer from a common progenitor cell, i.e., the endocervical reserve cell that has been shown to express keratins 5, 8, 14, 17, 18, and 19.     

Keratin expression in schwannoma; a study of 115 retroperitoneal and 22 peripheral schwannomas.

Schwannomas have been variably observed to be glial fibrillary acid protein (GFAP) and occasionally keratin positive, with antibodies reacting with multiple keratins (pankeratins, keratin cocktail (CK), but specific keratin polypeptides (K) have not been examined for in schwannoma. Since we observed CK positivity in retroperitoneal schwannomas, we wanted to study a large group of retroperitoneal and peripheral schwannomas with GFAP, CK and Ks to explore the frequency and biologic background of this finding. We immunohistochemically evaluated a large number of retroperitoneal (n=115) and peripheral schwannomas (n=22) for GFAP, 16 individual K and AE1/AE3 keratin cocktail. The great majority (104/115, 90%) of retroperitoneal schwannomas were positive for GFAP, and 72/104 (69%) cases were positive for AE1/AE3, often extensively. Both markers highlighted the cellular Antoni A areas, particularly adjacent to the capsule, myxoid or degenerative areas, and perivascularly. Most cases 87/104 (84%) stained for both AE1/AE3 and GFAP at least focally. No tumors stained for keratins that were GFAP negative. None of the immunostains for individual K showed positivity comparable to that obtained with AE1/AE3 CK. However, 62% were focally positive for high molecular weight K1 and 8/61 (13%) for K7. None of the retroperitoneal schwannomas were positive for other keratins including K2, 4, 5, 8, 9, 10 and K14-20. Peripheral schwannomas showed GFAP-positivity in only three of 22 cases (14%), and all were negative for keratins, both cocktail and individual K. We conclude that crossreactivity of AE1/AE3 with other intermediate filament proteins, such as GFAP, as previously observed in brain and glioma tissue, probably accounts for the extensive keratin-positivity seen in some retroperitoneal schwannomas. However, focal expression of K1 and K7 cannot be ruled out. Keratin-positive schwannomas should not be confused with other keratin-positive tumors, such as sarcomatoid carcinoma, mesothelioma, and synovial sarcoma.     

Keratin expression in anal carcinoma: an immunohistochemical study

The keratin expression of 40 frozen tissue specimens of anal carcinoma was investigated using a panel of 17 monoclonal antibodies to 14 individual keratins. The tumours were divided into three histological subgroups showing pure squamous, squamous and basaloid, or squamous and glandular differentiation. A further assessment of the tumour grade was made. The overall profile was of expression of keratins 4, 13, 17, 18 and 19 across the majority of the tumours, with the minority expressing keratins 1 and 10, and keratin 7. Dedifferentiation was associated with loss of expression of keratinocyte keratins, particularly the cornification markers keratin 1 and 10, and K6 and 16 associated with keratinocyte hyperproliferation and differentiation. This correlated with acquisition of the simple epithelial keratins 7 and 8. Compared with the tumours as a whole, well differentiated squamous tumours (the most easily identifiable histological group) showed consistent positivity for keratins 6 and 16, expressed suprabasally, while simple keratins 18 and 19 were also found. Independent of grade, mixed tumours showed more widespread positivity for simple epithelial keratins 7, 8 and 18 and loss of expression of cornification keratins 1 and 10 and K6 and 16 compared with pure squamous tumours. The relatively limited keratin profile of pure squamous tumours, predominantly consisting of keratinocyte keratins, suggests that these malignancies are less likely to originate from the region of the anal canal where the keratin profile is heterogeneous, i.e. the anal transitional zone.     

The limited difference between keratin patterns of squamous cell carcinomas and adenocarcinomas is explicable by both cell lineage and state of differentiation of tumour cells.

AIM: To study the differentiation of epithelial tissues within their histological context, and to identify hypothetically, on the basis of keratin pattern, the putative tissue origin of a (metastatic) carcinoma. METHODS: Using well characterised monoclonal antibodies against individual keratins 7, 8, 18, and 19, which are predominantly found in columnar epithelia, and keratins 4, 10, 13, and 14, predominantly expressed in (non)-keratinising squamous epithelia, the keratin patterns for a series of 45 squamous cell carcinomas and 44 adenocarcinomas originating from various epithelial tissues were characterised. RESULTS: The predominant keratins in all adenocarcinomas proved to be 8, 18, and 19. In addition, these keratins were also abundantly present in squamous cell carcinomas of the lung, cervix, and rectum and, to a lesser extent, of the larynx, oesophagus, and tongue, but not in those of the vulva and skin. Keratins 4, 10, 13, and 14 were present in almost all squamous cell carcinomas, but also focally in some of the adenocarcinomas studied. CONCLUSIONS: There is a limited differential expression of distinctive keratin filaments between squamous cell carcinomas and adenocarcinomas. Apparently, squamous cell carcinomas that originate from columnar epithelium by squamous metaplasia gain the keratins of squamous cells but retain the keratins of columnar epithelial cells. However, the simultaneous expression of two of three squamous keratins (4, 10, and 13) identifies a squamous cell carcinoma, and thus might be useful in solving differential diagnostic problems.     

Immunohistochemical detection of breast specific antigens and cytokeratins in metastatic breast carcinoma in the liver

The present study was performed to evaluate the diagnostic reliability of antibodies to breast carcinoma-specific antigen and antibodies to cytokeratin catalogue in a metastatic hepatic lesion. Immunohistochemical examinations using antibodies to gross cystic disease fluid protein-15 (GCDFP-15), BCA-225 (a glycoprotein secreted by T47D breast carcinoma cell line) and BRST-5 (a glycoprotein identified in SK-BR-7 breast carcinoma cell line), anti-cytokeratin monoclonal antibodies of MA904, AE3, CAM5.2, PKK1 and cytokeratin 19, and polyclonal anti-keratin antibodies were done. These were on 15 cases of primary breast carcinoma, eight cases of metastatic breast carcinoma in the liver, five cases of cholangiocarcinoma, eight cases of hepatocellular carcinoma and 11 cases of metastatic adenocarcinoma of another primary tumor in the liver. Results showed that GCDFP-15 antigen was most reliable: it was 100% positive in both primary and metastatic breast carcinomas unrelated to histological subtypes, and 100% negative in primary or other metastatic carcinomas in the liver. BCA-225 antigen was detected in high amounts in breast carcinomas (100%, 23/23), but it was positive in cholangiocarcinomas (80%, 4/5) and another metastatic carcinoma in the liver (64%, 7/11). BRST-5 was specifically positive in breast carcinomas but the positivity was low (13%, 3/23). Cytokeratin 19 and keratin were useful to discriminate hepatocellular carcinomas (0%, 0/8) from breast carcinomas (87%, 20/23; 96%, 22/23), but they were also positive in cholangiocarcinomas (100%, 5/5) and other metastatic carcinomas in the liver (91%, 10/11). AE3, CAM5.2 and PKK1 showed highly positive immunoreactivity for breast carcinomas, cholangiocarcinomas and other metastatic carcinomas in the liver, and hepatocellular carcinoma cells were sometimes stained (50%, 4/8; 88%, 7/8; 38%, 3/8). MA904 showed negative immunoreactivity for all cases examined. A discussion was made on the specificity of the antibodies available for a histologic differential diagnosis.     

Keratin subsets in papillary and follicular thyroid lesions

 Previous studies indicate that keratins 7, 8 and 18 are present in all thyroid papillary and follicular lesions, but the distribution of other keratins has been incompletely characterized. The profile of individual keratin (K) polypeptides was evaluated immunohistochemically in over 200 non-neoplastic and neoplastic thyroid papillary and follicular lesions. Monoclonal antibodies to K19, K17, K16, K5/6 and K10 were applied in paraffin sections of formaldehyde-fixed tissue. K19 was present variably, often only focally in goitres, and was present only sporadically in papillary hyperplasia. However, K19 was strongly and uniformly expressed in virtually all papillary carcinomas, indicating differential diagnostic usefulness in differentiating papillary hyperplasia and papillary carcinoma. About half of the follicular carcinomas (defined as tumours strictly excluding the follicular variant of papillary carcinoma) were also strongly K19-positive, suggesting that K19 patterns are not reliable in differentiating papillary and follicular carcinoma. K17 and K5/6 were present in cysts and squamous metaplasia of goitres, and focally in papillary but only exceptionally in follicular carcinoma in areas of squamous differentiation and tumour cells in desmoplastic stroma. K16 in turn was present only focally in well-developed squamous metaplasia in goitres but was not found in differentiated thyroid carcinomas. K10, a high-molecular-weight keratin typical of epidermal differentiation, was identified neither in non-neoplastic nor in neoplastic differentiated thyroid lesions, including squamous metaplasia. These results indicate that papillary carcinomas differ from other differentiated thyroid tumours in their varying, usually focal, expression of stratified epithelial keratins that are partly but not exclusively related to squamous differentiation in such lesions. However, papillary carcinomas do not express truly epidermally restricted keratins; their previously described reactivity with polyclonal ”epidermal keratin” antibodies most probably results from the reactivity of such antibodies with K19. Received: 14 April 1997 / Accepted: 28 May 1997     

Heterogeneity of keratin expression in epithelial tumor cells of adenolymphoma in paraffin sections

Immunohistochemical expressions of keratin polypeptides detected by monoclonal antibodies were described in tumor cells of adenolymphoma, and the possibility of intercalated duct and ductal basal cells in the salivary glands being the progenitors was discussed. Basal cells in the tumor showed positive staining for keratin nos. 8, 13, 16, 18 and 19 detecting for monoclonal keratin antibodies (PKK 1, K 4.62, K 8.12, K 8.13), columnar tumor cells displayed strongly positive reactions with RPN 1164 and K4.62 suggesting keratin nos. 8 and 19. Great heterogeneity of distribution for keratin polypeptides was displayed by epithelial cells of adenolymphoma. Intercalated duct cells of normal salivary glands reacted with RPN 1164, RPN 1165, K 4.62 and K 8.13 monoclonal antibodies, which indicates the presence of keratins 8 and 19; and ductal basal cells reacted with PKK 1, K 4.62 and K 8.12, suggesting nos. 8, 13, 16, 18 and 19 keratins. Distribution of involucrin was variable in tumor epithelium of adenolymphoma, and was negative in the normal gland. The immunohistochemical distribution of keratin types between basal tumor cells of adenolymphoma and ductal basal cells of the normal salivary gland was compared.     

Keratin expression in the normal anal canal

The pattern of epithelial keratin expression in the normal anal canal has not been extensively defined and is a necessary prerequisite to the interpretation of alterations in these intermediate filaments in pathological anal epithelial lesions. Thirty-five frozen tissue specimens of resected haemorrhoids were investigated immunohistolo-gically for expression of 14 individual keratins (K) using a panel of 17 monoclonal antibodies. Perianal skin showed basal expression of karatinocyte Ks 5, 14 and 17, and suprabasal expression of keratinocyte Ks 14, 10, 1 and 16. Anal squamous epithelium showed persistent basal K5 and 17, basal and suprabasal K4, 13 and 16 positivity, with sporadic expression of K1 and 10. The expression of simple epithelial keratins in squamous epithelium adjacent to the anal transitional zone varied with basal expression of K7, K8, K18 and K19 and sporadic suprabasal expression of K7 and K19. The anal transitional zone (ATZ) expressed K19, as found in transitional epithelia elsewhere. The full thickness of epithelium was positive for the simple epithelial Ks 7, 8 18 and 19. Marked heterogeneity of keratinocyte keratin expression was seen. Basal layers expressed Ks 4, 13, 14 and 17 and variably K16, while suprabasal layers expressed Ks4 and 13, 14 and 17 and variably K16, while suprabasal layers expressed Ks4 and 13 and variably K14, 16 and 17. This anomalous expression of keratinocyte K4 and 13 has also been documented in transitional epithelium of the bladder. The anal glands and ducts showed a keratin distribution similar to the transition zone. Rectal columnar epithelium expressed simple keratins 7, 8 18 and 19. In addition, low levels of keratinocyte keratins were found as indicated by heterogeneous staining for K4, 13, 14 and 16. The overall pattern, particularly in the region of the anal transitional zone and immediately adjacent squamous and columnar epithelia, is of a flexible epithelial cell population able to express a range of keratins unrestricted by a particular morphological phenotype. In the light of these results, analysis of changes in keratin distribution within anal carcinomas may assist classification by providing information on the state of differentiation and histogenesis of these tumours.     

Expression of keratin 19 distinguishes papillary thyroid carcinoma from follicular carcinomas and follicular thyroid adenoma

Keratin expression with the use of chain-specific monoclonal antikeratin antibodies was investigated in normal thyroid tissue (n = 4), colloid nodules (n = 19), follicular thyroid adenomas (n = 18), follicular carcinomas (n = 10), and papillary carcinomas (n = 12). Frozen sections were stained with monoclonal antibodies M20 (keratin 8), M9 (keratin 18), and LP2K (keratin 19) with the use of the indirect immunoperoxidase technique. The immunohistochemical findings showed that the expression of keratins 8 and 18 was equally extensive in all normal, benign, and malignant lesions tested. In contrast, different staining patterns were observed with the use of monoclonal antibody to keratin 19. Follicular carcinomas were only focally stained with this antibody or were not reactive at all. Keratin 19, however, was present in all the tumor cells of papillary tissues and in a moderate amount of cells of nonneoplastic thyroid lesions and follicular adenomas. In papillary carcinoma, an identical homogeneous expression of keratin 19 was observed in both papillary and follicular structures, which suggests a common cellular origin. These results show that immunohistochemical staining with the use of monoclonal antibody against keratin 19 is useful to distinguish papillary thyroid carcinomas from follicular adenomas and follicular thyroid carcinomas.     

Marker profile of different phases in the transition of normal human ovarian epithelium to ovarian carcinomas.

To investigate whether early changes in the transformation of normal ovarian epithelial cells into tumor cells can be detected with monoclonal antibodies, a comparative immunohistochemical study was performed on normal human ovarian mesothelial cells, cystomas, cystadenomas, ovarian carcinomas, as well as granulosa cell tumor. Using monoclonal antibodies against different keratin subtypes, it was shown that mesothelial cells, ovarian cysts, cystadenomas, and carcinomas all reacted positively with broad-spectrum anti-keratin monoclonal antibodies (MAbs), as well as with MAbs to keratins 7, 8, 18, and 19. Keratins 4 and 13 were not found in mesothelial cells, but positive groups of cells were identified in several cystomas, adenomas, and carcinomas. While mesothelial cells did not react with the pan-epithelial marker BW495/36, invaginating metaplastic mesothelial cells, inclusion cysts, cystomas, adenomas, and carcinomas showed an increasing reactivity with BW495/36, with an increasing degree of malignancy. The reactivity of MAbs against ovarian carcinoma-associated antigens (OV-TL 3, OC 125, MOv 18, and OV-TL 10) was limited to weak staining reaction in some mesothelial cells but were found to be positive on more than 50% of the ovarian cystadenomas and more than 90% of the ovarian carcinomas. Thecal and granulosa cells of primordial, primary, and secondary follicles all reacted positively with antibodies to the broad-spectrum keratins OV-TL 12/5 and RCK 102, and to keratins 8 and 18, but not with keratins 4, 7, 13, and 19. These keratins decreased or disappeared in granulosa cells of mature follicles (Graafian follicles), whereas granulosa cell tumors did not react with anti-keratin antibodies. The reactivity of BW 495/36 was negative or limited to traces in some granulosa cells. Ovarian carcinoma-associated antigens were not expressed in granulosa cells or granulosa cell tumors. The data indicate that mesothelial cells undergoing metaplastic changes finally resulting in ovarian cystadenomas (and carcinomas) initiate the synthesis of a 200-kd glycoprotein recognized by MAb (BW 495/36), the production of ovarian carcinoma associated antigens, in addition to focal production of keratin 4 and/or 13, as seen in several samples. The granulosa cell tumors decrease or switch off their keratin production and remain negative for the 200-kd glycoprotein and the ovarian carcinoma-associated antigens.     

Villin,intestinal brush border hydrolases and keratin polypeptides in intestinal metaplasia and gastric cancer; an immunohistologic study emphasizing the different degrees of intestinal and gastric differentiation in signet ring cell carcinomas

Summary Gastric carcinomas have been assayed for the presence of villin and for the small intestinal hydrolases aminopeptidase N and sucrase isomaltase. These proteins seem not to be present in normal stomach epithelium. However intestinal metaplasia in stomach, and tumour cells in the glandular patterns of gastric carcinoma were positive for all three markers, showing characteristic apical positivity. In contrast, in diffuse gastric carcinomas the percentage of signet ring cells positive for these markers varied from 10–100% with each marker showing a similar percentage of positive cells. Testing of gastric carcinomas with antibodies specific for different keratin polypeptides showed that while all 7 tumours were positive for keratins 8 and 18,2 were also positive for keratin 7. In the keratin 7 positive tumours all tumour cells were keratin 7 positive. The keratin 8 antibody also reacted on routinely fixed specimens. Thus gastric carcinomas reveal different degrees of gastric and intestinal differentiation     

Are keratin proteins a better tumor marker than epithelial membrane antigen? A comparative immunohistochemical study of various paraffin-embedded neoplasms using monoclonal and polyclonal antibodies

Epithelial membrane antigen and keratin proteins represent markers of epithelial differentiation that may be detected in routine formalin-fixed, paraffin-embedded tissues. Eighty-seven neoplasms, including 48 adenocarcinomas of various types, squamous and transitional cell carcinomas, small-cell anaplastic carcinomas, carcinoid tumors, mesotheliomas, hepatomas, melanomas (metastatic), adrenal cortical carcinomas, germ cell tumors, and extramammary Paget's disease, were assessed to determine the relative effectiveness of these antigens as tumor markers. Immunoperoxidase studies were performed using monoclonal antibodies to epithelial membrane antigen and monoclonal (combined AE1 and AE3) and polyclonal (bovine muzzle keratins) antibodies to keratin proteins. In more than half the cases (50/87%), both markers yielded comparable results. However, in 29 cases (33%), keratin proteins were clearly superior to epithelial membrane antigen as a tumor cell marker. Particular discrepancies were apparent for some gastrointestinal adenocarcinomas, squamous cell carcinomas, hepatomas (hepatocellular type), spindle cell components of mesotheliomas, and carcinoid tumors. Epithelial membrane antigen represented a better marker in eight cases (9%), mainly for small-cell anaplastic carcinomas and some renal cell and pulmonary adenocarcinomas. Adrenal cortical carcinomas, melanomas, and seminomas were nonimmunoreactive for both antigens. Epithelial membrane antigen and keratin proteins represent useful complementary markers in diagnostic surgical pathology.     

Epithelioid sarcoma: an immunohistochemical analysis of 112 classical and variant cases and a discussion of the differential diagnosis.

Epithelioid sarcoma (ES) is a distinctive soft tissue neoplasm with a predilection for the distal extremities of young adults. This tumor typically contains nodular aggregates of epithelioid and spindle cells with zonal necrosis. The neoplastic cells are generally reported to coexpress keratin and vimentin and are often stated to be positive for CD34. However, there is no large series with extensive immunohistochemical data, there are few data with regard to expression of different keratin subtypes, and there are no large series discussing the epithelioid sarcoma subtypes. In the current study, we immunohistochemically evaluated 88 typical and 24 variant (8 angiomatoid, 9 large cell/rhabdoid, and 7 "fibroma-like") ESs. Nearly all ESs with typical histology (94%) were positive for keratin 8 (K8), whereas 72% were positive for K19, 48% for intermediate- and high-molecular-weight keratins (34betaEH12), and 22% for K7; reactivity with the latter two antibodies was usually seen in only a minority of tumor cells. Vimentin reactivity was present in all cases, EMA in 96% of cases and muscle-specific actin and CD34 were noted in 41% and 52% of the cases, respectively. A few ESs (7%) showed focal cytoplasmic CD31 reactivity, but none exhibited a distinctive membrane staining pattern, and examples tested for FVIIIRAg were negative. The angiomatoid, fibroma-like, and large cell-rhabdoid ES variants had immunohistochemical profiles similar to the classic cases, supporting a common pathogenesis. Although not consistently expressed in ES, the presence of CD34 is helpful in distinguishing this entity from primary and metastatic carcinomas and other sarcomas such as malignant rhabdoid tumor.     

Detection of keratin subtypes in routinely processed cervical tissue: implications for tumour classification and the study of cervix cancer aetiology

We investigated the expression of keratin subtypes 7, 8, 10, 13, 14, 17, 18 and 19 in the normal cervix, in cervical intraepithelial neoplasia (CIN) lesions and in cervical carcinomas, using a selected panel of monoclonal keratin antibodies, reactive with routinely processed, formalin fixed paraffin embedded tissue fragments. The reaction patterns derived for each keratin antibody were compared with known expression patterns of the various epithelia, previously examined in frozen tissues. Although the reactivity of the antibodies was generally acceptable, considerable modifications to the manufacturers' staining instructions were often necessary. For some antibodies, which were previously thought to be reactive with fresh frozen tissue only, we developed staining protocols rendering them reactive with routinely processed material. As with previous findings in frozen sections we observed increasing expression of keratins 7, 8, 17, 18 and 19 with increasing grade of CIN. In cervical carcinomas the differences in keratin detectability between the main categories were more pronounced than in frozen sections, probably due to fixation and processing. For routine pathology, keratin phenotyping of cervical lesions may be of value in classification. The fact that keratin 7 was detected for the first time in reserve cells, and that this keratin was also found to be expressed in a considerable number of CIN lesions and cervical carcinomas supports the suggestion that reserve cells are a common progenitor cell for these lesions.