Anatomie der Brustdrüse

The human breast consists of lobes with a luminal glandular and a basal myoepithelial layer. Immunofluorescence studies have shown that the breast epithelium contains cytokeratin (CK)5/14-positive precursor cells which give rise to CK8/18-positive glandular or sm-actin-positive myoepithelial cells. Only some of the glandular cells contain estrogen receptors. The luminal epithelium of the lobules shows a much higher glandular differentiation than the ductal system. Diagnostically important cytokeratins of normal breast epithelium and its proliferative epithelial processes include luminal cytokeratins (CK7, CK8 and CK18) as markers of glandular differentiation and basal cytokeratins (CK5, CK14 and CK17) as markers of progenitor cells and early cells of the glandular and myoepithelial differentiation pathway. The most important myoepithelial markers are currently CD10, SMA, SMM-HC and Calponin.     

Basal cell hyperplasia, adenoid basal cell tumor, and adenoid cystic carcinoma of the prostate gland: An immunohistochemical study

Basal cell hyperplasia (BCH) is an uncommon proliferative lesion of the prostate gland. We studied ten cases of BCH, one case of an unusual adenoid basal cell tumor (ABT), and one case of a prostatic adenoid cystic carcinoma (ACC), using a panel of antibodies to define the histogenesis of these lesions. Monoclonal antibodies (MoAb) directed against a cytokeratin, which selectively stains basal cells (34 beta E12), and against muscle-specific actin, which stains myoepithelial cells (HHF35), were used. In addition, antibodies directed against prostatic acid phosphatase (PAP), prostate-specific antigen (PSA), S-100 protein, and vimentin were used. In the normal prostate, epithelial cells reacted positively with 34 beta E12, PAP, and PSA, and negatively with the actin, S-100 protein, and vimentin antibodies. In BCH, positive staining was seen for 34 beta E12, PSA, and PAP, with no reactivity for actin, S-100 protein, and vimentin. In ABT and ACC, positive reactivity was demonstrated for all antibodies except actin and vimentin. These findings indicate that the basaloid cells of BCH, ABT, and ACC are derived from basal cells of the normal prostate gland and suggest a continuum among the three lesions. The presence of S-100 protein in ABT and ACC may be related to the lack of this antigen's specificity for myoepithelial cells. The absence of reactivity with the HHF35 MoAb supports our belief that the S-100 positivity does not necessarily indicate myoepithelial cell differentiation.     

Microglandular adenosis of the breast. An immunohistochemical comparison with tubular carcinoma.

Microglandular adenosis (MA) of the breast is a benign, disorganized proliferation of glands lined by a single layer of cells. As such, differential diagnosis between MA and tubular carcinoma may be challenging in selected cases. A panel of antibodies was applied to 10 cases of MA and 10 of tubular carcinoma to investigate the potential benefit of immunohistochemistry in the separation of these lesions and the possible role of myoepithelial cells in MA. The luminal cells in nine cases of MA were surrounded by a cuff of muscle-specific actin-reactive cells, which also coexpressed cytokeratin and vimentin. The immunophenotype of these cells is characteristic of myoepithelial differentiation, which was heretofore thought to be lacking in MA. This finding demonstrates that myoepithelial cells are indeed present in MA subjacent to luminal epithelial cells; moreover, it distinghuishes MA from tubular carcinoma, all examples of which were actin negative in this analysis. In addition, circumferential type IV collagen deposition was observed around constituent glands of MA in nine cases but was lacking in all tubular carcinomas. Other markers included in this evaluation (S100 protein, gross cystic disease fluid protein 15, carcinoembryonic antigen, estrogen receptor protein) were of no differential diagnostic value.     

An immunohistochemical study of pleomorphic adenomas of the salivary gland: glial fibrillary acidic protein-like immunoreactivity identifies a major myoepithelial component

An immunohistochemical study of 34 pleomorphic adenomas of the major salivary glands demonstrated phenotypic differences among the various morphologic regions in these tumors. The phenotypes expressed were comparable to those of normal salivary gland cells. In the normal glands, myoepithelial cells were immunoreactive for glial fibrillary acidic protein (GFAP), S-100 protein, and keratin; acinic cells exhibited strong, predominantly nuclear S-100 staining and weaker keratin staining; intercalated ducts had both cytoplasmic and nuclear S-100 positivity; and several epithelial antigens were observed throughout the ductal system. In the tumors, the presence of classic epithelial markers (including carcinoembryonic antigen, epithelial membrane antigen, secretory component, and keratin) in the luminal cells of ducts and the intense immunoreactivity with GFAP (with weaker keratin and S-100 staining) in periductal and stromal cells indicated distinct epithelial and myoepithelial differentiation. Solid epithelioid areas consisted phenotypically of intercalated duct/acinic cells and/or myoepithelial cells, the former exhibiting predominant nuclear S-100 positivity. The presence of GFAP-like immunoreactivity in normal myoepithelial cells strongly supports the extensive involvement of this cell in pleomorphic adenomas. The spectrum of phenotypes expressed adds weight to existing evidence for pleomorphism rather than a mixed origin of this tumor. The combination of keratin, S-100, and GFAP immunostaining is particularly useful in identifying the component cells in pleomorphic adenomas of the salivary glands.     

Structural distinctions among human breast epithelial cells revealed by the monclonal antikeratin antibodies AE1 and AE3

Two monoclonal antikeratin antibodies, AE1 and AE3, were used in indirect immunocytochemistry to examine keratin expression in normal, benign proliferative, and malignant human breast epithelium. Both antibodies reacted strongly with most luminal cells in ducts and acini of normal gland. While AE1 did not stain myoepithelium, AE3 recognized myoepithelial cells of ducts but not acini, implying a cytoskeletal difference between the myoepithelium of these two components. Moreover, the antibodies reacted differently with the myoepithelium of intracanalicular as compared with pericanalicular types of fibroadenomas. Tumour cells of infiltrating ductal carcinomas with a prominent intraductal component stained more homogeneously with AE1 and AE3 than those without intraductal growth. The results provide evidence for two phenotypes of myoepithelial cells and for the presence of cryptic keratin epitopes in human breast epithelial cells. The finding that neither AE1 nor AE3 is a universal detector of these cells has important clinical and experimental implications.     

Erosive adenomatosis of the nipple: histology, immunohistology, and differential diagnosis.

Erosive adenomatosis of the nipple (EAN) is a complex benign mammary proliferation that has a variety of histologic appearances. All forms of this lesion are thought to be composed of two apparent cell types: epithelial luminal cells and basal myoepithelial cells. A panel of immunohistochemical reagents was employed to determine whether this divergence of differentiation could be confirmed immunohistochemically. It included antibodies against cytokeratin (CK), vimentin (VIM), glial fibrillary acidic protein (GFAP), and muscle-specific actin (MSA); the latter three markers are associated with myoepithelial differentiation. EAN was also assessed with reagents directed at carcinoembryonic antigen (CEA) and collagen type IV (CIV). Basal glandular cells in EAN homogeneously expressed CK and MSA. They also were positive for VIM in 10 cases, and for GFAP in three. Luminal glandular cells in EAN expressed CK uniformly and CEA focally. Lesional glands were surrounded by a concentric layer of CIV. The authors conclude that two cell types are indeed demonstrable immunohistochemically in EAN, one of which has myoepithelial features. CEA may be expressed by this lesion despite its innocuous biological nature, and constituent glands synthesize basement membrane proteins in a pattern that is characteristic of benign mammary proliferations. Differential diagnosis between EAN and invasive carcinoma of the breast may be facilitated by immunohistologic evaluation, but the latter modality of study is not capable of distinguishing between EAN and other benign proliferative mammary lesions.     

Cytokeratin 5/6 immunohistochemistry assists the differential diagnosis of atypical proliferations of the breast

AIMS: This study was performed to determine the diagnostic value of keratin 5/6 (CK 5/6) immunophenotyping on routinely processed breast tissues. METHODS AND RESULTS: Six hundred and ninety-nine breast lesions, including normal tissues as well as benign and malignant lesions in 321 formalin-fixed, paraffin-embedded samples from 158 different patients were investigated immunohistochemically, following wet autoclave pre-treatment for antigen retrieval. In normal breast tissues, both myoepithelial and luminal epithelial cells expressed CK 5/6 in varying amounts. While myoepithelial immunoreactivity was most pronounced in the duct system, luminal epithelial immunoreactivity was strongest in the terminal duct lobular units. In ductal hyperplasias (DH), luminal epithelial cells predominantly revealed CK 5/6 immunoreaction. In contrast, neoplastic epithelial cells in atypical ductal and lobular hyperplasias (ADH and ALH) lacked such an expression, whereas in ductal in-situ carcinomas (DCIS) and in infiltrating ductal carcinomas 3.7% and 7.7%, of the cases respectively, showed positive immunostaining for CK 5/6. CONCLUSIONS: Immunophenotyping of keratin 5/6 expression can be helpful in the diagnosis of atypical hyperplasias and in-situ carcinomas of the breast. It is particularly valuable in the differential diagnosis between benign and atypical proliferative lesions.     

Keratin 14 immunoreactive cells in pleomorphic adenomas and adenoid cystic carcinomas of salivary glands

Our recent study of developing myoepithelial cells (MECs) in rat salivary glands demonstrated that developing MECs begin to express α-smooth muscle actin (αSMA) first and, thereafter, keratin 14. Therefore, it is unlikely that duct basal cells expressing keratin 14 alone are immature or undifferentiated MECs. In this study we carried out immunohistochemistry of pleomorphic adenomas and adenoid cystic carcinomas including normal salivary glands using monoclonal antibodies to keratin 14, smooth muscle proteins and keratin 19. The smooth muscle proteins examined included αSMA, h-caldesmon and h1-calponin; h1-calponin was observed in keratinocytes and nerve fibers, indicating that the protein is not specific to smooth muscle, whereas αSMA and h-caldesmon turned out to be highly specific markers for smooth muscle cells in normal tissues. In normal glands, MECs were positive for both keratin 14 and smooth muscle proteins (αSMA and h-caldesmon). Non-MEC cells were essentially devoid of smooth muscle proteins. Non-MEC duct basal cells expressed keratin 14 with or without keratin 19, and luminal cells keratin 19 with or without keratin 14. This suggests that the keratin 14-positive, smooth muscle proteins-negative duct basal cells are luminal cell progenitors. Luminal cells in tubular structures of both tumors were positive for keratin 19 with or without keratin 14. Nonluminal peripheral cells of pleomorphic adenomas were mostly positive for keratin 14, and a small fraction of them expressed smooth muscle proteins. Conversely, peripheral cells of adenoid cystic carcinomas were mostly positive for smooth muscle proteins, and some of them expressed keratin 14. These results strongly suggest (1) that the luminal cell progenitors transform into major constituents of pleomorphic adenoma cells with keratin 14 but not smooth muscle proteins, and (2) that the peripheral cells of adenoid cystic carcinoma are derived from undifferentiated MECs. Solid structures of pleomorphic adenomas were formed by proliferation of the peripheral cells. MECs were observed only occasionally in the periphery. Solid and cribriform structures of adenoid cystic carcinomas were formed by proliferation of the luminal cells. MECs were observed in the periphery and around the pseudocyst. Received: 2 December 1999 / Accepted: 12 January 2000     

Cytokeratins, smooth muscle actin and vimentin in human normal salivary gland and pleomorphic adenomas. Immunohistochemical studies with particular reference to myoepithelial and basal cells.

The distribution of immunostaining in normal major salivary gland and in 12 pleomorphic adenomas was studied using monospecific monoclonal antibodies to a number of cytokeratins, including cytokeratin 14, to smooth muscle actin and vimentin. A number of these antibodies enabled a distinction to be made between structural components of the normal gland, and to relate this to the different structures of pleomorphic adenomas. In the normal gland, the luminal duct cells expressed cytokeratins 7, 8, 18 and 19. Three antibodies were of particular value for the characterization of normal myoepithelial and basal cells; while the antibody to smooth muscle actin and the cytokeratin antibody Ks8.12 mutually exclusively stained the myoepithelial (basket) cells and the basal duct (light) cells, respectively, the recently established monospecific antibodies to cytokeratin 14 showed specific immunostaining with both cell types. These three antibodies left luminal cells virtually unstained. Ck 13 was found occasionally in single luminal excretory duct cells. Antibodies to cytokeratins 1/2, 10 and 10/11 did not show any staining in the normal gland. In the pleomorphic adenomas, the staining pattern of the two-layered tubular formation resembled that of the normal gland ducts: tumour luminal cells showed the characteristic, although more irregular, expression of cytokeratins 7, 8, 18 and 19; the outer cells resembled normal ductal basal cells with their anti-cytokeratin 14/Ks8.12-epitope staining and in that they virtually lacked staining for smooth muscle actin. Trabecular formations and cells in myxoid areas were reactive with Ks8.12 and for cytokeratin 14, occasionally also for cytokeratins 7, 18 and 19. Epidermoid cell islets expressed mainly cytokeratin 14 and inconsistently the squamous epithelial cytokeratin 13 and the epidermal cytokeratin 10/11. Vimentin was found in cells of myxoid areas. The results support the postulate that some of the normal duct basal cells act as reserve cells and can give rise to tumour formation with a primitive myxoid or trabecular pattern and a more differentiated tubular or epidermoid configuration.     

Keratin profiles in normal/hyperplastic prostates and prostate carcinoma

Summary Immunoreactivities in 25 cases of prostatic adenocarcinoma and 10 normal/hyperplastic prostates were investigated in methacarn-fixed, paraffin-embedded serial sections using a panel of nine anti-keratin monoclonal antibodies (mAbs); 34 E12, CK8.12, 312C8-1, CK4.62, RPN1165, RPN1162, 35H11, CK5, M20, and one of anti-actin mAb, HHF35. In normal/ hyperplastic prostates, RPN1162, 35H11, CK5 and M20 stained luminal cells without staining basal cells, and 34E12, CK8.12 and 312C8-1 stained basal cells but not luminal cells. Other mAbs, CK4.62 and RPN1165, stained basal cells as well as luminal cells. All of the mAbs labelling luminal cells stained cancer cells with variable frequencies in a manner unrelated to the grade of tumour differentiation. Of the prostate cancer cases 92% were scored positive with M20, 84% with 35H11, 80% with CK5, 68% with CK4.62, 60% with RPN1165 and 4% with RPN1162. However, basal cell-specific keratins labelled with 34E12, CK8.12 and 312C8-1 were totally negative in the cancer cells. HHF35 showed no labelling in normal, hyperplastic or neoplastic epithelial cells of the prostate. Our findings indicate that the major part of the cells of prostatic adenocarcinomas have keratin phenotypes similar to luminal cells but not basal cells, and that no myoepithelial differentiation can be detected in epithelial cell of the prostate. Thus, mAbs for keratins facilitate the identification of epithelial cell phenotypes in normal, benign and malignant conditions of the prostate.     

Immunohistochemical localisation of keratin and luminal epithelial antigen in myoepithelial and luminal epithelial cells of human mammary and salivary gland tumours

Rabbit antisera to human 40-63 000 MW epidermal keratin, one batch with restricted distribution of reactivity from an initial (aK1) and one with "broad spectrum" distribution of reactivity from a late bleeding (aK), and to "luminal epithelial antigen" (aLEA) were applied to formalin fixed paraffin embedded sections of human normal and neoplastic mammary and salivary glands using an indirect immunoperoxidase method. aK1 reacted with myoepithelial cells, aLEA with luminal epithelial cells and aK with both cell types in normal mammary and salivary gland. In breast carcinomas the majority of intraluminal and infiltrating carcinoma cells reacted with aLEA but not with aK1 which reacted only with surrounding myoepithelial cells. aK reacted with both myoepithelial cells and with intraluminal and infiltrating tumour cells. In the salivary gland adenomas the majority of cells reacted with aK, and those cells arranged in a tubular fashion reacted with aLEA.     

Immunolocalization of the human basal epithelial marker monoclonal antibody 312C8-1 in normal tissue and mammary tumours of rodents

Summary Using immunoperoxidase staining of monoclonal antibody 312C8-1 against 51 000 dalton human keratin polypeptide, immunolocalization was observed in frozen sections of normal tissue and mammary tumours of adult female mice and rats. In normal tissue, the epitope was recognized in myoepithelial cells of the mammary, sweat and salivary glands, and in basal and suprabasal cells of the epidermis. However, the antibody did not react with luminal epithelial cells of the above glands or with mesenchymal cells. In spontaneous mammary tumours of mice, marker-positive tumour cells were distributed only in the outer layer of adenocarcinoma Type A, while they were scattered in some foci of adenocarcinoma Type B, and encircled the epithelial foci of pregnancy dependent tumours (plaque). All layers of epidermoid structures in adenoacanthoma revealed positivity. In rat mammary tumours induced by local dusting with 7, 12-dimethylbenz()anthracene (DMBA) powder, the staining pattern of benign tumours was comparable to that of the normal mammary gland. But, in addition to basally situated cells, marker-positive tumour cells were found scattered in the foci of adenocarcinoma, and were not restricted to basal cells in squamous cell carcinoma. The marker was not found in sarcomatous tissue. This antibody can therefore also be applied to rodents, and the staining pattern can be used to identify the epithelial subclass specific marker in normal tissue and in mammary tumours.     

Usual ductal hyperplasia of the breast is a committed stem (progenitor) cell lesion distinct from atypical ductal hyperplasia and ductal carcinoma in situ

Current classification systems in proliferative mammary gland pathology are based on a two-cell system, recognizing only glandular and myoepithelial lines of differentiation. A third cell type has recently been characterized in normal breast tissue by double-immunofluorescence analysis to express cytokeratin 5 (Ck5) only. These cells were shown to represent progenitor or adult stem cells that give rise to the glandular and myoepithelial cell lineage. The double-labelling technique has been applied to characterize a spectrum of intraductal epithelial proliferations, namely benign usual ductal hyperplasia, atypical ductal hyperplasia, and ductal carcinoma in situ, all of which are thought to represent the gradual steps of a sequence in the development of breast cancer. Immunofluorescence studies with specific antibodies against Ck5, Ck8/18/19, and smooth muscle actin were complemented by western blotting analysis of Ck5 and Ck8/18/19 expression in normal breast tissue and in proliferative lesions. Usual ductal hyperplasia appears to be a Ck5-positive committed stem (progenitor) cell lesion with the same differentiation potential as seen in the normal breast. This is in sharp contrast to atypical ductal hyperplasia/ductal carcinoma in situ, which display the differentiated glandular immunophenotype (Ck8/18/19-positive, but Ck5-negative). These data require the abandonment of the idea of an obligate biological continuum of intraductal proliferations from benign to malignant. This study provides evidence that cells undergoing malignant transformation tend to be fairly advanced in the glandular lineage of differentiation. The committed stem (progenitor) cell model may contribute to a better understanding of both benign proliferative breast disease and breast cancer development.     

Plasmacytoid cells in salivary-gland pleomorphic adenomas: evidence of luminal cell differentiation

To determine the cellular origin of plasmacytoid cells in salivary gland adenomas, immunohistochemistry was performed on sections from 12 pleomorphic adenomas rich in these cells. In normal salivary glands included in these sections, the myoepithelial cells (MECs) expressed -smooth muscle actin (SMA) and smooth muscle myosin heavy chain (SMMHC), whereas the duct luminal cells expressed keratins 19, 18 and 8. Some of the salivary duct basal cells expressed these keratins, and the acinar cells expressed keratins 18 and 8. The expression profile was similar in rat salivary glands not only after but also during development. The immature MECs never expressed the keratins nor did the immature duct cells express SMA. In seven cases, up to 60% of the plasmacytoid cells expressed keratin 19. In three of these cases, about 10% of the plasmacytoid cells expressed keratin 18. No plasmacytoid cells expressed SMA, SMMHC or keratin 8. These results indicate that plasmacytoid cells originate from luminal cells and not from MECs. Furthermore, in addition to the luminal tumor cells, the non-luminal cells could express keratins 19, 18 and 8. Therefore, it is necessary to re-evaluate the prevailing notion that non-luminal cells are modified MECs. Keratin 14, basic calponin, vimentin and p63 were bi-specific for the MECs and the duct cells. Therefore, expression of these proteins by significant numbers of the non-luminal tumor cells and the plasmacytoid cells never denied the above notion.     

Distribution of cytoskeletal and contractile proteins in normal and tumour bearing salivary and lacrimal glands

Summary We have evaluated by means of immunocytochemistry the distribution of various cytoskeletal and contractile proteins (cytokeratins, vimentin, desmin and -smooth muscle actin) in 23 salivary or lacrimal gland primary tumours (15 pleomorphic adenomas and 8 carcinomas in pleomorphic adenoma), one third of which contained areas of normal gland. Normal epithelial luminal cells were stained by cytokeratin antibodies with a general specificity, while myoepithelial cells were selectively stained by a monoclonal antibody (SK2-27) reacting in immunoblots with cytokeratin polypeptides 14, 16 and 17, according to the classification of Moll et al. (1982) and by an antibody directed against -smooth muscle actin (Skalli et al. 1986). In pleomorphic adenomas, both epithelial and myoepithelial cells displayed typical topographic distributions; moreover, myoepithelial cells showed two distinct cytoskeletal phenotypes. These findings could account in part for the heterogeneity of aspects observed in this tumour. In carcinomas, malignant cells were always positive to cytokeratin antibodies with general specificity and myoepithelial cells were absent as judged by anticytokeratin SK2-27 and anti--smooth muscle actin immunostainings. However, interestingly, there was in all cases a strong positivity for -smooth muscle actin in stromal cells, similarly to what has previously been described for mammary carcinoma (Skalli et al. 1986). Our findings may be useful for the interpretation of the histogenesis of salivary and lacrimal tumour and stromal cells.     

CD10 and HHF35 actin in the differential diagnosis between Collagenous spherulosis and adenoid-cystic carcinoma of the breast

Collagenous Spherulosis (CS) and Adenoid-Cystic Carcinoma (AdCC) of the breast consist of cribriform proliferations of epithelial and myoepithelial cells with an immunophenotypic overlap of some myoepithelial markers, such as p63 and smooth muscle actin (SMA). To our knowledge, CD10 and HHF35 actin have not been assessed in the differential diagnosis of these two breast lesions. We performed an immunohistochemical study on 6 cases of CS and 9 cases of AdCC. We found CD10, muscle-specific actin (HHF35), Estrogen and Progesterone receptors (ER and PR) to be strongly expressed in CS, but not in AdCC; C-kit was diffusely positive in AdCC and scanty in CS; SMA, p63 and Cytokeratine 5/6 (CK5/6) were positive in both. Our results also confirm that AdCC could be true basal-like neoplasia, probably arising from a basal stem line tending to divergent differentiation toward CK5/6/C-kit+, ER/PR-, epithelial basal-like cell type, and toward a myoepitelial-like cell type, with an incomplete SMA/p63+, CD10/HHF35- immunophenotype. By contrast, CS is a reactive, benign proliferation of two well-differentiated cell types: epithelial (ER/PR+, C-kit-) and myoepithelial cells with a complete immunophenotype including CD10/HHF35 positivity. Our study highlights the usefulness of CD10 and HHF35 in the differential diagnosis and helps to understand the histogenesis of the two lesions.     

A monoclonal antibody that detects myoepithelial cells in exocrine glands,basal cells in other epithelia and basal and suprabasal cells in certain hyperplastic tissues

Summary Myoepithelial and luminal cells of human exocrine glands can be positively identified with two different monoclonal antibodies. Myoepithelial cells including those of the salivary gland, mammary gland and sweat gland are positively identified by an antibody CKB1. This antibody does not stain luminal cells, but stains the basal cell layer of certain human stratified epithelia and a few basal cells in simple epithelia. Thus myoepithelial cells and basal cells have certain common features. Luminal cells can be positively stained with the CK5 monoclonal keratin antibody specific for keratin polypeptide 18; this antibody does not stain myoepithelial cells. Of interest is that CKB1 also appears to stain basal and suprabasal cells in certain hyperplastic conditions.Dedicated to Prof. Dr. F.H. Caselitz on the occasion of his 65th birthdaySupported by grants from the Deutsche Forschungsgemeinschaft and the Hamburger Stiftung zur Förderung der Krebsbekämpfung to J.C. and from the Deutsche Krebshilfe to M.O.     

Regeneration of myoepithelial cells in rat submandibular glands after yttrium aluminium garnett laser irradiation

The regeneration of myoepithelial cells in rat submandibular salivary gland after partial irradiation with yttrium aluminium garnett (YAG) laser was investigated. The irradiated glands were examined immunohistochemically for actin, histochemically for alkaline phosphatase (ALP), and by transmission electron microscopy (TEM). In control glands, myoepithelial cells were positive for actin and ALP. Electron microscopically, the positive reaction for actin was associated with the myofilaments of myoepithelial cells, and the plasma membrane of myoepithelial cells was positive for ALP. One day after YAG laser irradiation, the irradiated region was necrotic. By 5 days, duct-like structures and epithelial clusters were observed at the interface between the necrotic zone and the remaining undamaged glands; immature acini appeared after 7 days. No reaction in duct-like structures or epithelial clusters to actin or ALP was recognizable by 5 days. However, at 7 days, actin and ALP-positive spindle cells appeared at the periphery of the duct-like structures and immature acini. After 10 days, both actin-positive and ALP-positive cells increased in number. These observations indicate that during regeneration, actin-positive and ALP-positive cells regenerate myoepithelial cells, and it is suggested that this differentiation to myoepithelial cells is closely related to that of luminal to acinar cells. In addition, TEM observations indicate that regenerated myoepithelial cells originated from the basal cells of duct-like structures.     

Warthin's Tumor: An Ultrastructural and Immunohistochemical Study of Basilar Epithelium

The cellular characteristics of the basilar epithelium in Warthin's tumor have had limited investigation. Ultrastructural examination of basal cells in 9 Warthin's tumors reveals that in addition to numerous mitochondria these cells possess a rich complement of tonofilaments. However, in three examples there are a proportion of these tonofilament-rich cells that have a narrow band of microfilaments in the peripheral cytoplasm adjacent to the basal lamina. Frozen sections of Warthin's tumor and normal salivary glands, doubly labeled with rhodamine-phalloidin for actin and monoclonal antibody 312C8-1 for cytokeratin 14, show that normal myoepithelial cells of acini and intercalated ducts have both of these filaments, as do a proportion of basal cells in the tumor. There are distinct differences in the cytokeratin polypeptide complement between normal luminal and myoepithelial cells as well as between luminal and basal cells in Warthin's tumor. Differences occur in the cytokeratin profiles between the luminal and basal cells of Warthin's tumor and comparable cells in the normal gland; however, there continue to be some similarities in the cytokeratin polypeptides of myoepithelium and the basal cells of normal salivary ducts and the basal cells of Warthin's tumor. These findings show that basal cells in Warthin's tumor are a mixed population with some capable of differentiating as myoepithelial-like cells, and that this tumor could arise from any level of the normal salivary gland duct system.     

Pleomorphic adenomas,adenoid cystic carcinomas and adenolymphomas of salivary glands analysed by a monoclonal antibody against myoepithelial/basal cells

Summary Myoepithelial and basal cells were identified by a monoclonal antibody raised against keratin. This antibody (CK B1) which detects myoepithelial cells in normal salivary glands, labels spindle shaped and polygonal cells in pleomorphic adenomas. Most cells in adenoid cystic carcinomas and some basal cells in adenolymphomas were also positive for this antibody. The oncocytic epithelium of adenolymphoma was negative.An inverse reaction was seen with an antibody against cytokeratin 18.The antibody CK B1 seems to be of interest for the detection of myoepithelial/basal cells in salivary glands and salivary gland tumours.Dedicated to Prof. Dr. G. Seifert on the occasion of his 65th birthdaySupported by the Deutsche Forschungsgemeinschaft and by the Hamburger Stiftung zur Förderung der Krebsbekämpfung