Originally misdiagnosed rhabdoid tumour of the kidney. A case report and differential diagnosis

Rhabdoid tumour of the kidney (RTK) is considered to be one of the most aggressive neoplasms of early life. The histogenesis of RTK still remains a matter of controversy. Immunohistochemistry usually shows diffuse reactivity for vimentin, focal reactivity to the epithelial marker, variable expression of mesenchymal and neuroectodermal markers, and loss of INI1 protein staining. Expression of the Wilms' tumour protein (WT1) was described in the RTK cases. We would like to present a case of rhabdoid tumour of the kidney in Latvia, which caused diagnostic difficulties of a 27-month-old girl, and a short review of literature.     

Alpha-methylacyl-CoA racemase as a marker in the differential diagnosis of metanephric adenoma.

Metanephric adenoma (MA), a well-described renal neoplasm, usually behaves in a benign fashion. It may have areas that are morphologically similar to papillary renal cell carcinoma (RCC) type, or epithelial (tubular predominant) type Wilms' tumor. Prior immunohistochemical studies of MA have reported variable staining patterns. Alpha-methylacyl-CoA racemase (AMACR), a molecular marker for prostate carcinoma, has subsequently been found to be overexpressed in breast, colorectal and ovarian cancers, among others. Recent microarray analysis of renal tumors has shown an increase of AMACR mRNA levels in papillary RCC but not in other subtypes. We investigated the utility of immunohistochemical staining for AMACR, cytokeratin 7(CK7), CD57 and WT1 to differentiate between the above-mentioned three neoplasms. Immunohistochemical stains were performed on paraffin-embedded tissue sections from 25 papillary RCC, 10 MAs and eight Wilms' tumors. AMACR was positive in one (10%) of 10 MAs and 24 (96%) of 25 papillary RCC, while it was negative in all Wilms' tumors. CK7 was positive in 20 of 25 papillary RCCs, focally positive in one Wilms' tumor and was negative in all MAs. CD57 was positive in all six MAs that were stained, focally positive in one of 25 papillary RCC and one of eight Wilms' tumors. WT1 was positive in seven of 10 MAs, three of 25 papillary RCCs and all eight Wilms' tumors. In conclusion, diffuse and strong immunoreactivity for AMACR may be useful in differentiating papillary RCC from MA but a panel which includes AMACR, CK7 and CD57 is better in this differential diagnosis. AMACR is not helpful in differentiating MA from Wilms' tumor, but CD57 is helpful in this differential diagnosis. WT1 may be useful in separating Wilms' tumor from MA and papillary RCC but is not helpful in differentiating MA from papillary RCC.     

Light microscopic, ultrastructural and immunocytochemical spectrum of malignant lacrimal and salivary gland tumors, including malignant mixed tumors.

Ten malignant myoepithelial tumors of the salivary glands and one of lacrimal gland origin were studied by light, electron microscopy and immunocytochemistry. The light microscopic appearance of the tumors varied from primarily spindle cell neoplasms (two cases), to others with predominantly epithelial components (four cases) and mixed varieties (five cases). Therefore, they can be confused with other epithelial and mesenchymal neoplasms. The electron microscopic spectrum varied from tumors with widespread and typical myoepithelial differentiation (i.e. myofilament bundles at the cell periphery, attachment plaques and intercellular junctions) to some with diffusely distributed filaments, without associated spindle densities but with attachment plaques, and others with evidence of duct formation and containing scattered cells showing intracytoplasmic tonofilaments. Often the tumors revealed mixed ultrastructural features; the relative numbers of the different cellular components was variable. The eleven neoplasms were S-100 protein, actin and keratin positive, either focally or diffusely, with varying degrees of intensity. Ten of the eleven tumors were positive for vimentin and nine of ten tested expressed carcinoembryonic antigen. Only two of nine were focally positive for glial fibrillary acidic protein. The study emphasizes the variable light microscopic appearances of these neoplasms and their immunocytochemical and ultrastructural spectrum. Accurate determination of myoepithelial differentiation sometimes requires careful evaluation of the light, ultrastructural and immunocytochemical findings. If all three diagnostic modalities are not utilized, it is likely that some of these neoplasms will be improperly classified.     

Cytological identification of metastatic epithelial nephroblastoma in pleural fluid: report of a case and review of literature

Nephroblastoma (Wilms' tumor) is the most common childhood renal tumor and usually presents with a histology and cytology consisting of blastemal, epithelial, and stromal cells. Effusions are not uncommon and may suggest an unfavorable prognosis when containing anaplastic tumor cells. In the present case, we report the cytological appearance of a Wilms' tumor metastatic to the pleura. The effusion consisted primarily of tumor cells demonstrating epithelial differentiation. The tumor cells mostly presented as three-dimensional aggregates in an inflammatory background. Many cystic and tubular structures were identified. The tumor cells demonstrated strong CD56 and WT1 immunoreactivity. The histology of a subsequent surgical specimen reflected the features seen in cytology.     

Diagnostic approach and prognostic factors of cancers

When one follows a systematic approach to make a diagnosis of a malignant lesion, it is relatively easy to render a correct cancer diagnosis in most cases during routine daily practice. The first step is to recognize whether or not the specimen contains a lesion and then to determine whether the lesion is neoplastic or non-neoplastic. As a neoplasm is a clonal proliferation, neoplastic conditions are consisted of a single cell type, whereas non-neoplastic conditions consist of multiple different cell types. After determining that a lesion is neoplastic, the next step is to decide whether the neoplasm is of an epithelial origin or mesenchymal origin. The main differences between epithelial tumors and mesenchymal tumors include: (1) The tumor cells in epithelial tumors are oval-round to polygonal, but in mesenchymal tumors, the tumor cells are in general spindle-shaped; (2) Epithelial tumors generally form tumor cell nests, but mesenchymal tumors are arranged diffusely in sheets, without forming tumor cell nests; (3) In epithelial tumors, desmoplastic stroma is well formed in between tumor cell nests, but in mesenchymal tumors there is no desmoplastic stroma; and lastly, (4) feeding vessels open in the stroma in epithelial tumors but open directly between tumor cells in mesenchymal tumors. After this, we can decide whether the tumor is benign or malignant. The differences between benign and malignant tumors include; (1) differentiation, (2) growth rate, (3) growth pattern, and (4) metastasis. A benign tumor is well differentiated, grows slowly, shows expansile growth with encapsulation and does not metastasize. In contrast, a malignant tumor is often poorly differentiated, grows rapidly with many mitoses, shows invasive growth with no capsule and frequently metastasizes. In general, malignant tumors show high cellularity, tumor necrosis and nuclear alterations, which include nuclear enlargement with a high nuclear/cytoplasmic ratio, hyperchromatism, pleomorphism, prominent nucleoli, and frequent mitoses. The final step is to classify the type of tumor based on the cellular differentiation and gross and microscopic growth pattern based on the light microscopic examination of hematoxylin and eosin stained slides. For the correct identification of the tumor, immunostaining, molecular diagnostic tools, or possibly electron microscopic evaluation may be required. After making a diagnosis of malignancy, one should then consider the relevant prognostic factors. The 2 well-known prognostic factors (category I prognostic factors) important in almost all tumors include stage and grade. Therefore, information for regarding stage and grade should be included in the pathology report.     

Stromal Elements for Tumor Diagnosis: A Brief Review of Diagnostic Electron Microscopic Features

Tumor diagnosis mainly depends on the appearance of the tumor cells in recapitulating the appearance of primordial cells from which they arise. However, certain tumors may present with specific stromal changes that may assist/enhance the diagnosis. In this presentation, diagnostic stromal features have been reviewed. The cytoplasm is enclosed by a unit membrane, which serves as a barrier to, as well as an interface with, surrounding structures. Epithelial cells usually show characteristic basal–apical orientation. In mesenchymal tissue, different types of interface can be found in different types of mesenchymal tissue. External lamina can be defined as an anatomic structure, which encloses anatomic functional units. In epithelial tissue, cells in a functional unit are enclosed within a well-defined external lamina (EL). In malignant epithelial tumors, EL can become increasingly indistinct as tumors become less differentiated, and one has to look for it diligently. Within the external lamina, epithelial cells are closely packed with closely apposed cell membranes and cell attachment junctions. In contrast to epithelial tissue, mesenchymal tissue is usually characterized by the stromal elements they produce. Individual cells are embedded in the stroma, and individual mesenchymal cells represent the functional unit. Vascular endothelial cells are an exception since their relationship to stroma resembles to that of epithelial cells. Thus, tumors deriving from mesenchymal cells known to have external lamina such as muscle cells and Schwann cells tend to show total enclosure of cells by external lamina. In malignant muscle tumors, external lamina production can be focally present and found only by diligent search. In Schwann cell tumors, the presence of EL is prominent in low-grade tumors and more irregular and variable in malignant tumors. In the latter, stromal aggregation of scrolls of external lamina can be characteristic. Similar features are seen in ossifying fibromyxoid tumors. Fibronexus junctions (composed of extracellular fibronectin fillements linking intracellular 5-nm filaments) is claimed to be typical of myofbroblasts. Finding them in spindle cell tumors justifies a diagnosis of myofibroblastomas. There have been several stromal changes diagnostic for certain tumors found only by electron microscopy. Fibrous long-spaced collagen (known as Luse bodies) is diagnostic for peripheral nerve sheath tumors, but they can rarely be found in other tumors. Luse bodies usually appear as focally as crystallized aggregates apart from the regular collagenous interstitial stroma. They should be distinguished from other nonspecific long-spaced collagen changes. The changes are diffusely stromal in contrast to Luse bodies. Spiny collagen and amianthoid fibers are interesting collagen fibrils and their diagnostic value is questionable. Skeinoid fibers (SF) are short-spaced collagen of 41- to 45-nm banding so-named because of their peculiar appearance by electron microscopy simulating skeins of yarn. They were originally described in neurogenic tumors and small intestinal stromal tumors with features of gastrointestinal autonomic nerve tumors (GANT). Although there have been a few sporadic case reports of the presence of skeinoid fibers in nonneurogenic tumors, the frequent presence of SF in spindle cell tumors signifies their neurogenic nature in this authors’ experience. An exception to this is that SF can be a constant element of rare ciliary body tumors known as ciliary mesectodermal leiomyomas, in which tumor cells show some resemblance to smooth muscle as well as Schwann cells. In addition to SF, several other types of peculiar crystallized collagen were observed in GANT tumors, particularly those with multiple tumor syndromes such as neurofibromatosis and Carney's triad. They simulate the appearance of railroad tracks or centrosomes. The reason for this is not known. The authors speculate that such collagen crystallization may be caused by genetic alterations involving collagenosis. Further studies will be necessary to clarify their pathogenesis. Another peculiar stromal change is electron-dense stromal filamentous aggregates with extra-long banding of > 250-nm periodicity previously described in Ewing sarcomas. This stromal change simulating a tiger skin pattern is also seen in primitive neuroectodermal tumors and malignant melanomas. In view of continually new discoveries of stromal changes that can be used for the differential diagnosis of tumors, the importance of close evaluation of stromal elements of tumors, and diligent application of electron microscopy in tumor diagnosis cannot be overemphasized.     

Stromal elements for tumor diagnosis: a brief review of diagnostic electron microscopic features

Tumor diagnosis mainly depends on the appearance of the tumor cells in recapitulating the appearance of primordial cells from which they arise. However, certain tumors may present with specific stromal changes that may assist/enhance the diagnosis. In this presentation, diagnostic stromal features have been reviewed. The cytoplasm is enclosed by a unit membrane, which serves as a barrier to, as well as an interface with, surrounding structures. Epithelial cells usually show characteristic basal-apical orientation. In mesenchymal tissue, different types of interface can be found in different types of mesenchymal tissue. External lamina can be defined as an anatomic structure, which encloses anatomic functional units. In epithelial tissue, cells in a functional unit are enclosed within a well-defined external lamina (EL). In malignant epithelial tumors, EL can become increasingly indistinct as tumors become less differentiated, and one has to look for it diligently. Within the external lamina, epithelial cells are closely packed with closely apposed cell membranes and cell attachment junctions. In contrast to epithelial tissue, mesenchymal tissue is usually characterized by the stromal elements they produce. Individual cells are embedded in the stroma, and individual mesenchymal cells represent the functional unit. Vascular endothelial cells are an exception since their relationship to stroma resembles to that of epithelial cells. Thus, tumors deriving from mesenchymal cells known to have external lamina such as muscle cells and Schwann cells tend to show total enclosure of cells by external lamina. In malignant muscle tumors, external lamina production can be focally present and found only by diligent search. In Schwann cell tumors, the presence of EL is prominent in low-grade tumors and more irregular and variable in malignant tumors. In the latter, stromal aggregation of scrolls of external lamina can be characteristic. Similar features are seen in ossifying fibromyxoid tumors. Fibronexus junctions (composed of extracellular fibronectin fillements linking intracellular 5-nm filaments) is claimed to be typical of myofbroblasts. Finding them in spindle cell tumors justifies a diagnosis of myofibroblastomas. There have been several stromal changes diagnostic for certain tumors found only by electron microscopy. Fibrous long-spaced collagen (known as Luse bodies) is diagnostic for peripheral nerve sheath tumors, but they can rarely be found in other tumors. Luse bodies usually appear as focally as crystallized aggregates apart from the regular collagenous interstitial stroma. They should be distinguished from other nonspecific long-spaced collagen changes. The changes are diffusely stromal in contrast to Luse bodies. Spiny collagen and amianthoid fibers are interesting collagen fibrils and their diagnostic value is questionable. Skeinoid fibers (SF) are short-spaced collagen of 41- to 45-nm banding so-named because of their peculiar appearance by electron microscopy simulating skeins of yarn. They were originally described in neurogenic tumors and small intestinal stromal tumors with features of gastrointestinal autonomic nerve tumors (GANT). Although there have been a few sporadic case reports of the presence of skeinoid fibers in nonneurogenic tumors, the frequent presence of SF in spindle cell tumors signifies their neurogenic nature in this authors' experience. An exception to this is that SF can be a constant element of rare ciliary body tumors known as ciliary mesectodermal leiomyomas, in which tumor cells show some resemblance to smooth muscle as well as Schwann cells. In addition to SF, several other types of peculiar crystallized collagen were observed in GANT tumors, particularly those with multiple tumor syndromes such as neurofibromatosis and Carney's triad. They simulate the appearance of railroad tracks or centrosomes. The reason for this is not known. The authors speculate that such collagen crystallization may be caused by genetic alterations involving collagenosis. Further studies will be necessary to clarify their pathogenesis. Another peculiar stromal change is electron-dense stromal filamentous aggregates with extra-long banding of > 250-nm periodicity previously described in Ewing sarcomas. This stromal change simulating a tiger skin pattern is also seen in primitive neuroectodermal tumors and malignant melanomas. In view of continually new discoveries of stromal changes that can be used for the differential diagnosis of tumors, the importance of close evaluation of stromal elements of tumors, and diligent application of electron microscopy in tumor diagnosis cannot be overemphasized.     

Multiple tumor types appear in a transgenic mouse with the ras oncogene.

A transgenic mouse strain with the zeta-globin promoter and the vHa-ras oncogene develops an array of mesenchymal and epithelial neoplasms described here. The predominate mesenchymal tumors were dermal spindle cell tumors, which resembled malignant fibrous histiocytomas found in humans. They were associated with hepatosplenomegaly and developed beneath squamous papillomas. The hepatosplenomegaly was associated with infiltrates of cells that tended toward myelocytic or monocytic differentiation. Other epithelial tumors included keratoacanthomas and squamous cell carcinomas. Squamous cysts, some with squamous cell carcinomas, of the salivary glands and mammary carcinomas were also found. Odontogenic tumors, which sometimes differentiated into ameloblastomas, were one of the more unusual tumor types observed. Other, less frequent tumors were also noted. The tumors described here are a potentially valuable experimental resource that may lead to an understanding of malignant fibrous histiocytoma-like lesions, odontogenic tumors, and tumor progression.     

Clear cell sarcoma of the kidney. An immunohistochemical study

Three cases of clear cell sarcoma of the kidney (CCSK) and 5 cases of Wilms' tumor were investigated immunohistochemically to examine the expression of tissue-specific intermediate filaments (cytokeratin, vimentin, and desmin) and myoglobin. In CCSK, tumor cells were negative for cytokeratin, except for occasional tubular structures, and vimentin was demonstrated in only one case. In Wilms' tumor, epithelial components were positive for cytokeratin and stromal cells were positive for vimentin, while no staining was found in blastemal cells for either. Both desmin and myoglobin were negative in all tumor cells except for skeletal muscle cells in Wilms' tumor. In the current study, some neoplastic cells in CCSK were revealed to be of mesenchymal nature, but blastemal cells in Wilms' tumor were not.     

CLEAR CELL SARCOMA OF THE KIDNEY An Immunohistochemical Study

Three cases of clear cell sarcoma of the kidney (CCSK) and 5 cases of Wilms' tumor were investigated immunohistochemically to examine the expression of tissue-specific intermediate filaments (cytokeratin, vimentin, and desmin) and myoglobin. In CCSK, tumor cells were negative for cytokeratin, except for occasional tubular structures, and vimentin was demonstrated in only one case. In Wilms' tumor, epithelial components were positive for cytokeratin and stromal cells were positive for vimentin, while no staining was found in blastemal cells for either. Both desmin and myoglobin were negative in all tumor cells except for skeletal muscle cells in Wilms' tumor. In the current study, some neoplastic cells in CCSK were revealed to be of mesenchymal nature, but blastemal cells in Wilms' tumor were not.     

Immunohistochemical localization of transport mediators in Wilms' tumor: comparison with fetal and mature human kidney

Immunostaining for Na+, K+-ATPase, carbonic anhydrase (CA) II, and band 3 anion channel glycoprotein was compared in developing and mature human kidneys and in Wilms' tumors. In fetal kidneys, ATPase first appeared in proximal and distal tubules. At birth an adult pattern was present with abundant enzyme in all segments of the distal tubule and lesser amounts in proximal and collecting tubules. CA II was detected in fetal kidneys first in proximal and then in distal tubules and eventually, as in the adult, throughout the nephron. Band 3 glycoprotein was not detected in fetal kidneys and only weak staining was present in the basolateral plasmalemma of intercalated cells in newborn and infant kidneys. The number of cells reactive for band 3 and the intensity of staining in a given cell increased to near adult levels at about 2 years. This finding may provide a partial explanation for the 'physiological acidosis' characterized by a low systemic pH in newborn and young infants. ATPase was present in basolateral membranes of most epithelial cells in nonanaplastic Wilms' tumors but was absent in the epithelial component of two anaplastic Wilms' tumors. CA II was detected only in a few epithelial cells in four tumors. Neoplastic epithelial cells reactive for CA II also stained for ATPase but not vice versa. Band 3 glycoprotein was not detected in any Wilms' tumor. These findings show that the immunohistochemical assessment of protein involved in electrolyte transport provides a further means for determining the relative level of differentiation of tumor cells of epithelial origin and suggest that these methods may be a valuable aid in determining the prognosis of some carcinomas.     

Aspiration cytology of Wilms' tumor: correlation of cytologic and histologic features

We examined the cytomorphologic features of fine-needle aspiration biopsy (FNAB) specimens from 23 Wilms' tumor patients. The findings were correlated with histopathologic patterns from these tumors. The study revealed a close resemblance between the cytologic and histopathologic appearance of various cellular elements in Wilms' tumors. The major cellular patterns seen in Wilms' tumor include blastemal cells, blastemal cells with epithelial differentiation, blastemal cells with tubular differentiation, and stromal elements. It is hoped that recognition of these cellular components in aspiration smears will be helpful in establishing an FNAB diagnosis of Wilms' tumor.     

The in vitro growth and characterization of the skeletal muscle component of Wilms'' tumor.

Skeletal muscle differentiation within a Wilms' tumor is a well-documented histopathologic entity thought to occur at a relatively low incidence and influence prognosis. A serum-free hormonally defined growth medium has been developed, allowing the long-term growth of the skeletal muscle component of Wilms' tumors. Eight Wilms' tumors have been grown under these conditions. Three cases grew a homogeneous population of cells which ultrastructurally displayed all stages of myogenesis through myotubule formation. They also possessed immunoreactivity for skeletal muscle myosin and myoglobin and synthesized the M and B subunits of creatine kinase. Of interest was the finding that the ability to yield skeletal muscle cultures was limited to those cases which exhibited skeletal muscle fibers in vivo. This technique is also a very sensitive marker for identifying Wilms' tumors possessing a myoid component. A second serum-free hormonally defined medium has also been developed that supports the long-term culture of a unique cell type from Wilms' tumors which contain a myoid component. These cells are spindle-shaped and exhibit all of the characteristics of early myoblasts.     

Different immunohistochemical patterns of Fhit protein expression in renal neoplasms.

BACKGROUND: The FHIT gene on human chromosome 3p14.2 is deleted in a variety of malignant tumors, including clear cell renal carcinomas (RCCs) resulting in a loss of expression of Fhit protein. The Fhit expression in specific subtypes of renal carcinomas has not been characterized. We have investigated the association of Fhit expression with particular subtypes of renal tumors to determine the role and specificity of this putative tumor suppressor gene in renal neoplasia. MATERIAL AND METHODS: The immunohistochemical expression of Fhit was tested in normal kidneys and in 109 renal neoplasms consisting of 51 clear cell RCCs, 26 papillary RCCs, two chromophobe carcinomas, six oncocytomas, four pelvic transitional cell carcinomas and 20 Wilms' tumors from formalin fixed and routinely processed tissue. RESULTS: Normal renal tubules expressed Fhit strongly and consistently. The majority (78%) of clear cell RCCs showed reduced or absent expression of Fhit, whereas the majority (74%) of papillary carcinomas, all chromophobe renal cell carcinomas, and oncocytomas were strongly positive. Sixty-eight percent of low-grade (G1 plus G2) but only 9% of high-grade (G3 plus G4) clear cell carcinomas were Fhit negative. Wilms' tumors demonstrated focal staining in the epithelial component in 8 of 20 cases (40%). CONCLUSIONS: The loss of Fhit expression in a high percentage of clear cell RCCs with conservation of Fhit in other types of tumors supports the proposed role of FHIT alterations in the genesis of clear cell carcinomas in contrast to other types of renal epithelial tumors. FHIT expression may play a role in epithelial differentiation of nephroblastomas (Wilms' tumors).     

Localized fibrous tumors of the pleura: correlation of histopathological, immunohistochemical and ultrastructural features.

The histogenesis of localized fibrous tumor of the pleura (LFTP) is controversial. We studied 12 LFTP's by light microscopy; by immunohistochemical staining for cytokeratin (CK), vimentin, muscle-specific actin, desmin, S-100 protein, epithelial membrane antigen (EMA) and factor VIII; by electron microscopy in 6 tumors; and by lung digestion for asbestos bodies in 4 cases. Three histologic patterns occurred in combination: 1) collagenous, 2) cellular and 3) hypocellular/myxoid. Hemangiopericytoma-like foci were prominent in the cellular areas of 9 tumors. Unusual features included diffuse small cells in 3 tumors, microcystic foci in 2, macrocystic areas in 5 and tumor giant cells in 4 tumors. Neoplastic cells in all patterns stained positively for vimentin and actin in 9 and 4 tumors, respectively, and were negative for all other markers. CK and EMA were identified in mesothelial and epithelial invaginations only. Ultrastructurally, neoplastic cells demonstrated intercellular junctions, intermediate or thin filaments, dense bodies and rough endoplasmic reticulum. Basal lamina was focally present in 5 tumors, while tonofilaments, desmosomes and short microvilli were observed in one case. Our results support the conclusion that LFTP is a neoplasm of the multipotential subserosal cell, and usually expresses mesenchymal (fibroblastic/myofibroblastic) differentiation. Coexpression of mesothelial features is rare. Lung asbestos body quantitation in 4 patients suggests that there is no association between LFTP and asbestos exposure.     

Cytological features of epithelioid mesenchymal neoplasms: a study of 21 cases

Epithelioid mesenchymal neoplasms (EMNs) are rare tumors that share cytological, histological, and immunohistochemical features with epithelial tumors. It is important to distinguish EMNs from epithelial tumors in cytology specimens due to their different clinical management and prognosis. The cytomorphological features of histologically confirmed EMN were reviewed. Twenty-one cytological specimens of EMN were evaluated and characterized by polygonal cells with moderate to abundant dense cytoplasm, prominent nucleoli, and pleomorphism. Additional findings included the presence of a distinct population of spindle cells, hemosiderin-containing cells, multinucleated cells, and granuloma-like structures in selected cases. Cytokeratin immunoreactivity was seen in two cases and was negative in one case. This study shows that the cytological features of EMNs and epithelial tumors overlap; nonetheless, some features are more helpful in suggesting EMN. A panel of immunocytochemical studies must include specific mesenchymal markers to avoid a misdiagnosis of carcinoma in cases of cytokeratin-positive EMN.     

Transitional cell carcinoma with sarcomatous elements in the urinary tract. Six cases examined by immunohistochemistry.

We report six cases of carcinoma showing sarcomatous change in the urinary tract examined by conventional histochemistry and immunohistochemistry. All of the cases were transitional cell carcinoma with or without focal squamous cell carcinoma. Sarcomatous components resembling spindle cell sarcoma with a marked myxoid stroma or chondrosarcomatous element were also observed in all cases. The sarcomatous elements were closely associated with the areas of squamous cell carcinoma in three cases. Various histochemical staining procedures demonstrated mesenchymal features in the stroma of sarcomatous areas. By immunohistochemical examination, the epithelial components showed positive reactions for keratin, epithelial membrane antigen and, focally, carcinoembryonic antigen. The sarcomatous components revealed a positive immunoreaction for keratin but lacked other epithelial markers in all cases. Chondrosarcomatous elements in two cases were positive for both keratin and S-100 protein. These findings indicate that sarcomatous elements in carcinoma may represent mesenchymal metaplasia with partial or complete loss of epithelial features. However, further study will be necessary in order to determine whether heterogeneous elements, such as chondrosarcomatous areas, are epithelial or truly mesenchymal in origin.     

Identification of genetically aberrant cell lineages in Wilms' tumors

Most Wilms' tumors contain several predominant cell types, of which a primitive blastemal population is often the most prominent. Other typical components include undifferentiated mesenchymal and epithelial cells, but it has not been demonstrated that these components are neoplastic. We used a combined cytogenetic and fluorescence in situ hybridization approach to determine the clonal relationship of different cell populations within six Wilms' tumors. Clonal numerical chromosome aberrations in three Wilms' tumors were found in blastemal cells, but not in mesenchymal cells. Loss of one WTl allele in two other tumors was detected in both blastemal and mesenchymal cells. Tetrasomy 18 in a sixth case was observed in mesenchymal and epithelial cells; blastemal cells could not be evaluated in this tumor. These findings demonstrate that mesenchymal and epithelial cells in some Wilms' tumors are neoplastic. Different histologic components in some Wilms' tumors derive from a single chromosomally aberrant ancestor which is most likely to be the primitive blastemal cell. Genes Chrom Cancer 10:40–48 (1994). © 1994 Wiley-Liss, Inc.     

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