C-kit expression in renal oncocytomas and chromophobe renal cell carcinomas

C- kit encodes the membrane-bound tyrosine kinase KIT, whose expression has been identified in several types of human neoplasms. Recently, KIT has been reported to be a marker for chromophobe renal cell carcinoma (RCC) and renal angiomyolipoma. However, expression of this molecule has not been adequately studied in other renal tumors, particularly oncocytoma, which may morphologically resemble chromophobe RCC. In this study, we analyzed c- kit messenger RNA (mRNA) levels in 17 chromophobe RCCs and 20 renal oncocytomas obtained from complementary DNA (cDNA) microarrays. Furthermore, comprehensive immunohistochemical analysis of KIT protein using a monoclonal antibody was performed in 226 renal tumors including chromophobe RCC (n=40), oncocytoma (n=41), clear-cell RCC (n=40), renal angiomyolipoma (n=29), and papillary RCC (n=21) on tissue microarrays (TMAs) and was compared with immunostaining results from 25 chromophobe RCCs and 30 oncocytomas using standard sections. The staining intensity was semiquantitatively graded on a 3-tier scoring system. All chromophobe RCCs and oncocytomas showed significant overexpression of c- kit mRNA. The average increase of mRNA compared with normal kidney tissue was 7.4-fold for chromophobe RCCs and 7.4-fold for oncocytomas. Immunohistochemical expression of KIT was found in most chromophobe RCCs (95% in TMAs and 96% in conventional sections) and oncocytomas (88% in TMAs and 100% in conventional sections) but was infrequently observed in renal angiomyolipomas (17%), papillary RCCs (5%), and clear-cell RCCs (3%). Furthermore, the average KIT immunoreactivity in TMAs was stronger in chromophobe RCC (1.93) and oncocytoma (2.07) than in other subtypes of renal tumors tested, including angiomyolipomas (0.17), papillary RCCs (0.05), and clear-cell RCCs (0.03). In conclusion, we found a significant elevation of c- kit mRNA by cDNA expression microarrays and overexpression of KIT protein by immunohistochemistry not only in chromophobe RCCs but also in oncocytomas. In contrast, immunohistochemical expression of KIT was not detected in most other types of renal cell tumors evaluated. The differential expression of c- kit in these renal tumors may have diagnostic and therapeutic implications.     

Expression of GLUT1 in primary renal tumors: morphologic and biologic implications

This study aimed to assess whether glucose transporter 1 (GLUT1) is useful in prognostication or differential diagnosis of renal tumors. GLUT1 immunostain for 228 renal tumors showed a membranous or cytoplasmic pattern. The membranous pattern was seen in 86.2% of 145 clear cell renal cell carcinomas (RCCs) and 100% of 11 transitional cell carcinomas (TCCs) but in no oncocytomas, other subtypes of RCC, or sarcomatoid areas of RCCs. The cytoplasmic pattern was seen in 55.2% of 145 clear cell RCCs, 38% of papillary RCCs (11/29), 13% of chromophobe RCCs (2/16), 22% of oncocytomas (5/23), and 82% of TCCs (9/11). Western blot showed a markedly increased GLUT1 protein content in clear cell RCCs compared with a low level in papillary RCCs and normal kidney specimens. GLUT1 expression in clear cell RCC was not significantly correlated with patient survival, tumor grade, or tumor stage. GLUT1 may be a novel target for immunotherapy and a useful marker in the differential diagnosis and classification of renal tumors.     

Expression of kidney-specific cadherin distinguishes chromophobe renal cell carcinoma from renal oncocytoma

Distinguishing renal oncocytoma from chromophobe and other renal carcinomas is essential, considering their differing biological potentials. Although renal oncocytoma is considered a benign tumor, chromophobe renal cell carcinoma has potentially malignant biological behavior. The numerous reported studies on distinguishing these 2 entities have been based on morphological, histochemical, immunohistochemical, ultrastructural, and cytogenetic features. But none of these features has proven to be reliably specific, especially in tumors with overlapping phenotypes. We report a novel immunohistochemical approach based on the expression of a recently described kidney-specific cadherin (Ksp-cadherin) for the differential diagnosis of these 2 tumors. We compared Ksp-cadherin expression in 212 renal tumors, including 102 clear cell renal carcinomas, 46 papillary renal cell carcinomas, 30 chromophobe carcinomas, 3 collecting duct carcinomas, and 31 oncocytomas. In addition, we examined the expression of epithelial membrane antigen, vimentin, CK7, and Hale's colloidal iron staining. We found that chromophobe renal cell carcinomas consistently (96.7% of cases) demonstrated a distinctive membrane pattern of Ksp-cadherin expression, whereas renal oncocytomas (3.2%), clear cell renal cell carcinomas (0%), papillary renal cell carcinomas (2.2%), and collecting duct carcinomas (0%) usually did not express Ksp-cadherin. CK7 expression was found in 90.0%, 6.5%, 7.8%, 76.1%, and 33.3% of these tumor cases, respectively. Whereas CK7 was detected in different types of renal cell carcinomas, Ksp-cadherin was expressed almost exclusively in chromophobe renal cell carcinomas. Immunohistochemical analysis of Ksp-cadherin offers a fast, reliable approach for the distinguishing between renal oncocytoma and chromophobe renal cell carcinoma that is applicable for routine pathology laboratory studies without the need for time-consuming and costly ancillary studies.     

Expression of intermediate filament proteins in subtypes of renal cell carcinomas and in renal oncocytomas. Distinction of two classes of renal cell tumors

We examined the expression of the diverse cytokeratin (CK) polypeptides as well as vimentin in human renal cell carcinomas of various subtypes and in renal oncocytomas by applying both two-dimensional gel electrophoresis and immunocytochemistry by using polypeptide-specific monoclonal antibodies. The tumors were classified according to the guidelines of the World Health Organization, with some modifications based primarily on recently proposed cytomorphological criteria. All clear cell carcinomas (G I, G II; N = 20) co-expressed CKs nos. 8 and 18, and vimentin, with CK no. 19 being present in 13 of the 20 cases and exhibiting a heterogeneous distribution. Dedifferentiated carcinomas (G III; N = 8) also co-expressed CKs nos. 8 and 18 as well as vimentin, but in addition, exhibited CK no. 19 and, in many cases, CK no. 7; in 1 case, only vimentin was expressed. Both eosinophilic-granular (N = 3) and basophilic (small cell cuboidal; N = 6) carcinomas contained CKs nos. 8 and 18, and the co-expression of vimentin was a consistent feature of these tumors; CK no. 19 was found in all of these cases, while CK no. 7 was present in the majority. In chromophobe cell carcinomas (N = 8), in contrast to all of the other carcinoma types, no vimentin was detected in the tumor cells, with only CKs nos. 8, 18, and to a variable extent 7, being present. Similarly, oncocytomas (N = 8) lacked vimentin and exhibited only CKs nos. 8 and 18. Conspicuous scattered CK no. 19-positive cells were found in these two last tumor types. No CK polypeptides other than simple-epithelium-type CKs (nos. 7, 8, 18, and 19) were detected in any of the tumors studied. These results indicate that, in renal cell tumors, the expression of intermediate-filament proteins is strikingly correlated with the specific morphologic appearance. While the co-expression of CKs nos. 8 and 18 and vimentin was a surprisingly consistent feature of the most common subtypes of renal cell carcinomas, CK no. 19 exhibited remarkable heterogeneity of expression both within individual tumors and between different tumors, the expression patterns of this CK being correlated to the tumor subtypes. The consistent absence of vimentin in chromophobe cell carcinomas and oncocytomas makes it possible to define these as a separate class of renal cell tumors. This finding supports the view that chromophobe cell carcinomas represent a distinct tumor entity and points to their close phenotypic relationship to benign oncocytomas as well as to normal renal tubules.     

Expression of MUC1 (EMA) and E-cadherin in renal cell carcinoma: a systematic immunohistochemical analysis of 188 cases.

MUC1 (epithelial membrane antigen) is a membrane-associated mucin known to interfere with both cell-cell and cell-matrix adhesions. Overexpression has been associated with poor prognosis in a variety of cancers. We investigated the expression of MUC1 (using two different antibodies, MA695 and E29) and E-cadherin in renal cell carcinomas (137 conventional, 23 chromophobe, 20 papillary, and eight unclassified tumors) with respect to diagnostic and prognostic significance using a tissue microarray technique. Immunoreactivity was correlated with histological subtype, pT-stage, and grade using the chi2 test or the Fisher's exact test, respectively. Impact on disease-free survival was analyzed using the Kaplan-Meier method and the log-rank test. Immunoreactivity of more than 10% of cancer cells with MA695, E 29, and E-cadherin antibodies was found in 112/133 (84%), 86/133 (65%), and 7/131 (5%) conventional, 20/22 (91%), 19/22 (86%), and 21/22 (95%) chromophobe, 13/20 (65%), 8/20 (40%), and 3/20 (15%) papillary as well as 5/8 (63%), 5/8 (63%), and 4/8 (50%) unclassified carcinomas, respectively. The two different MUC1 antibodies yielded comparable staining results. A diffuse cytoplasmic staining pattern for MUC1 was found exclusively in chromophobe carcinomas, whereas conventional and papillary subtypes showed predominantly membranous staining (P<0.0001). Regarding papillary carcinomas, MUC1 was predominantly associated with type 1 (P=0.0001), and E-cadherin with type 2 (P=0.049) tumors. The cellular staining pattern of MUC1 in conventional tumors was related to pT-stage (P=0.002) and tumor grade (P=0.001): Low-stage (pT1/pT2) and grade (G1/G2) tumors showed a predominantly apical membranous staining, high-stage (pT3a/pT3b) and grade (G3/G4) tumors a predominantly circumferential membranous staining (with or without additional diffuse cytoplasmic immunoreactivity), which, in the conventional subtype, was associated with poor prognosis (P<0.0001). In conclusion, MUC1 and E-cadherin are diagnostically and prognostically useful markers in renal tumor pathology, especially when cellular staining patterns are considered.     

Chromophobe cell carcinoma and renal cell neoplasms with mucin-like changes

Hale's colloidal iron staining of 8 chromophobe cell carcinomas (CCC) was compared with that of non-chromophobe renal cell carcinomas (RCC), renal oncocytomas, and renal adenomas. Six non-chromophobe RCC showing diffuse and moderate cytoplasmic staining contained extensive areas with translucent cytoplasm as observed in CCC. Seventeen of 25 conventional RCC of the clear cell variant (randomly chosen from 130 cases), 21 of 26 RCC with areas of chromophilic cytoplasm, and 16 of 20 papillary RCC, 7 of 14 adenomas and 14 of 16 oncocytomas displayed focal areas with mild to moderate staining of the cytoplasm. Hale's colloidal iron staining was partially reduced by digestion with neuramidase but not with hyaluronidase. This positive staining demonstrated glycoproteins containing sialylated glycoconjugates, probably a type of acid epithelial mucin. We suggest that there is a spectrum of mucin-like changes in typical CCC representing RCC with extensive and marked "mucin-like changes". The eosinophilic variant of CCC and some RCC with extensive chromophobe cell features represent renal neoplasms with moderate changes. The other RCC, oncocytomas and papillary renal neoplasms with mild to moderate staining with Hale's colloidal iron represent renal neoplasms with focal mucin-like changes. RCC with extensive chromophobe cell features may pose a differential diagnostic problem with CCC.     

Alpha-methyl CoA racemase expression in renal cell carcinomas

Alpha-methyl CoA racemase (AMACR), a new molecular marker for prostate cancer, has been recently reported to be one of the most highly expressed genes in papillary renal cell carcinomas (RCCs). We tested the diagnostic usefulness of AMACR antibody in a series of 110 renal tumors: 53 papillary RCCs (33 type 1, 20 type 2); 25 conventional RCCs; 6 chromophobe RCCs; 9 oncocytomas; 5 mucinous tubular and spindle tumors; 2 urothelial carcinomas; 7 angiomyolipomas; and 2 Bellini carcinomas. Immunohistochemical staining was performed on formalin-fixed, paraffin-embedded tissue sections, with a primary prediluted rabbit monoclonal anti-AMACR antibody. Both type 1 and type 2 papillary RCCs exhibited cytoplasmic immunoreactivity for AMACR, with diffuse strong granular staining in 96.4% (53/55) of tumors, without correlation with type or nuclear grade. The 5 mucinous, tubular, and spindle cell carcinomas strongly expressed AMACR, and only 5 of 25 clear cell RCCs and 1 of 9 oncocytomas were focally reactive. The remaining 6 chromophobe RCCs, 5 urothelial carcinomas, and Bellini duct carcinomas showed no immunoreactivity for AMACR. Because high expression of AMACR is found in papillary RCCs (type 1 and 2) and in mucinous, tubular, and spindle cell carcinomas of the kidney, immunostaining for AMACR should be used in conjunction with other markers when histological typing of a renal tumor is difficult.     

Diagnostic utility of S100A1 expression in renal cell neoplasms: an immunohistochemical and quantitative RT-PCR study.

S100A1 is a calcium-binding protein, which has been recently found in renal cell neoplasms. We evaluated the diagnostic utility of immunohistochemical detection of S100A1 in 164 renal cell neoplasms. Forty-one clear cell, 32 papillary, and 51 chromophobe renal cell carcinomas, and 40 oncocytomas, 164 samples of normal renal parenchyma adjacent to the tumors and 13 fetal kidneys were analyzed. The levels of S100A1 mRNA detected by quantitative RT-PCR analysis of frozen tissues from seven clear cell, five papillary, and six chromophobe renal cell carcinomas, four oncocytomas, and nine samples of normal renal tissues adjacent to neoplasms were compared with the immunohistochemical detection of protein expression. Clear cell and papillary renal cell carcinomas showed positive reactions for S100A1 in 30 out of 41 tumors (73%) and in 30 out of 32 (94%) tumors, respectively. Thirty-seven renal oncocytomas out of 40 (93%) were positive for S100A1, whereas 48 of 51 (94%) chromophobe renal cell carcinomas were negative. S100A1 protein was detected in all samples of unaffected and fetal kidneys. S100A1 mRNA was detected by RT-PCR in all normal kidneys and renal cell neoplasms, although at very different levels. Statistical analyses comparing the different expression of S100A1 in clear cell and chromophobe renal cell carcinomas observed by immunohistochemical and RT-PCR methods showed significant values (P<0.001), such as when comparing by both techniques the different levels of S100A1 expression in chromophobe renal cell carcinomas and oncocytomas (P<0.001). Our study shows that S100A1 protein is expressed in oncocytomas, clear cell and papillary renal cell carcinomas but not in chromophobe renal cell carcinomas. Its immunodetection is potentially useful for the differential diagnosis between chromophobe renal cell carcinoma and oncocytoma. Further, S100A1 protein expression is constantly detected in the normal parenchyma of the adult and fetal kidney.     

Parvalbumin is constantly expressed in chromophobe renal carcinoma.

Chromophobe renal carcinoma is composed of neoplastic cell showing several features similar to those found in the intercalated cells of the collecting ducts. Because the distal nephron expresses calcium-binding proteins playing a role in calcium homeostasis, we reasoned that these proteins could be expressed by chromophobe carcinoma and therefore represent a diagnostic marker. We studied the immunohistochemical expression of different calcium-binding proteins (parvalbumin, calbindin-D28K, and calretinin) in 140 renal tumors, including 75 conventional (clear cell) carcinomas, 32 chromophobe carcinomas, 17 papillary renal cell carcinomas, and 16 oncocytomas. Parvalbumin was strongly positive in all primary chromophobe carcinomas and in one pancreatic metastasis; it was positive in 11 of 16 oncocytomas and absent in conventional (clear cell) and papillary renal cell carcinomas, either primary or metastatic. Calbindin-D28K and calretinin were negative in all tumors, with the exception of two chromophobe carcinomas, four oncocytomas, and two papillary renal cell carcinomas showing inconspicuous calretinin expression. Our data demonstrate that parvalbumin may be a suitable marker for distinguishing primary and metastatic chromophobe carcinoma from conventional (clear cell) and papillary renal cell carcinoma. Moreover, they suggest a relationship between chromophobe renal carcinoma and renal oncocytoma and indicate that chromophobe carcinoma exhibits differentiation toward the collecting-duct phenotype.     

Claudin-7 and claudin-8: immunohistochemical markers for the differential diagnosis of chromophobe renal cell carcinoma and renal oncocytoma

Claudin-7 and claudin-8 code for tight junction proteins expressed in distal nephron epithelium. In a recent oligonucleotide microarray study, we identified claudin-7 and claudin-8 as candidate markers to distinguish chromophobe renal cell carcinoma from other renal tumors, including oncocytoma. Distinction of these lesions can be difficult by light microscopy but is clinically important because chromophobe renal cell carcinoma has malignant biological potential, whereas renal oncocytoma is benign. Claudin-7 and claudin-8 expression was studied by immunohistochemistry in 11 chromophobe renal cell carcinomas and 17 oncocytomas using formalin-fixed paraffin-embedded tissue sections of tumor with adjacent nonneoplastic kidney. Steam antigen retrieval was performed before immunohistochemistry. Specificity was verified by negative control reactions without primary antibody and appropriate membranous staining patterns in positive control tissues (colon carcinoma and adjacent nonneoplastic kidney). Claudin-7 protein was expressed in a membranous pattern in 10 of 11 chromophobe renal cell carcinomas and 4 of 17 oncocytomas (P < .01). Claudin-8 was expressed in multiple patterns: In oncocytoma, 11 of 17 cases showed cytoplasmic, 4 of 17 membranous, and 2 of 17 negative reactions. In chromophobe renal cell carcinoma, 0 of 11 cases showed cytoplasmic, 3 of 11 membranous, and 8 of 11 negative reactions (P < .01). The immunohistochemical pattern of membranous claudin-7 and negative claudin-8 was seen in 7 of 11 chromophobe renal cell carcinomas and 1 of 17 oncocytomas (63% sensitivity, 84% specificity, 88% positive predictive value for chromophobe renal cell carcinoma). Negative claudin-7 and cytoplasmic claudin-8 were observed in 10 of 17 oncocytomas and 0 of 11 chromophobe renal cell carcinomas (59% sensitivity, 100% specificity and positive predictive value for oncocytoma). The distal nephron proteins claudin-7 and claudin-8 have potential use as immunohistochemical biomarkers in the differential diagnosis of chromophobe renal cell carcinoma and oncocytoma. Expression of claudin-7 and claudin-8 may reflect the relationship of chromophobe renal cell carcinoma and oncocytoma to intercalated cells of the cortical collecting duct. It may be necessary to identify additional biomarkers to include with claudin-7 and claudin-8 in a larger immunohistochemical panel to improve diagnostic sensitivity and specificity.     

Fluorescence in situ hybridization as an adjunct tool in the diagnosis of primary and metastatic renal cell carcinoma in fine needle aspiration specimens

We investigated the role of fluorescence in situ hybridization (FISH) in the diagnosis of primary renal neoplasms and lesions suspicious for metastatic renal cell carcinoma. Consecutive fine‐needle aspiration biopsies (FNAB) of 39 renal masses and 41 metastatic tumours suspicious for renal cell origin were assessed with an immunohistochemical panel for CK7, RCC antigen, CD10, AMACR, PAX8, vimentin, and CD117. In addition, FISH was performed using probes for chromosomes 1p, 3p, 7, 17, X, and Y. A total of 31 of 39 primary renal masses and 33 of 41 metastatic tumors suspicious for renal origin demonstrated typical cytological and immunohistochemical (IHC) features of subtypes of renal neoplasms (40 clear cell renal cell carcinoma (RCC), 20 papillary RCC, and 4 renal oncocytomas). FISH analysis of 15 randomly selected cases each of primary and metastatic lesions revealed chromosomal abnormalities consistent with the diagnosis in 73% of these cases. Of 8 primary renal masses demonstrating atypical microscopic features and noncontributory IHC profiles, FISH was helpful in subtyping 5 (62%) of these lesions (2 clear cell RCC, 1 solid variant of oncocytic papillary RCC, 1 mixed clear cell and papillary RCC, and 1 chromophobe RCC with papillary architecture). Of 8 metastatic tumors clinically suspicious for renal cell origin and supportive, but nondiagnostic IHC, FISH revealed supportive chromosomal changes in 6 (75%) cases. In conclusion FISH analysis on FNAB material, even with limited tissue, may be contributory to the diagnosis and subtyping of RCC in diagnostically challenging biopsies. Diagn. Cytopathol. 2014;42:1013–1023. © 2014 Wiley Periodicals, Inc.     

肾损伤因子-1在肾上皮性肿瘤中的表达及临床意义

目的 明细胞癌、乳头状肾细胞癌、肾嫌色细胞癌、Xp11.2易位/TFE3基因融合相关性肾癌和转移性透明细胞癌中的表达率分别是77.8%(49/63)、90.9%(20/22)、1/13、7/7和87.5%(21/24),7例嗜酸细胞腺瘤均阴性.在原发性肾透明细胞癌中,KIM-1弥漫阳性表达更易发生于Furhman细胞核Ⅲ/Ⅳ级的病例(P=0.010).肾特异性钙黏蛋白主要表达于嫌色细胞癌和嗜酸细胞腺瘤.结论 KIM-1仅表达于损伤的近曲小管和由其起源的肿瘤,对原发性和转移性肾透明细胞癌、乳头状肾细胞癌及Xp11.2易位/TFE3基因融合相关性肾癌具有高度的特异性和敏感性,与肾特异性钙黏蛋白合用可以提高原发性肾脏上皮性肿瘤组织学分类的准确性和转移性肾透明细胞癌的诊断率.     

Prognostic value of keratin subtyping in transitional cell carcinoma of the upper urinary tract

To investigate the prognostic value of keratin subtyping in invasive transitional cell carcinomas (TCCs), we performed a systematic study applying 15 different monoclonal keratin antibodies on 53 upper urinary tract TCCs using a tissue microarray technique. Immunoreactivity was correlated with pT stages and tumour grades using the Fishers exact test. Impact on disease-free survival was analysed using the Kaplan-Meier method and compared by the log-rank test. Immunoreactivity for keratins 5/6, 6, 7, 8, 13, 14, 17, 18, 19, 20, low molecular weight (LMW) keratins (8, 18) and high molecular weight (HMW) keratins (1, 5, 10, 14) was detected in varying quantities. Regarding semi-quantitative assessment, a prognostic impact was found for keratins 5/6, 7, 8, 13, 17, 20 and HMW keratins, with reduced expression or loss of immunoreactivity being significantly associated with disease progression. With respect to analysis of staining patterns, the retention of a basally accentuated labelling for keratin 5/6 and HMW keratin as well as a superficially accentuated labelling for keratin 20 was significantly associated with a favourable outcome. In conclusion, this investigation is the first to demonstrate a possible prognostic value for keratin subtyping in invasive (upper urinary tract) TCCs with respect to metastasis-free survival. Further studies, however, are needed to substantiate our results.     

The diagnostic utility of MOC31, BerEP4, RCC marker and CD10 in the classification of renal cell carcinoma and renal oncocytoma: an immunohistochemical analysis of 328 cases

AIMS: To demonstrate the diagnostic utility of MOC31, BerEP4, renal cell carcinoma marker (RCC Ma) and CD10 in the classification of RCC and renal oncocytoma, based upon a comprehensive immunohistochemical analysis. METHODS AND RESULTS: Immunohistochemistry was performed on 328 samples consisting of 256 clear cell/conventional, 27 papillary, 28 chromophobe, five collecting duct, five unclassified RCCs and seven renal oncocytomas using antibodies MOC31, BerEP4 and antibodies against cytokeratins (KL-1, CAM5.2, 34betaE12, cytokeratin 7), RCC Ma, epithelial membrane antigen, E-cadherin, CD10, CD15 and vimentin. Multivariate analysis showed that MOC31, BerEP4, RCC Ma and CD10 have discriminatory value. MOC31 and BerEP4 chiefly labelled distal tubules of normal kidney while RCC Ma and CD10 labelled the proximal tubules. Twenty-three chromophobe RCCs (82%) were reactive for MOC31, while only four clear cell RCCs and three papillary RCCs were positive for this marker. Clear cell RCCs were characterized by a high positive rate for CD10 (82%) and a low positive rate for BerEP4 (27%). Papillary RCCs frequently coexpressed RCC Ma and BerEP4 (51%). All renal oncocytomas were negative for MOC31 and CD10. CONCLUSIONS: MOC31 has diagnostic merit in discerning chromophobe RCC. The CD10+/BerEP4- profile and RCC Ma+/BerEP4+ profile achieve moderate sensitivity and good specificity for clear cell RCC and papillary RCC, respectively. The non-reactivity for both MOC31 and CD10 is helpful in distinguishing renal oncocytoma from RCC. When properly selected, antibodies have immunohistochemical diagnostic utility for the classification of renal cortical epithelial tumours.     

Cytogenetic analysis of six renal oncocytomas and a chromophobe cell renal carcinoma. Evidence that -Y, -1 may be a characteristic anomaly in renal oncocytomas.

Renal oncocytomas are benign tumors whose morphologic features may sometimes be confused with those of certain low-grade malignant neoplasms of the kidney, e.g., chromophobe cell and granular cell variants of renal carcinoma. The presence of a specific genetic abnormality might help differentiate these tumors. Because very few cytogenetic studies of renal oncocytomas have been published, we investigated a consecutive series of six such tumors. We also performed chromosome analysis on a chromophobe cell carcinoma because cytogenetic analyses of this tumor have not been previously reported. Tumor cell metaphases were analyzed after mechanical and enzyme disaggregation, in situ culture, and robotic harvesting. Clonal abnormalities were present in five of the six oncocytomas, and loss of chromosome 1 with loss of the Y chromosome occurred in two. Review of the literature disclosed four other renal oncocytomas with the 44,X,-Y,-1 karyotype. In the chromophobe cell carcinoma, we noted an abnormal clone with a del(11)(p12p15.1); similar anomalies were not observed in the renal oncocytomas. We conclude that renal oncocytomas have clonal chromosome abnormalities and that a subgroup of these tumors may be specifically associated with loss of chromosomes 1 and Y. Because this is a small series, further investigation may help establish whether cytogenetic studies can provide diagnostic and pathogenic information about renal oncocytomas.     

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).     

Mismatch repair genes in renal cortical neoplasms

Mutation of human mutL homolog 1 (MLH-1) and human mutS homolog 2 (MSH-2) has been linked with the pathogenesis of colorectal carcinoma in hereditary nonpolyposis colorectal cancer syndrome and other carcinomas. Mutations of these genes in renal cell carcinomas were recently described. The aim of this study was to examine the expression of MLH-1 and MSH-2 in renal cortical neoplasms of various histological types by immunohistochemistry. Thirty-eight (n = 38) resected renal tumors were obtained from the surgical pathology files of the UMass Memorial Healthcare, including clear cell carcinomas (CLEARs, n = 20), papillary carcinomas (PAPs, n = 8), chromophobe carcinomas (CHRs, n = 4), and oncocytomas (ONCs, n = 6). Positive immunostaining for MLH-1 and MSH-2 was graded by the number of positive tumor cell nuclei, as follows: 0, negative; 1, up to one third of positive nuclei; 2, one to two thirds positive; and 3, greater than two thirds positive. Loss of MLH-1 or MSH-2 was defined as a tumor with grade 0 or 1, compared with the normal tubules. Normal tubules and intercalated ducts contained cells positive for MLH-1 and MSH-2 in all cases. For both antibodies, positive staining in tumors ranged from grade 1 to 3 in the CLEAR and PAP but was only grade 2 to 3 in the CHR and ONC. Loss of MLH-1 and/or MSH-2 occurred in malignant tumors but not in ONC. Loss of MLH-1 was present in 8 (40%) of 20 CLEARs and 4 (50%) of 8 PAPs, compared with loss of MSH-2 in 4 (20%) of 20 CLEARs and 1 (25%) of 4 CHRs. Our results suggest that loss of mismatch repair genes is involved in the malignant transformation in some renal carcinomas, particularly those derived from the proximal tubules.     

Overexpression of KIT (CD117) in chromophobe renal cell carcinoma and renal oncocytoma

KIT expression has not been studied substantially in renal tumors. We analyzed the immunohistochemical expression for KIT in 256 conventional renal cell carcinomas (RCCs), 29 chromophobe RCCs, 25 papillary RCCs, 6 collecting duct RCCs, 6 unclassified RCCs, 7 renal oncocytomas, 20 urothelial carcinomas, 7 nephroblastomas, and 23 angiomyolipomas. We found that 24 chromophobe RCCs (83%) and 5 renal oncocytomas (71%) revealed membranous immunoreactivity for KIT while none of the RCCs of other types expressed KIT immunohistochemically. Sporadic cases of urothelial carcinoma and nephroblastoma were focally positive for KIT. All angiomyolipomas were negative. Genomic DNA extracted from the chromophobe RCCs and renal oncocytomas was submitted for polymerase chain reaction and direct sequencing of the juxtamembrane (exons 9 and 11) and tyrosine kinase (exons 13 and 17) domains. No mutation was found. Our results demonstrate that KIT could be a useful immunophenotypic marker for chromophobe RCC and renal oncocytoma; therefore, it has value for the precise classification of renal cortical epithelial tumors. However, the therapeutic relevance of KIT overexpression in these tumors is uncertain owing to the lack of mutations that would lead to constitutive activation of the protein.     

Primary collision tumors of the kidney composed of oncocytoma and papillary renal cell carcinoma: A review

BackgroundThere are well known cases of hybrid tumors of chromophobe renal cell carcinoma (RCC) and oncocytoma in kidney, where both tumors have the same cell of origin – intercalated cell of the collecting duct. However, collision tumors composed of neoplasms originating from different cell lineages such as oncocytoma and papillary RCC are extremely rare. Herein, we made a collective literature review of reported cases of collision tumors composed of oncocytoma and papillary RCC, adding a case that we recently experienced.Material and methodsA PubMed database was search for collision tumors of the kidney composed of oncocytoma and papillary RCC and a collective literature review was made. To this cohort, we also added a recently encountered case with similar, confirmed by immunohistochemistry, morphological features.ResultsTo date 8 cases of a collision tumor composed of papillary RCC and oncocytoma have been described in the literature. All of them had a smaller papillary RCC component present within a larger oncocytoma.ConclusionBecause of a few cases of such a collision tumors reported, it is difficult to make classification and right clinical management of these patients. None of the reported cases had tumor recurrence or progression on a follow-up. The presence of only small portion of papillary RCC in a large oncocytoma raises a possibility of under-sampling of malignant component in large oncocytomas in core biopsy or surgically resected specimens. We recommend better sampling, particularly at the periphery of otherwise classic oncocytomas to unveil this possible association.