Carbonic anhydrase IX expression in renal neoplasms: correlation with tumor type and grade

Carbonic anhydrase IX (CAIX), a hypoxia-induced protein, is expressed in some renal tumors. We evaluated its immunohistochemical expression in 317 primary and 42 metastatic renal neoplasms (186 clear cell, 52 papillary, 35 chromophobe, 47 unclassified, and 15 Xp11.2 translocation renal cell carcinomas [RCCs]; 26 oncocytomas; 2 metanephric adenomas; 1 urothelial carcinoma; 1 mixed epithelial and stromal tumor; and 1 angiomyolipoma); 7 neoplasms were unknown as to whether they were primary or metastatic. We also correlated expression with tumor type and grade. Variable staining was seen in clear cell, papillary, unclassified, and Xp11.2 translocation carcinomas. One chromophobe carcinoma had focal expression. No staining was seen with other tumors. An association was found between high expression and clear cell vs non-clear cell carcinomas with all cases (P < .01) and primary (P < .01) cases. An association between CAIX expression and grade (P < .01) in primary clear cell carcinomas was found. CAIX expression is more common in clear cell RCC than other renal tumor types and is associated with grade.     

Role of carbonic anhydrase IX, α-methylacyl coenzyme a racemase,cytokeratin 7, and galectin-3 in the evaluation of renal neoplasms: a tissue microarray immunohistochemical study

Kidney tumors of various types may behave differently and have different prognosis. Because of some overlapping morphological features and immunohistochemical staining pattern, they may pose diagnostic challenge. Therefore, it is necessary to explore additional immunohistochemical stains to help classifying these epithelial neoplasms. Tissue microarrays of 20 cases each of renal cell carcinomas of clear cell, chromophobe, and papillary variants and oncocytoma were constructed and used to test a panel of immunohistochemical markers including carbonic anhydrase IX, galectin-3, cytokeratin 7 (CK7), and α-methylacyl coenzyme a racemase. Carbonic anhydrase IX was highly sensitive for clear cell renal cell carcinoma (90% positivity) and was negative in all other renal epithelial tumors except for 1 chromophobe renal cell carcinoma (chRCC). Expression of galectin-3 was found mostly in renal tumors with oncocytic features, including oncocytomas (100%) and chRCCs (89%). α-Methylacyl coenzyme a racemase was positive in papillary renal cell carcinoma (100%). CK7 was positive in papillary renal cell carcinoma (90%), chRCC (89%), and oncocytoma (90%). Although both chRCC and oncocytoma were positive for CK7, but with a different patterns, CK7 staining in chRCC was diffuse, whereas it was sporadic in oncocytoma. Panel of carbonic anhydrase IX, galectin-3, CK7, and α-methylacyl coenzyme a racemase is sensitive and specific for the differential diagnosis of the renal epithelial tumors.     

The expanding role of renal mass biopsy

Usage of renal mass biopsy has increased in recent years, ranging from selected clinical scenarios to routine implementation in some institutions. Major tasks for the field of diagnostic histopathology include discriminating primary renal cell cancers from other tumors, especially metastases, hematolymphoid tumors, and urothelial carcinoma. Within primary renal cell neoplasms, relevant distinctions include recognizing clear cell papillary renal cell carcinoma, which despite its resemblance to clear cell cancer is nonaggressive, as well as discriminating oncocytoma from chromophobe carcinoma. Helpful immunohistochemical markers include PAX8 for verification of primary renal cell lineage and carbonic anhydrase IX for support of clear cell subtype. Cytokeratin 7 is generally considered the best marker for discriminating oncocytoma from chromophobe renal cell carcinoma, showing only rare positive cells in oncocytoma and greater staining in chromophobe carcinoma. For metastatic tumors, attempting to discriminate clear cell from non-clear cell types may be important for treatment selection.     

Useful immunohistochemical panel for differentiating clear cell papillary renal cell carcinoma from its mimics

Clear cell papillary renal cell carcinoma (CCPRCC) is a recently described low-grade renal cell tumor. In this study, we investigated the expression of paired box 8 (PAX-8), carbonic anhydrase IX (CA IX), CK7, and α-methylacyl-CoA-racemase (AMACR) in this tumor by immunohistochemistry in a group of 20 cases of CCPRCC. Clear cell papillary renal cell carcinoma showed diffuse (70%) or intermediate (30%) nuclear positivity for PAX-8 in each case, with predominantly moderate intensity (50%). Ninety percent of the cases showed some degree of cytoplasmic staining for CA IX, predominantly with moderate intensity (50%). In addition, each case of CCPRCC also showed diffuse membranous staining for CK7. Most CCPRCCs (95%) were negative for AMACR. PAX-8, CA IX, CK7, and AMACR comprise a concise panel for distinguishing CCPRCC from its mimics. PAX-8 positivity helps to confirm the renal origin of this tumor. Positivity for CA IX and CK7 differentiate CCPRCC from conventional clear cell renal cell carcinoma, which is usually CA IX positive while CK7 negative. The CK7-positive and AMACR-negative pattern seen in CCPRCC differentiates it from papillary renal cell carcinoma, which is usually positive for both AMACR and CK7.     

Analysis of insulin-like growth factors and insulin-like growth factor I receptor expression in renal cell carcinoma

The expression of insulin-like growth factors I (IGF-I) and II (IGF-II) and insulin-like growth factor-I receptor (IGF-IR) was studied in 137 clear cell, 23 chromophobe, and 20 papillary renal cell carcinomas (RCCs) using a tissue microarray technique. IGF-I immunoreactivity was detected in 110 (82.1%) of 134 clear cell, 8 (36%) of 22 chromophobe, and 3 (15%) of 20 papillary RCCs (P < .001). IGF-IR immunoreactivity was detected in 39 (29.5%) of 132 clear cell, 9 (41%) of 22 chromophobe, and 19 (95%) of 20 papillary RCCs (P < .001). In contrast, all tumors lacked IGF-II expression. Expression of IGF-I and IGF-IR was not related to tumor stage, grade, or prognosis. The IGF system is expressed differentially among different tumor types. The expression of IGF-I together with its receptor, IGF-IR, provides evidence for the existence of an autocrine-paracrine loop of tumor cell stimulation in RCC and makes this type of cancer a candidate for therapeutic strategies aimed to interfere with the IGF pathway.     

Expression of carbonic anhydrase IX,PAX2 and PAX8 and their association with clinicopathologic characteristics in renal epithelial tumors北大核心CSCD

Objective: To study the expression of carbonic anhydrase IX (CAIX), PAX2 and PAX8 in different types of renal epithelial tumor and their association with clinicopathologic characteristics. Methods: Immunohistochemical study by EnVision method was performed in order to assess the expression of CAIX, PAX2 and PAX8 in 155 cases of renal cell carcinoma and 4 cases of metastatic clear cell renal cell carcinoma (CCRCC). Ninety-six cases of non-neoplastic renal parenchymal tissue adjacent to CCRCC, 8 cases of clear cell hepatocellular carcinoma and 2 cases of clear cell hidradenoma were used as controls. Results: CAIX was commonly expressed in CCRCC (94. 0%, 63/67), of which 77. 8% (49/63) showed strong positivity. CAIX was focally positive in papillary renal cell carcinoma, collecting duct carcinoma and urothelial carcinoma of renal pelvis. It was negative in chromophobe renal cell carcinoma, oncocytoma and adjacent non-neoplastic renal tissue. CAIX was also strongly expressed in the 4 cases of metastatic CCRCC. Focal expression of CAIX was demonstrated in the 8 cases of clear cell hepatocellular carcinoma and 2 cases of clear cell hidradenoma. The expression of CAIX in CCRCC did not correlate with tumor grading, clinical staging and presence of distal metastasis. On the other hand, PAX2 showed positive expression in different types of renal epithelial tumor, clear cell hepatocellular carcinoma and clear cell hidradenoma in various degrees. In contrast, PAX8 was commonly expressed in all types of renal epithelial tumor, with the exception of urothelial carcinoma of renal pelvis. PAX8 was not expressed in clear cell hepatocellular carcinoma and clear cell hidradenoma. Regarding diagnosis of CCRCC, CAIX demonstrated high sensitivity and specificity. PAX2 showed high specificity but low sensitivity. PAX8 was sensitive and specific in the diagnosis of renal epithelial tumor. Conclusions: CAIX is a useful immunohistochemical marker with high specificity and sensitivity in distinguishing CCRCC from other types of renal epithelial tumor and clear cell tumors of non-renal origin. PAX2 is a marker with high sensitivity and low specificity for diagnosis of renal epithelial tumors. PAX8 is typically expressed in renal epithelial tumors. The combined detection of CAIX, PAX2 and PAX8 is useful in the diagnosis and differential diagnosis of renal epithelial tumors.     

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.     

Expression of carbonic anhydrase IX in genitourinary and adrenal tumours

Donato D P, Johnson M T, Yang X J & Zynger D L
(2011) Histopathology  59 , 1229–1239
Expression of carbonic anhydrase IX in genitourinary and adrenal tumours Aims: High expression of carbonic anhydrase IX (CAIX) is reported for clear cell renal cell carcinoma (RCC), with a paucity of data for non‐renal genitourinary or adrenal tumours. This study investigated the immunohistochemical expression of CAIX throughout the genitourinary tract and adrenal gland. Methods and results: High expression in the renal cortex was restricted to clear cell, papillary and clear cell papillary RCC and carcinoid. Core biopsies of clear cell RCC were consistently positive. Positivity within the urothelial tract was seen in urothelial carcinoma including squamous, small‐cell, sarcomatoid and adenomatous differentiation and clear cell adenocarcinoma. Signet ring and plasmacytoid variants of urothelial carcinoma were negative. Phaeochromocytoma, adrenal cortical adenoma, seminoma, yolk sac tumour, choriocarcinoma, Leydig cell tumour and prostatic adenocarcinoma were predominately negative, with variable reactivity in adrenal cortical carcinoma, embryonal carcinoma, teratoma and Sertoli cell tumour. Conclusions: Carbonic anhydrase IX is a sensitive marker for clear cell RCC in core biopsies. However, other genitourinary or adrenal tumours that can have a clear cell appearance including urothelial, squamous cell, clear cell adeno and adrenal cortical carcinoma and Sertoli cell tumour express CAIX. Knowledge of expression overlap between these entities may prevent incorrect interpretation of immunohistochemical results, particularly if limited tissue is available.     

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.     

Expression of claudin-7 in benign kidney and kidney tumors

Claudins, a family of tight junction-related transmembrane proteins, have been implicated in the pathogenesis of various human neoplasms. Expression of claudin-7 was increased in chromophobe renal cell carcinoma in a recent oligonucleotide microarray study. We studied the expression of claudin-7 in benign and neoplastic kidneys by immunohistochemical staining. Distal nephron (distal convoluted tubule and thick ascending limb of Henle's loop) epithelium showed strong membranous staining in 100% (174/174) of the cases. Chromophobe renal cell carcinoma was positive for claudin-7 expression in 100% (36/36) of cases, while papillary renal cell carcinoma, oncocytoma and clear cell renal cell carcinoma were positive in 90% (71/80), 45% (21/47) and 7% (7/98) of the cases, respectively. Differential expression of Claudin-7 in different types of renal cell neoplasms can be useful in their differential diagnosis, particularly when used in a panel of markers. In addition, results from this study support previous reports of distal nephron origin for chromophobe renal cell carcinoma and oncocytoma. The data also suggest that, as far as claudin-7 expression is concerned, papillary renal cell carcinoma may be more closely related to the distal nephron, rather than the proximal nephron.     

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.     

CD10 is expressed in a subset of chromophobe renal cell carcinomas.

CD10 has been considered a useful marker in the diagnosis of renal carcinomas, because of its expression in clear cell and papillary renal cell carcinomas and its absence in chromophobe renal cell carcinomas. On the other hand, chromophobe renal cell carcinoma expresses parvalbumin, which is absent in clear cell and papillary renal cell carcinomas. To further address the relevance of these markers, we studied the expression of CD10 and parvalbumin in 42 samples of chromophobe renal cell carcinoma (seven of which had aggressive features, including invasion beyond the renal capsule, renal vein invasion, metastases, or sarcomatoid transformation), 75 clear cell renal cell carcinomas (eight metastatic) and 51 papillary renal cell carcinomas (two metastatic). CD10 was found in 100% of clear cell renal cell carcinomas, 63% of papillary renal cell carcinomas and in all metastatic cases of both types. At variance with previous studies, we found CD10 expression in from 30 to 90% of the neoplastic cells, in 11 of 42 (26%) chromophobe renal cell carcinomas. The CD10-positive cases included five of the seven (71%) chromophobe renal cell carcinoma with aggressive features. Statistical analysis showed significant association of CD10-positive tumors with clinicopathologic aggressiveness (P=0.003) and mitotic figures (P=0.04). Parvalbumin was strongly expressed in all primary and metastatic chromophobe renal cell carcinomas. Western blot analysis was utilized to confirm the expression of both CD10 and parvalbumin in chromophobe renal cell carcinomas.     

Expression of prostate-specific membrane antigen in renal cortical tumors.

Prostate-specific membrane antigen is a type II membrane glycoprotein that is expressed in benign and neoplastic prostatic tissue and has been recently shown to be also expressed in the neovasculature of various solid malignant tumors including renal cell carcinoma. Renal cell carcinoma is a heterogeneous group of tumors with distinct morphologic and genetic characteristics and clinical behaviors. We performed immunohistochemical studies on formalin-fixed, paraffin-embedded archival material from 75 nephrectomies, using antibodies 13D6 against prostate-specific membrane antigen and CD31 against endothelial cells. The study included 30 clear cell renal cell carcinomas, and 15 of each of papillary and chromophobe renal cell carcinoma and oncocytoma. The extent and intensity of staining were assessed semiquantitatively. In all cases, immunoreactivity was detected only in the tumor-associated neovasculature and not in tumor cells. Clear cell renal cell carcinoma showed the most diffuse staining pattern, where 24/30 cases or 80% had >50% reactive vessels, followed by chromophobe renal cell carcinoma (9/15; 60%) and oncocytoma (5/15, 33%). No diffuse staining was detected in any of the papillary renal cell carcinomas and only focal staining was detected in 11 cases (11/15; 73%). Staining intensity was the strongest in clear cell renal cell carcinoma (25/30; 83%) followed by chromophobe renal cell carcinoma (9/15; 60%), oncocytoma (8/15, 53%) and papillary renal cell carcinoma (5/15; 33%). In summary, prostate-specific membrane antigen is expressed in tumor-associated neovasculature of the majority of renal cortical tumors and is most diffusely and intensely expressed in clear cell renal cell carcinoma and least in papillary renal cell carcinoma. The differences in the expression of prostate-specific membrane antigen in renal cell carcinoma subtypes provide further evidence of the biological diversity of these tumors, and diagnostic and therapeutic applications of such expression can be expanded to include subtypes of renal cell carcinoma.     

Recent advances of immunohistochemistry for diagnosis of renal tumors

The recent classification of renal tumors has been proposed according to genetic characteristics as well as morphological difference. In this review, we summarize the immunohistochemical characteristics of each entity of renal tumors. Regarding translocation renal cell carcinoma (RCC), TFE3, TFEB and ALK protein expression is crucial in establishing the diagnosis of Xp11.2 RCC, renal carcinoma with t(6;11)(p21;q12), and renal carcinoma with ALK rearrangement, respectively. In dialysis‐related RCC, neoplastic cells of acquired cystic disease‐associated RCC are positive for alpha‐methylacyl‐CoA racemase (AMACR), but negative for cytokeratin (CK) 7, whereas clear cell papillary RCC shows the inverse pattern. The diffuse positivity for carbonic anhydrase 9 (CA9) is diagnostic for clear cell RCC. Co‐expression of CK7 and CA9 is characteristic of multilocular cystic RCC. CK7 and AMACR are excellent markers for papillary RCC and mucinous tubular and spindle cell carcinoma. CD82 and epithelial‐related antigen (MOC31) may be helpful in the distinction between chromophobe RCC and renal oncocytoma. WT1 and CD57 highlights the diagnosis of metanephric adenoma. The combined panel of PAX2 and PAX8 may be useful in the diagnosis of metastatic RCC.     

肾脏特异性钙黏蛋白在肾上皮性肿瘤的表达及其临床病理意义

目的探讨肾脏特异性钙黏蛋白（Ksp—cadherin）的新抗体在肾细胞癌和肾嗜酸细胞腺瘤中的表达意义。方法收集166例肾脏肿瘤标本,其中肾原发性透明细胞癌120例、乳头状肾细胞癌20例（I型乳头状肾细胞癌15例,Ⅱ型乳头状肾细胞癌5例）、嫌色细胞癌18例、嗜酸细胞腺瘤8例。使用Ksp—cadherin、CD10、波形蛋白、上皮细胞膜抗原（EMA）、CK7进行免疫组织化学（EnVision法）染色。结果Ksp-cadherin的表达率分别是透明细胞癌23％（27／120）,乳头状肾细胞癌20％（4／20）,嫌色细胞癌18／18,嗜酸细胞腺瘤6／8。CD10、波形蛋白在透明细胞癌和乳头状肾细胞癌有高表达,CK7主要表达于嫌色细胞癌和乳头状肾细胞癌,EMA在这4种肿瘤均有高表达。此外,CDl0在肾嫌色细胞癌中也有表达,但其表达于胞质,而在其他肿瘤的表达在细胞膜。Ksp—cadherin在肾透明细胞癌的表达程度与其分期分级呈正相关。结论Ksp—cadherin局限表达于远端肾小管及其起源的肾脏肿瘤。在嫌色细胞癌和嗜酸细胞腺瘤中有高度的特异和敏感性,在透明细胞癌中的表达和分期分级有关,在肾脏常见的上皮性肿瘤中具有鉴别诊断和预后价值。     

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.     

A renal cell carcinoma with components of both chromophobe and papillary carcinoma

We report a case of a morphologically unusual renal cell carcinoma with features of both chromophobe and papillary carcinoma. Immunohistochemical analysis of high molecular weight cytokeratins (HMWCK), cytokeratin 7 (CK7), cytokeratin 19 (CK19), c-Kit, and α-methylacyl-CoA racemase (AMACR) demonstrated differential profiles for the two components of the tumor, consistent with the respective patterns commonly observed for pure chromophobe and papillary renal cell carcinomas. Specifically, the chromophobe tumor cells expressed CK7 and c-Kit weakly, while HMWCK, CK19, and AMACR were not detectable. In contrast, the papillary tumor cells expressed uniformly HMWCK, CK7, and c-Kit and focally CK19 and AMACR. Fluorescence in situ hybridization analysis of nuclei isolated from paraffin-embedded tumor tissue detected monosomy 1, disomy 7, and monosomy 17, a common and characteristic finding in chromophobe carcinomas, in a majority of, but not all tumor cells, whereas a population characterized by disomy 1, trisomy 7, and trisomy 17, a frequent finding in papillary carcinoma, was not identifiable. Electron microscopic analysis revealed numerous characteristic small cytoplasmic vesicles in the chromophobe areas, which were absent in the papillary component. This case illustrates the rare coexistence of two distinct and admixed histologic types of renal cell carcinoma.     

Chromophobe renal cell carcinoma,eosinophilic variant with papillary growth: a case report

We report the case of an 80-year-old man who presented with pathologically diagnosed chromophobe renal cell carcinoma composed of eosinophilic cells with partial papillary growth. The patient had a 2.5 cm diameter renal mass incidentally detected by abdominal ultrasound examination. Laparoscopic left partial nephrectomy was performed under a diagnosis of left renal tumor. Histopathology demonstrated uniform eosinophilic cuboidal cells growing with a partially papillary pattern: differential diagnosis of oncocytoma, papillary renal cell carcinoma, or oncocytic papillary renal cell carcinoma was necessary. Immunohistochemical staining with anti-monoclonal antibody 31 and -CD82 antibody, and choroid iron staining, were positive. Cytogenetic analysis by comparative genomic hybridization showed gains of chromosomes 1p, 9q, 19q, 20, and 21q, and losses of chromosomes 1p and q, 2q, 6q and 7q, leading to diagnosis of chromophobe RCC. We describe differential diagnosis for chromophobe renal cell carcinoma, eosinophilic variant, growing in a papillary fashion in the kidney.