The Golgi apparatus is an organelle where membrane or secretory proteins receive post-translational modifications such as glycosylation and sulfation, after which the proteins are selectively transported to their final destinations through vesicular transport. When the synthesis of secretory or membrane proteins is increased and overwhelms the capacity of the Golgi (Golgi stress), eukaryotic cells activate a homeostatic mechanism called the Golgi stress response to augment the capacity of the Golgi. Four response pathways of the Golgi stress response have been identified, namely the TFE3, CREB3, HSP47, and proteoglycan pathways, which regulate the general function of the Golgi, apoptosis, cell survival, and proteoglycan glycosylation, respectively. Here, we identified a novel response pathway that augments the expression of glycosylation enzymes for mucins in response to insufficiency in mucin-type glycosylation in the Golgi (mucin-type Golgi stress), and we found that expression of glycosylation enzymes for mucins such as GALNT5, GALNT8, and GALNT18 was increased upon mucin-type-Golgi stress. We named this pathway the mucin pathway. Unexpectedly, mucin-type Golgi stress induced the expression and activation of TFE3, a key transcription factor regulating the TFE3 pathway, suggesting that the activated mucin pathway sends a crosstalk signal to the TFE3 pathway. We identified an enhancer element regulating transcriptional induction of TFE3 upon mucin-type Golgi stress, and named it the mucin-type Golgi stress response element, of which consensus was ACTTCC(N9)TCCCCA. These results suggested that crosstalk from the mucin pathway to the TFE3 pathway has an important role in the regulation of the mammalian Golgi stress response. Key words: Golgi stress; mucin; TFE3; organelle autoregulation; organelle zone.

Translocation renal cell carcinomas (TFE3 RCC) are associated with variable genetic rearrangements of the TFE3 gene on chromosome Xp11.2. Translocation tumors represent 1% to 5% of all cases of RCC, with the greatest frequency among children and young adults. We sought to characterize the clinicopathologic features of translocation RCC at a Middle Eastern institution.

The clinical and pathologic data from a single institution were retrospectively reviewed. A total of 14 patients with translocation RCC had been diagnosed from 2005 to 2014. The outcome measures included patient characteristics, clinical manifestations, pathologic features, treatment outcomes, cancer-specific survival, and progression-free survival.

The mean age at diagnosis was 35 years. Of the 14 patients, 5 were female. Translocation RCC was an incidental diagnosis for all but 2 of the 14 patients. The mean tumor size was 9 cm; 1 patient had bilateral tumors, and 3 presented with positive lymph nodes. Three patients underwent partial nephrectomy. Three patients had developed metastasis at 4 months, 5 months, and 3 years after diagnosis. One patent had died 4 months after surgery and one had died 21 months after surgery (both of metastases). The disease-free survival rate was 71% at a mean follow-up of 31 months.

Translocation RCC is a rare and potentially aggressive subtype of kidney cancer. An overall survival of>> 3 years has been noted, unless metastasis is present at diagnosis.

The transcription factor for immunoglobulin heavy-chain enhancer 3 (TFE3) gene encodes a transcription factor that regulates embryonic stem cell (ESC) differentiation. Its phosphorylation by the lysosomal Rag GTPase signaling pathway leads to cytoplasmic sequestration and inactivation promoting ESC differentiation and exit from pluripotency. Somatic translocations of this X-linked gene cause papillary renal cell carcinoma in which nuclear accumulation of the TFE3 oncoprotein is one of the most significant histopathologic characteristics. Early this year, Villegas et al. identified missense mutations in a TFE3 domain required for cytoplasmic inactivation as potentially causal for a mosaic human developmental disorder. They published five patients with de novo TFE3 nonsynonymous missense variants, four females and one male, with severe intellectual disability (5/5), coarse facial features (4/5), and Blaschkoid pigmentary mosaicism (4/5). The only male described has somatic mosaicism. All patients had normal brain Magnetic Resonance Imagings (MRIs). We present two unrelated females with this distinctive phenotype including the above triad along with other features not previously well described. Both were found to have de novo heterozygous variants in TFE3 on whole exome sequencing, one nonsynonymous missense, and one canonical splice site variant, thereby expanding the phenotypic and mutational spectrum for this disorder. Interestingly, due to significant coarsening of the facial features, both patients were initially thought to have a lysosomal storage disorder but enzyme screening and brain MRIs were negative.

The microphthalmia (MiT) subfamily of transcription factors includes TFE3, TFEB, TFEC, and MITF. In the 2016 World Health Organization classification, MiT family translocation renal cell carcinoma (tRCC) including Xp11 tRCC and t(6;11) RCC, was newly defined as an RCC subtype. Xp11 and t(6;11) RCC are characterized by the rearrangement of the MiT transcription factors TFE3 and TFEB, respectively. Recent studies identified the fusion partner-dependent clinicopathological and immunohistochemical features in TFE3-rearranged RCC. Furthermore, RCC with TFEB amplification, melanotic MiT family translocation neoplasms, was identified may as a unique subtype of MiT family associated renal neoplasms, along with MITF associated RCC. In this review, we will collect available literature of these newly-described RCCs, analyze their clinicopathological and immunohistochemical features, and summarize their molecular and genetic evidences. We expect this review would be beneficial for the understanding of these rare subtypes of RCCs, and eventually promote clinical management strategies.

Metastases to the breast are uncommon, accounting for 0.5% of breast tumors, and most of them are originated from lymphoma, melanoma and carcinomas of various organs. Alveolar soft part sarcoma (ASPS) is a very rare neoplasm that is usually found in the lower extremities. Lungs are the common site of dissemination and may represent initial manifestation of disease. We report a clinically unsuspected case of ASPS presenting as a breast metastasis in a 25-year-old woman. The patient's medical history was notable for a thyroid cancer treated by surgery and radioiodine ablation 2 years ago. Core needle biopsy of slowly growing breast mass yielded polygonal cells with abundant eosinophilic cytoplasm arranged into solid pattern. Differential diagnosis between apocrine cell carcinoma, paraganglioma, granular cell tumor, neuroendocrine carcinoma, ASPS and metastatic hepatocellular and renal cell carcinoma was rendered by immunohistochemistry. Strong nuclear TFE3 immunoreactivity confirmed a diagnosis of ASPS. Retrospectively a primary tumor was found in the thigh. Most likely, ASPS and thyroid cancer in the patient were growing synchronously and independently.

Alveolar soft part sarcoma (ASPS) is a distinct type of soft tissue sarcoma holding a specific ASPL-TFE3 fusion transcript. Curative therapy is based on surgical removal, whereas lately, antiangiogenic targeted therapy regimens have proven effective. In ASPS, analysis of small series additionally display mTOR (mammalian target of rapamycin) pathway activity, thus making mTOR a possible additive target in ASPS, because it is in other tumor entities. Therefore, we systematically evaluated mTOR pathway activity in a large series of ASPS in comparison with soft tissue sarcomas of other differentiation (non-ASPS). Upstream and downstream factors of mTOR signaling and ancillary targets were analyzed in 103 cases (22 ASPS, 81 non-ASPS) by immunohistochemistry mostly using phospho-specific antibodies. TFE3 (transcription factor for immunoglobulin heavy-chain enhancer 3) translocation status was determined by FISH and RT-PCR. All ASPS were positive in TFE3 break-apart FISH and exhibited specific fusion products when RNA was available (type 1: 9x, type 2: 11x), whereas TFE3-immunoreactive non-ASPS did not. In ASPS, TFE3-, cMET-, pAKT T308- (all P < .0001), pp70S6K- (P = .002), and p4EBP1 (P = .087) expression levels were elevated, whereas pAKT S473 was decreased (P < .0001). In addition, ASPS exhibited higher TFE3-, cMET-, pAKT T308-, and pp70S6K- expression levels compared with TFE3-immunopositive non-ASPS sarcomas (all P < .001). We demonstrate elevated mTOR complex 1 (mTORC1) activity in ASPS independent of mTOR complex 2 (mTORC2) activation. mTORC1 activity seems to be related to the existence of ASPL-TFE3 fusion transcripts because TFE3-immunoreactive non-ASPS without ASPL-TFE3 fusion transcripts exhibit significantly lower mTORC1 activation status. Small molecule-based targeting of mTOR might therefore represent a potential mechanism in ASPS alone or in combination with contemporary upstream approaches.

OBJECTIVE

To investigate the expression of the chimeric genes resulting from the specific chromosomal translocations in soft tissue sarcomas (STS) and its diagnostic significance for STS.

METHODS

The variety of fusion transcripts were detected in 103 cases of STS, including 30 cases of synovial sarcoma (SS), 15 cases of rhabdomyosarcoma (RMS), 25 cases of Ewing's sarcoma/peripheral primitive neuroectodermal tumors (ES/pPNET), 12 cases of dermatofibrosarcoma protuberans (DFSP), 14 cases of aveolar soft part sarcoma (ASPS), 3 cases of leiomyosarcoma (LMS), 2 cases of malignant fibrous histocytoma (MFH), and 2 cases of fibrosarcoma (FS); and 20 cases of control tumors by reverse transcription-polymerase chain reaction (RT-PCR) using formalin fixed, paraffin embedded specimens.

RESULTS

Of the 34 cases of SS 28 (93.3%) expressed SSX-SYT chimeric transcripts (14 were positive for SYT-SSX1, 9 for SYT-SSX2). Four of the six cases of alveolar RMS had a PAX3/PAX7-FKHR fusion transcript. None of the 9 cases of embryonic and polymorphic RMS expressed PAX3/PAX7-FKHR. Of the 25 cases of ES/pPNET, 19 were positive for EWS-FLI1 fusion transcript and 1 for EWS-ERG fusion transcript. COL1A1-PDGFB fusion transcript was expressed in 8 of the 12 cases (66.7%) of DFSP. Of the fourteen cases of ASPS, ten expressed ASPL-TFE3 fusion transcript. None of the 3 cases of LMS, 2 cases of MFH, 2 cases of FS, and 20 control cases contained any of the fusion transcript.

CONCLUSIONS

Chimeric gene transcript resulting from specific chromosomal translocations is a reliable index for the molecular diagnosis of STS and RT-PCR assay for detection of specific fusion gene provides a useful tool for confirmation of the diagnosis of STS in diagnostically difficult cases and in retrospective studies.

In a subset of papillary renal cell carcinomas a t(X;1)(p11;q21) chromosome translocation has repeatedly been reported. Positional cloning has demonstrated that, as a result of this translocation, the transcription factor TFE3 gene on the X-chromosome becomes fused to a novel gene, PRCC, on chromosome 1. Since as yet little is known about the function of PRCC, we sought to identify the mouse counterpart of the PRCC gene. Isolation and sequence analysis of a mouse Prcc cDNA revealed a high level of conservation between man and mouse, both at the nucleotide and protein level. As the human PRCC gene, the mouse Prcc gene is ubiquitously expressed. It shows low expression in all mouse fetal tissues examined. In addition, we identified a genomic cosmid clone containing the complete Prcc gene. The mouse Prcc gene consists of seven exons, all of which contain coding sequences. The small second exon, which was found to be located adjacent to the t(X;1) breakpoint in the human gene on chromosome 1, is also conserved between man and mouse. In mouse, Prcc is located on chromosome 3. These cDNA and genomic clones will be instrumental in the creation of mouse models for a further elucidation of the function of PRCC.

Alpha-fetoprotein (AFP) is a useful tumor marker for hepatocellular carcinomas and yolk sac tumors. Rare extrahepatic visceral malignancies may be associated with AFP production and those exhibiting a hepatoid differentiation by morphology and immunohistochemical are classified as hepatoid adenocarcinoma. Renal cell carcinoma (RCC) producing AFP is a rare entity. To date, only one case of AFP-producing Xp11 translocation RCC has been reported. We reported another case of Xp11 translocation RCC, in which the tumor cells displayed strong immunostaining for AFP, HepPar1, and GPC-3. Additionally, the other published cases are reviewed.

Keywords: AFP; Renal cell carcinoma; TFE3.

The Golgi stress response is a homeostatic mechanism that augments the functional capacity of the Golgi apparatus when Golgi function becomes insufficient (Golgi stress). Three response pathways of the Golgi stress response have been identified in mammalian cells, the TFE3, HSP47 and CREB3 pathways, which augment the capacity of specific Golgi functions such as N-glycosylation, anti-apoptotic activity and pro-apoptotic activity, respectively. On the contrary, glycosylation of proteoglycans (PGs) is another important function of the Golgi, although the response pathway upregulating expression of glycosylation enzymes for PGs in response to Golgi stress remains unknown. Here, we found that expression of glycosylation enzymes for PGs was induced upon insufficiency of PG glycosylation capacity in the Golgi (PG-Golgi stress), and that transcriptional induction of genes encoding glycosylation enzymes for PGs was independent of the known Golgi stress response pathways and ER stress response. Promoter analyses of genes encoding these glycosylation enzymes revealed the novel enhancer elements PGSE-A and PGSE-B (the consensus sequences are CCGGGGCGGGGCG and TTTTACAATTGGTC, respectively), which regulates their transcriptional induction upon PG-Golgi stress. From these observations, the response pathway we discovered is a novel Golgi stress response pathway, which we have named the PG pathway. Key words: Golgi stress, proteoglycan, ER stress, organelle zone, organelle autoregulation.

To date, 13 cases of sporadic renal hemangioblastoma have been reported. In this article, we report such a case that might cause the diagnostic pitfall. A 37-year-old Japanese was found to have a renal mass by periodic medical check-up. He underwent radical nephrectomy. Macroscopically, the tumor was well-defined without fibrous capsule and the cut surface of the tumor exhibited light brown to gray-tan color without hemorrhage or necrosis. Microscopically, the tumor was made up of large polygonal to short spindle cells with eosinophilic cytoplasm with occasional vacuolization and abundant arborizing capillary network. Immunohistochemically, neoplastic cells showed diffuse positivity for inhibin-alpha, S-100 protein, vimentin, CA9, PAX2 and PAX8, but negativity for cytokeratin CAM5.2, alpha smooth muscle actin, Melanosome, Melan A, TFE3 and cathepsin K. In genetic analyses, this tumor showed no changes of VHL gene mutation, hypermethylation and loss of heterozygosity of chromosome 3p. Additionally, G-band karyotype and array comparative genomic hybridization studies showed a normal chromosome. In conclusion, the positivity for CA9, PAX2 and PAX8 in sporadic renal hemangioblastoma may cause the critical diagnostic pitfall in the differential diagnosis from clear cell renal cell carcinoma. Pathologists need to pay attention to systemic evaluation including macroscopic, microscopic and immunohistochemical findings. In some cases, molecular genetic study may be necessary.

We report the first case of inflammatory variant of hepatic angiomyolipoma (AML) with expression of transcription factor E3 (TFE3) protein but negativity for HMB45 and melan A in a 62-year-old female. Imaging studies revealed a tumor in the left lobe of liver, sized 5.8 cm in maximum diameter. Microscopically, the lesion was composed of large polygonal or epithelioid cells with copious eosinophilic granular cytoplasm. There was a very prominent stromal lymphoplasmacytic infiltrate. Immunohistochemically, the tumor cells showed very strong and diffuse positivity for smooth muscle actin, and cathepsin K, while S-100 protein, keratin, desmin, HMB45 and Melan-A are negative. However, there was multifocal and very convincing nuclear positivity for TFE3, thus confirms the diagnosis.

Cadmium (Cd), is a well-known environmental and occupational hazard with a potent neurotoxic action. However, the mechanism underlying cadmium-induced neurotoxicity remains unclear. Herein, we exposed Neuro-2a cells to different concentrations of cadmium chloride (CdCl2) (12.5, 25 and 50 μM) for 24 h and found that Cd significantly induced lysosomal membrane permeabilization (LMP) with the release of cathepsin B (CTSB) to the cytosol, which in turn caused the release of mitochondrial cytochrome c (Cyt c) and eventually triggered caspase-dependent apoptosis. Interestingly, Cd decreased TFE3 expression but induced the nuclear translocation of TFE3 and TFE3 target-gene expression, which might be associated with lysosomal stress mediated by Cd. Notably, Tfe3 overexpression protected against Cd-induced neurotoxicity by maintaining the lysosomal-mitochondrial axis, and the protective effect of TFE3 is not dependent on the restoration of autophagic flux. In conclusion, our study demonstrated for the first time that lysosomal-mitochondrial axis dependent apoptosis, a neglected mechanism, may be the most important reason for Cd-induced neurotoxicity and that manipulation of TFE3 signaling may be a potential therapeutic approach for treatment of Cd-induced neurotoxicity.

Clear cell "sugar" tumor is a rare benign neoplasm arising in the lung, considered as a part of the PEComa family. As PEComas of other sites, this tumor expresses melanocytic markers such as HMB45 and Melan-A. Despite cathepsin K, MITF and CD68 staining are known to be positive in a large number of PEComas and TFE3 rearrangement has been reported in a subset of PEComas, no data is available regarding the expression of these markers and the occurrence of TFE3 and TFEB rearrangement in clear cell "sugar" tumor of the lung. We have investigated the immunolabeling of cathepsin K, MITF, and CD68 in five cases of clear cell "sugar" tumor. Moreover, we have also sought the presence of TFE3 and TFEB rearrangement by fluorescence in situ hybridization (FISH) assay. In all tumors, strong immunoreactivity of cathepsin K and CD68 (PG-M1 and KP1 clone) was demonstrated, whereas none of them labeled for MITF staining and showed TFE3 or TFEB rearrangement. These findings widen the immunohistochemical profile of clear cell "sugar" tumor providing useful new markers for challenging cases. The expression of lysosomal markers, such as cathepsin K and CD68, strengthens the hypothesis that this tumor is part of the PEComa family.

The immunoglobulin mu intronic enhancer is a potent B cell-specific transcriptional activator. The enhancer is activated by the appropriate combination of transcription factors, amongst which are ets and bHLH proteins. HMGA1 (formerly HMG-I(Y)) is a demonstrated co-activator of the mu enhancer. HMGA1 functions through direct interaction with PU.1, one of the ets proteins critical for enhancer activation. New data demonstrates dominant negative HMGA1 dramatically decreases enhancer activity in B cells. EMSA analysis demonstrated that DN HMGA1 disrupts established PU.1/mu enhancer binding. Similarly, DN HMGA1 blocks mu enhancer binding by Ets-1. In sharp contrast, DN HMGA1 had no effect on binding activity of the ETS DNA binding domains of either PU.1 or Ets-1, or the bHLH-zip protein TFE3, suggesting specificity. Taken together, the data suggest that DN HMGA1 utilizes a novel mechanism to specifically block interaction between ets proteins and mu enhancer DNA, suggesting DN HMGA1 represents a new, highly specific means of regulating mu enhancer activity.

Lower lobe predominant pulmonary cysts occur in up to 90% of patients with Birt-Hogg-Dubé (BHD) syndrome, but the key pathologic cell type and signaling events driving this distinct phenotype remain elusive. Through examination of the LungMAP database, we found that folliculin (FLCN) is highly expressed in neonatal lung mesenchymal cells. Using RNA-Seq, we found that inactivation of Flcn in mouse embryonic fibroblasts (MEFs) leads to changes in multiple Wnt ligands, including a 2.8-fold decrease in Wnt2. This was associated with decreased TCF/LEF activity, a readout of canonical WNT activity, after treatment with a GSK3-α/β inhibitor. Similarly, FLCN deficiency in HEK293T cells decreased WNT pathway activity by 76% post GSK3-α/β inhibition. Inactivation of FLCN in human fetal lung fibroblasts (MRC-5) led to ~100-fold decrease in Wnt2 expression and a 33-fold decrease in Wnt7b expression- two ligands known to be necessary for lung development- furthermore, canonical WNT activity was decreased by 60%. Classic WNT targets such as AXIN2 and BMP4, and WNT enhanceosome members including TCF4, LEF1, and BCL9, were also decreased after GSK3-α/β inhibition. FLCN-deficient MRC-5 cells failed to upregulate LEF1 in response to GSK3-α/β inhibition. Finally, we found that a constitutively active β-catenin could only partially rescue the decreased WNT activity phenotype seen in FLCN-deficient cells, whereas silencing the transcription factor TFE3 completely reversed this phenotype. In summary, our data establish FLCN as a critical regulator of the WNT pathway via TFE3 and suggest that FLCN-dependent defects in WNT pathway developmental cues may contribute to lung cyst pathogenesis in BHD.

FLCN is a tumor suppressor gene which controls energy homeostasis through regulation of a variety of metabolic pathways including mitochondrial oxidative metabolism and autophagy. Birt-Hogg-Dubé (BHD) syndrome which is driven by germline alteration of the FLCN gene, predisposes patients to develop kidney cancer, cutaneous fibrofolliculomas, pulmonary cysts and less frequently, salivary gland tumors. Here, we report metabolic roles for FLCN in the salivary gland as well as their clinical relevance. Screening of salivary glands of BHD patients using ultrasonography demonstrated increased cyst formation in the salivary gland. Salivary gland tumors that developed in BHD patients exhibited an upregulated mTOR-S6R pathway as well as increased GPNMB expression, which are characteristics of FLCN-deficient cells. Salivary gland-targeted Flcn knockout mice developed cytoplasmic clear cell formation in ductal cells with increased mitochondrial biogenesis, upregulated mTOR-S6K pathway, upregulated TFE3-GPNMB axis and upregulated lipid metabolism. Proteomic and metabolite analysis using LC/MS and GC/MS revealed that Flcn inactivation in salivary gland triggers metabolic reprogramming towards the pentose phosphate pathway which consequently upregulates nucleotide synthesis and redox regulation, further supporting that Flcn controls metabolic homeostasis in salivary gland. These data uncover important roles for FLCN in salivary gland; metabolic reprogramming under FLCN deficiency might increase nucleotide production which may feed FLCN-deficient salivary gland cells to trigger tumor initiation and progression, providing mechanistic insight into salivary gland tumorigenesis as well as a foundation for development of novel therapeutics for salivary gland tumors.

OBJECTIVE

To explore the value of self-designed fluorescent in situ hybridization (FISH) polyclonal break-apart probes specific for TFE3 gene in the diagnosis of Xp11.2 translocation renal cell carcinoma.

METHODS

All tissue samples were collected from 2006 to 2013, including Xp11.2 translocation renal cell carcinoma (n = 10), renal clear cell carcinoma (n = 10) and renal papillary cell carcinoma (n = 10). FISH was conducted for paraffin-embedded tumor tissue sections with probes. The types of fluorescence were observed by fluorescent microscopy to determine the existence or non-existence of translocated TFE3 gene.

RESULTS

All sections were successfully probed. The split red and green signals within a single nucleus were detected simultaneously in 9 cases of Xp11.2 translocation renal cell carcinoma as diagnosed by traditional pathological and immunohistochemical methods. And it was consistent with the initial diagnosis. Detection of fusion signal in 1/10 and negative FISH result did not conform to the initial diagnosis. The fluorescent types of renal clear cell carcinoma and renal papillary cell carcinoma were all fusion signals. FISH tests were negative for renal clear and papillary cell carcinomas.

CONCLUSIONS

Xp11.2 translocation renal cell carcinomas diagnosed by traditional pathological and immunohistochemical methods are sometimes misdiagnosed. Detecting the translocation of TFE3 gene with FISH polyclonal break-apart probes is both accurate and reliable for diagnosing Xp11.2 translocation renal cell carcinoma.

We have determined the exon-intron structure of the human TFE3 gene located on Xp11.22-23. By designing PCR primers, we were able to amplify various segments of the TFE3 genomic region, thus establishing that this gene is composed of seven exons, the first six of which are small (from 56 to 159 nt). The 5' UT region is contained entirely in the first exon, while the 3' UT region is contained in the seventh exon. The comparison of the genomic and the published cDNA versions revealed that the deduced amino acid sequence of TFE3 in the C-terminus region is 125 amino acids shorter than previously reported. This eliminates most of the putative proline- and arginine-rich domain and makes the human sequence more similar to its mouse homolog. The activation domain at the N-terminus is contained in exon 2, as has been described for the mouse. The basic helix-loop-helix (BHLH) motif is spread over exons 4 to 6, while the leucine zipper (LZ) is almost all contained in the last portion of exon 6. This split BHLH is different from other BHLH-LZ genes whose genomic structures have been determined up to now.

Papillary renal-cell carcinoma, which accounts for 15%-20% of renal-cell carcinomas, is a heterogeneous disease that consists of various types of renal cancer, including tumors with indolent, multifocal presentation, and solitary tumors with an aggressive, highly lethal phenotype. Little is known about the genetic basis of sporadic papillary renal-cell carcinoma, and no effective forms of therapy for advanced disease exist.

We performed comprehensive molecular characterization of 161 primary papillary renal-cell carcinomas, using whole-exome sequencing, copy-number analysis, messenger RNA and microRNA sequencing, DNA-methylation analysis, and proteomic analysis.

Types 1 and 2 papillary renal-cell carcinomas were shown to be different types of renal cancer characterized by specific genetic alterations, with type 2 further classified into 3 individual subgroups on the basis of molecular differences associated with patient survival. Type 1 tumors were associated with MET alterations, whereas type 2 tumors were characterized by CDKN2A silencing, SETD2 mutations, TFE3 fusions, and increased expression of the NRF2-antioxidant response element (ARE) pathway. A CpG island methylator phenotype was observed in a distinct subgroup of type 2 papillary renal-cell carcinomas that was characterized by poor survival and mutation of the gene encoding fumarate hydratase.

Types 1 and 2 papillary renal-cell carcinomas were shown to be clinically and biologically distinct. Alterations in the MET pathway were associated with type 1, and activation of the NRF2-ARE pathway was associated with type 2; CDKN2A loss and CpG island methylator phenotype in type 2 conveyed a poor prognosis. Furthermore, type 2 papillary renal-cell carcinoma consisted of at least 3 subtypes based on molecular and phenotypic features. (Funded by the National Institutes of Health.).

A comprehensive physical contig of yeast artificial chromosomes (YACs) and cosmid clones between ZNF21 and DXS255 has been constructed, spanning 2 Mb within the region Xp11.23-p11.22. As a portion of the region was found to be particularly unstable in yeast, the integrity of the contig is dependent on additional information provided by the sequence-tagged site (STS) content of cosmid clones and DNA marker retention in conventional and radiation hybrids. The contig was formatted with 43 DNA markers, including 19 new STSs from YAC insert ends and an internal Alu-PCR product. The density of STSs across the contig ranges from one marker every 20 kb to one every 60 kb, with an average density of one marker every 50 kb. The relative order of previously known genes and expressed sequence tags in this region is predicted to be Xpter-ZNF21-DXS7465E (MG66)-DXS7927E (MG81)-WASP, DXS1011E, DXS7467E (MG21)-DXS- 7466E (MG44)-GATA1-DXS7469E (Xp664)-TFE3-SYP (DXS1007E)-Xcen. This contig extends the coverage in Xp11 and provides a framework for the future identification and mapping of new genes, as well as the resources for developing DNA sequencing templates.

In recent years, an increasing number of TFE3 rearrangement-associated tumors with melanotic features have been reported as primary neoplasm in different anatomical sites, including the kidney. Melanotic Xp11 translocation renal cancer (MXTRC) and Xp11 renal cell carcinoma with melanotic features (XRCCM) have been proposed to be main categories for pigmented lesions in the microophthalmia-associated transcription factor (MiTF/TFE3) family of renal tumors that may show variable degrees of melanocytic differentiation. Herein we report a rare case of TFE3-related pigmented renal tumor showing unusual immunoexpression of cytokeratins (AE1/AE3) and renal cell carcinoma markers (RCC, CD10). Cathepsin-K and Vimentin were diffusely positive whereas melanocytic markers (HMB-45 and Melan-A) displayed weak and patchy expression. We found no labelling for PAX-8, muscle markers (desmin, smooth muscle actin, muscle-specific actin and caldesmon) and S-100. TFE3 fusion was confirmed by break-apart fluorescence in situ hybridization (FISH). This case corroborates previous evidence for overlap in the TFE3-associated cancer family and illustrates that it may not be possible to set a clear cutoff between epithelial (XRCCM) and mesenchymal (MXTRC) subgroups.