MicroRNAs (miRs) are involved in the pathogenesis of several neoplasms; however, there are no data on their expression patterns and possible roles in adrenocortical tumors. Our objective was to study adrenocortical tumors by an integrative bioinformatics analysis involving miR and transcriptomics profiling, pathway analysis, and a novel, tissue-specific miR target prediction approach. Thirty-six tissue samples including normal adrenocortical tissues, benign adenomas, and adrenocortical carcinomas (ACC) were studied by simultaneous miR and mRNA profiling. A novel data-processing software was used to identify all predicted miR–mRNA interactions retrieved from PicTar, TargetScan, and miRBase. Tissue-specific target prediction was achieved by filtering out mRNAs with undetectable expression and searching for mRNA targets with inverse expression alterations as their regulatory miRs. Target sets and significant microarray data were subjected to Ingenuity Pathway Analysis. Six miRs with significantly different expression were found. miR-184 and miR-503 showed significantly higher, whereas miR-511 and miR-214 showed significantly lower expression in ACCs than in other groups. Expression of miR-210 was significantly lower in cortisol-secreting adenomas than in ACCs. By calculating the difference between dCTmiR-511 and dCTmiR-503 (delta cycle threshold), ACCs could be distinguished from benign adenomas with high sensitivity and specificity. Pathway analysis revealed the possible involvement of G2/M checkpoint damage in ACC pathogenesis. To our knowledge, this is the first report describing miR expression patterns and pathway analysis in sporadic adrenocortical tumors. miR biomarkers may be helpful for the diagnosis of adrenocortical malignancy. This tissue-specific target prediction approach may be used in other tumors too.
Zsófia Tömböl, Peter M Szabó, Viktor Molnár, Zoltán Wiener, Gergely Tölgyesi, János Horányi, Peter Riesz, Peter Reismann, Attila Patócs, István Likó, Rolf-Christian Gaillard, András Falus, Károly Rácz and Peter Igaz
Birke Bausch, Ulrich Wellner, Dirk Bausch, Francesca Schiavi, Marta Barontini, Gabriela Sanso, Martin K Walz, Mariola Peczkowska, Georges Weryha, Patrizia Dall'Igna, Giovanni Cecchetto, Gianni Bisogno, Lars C Moeller, Detlef Bockenhauer, Attila Patocs, Karoly Rácz, Dmitry Zabolotnyi, Svetlana Yaremchuk, Iveta Dzivite-Krisane, Frederic Castinetti, David Taieb, Angelica Malinoc, Ernst von Dobschuetz, Jochen Roessler, Kurt W Schmid, Giuseppe Opocher, Charis Eng and Hartmut P H Neumann
A third of patients with paraganglial tumors, pheochromocytoma, and paraganglioma, carry germline mutations in one of the susceptibility genes, RET, VHL, NF1, SDHAF2, SDHA, SDHB, SDHC, SDHD, TMEM127, and MAX. Despite increasing importance, data for long-term prognosis are scarce in pediatric presentations. The European-American-Pheochromocytoma–Paraganglioma-Registry, with a total of 2001 patients with confirmed paraganglial tumors, was the platform for this study. Molecular genetic and phenotypic classification and assessment of gene-specific long-term outcome with second and/or malignant paraganglial tumors and life expectancy were performed in patients diagnosed at <18 years. Of 177 eligible registrants, 80% had mutations, 49% VHL, 15% SDHB, 10% SDHD, 4% NF1, and one patient each in RET, SDHA, and SDHC. A second primary paraganglial tumor developed in 38% with increasing frequency over time, reaching 50% at 30 years after initial diagnosis. Their prevalence was associated with hereditary disease (P=0.001), particularly in VHL and SDHD mutation carriers (VHL vs others, P=0.001 and SDHD vs others, P=0.042). A total of 16 (9%) patients with hereditary disease had malignant tumors, ten at initial diagnosis and another six during follow-up. The highest prevalence was associated with SDHB (SDHB vs others, P<0.001). Eight patients died (5%), all of whom had germline mutations. Mean life expectancy was 62 years with hereditary disease. Hereditary disease and the underlying germline mutation define the long-term prognosis of pediatric patients in terms of prevalence and time of second primaries, malignant transformation, and survival. Based on these data, gene-adjusted, specific surveillance guidelines can help effective preventive medicine.
Hartmut P Neumann, William F Young Jr, Tobias Krauss, Jean-Pierre Bayley, Francesca Schiavi, Giuseppe Opocher, Carsten C Boedeker, Amit Tirosh, Frederic Castinetti, Juri Ruf, Dmitry Beltsevich, Martin Walz, Harald-Thomas Groeben, Ernst von Dobschuetz, Oliver Gimm, Nelson Wohllk, Marija Pfeifer, Delmar M Lourenço Jr, Mariola Peczkowska, Attila Patocs, Joanne Ngeow, Özer Makay, Nalini S Shah, Arthur Tischler, Helena Leijon, Gianmaria Pennelli, Karina Villar Gómez de las Heras, Thera P Links, Birke Bausch and Charis Eng
Although the authors of the present review have contributed to genetic discoveries in the field of pheochromocytoma research, we can legitimately ask whether these advances have led to improvements in the diagnosis and management of patients with pheochromocytoma. The answer to this question is an emphatic Yes! In the field of molecular genetics, the well-established axiom that familial (genetic) pheochromocytoma represents 10% of all cases has been overturned, with >35% of cases now attributable to germline disease-causing mutations. Furthermore, genetic pheochromocytoma can now be grouped into five different clinical presentation types in the context of the ten known susceptibility genes for pheochromocytoma-associated syndromes. We now have the tools to diagnose patients with genetic pheochromocytoma, identify germline mutation carriers and to offer gene-informed medical management including enhanced surveillance and prevention. Clinically, we now treat an entire family of tumors of the paraganglia, with the exact phenotype varying by specific gene. In terms of detection and classification, simultaneous advances in biochemical detection and imaging localization have taken place, and the histopathology of the paraganglioma tumor family has been revised by immunohistochemical-genetic classification by gene-specific antibody immunohistochemistry. Treatment options have also been substantially enriched by the application of minimally invasive and adrenal-sparing surgery. Finally and most importantly, it is now widely recognized that patients with genetic pheochromocytoma/paraganglioma syndromes should be treated in specialized centers dedicated to the diagnosis, treatment and surveillance of this rare neoplasm.
Ioana N Milos, Karin Frank-Raue, Nelson Wohllk, Ana Luiza Maia, Eduardo Pusiol, Attila Patocs, Mercedes Robledo, Josefina Biarnes, Marta Barontini, Thera P Links, Jan Willem de Groot, Sarka Dvorakova, Mariola Peczkowska, Lisa A Rybicki, Maren Sullivan, Friedhelm Raue, Ioana Zosin, Charis Eng and Hartmut P H Neumann
RET testing in multiple endocrine neoplasia type 2 for molecular diagnosis is the paradigm for the practice of clinical cancer genetics. However, precise data for distinct mutation-based risk profiles are not available. Here, we survey the clinical profile for one specific genotype as a model, TGC to TGG in codon 634 (C634W). By international efforts, we ascertained all available carriers of the RET C634W mutation. Age at diagnosis, penetrance, and clinical complications were analyzed for medullary thyroid carcinoma (MTC), pheochromocytoma, and hyperparathyroidism (HPT), as well as overall survival. Our series comprises 92 carriers from 20 unrelated families worldwide. Sixty-eight subjects had MTC diagnosed at age 3–72 years (mean 29). Lymph node metastases were observed in 16 subjects aged 20–72 and distant metastases in 4 subjects aged 28–69. Forty-one subjects had pheochromocytoma detected at age 18–67 (mean 36). Amongst the 28 subjects with MTC and pheochromocytoma, six developed pheochromocytoma before MTC. Six subjects had HPT diagnosed at age 26–52 (mean 39). Eighteen subjects died; of the 16 with known causes of death, 8 died of pheochromocytoma and 4 of MTC. Penetrance for MTC is 52% by age 30 and 83% by age 50, for pheochromocytoma penetrance is 20% by age 30 and 67% by age 50, and for HPT penetrance is 3% by age 30 and 21% by age 50. These data provide, for the first time, RET C634W-specific neoplastic risk and age-related penetrance profiles. The data may facilitate risk assessment and genetic counseling.
Frederic Castinetti, Ana Luiza Maia, Mariola Peczkowska, Marta Barontini, Kornelia Hasse-Lazar, Thera P Links, Rodrigo A Toledo, Sarka Dvorakova, Caterina Mian, Maria Joao Bugalho, Stefania Zovato, Maria Alevizaki, Andrei Kvachenyuk, Birke Bausch, Paola Loli, Simona R Bergmann, Attila Patocs, Marija Pfeifer, Josefina Biarnes Costa, Ernst von Dobschuetz, Claudio Letizia, Gerlof Valk, Marcin Barczynski, Malgorzata Czetwertynska, John T M Plukker, Paola Sartorato, Tomas Zelinka, Petr Vlcek, Svetlana Yaremchuk, Georges Weryha, Letizia Canu, Nelson Wohllk, Frederic Sebag, Martin K Walz, Charis Eng and Hartmut P H Neumann
Tobias Krauss, Alfonso Massimiliano Ferrara, Thera P Links, Ulrich Wellner, Irina Bancos, Andrey Kvachenyuk, Karina Villar Gómez de las Heras, Marina Y Yukina, Roman Petrov, Garrett Bullivant, Laura von Duecker, Swati Jadhav, Ursula Ploeckinger, Staffan Welin, Camilla Schalin-Jäntti, Oliver Gimm, Marija Pfeifer, Joanne Ngeow, Kornelia Hasse-Lazar, Gabriela Sansó, Xiaoping Qi, M Umit Ugurlu, Rene E Diaz, Nelson Wohllk, Mariola Peczkowska, Jens Aberle, Delmar M Lourenço Jr, Maria A A Pereira, Maria C B V Fragoso, Ana O Hoff, Madson Q Almeida, Alice H D Violante, Ana R P Quidute, Zhewei Zhang, Mònica Recasens, Luis Robles Díaz, Tada Kunavisarut, Taweesak Wannachalee, Sirinart Sirinvaravong, Eric Jonasch, Simona Grozinsky-Glasberg, Merav Fraenkel, Dmitry Beltsevich, Viacheslav I Egorov, Dirk Bausch, Matthias Schott, Nikolaus Tiling, Gianmaria Pennelli, Stefan Zschiedrich, Roland Därr, Juri Ruf, Timm Denecke, Karl-Heinrich Link, Stefania Zovato, Ernst von Dobschuetz, Svetlana Yaremchuk, Holger Amthauer, Özer Makay, Attila Patocs, Martin K Walz, Tobias B Huber, Jochen Seufert, Per Hellman, Raymond H Kim, Ekaterina Kuchinskaya, Francesca Schiavi, Angelica Malinoc, Nicole Reisch, Barbara Jarzab, Marta Barontini, Andrzej Januszewicz, Nalini Shah, William F Young Jr, Giuseppe Opocher, Charis Eng, Hartmut P H Neumann and Birke Bausch
Pancreatic neuroendocrine tumors (PanNETs) are rare in von Hippel–Lindau disease (VHL) but cause serious morbidity and mortality. Management guidelines for VHL-PanNETs continue to be based on limited evidence, and survival data to guide surgical management are lacking. We established the European-American-Asian-VHL-PanNET-Registry to assess data for risks for metastases, survival and long-term outcomes to provide best management recommendations. Of 2330 VHL patients, 273 had a total of 484 PanNETs. Median age at diagnosis of PanNET was 35 years (range 10–75). Fifty-five (20%) patients had metastatic PanNETs. Metastatic PanNETs were significantly larger (median size 5 vs 2 cm; P < 0.001) and tumor volume doubling time (TVDT) was faster (22 vs 126 months; P = 0.001). All metastatic tumors were ≥2.8 cm. Codons 161 and 167 were hotspots for VHL germline mutations with enhanced risk for metastatic PanNETs. Multivariate prediction modeling disclosed maximum tumor diameter and TVDT as significant predictors for metastatic disease (positive and negative predictive values of 51% and 100% for diameter cut-off ≥2.8 cm, 44% and 91% for TVDT cut-off of ≤24 months). In 117 of 273 patients, PanNETs >1.5 cm in diameter were operated. Ten-year survival was significantly longer in operated vs non-operated patients, in particular for PanNETs <2.8 cm vs ≥2.8 cm (94% vs 85% by 10 years; P = 0.020; 80% vs 50% at 10 years; P = 0.030). This study demonstrates that patients with PanNET approaching the cut-off diameter of 2.8 cm should be operated. Mutations in exon 3, especially of codons 161/167 are at enhanced risk for metastatic PanNETs. Survival is significantly longer in operated non-metastatic VHL-PanNETs.