Laurence Brugières

PURPOSE: The aim of the study was to update the description of Li-Fraumeni syndrome (LFS), a remarkable cancer predisposition characterized by extensive clinical heterogeneity. PATIENTS AND METHODS: From 1,730 French patients suggestive of LFS, we identified 415 mutation carriers in 214 families harboring 133 distinct TP53 alterations and updated their clinical presentation. RESULTS: The 322 affected carriers developed 552 tumors, and 43% had developed multiple malignancies. The mean age of first tumor onset was 24.9 years, 41% having developed a tumor by age 18. In childhood, the LFS tumor spectrum was characterized by osteosarcomas, adrenocortical carcinomas (ACC), CNS tumors, and soft tissue sarcomas (STS) observed in 30%, 27%, 26%, and 23% of the patients, respectively. In adults, the tumor distribution was characterized by the predominance of breast carcinomas observed in 79% of the females, and STS observed in 27% of the patients. The TP53 mutation detection rate in children presenting with ACC or choroid plexus carcinomas, and in females with breast cancer before age 31 years, without additional features indicative of LFS, was 45%, 42% and 6%, respectively. The mean age of tumor onset was statistically different (P < .05) between carriers harboring dominant-negative missense mutations (21.3 years) and those with all types of loss of function mutations (28.5 years) or genomic rearrangements (35.8 years). Affected children, except those with ACC, harbored mostly dominant-negative missense mutations. CONCLUSION: The clinical gradient of the germline TP53 mutations, which should be validated by other studies, suggests that it might be appropriate to stratify the clinical management of LFS according to the class of the mutation.

Casali, Paolo Giovanni; Bielack, Stefan S.; Abecassis, N.; Aro, Hannu; Bauer, Sebastian; Biagini, Roberto; Bonvalot, Sylvie; Boukovinas, Ioannis P.; Bovee, Judith V. M. G.; Brennan, Bernadette M. D.; Brodowicz, Thomas; Broto, Javier Martín; Brugières, Laurence; Buonadonna, Angela; De Álava, Enrique; Dei Tos, Angelo; García-Del-Muro, Xavier F.; Dileo, Palma; Dhooge, Catharina R. M.; Eriksson, Mikael; Fagioli, Franca; Fedenko, Alexander; Ferraresi, Virginia; Ferrari, Andrea; Ferrari, Stefano; Frezza, Anna Maria; Gaspar, Nathalie; Gasperoni, Silvia; Gelderblom, Hans J.; Gil, Thierry; Grignani, Giovanni; Gronchi, Alessandro; Haas, Rick LM.; Hassan, A. Bass; Hecker-Nolting, Stefanie; Hohenberger, Peter; Issels, Rolf Dieter; Joensuu, Heikki T.; Jones, Robin; Judson, Ian Robert; Jutte, Paul; Kaal, Suzanne E. J.; Kager, L. H.; Kasper, Bernd; Kopeckova, Kateřina; Krákorová, Dagmar; Ladenstein, Ruth Lydia; Le Cesne, Axel; López Pousa, Antonio; Lugowska, Iwona; Merimsky, Ofer; Montemurro, Michael; Morland, Bruce J.; Pantaleo, Maria Abbondanza; Piana, Raimondo; Picci, Piero; Piperno-Neumann, Sophie; Reichardt, Peter; Robinson, Martin H.; Rutkowski, Piotr; Safwat, Akmal Ahmed; Schöffski, Patrick; Sleijfer, Stefan; Stacchiotti, Silvia; Strauss, Sandra J.; Sundby Hall, Kirsten; Unk, Mojca; Van Coevorden, Frits; Van Der Graaf, Winette T. A.; Whelan, Jeremy S.; Wardelmann, Eva; Zaikova, Olga; Blay, Jean-Yves

The t(2;5)(p23;q35) translocation, associated with anaplastic large-cell lymphoma (ALCL), results in the expression of a chimeric NPM-ALK protein that can be detected by the ALK1 monoclonal antibody. This report describes the morphologic and phenotypic spectrum of 123 cases of lymphoma that all express ALK protein. The results provide strong evidence that the morphologic patterns of ALCL described in previous reports as representing possible subtypes of ALCL, eg, common type, lymphohistiocytic, or small cell patterns, are morphologic variants of the same disease entity. All of these morphologic patterns could be found within this series, and in some patients different subtypes coexisted in a single biopsy or were found in successive biopsies from a single patient. The link between these morphologic subtypes is further reinforced by the presence in all cases of a highly characteristic large cell, with an eccentric nucleus and an eosinophilic paranuclear region. We suggest that this cell can be considered as a major distinguishing feature of ALK-positive lymphomas. Another characteristic of these tumors was the perivascular pattern of neoplastic cell infiltration seen in a significant number of cases. In addition to ALK protein, all tumors expressed epithelial membrane antigen and lacked CD15, features that may be of value in differentiating ALCL from Hodgkin's disease. In the majority of cases (84%), malignant cells showed both a cytoplasmic and nuclear staining for ALK1 and thus presumably carried the 2;5 translocation, but staining was restricted to the cytoplasm in a few cases, suggesting that translocations other than t(2;5) may induce expression of ALK protein. We conclude from this study that ALK-positive neoplasms represent a distinct entity. Because their morphology is often neither anaplastic nor large cell, we suggest that they should henceforward be referred to as ALK lymphomas.