Morphologic features in a series of 352 Spitz melanocytic proliferations help predict their oncogenic drivers.

Spitz nevi are indolent melanocytic tumors arising preferentially during and after childhood. Over the last decades, recurrent oncogenic drivers, sparsely detected in melanoma, were identified in Spitz melanocytic proliferations. Therefore, the detection of such drivers appears as a relevant diagnostic tool to distinguish both entities. Interestingly, morphologic features might correlate with the oncogenic drivers. Thus, the goal of this study was to assess the performances of previously identified morphological criteria to predict the presence of specific drivers. In total, 352 Spitz melanocytic proliferations either with a genetically identified oncogenic driver or investigated for ALK, ROS1, and NTRK1 overexpression by immunohistochemistry were enrolled in the present study. The microscopic features of the cases were assessed blindly with regards to the molecular status and, performances of previously described morphological criteria to predict the molecular status were assessed applying the likelihood-ratio test (LHR). Overall, an oncogenic driver was identified in 76% of the cases (n = 268/352). No microscopic features allowed the reliable prediction of ROS1- and NTRK1-overexpressing cases. By contrast, a plexiform pattern can contribute to the recognition of ALK-overexpressing cases (LHR(+) = 6.14). Importantly, the pseudo-schwannoma variant was highly suggestive of NTRK3-rearranged cases (LHR(+) = 43). Moreover, atypical/malignant tumor (LHR(+) = 5.18), severe cellular atypia (LHR(+) = 5.07), and p16 loss (LHR(+) = 14) contribute to the recognition of MAP3K8-rearranged cases, while the presence of a sheet-like architecture (LHR(+) = 5.39) and a marked fibrosis of the stroma (LHR(+)=5.06) were predictive of BRAF-fused tumors. To conclude, our study confirms ALK-overexpressing, NTRK3-, MAP3K8-, and BRAF-rearranged cases harbored distinct morphologic features allowing their microscopic recognition.

Could Aberrant Migration Explain Metachronous Germ Cell Tumors?

BACKGROUND: Extragonadal germ cell tumors (GCTs) are thought to arise as a result of local transformation of primordial gonadal cells (PGCs) that become misplaced during embryogenesis. With the exception of bilateral testis tumors, metachronous GCT (i.e., occurring at a site classically described for primary GCTs) are rare events. PATIENTS AND METHODS: The clinical, radiological, and molecular data (if available) of patients with metachronous GCT were analyzed. RESULTS: Three Caucasian males were identified: case 1 presented with a pineal germinoma 19 years after a mediastinal seminoma that had been treated with chemotherapy, case 2 presented with a pineal non-seminomatous GCT (NSGCT) that occurred three years after a mediastinal seminoma treated with chemotherapy, and case 3 presented with a mediastinal seminoma concomitant with a suprasellar germinoma that occurred two years after a stage I testicular NSGCT treated exclusively with surgery. None of these patients had a positive family history or disorder of sex development. Molecular data were available for cases 2 and 3. In case 2, a CHEK2 gene biallelic inactivation in the second tumor suggested chemoresistance to cisplatin. This was further confirmed by tumor progression during second-line treatment. In case 3, the molecular analysis revealed different profiles in the three tumors, thus suggesting distinct tumor cell origins. CONCLUSION: These rare cases should alert clinicians of the possibility of multiple GCTs that should not be considered to be relapses. The underlying physiopathology is unknown, but multiple PGC mismigrations is a likely cause. Initial treatment with cisplatin may select chemo-resistant clones, thereby making the subsequent treatment more of a challenge.

ß-Catenin nuclear expression discriminates deep penetrating nevi from other cutaneous melanocytic tumors.

Recent advances in genomics have improved the molecular classification of cutaneous melanocytic tumors. Among them, deep penetrating nevi (DPN) and plexiform nevi have been linked to joint activation of the MAP kinase and dysregulation of the ß-catenin pathways. Immunohistochemical studies have confirmed cytoplasmic and nuclear expression of ß-catenin and its downstream effector cyclin D1 in these tumors. We assessed nuclear ß-catenin immunohistochemical expression in a large group of DPN as well as in the four most frequent differential diagnoses of DPN: "blue" melanocytic tumors, Spitz tumors, nevoid and SSM melanomas, and pigmented epithelioid melanocytomas (PEM). Nuclear ß-catenin expression was positive in 98/100 DPN and 2/16 of melanomas (one SSM and one nevoid melanoma with a plexiform clone) and was negative in all 30 Spitz, 26 blue, and 6 PEM lesions. In 41% DPN, ß-catenin expression was positive in more than 30% nuclei. No differences were observed in cytoplasmic and nuclear cyclin D1 expression between these tumor groups, suggesting alternate, ß-catenin-independent, activation pathways. We have subsequently studied nuclear ß-catenin expression in a set of 13 tumors with an ambiguous diagnosis, for which DPN was part of the differential diagnosis. The three out of four patients showing canonical DPN mutation profiles were the only ß-catenin-positive cases. We conclude that nuclear ß-catenin expression, independently from CCND1 expression, in a dermal melanocytic tumor is an argument for its classification as DPN. In ambiguous cases and in early combined DPN lesions, this antibody can be helpful as a screening tool. ß-Catenin is also potentially expressed in a subset of malignant melanomas with CTNNB1 mutations.