Next-generation sequencing of oncogenes and tumor suppressor genes in odontogenic myxomas.

BACKGROUND: Mutations previously considered drivers of malignant neoplasms also occur in benign tumors. From the biological perspective, the study of malignant and benign neoplasms is equally relevant. The study of rare tumors contributes to the understanding of the more common ones, as both could share the same hallmark genetic drivers. The identification of driver mutations in benign tumors is facilitated by the fact that they harbor quiet genomes. Pathogenic mutations have being described in benign epithelial odontogenic tumors, such as ameloblastomas and adenomatoid odontogenic tumors. However, the molecular pathogenesis of odontogenic myxoma (OM), a benign aggressive ectomesenchymal tumor, is still poorly characterized, precluding the development of personalized therapy. Aiming to find druggable genetic mutations, we investigated in OM mutations in 50 genes commonly mutated in cancer. METHODS: We used targeted next-generation sequencing to interrogate over 2,800 COSMIC mutations in OM. RESULTS: Missense single nucleotide variants were detected in KDR, TP53, PIK3CA, KIT, JAK3; however, these did not include pathogenic mutations. CONCLUSION: These aggressive tumors do not harbor pathogenic mutations in genes commonly mutated in human cancers or if they do, these mutations probably occur in a low proportion of cases.

Interaction of stromal and microvascular components in keratocystic odontogenic tumors.

OBJECTIVE: Little is known about the interaction of stromal components in odontogenic tumors. Thus, the aim of this study was to investigate mast cells (MCs), myofibroblasts, macrophages, and their possible association with angiogenesis and lymphangiogenesis in keratocystic odontogenic tumors (KCOTs). MATERIAL AND METHODS: Thirty cases of KCOTs were included and analyzed by immunohistochemistry for mast cell tryptase, α-SMA, CD34, CD163, and D240. For comparative purpose, 15 radicular cysts (CRs) and 7 pericoronal follicles (PFs) were included. RESULTS: There was an increase in MCs for RCs and this difference was significant when they were compared to KCOTS and PFs. A significant increase in the density of MFs was observed for KCOTs when compared to RCs and PFs (P = 0.00). No significant difference in CD163-positive macrophages (P = 0.084) and CD34-positive vessels (P = 0.244) densities was observed between KCOTs, RCs, and PFs, although KCOTs showed a higher density of all proteins. Significant difference in lymphatic vessel density was observed for KCOTs when compared to RCs and PFs (P = 0.00). Positive correlation was observed between mast cell tryptase and CD34 in KCOTs (P = 0.025). CONCLUSIONS: A significant interaction between the MC population and CD34-positive vessels in KCOTs supported the hypothesis that MCs and blood vessels contribute to the stromal scaffold of KCOT.