Head and neck mucosal melanoma (MM) is an aggressive and rare neoplasm of melanocytic origin. To date, few retrospective series and case reports have been reported on MM. This article reviews the current evidence on head and neck MM and the molecular pathways that mediate the pathogenesis of this disease. Head and neck MM accounts for 0.7%-3.8% of all melanomas and involve (in decreasing order of frequency) the sinonasal cavity, oral cavity, pharynx, larynx, and upper esophagus. Although many studies have examined MM of the head and neck and the underlying molecular pathways, individual genetic and molecular alterations were less investigated. Further studies are needed to complement existing data and to increase our understanding of melanocytes tumorigenesis.
a diffuse expression in mucous and serous acini, in addition to strong apical membrane expression within lumen of intercalated ductal cells. This topographic analysis of AQP1, 3 and 5 revealed differences in the expression pattern throughout salivary gland developmental stages, suggesting different roles for each protein in human glandular maturation.
Oral mucosal melanoma is rare. Its incidence peaks between 41 and 60 years of age; male/female ratio is 2:1. Preferred oral sites include hard palate and maxillary gingiva. Risk factors have not been clearly identified, but pigmented lesions may be present before the diagnosis of oral melanoma. We report an unusual case of oral mucosal melanoma of long-standing duration on hard palate and maxillary alveolar ridge in a male patient. Histopathologic features confirmed the diagnosis of invasive melanoma with a prominent in situ component. A cell lineage derived from the tumor was established and characterized, with phenotypic markers of melanocytes.
Background: Detection of somatic mutations is a mandatory practice for therapeutic definition in precision oncology. However, somatic mutation detection protocols use DNA from formalin-fixed and paraffin-embedded (FFPE) tumor tissues, which can result in detection of nonreproducible sequence artifacts, especially C:G > T:A transitions, in DNA. In recent studies, DNA pretreatment with uracil DNA glycosylase (UDG), an enzyme involved in base excision repair, significantly reduced the number of DNA artifacts after mutation detection by next-generation sequencing (NGS) and other methods, without affecting the capacity to detect real mutations. This study aimed to evaluate the effects of UDG enzymatic pretreatment in reducing the number of DNA sequencing artifacts from FFPE tumor samples, to improve the accuracy of genetic testing in the molecular diagnostic routine. Methods: We selected 12 FFPE tumor samples (10 melanoma, 1 lung, and 1 colorectal tumor sample) with different storage times. We compared sequencing results of a 16-hotspot gene panel of NGS libraries prepared with UDG-treated and untreated samples. Results: All UDG-treated samples showed large reductions in the total number of transitions (medium reduction of 80%) and the transition/transversion ratio (medium reduction of 75%). In addition, most sequence artifacts presented a low variant allele frequency (VAF < 10%) which are eliminated with UDG treatment. Conclusion: Including UDG enzymatic treatment before multiplex amplification in the NGS workflow significantly decreased the number of artifactual variants detected in FFPE samples. Thus, including this additional step in the current methodology should improve the rate of true mutation detection in the molecular diagnostic routine.
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