Genetic profiles of different subsets of Merkel cell carcinoma show links between combined and pure MCPyV-negative tumors.

Tumorigenesis in Merkel cell carcinoma (MCC) is driven by (1) clonal integration of the Merkel cell polyomavirus (MCPyV) in neoplastic cells and/or (2) genetic damage by ultraviolet (UV) light. A higher mutational burden, a UV-mutational signature, and many mutations in the TP53 and RB1 genes characterize the virus-negative subset. MCPyV-negative MCCs include combined (often squamous and neuroendocrine) and pure (neuroendocrine) tumors. Because a combined morphology could elude detection microscopically, we sought a genetic link between combined and pure virus-negative tumors. From a global cohort of 46 cases, 9 pure MCPyV-positive, 9 pure MCPyV-negative, and 10 combined MCPyV-negative MCCs were studied by genome-wide microarray in search of copy number aberrations. The entire cohort (n=46) was evaluated by next-generation sequencing for mutations in selected tumor suppressor genes and oncogenes. More copy number aberrations and a greater fraction of the genome were changed in combined and pure MCPyV-negative tumors relative to MCPyV-positive cases (P<.01 for all comparisons). No difference in these parameters was found between the 2 MCPyV-negative groups. Copy number loss of RB1 or an inactivating RB1 mutation (either or both) was common in combined (8/10, 80%) and pure (7/9, 78%) MCPyV-negative tumors but not MCPyV-positive cases (1/9, 11%). A similar trend was seen for TP53 (combined [2/10, 20%] and pure virus-negative tumors [5/9, 56%] showed gene copy number loss or mutations contrasted with pure virus-positive cases [0/9, 0%]). The shared genetic profiles of combined and pure MCPyV-negative tumors link these subsets and separate them from MCPyV-positive tumors.