Abstract C53: The genetic evolution of oral cancer fields

Abstract

Abstract Introduction: The evolution of oral cancer results from the accumulation of genetic alterations. Field cancerization, where histologically or molecularly abnormal cells surround a clinically visible tumor to a wider extent, imposes a challenge to delineate surgical boundaries. We applied a newly emerging optical technique using direct fluorescence visualization (FV) to redefine the field of alteration. Using genomic profiling we examined multiple biopsies within the field to assess clonal expansion of cells within this optically altered field. Experimental Approach: A hand-held FV device was used in the operating room to define the field that extended beyond the margins of clinically visible oral cancer. Multiple biopsies (N=15) were taken within the altered FV field (FV loss or FVL) and the surgical margins with no FVL, as controls, from three patients. Histological assessment and microdissection were performed for each biopsied sample. The genomic profile of each sample was generated using a tiling-path DNA microarray. A breakpoint detection algorithm was used to define genetic breakpoints and clonal ordering was performed to infer the sequence of genetic events of samples within each patient. Result: Early stage low-grade dysplasias were found within the FVL field in all patients, while no dysplasia was detected in the areas with no FVL. In general, each field is histologically and genetically heterogeneous. Specifically, patient A presented with a clinically identifiable SCC (#1), while another SCC (#3) was found in an area 10-mm anterior to SCC#1, which was not clinically apparent but showed FVL. A moderate dysplasia (#2) was found between SCC#1 and SCC#3. Interestingly, 5q, 8p, and 8q loss were common among all three samples (suggesting a common progenitor), while genetic alterations (e.g., high-level amplification on 9p22.3-pter) accumulated in both SCC#3 and dysplasia#2 but was absent in SCC#1. On the other hand, SCC#1 accumulated different genetic changes (e.g., gain of 11q13.2-q13.4 (CCND1)). This suggested that two clonal lineages were present within this cancerous field. Similarly, in patient B, the biopsies obtained revealed both common and different genetic signatures. For example, a moderate dysplasia showed genetic alterations specific to this lesion (e.g., high-level amplification of 8q11.21 (SNAI2)), while its corresponding carcinoma in situ harbored numerous different genetic alterations, including three regions of high-level amplification (e.g., 20q11.23 (SRC)). Genomic profiles of these samples suggest that two different genetic pathways diverged from a common progenitor, while subsequent genetic alterations accumulated for the formation of each unique subpopulation. In patient C, one genetic pathway was found governing the development of the clinically identifiable SCC, and increased genetic alterations were detected in the SCC compared to the mild dysplasia. All the controls did not show matching genetic changes. Conclusion: Our results indicate that the genetics of the oral cancer field is extremely dynamic, where different clones are evolving in the field. Genetic alterations occurring early in the genetic pathway may be important events that prime the area for further development of cancer. These findings provide evidence for the importance of implementing optical technologies in defining surgical margins as well as the importance of tailored targeted therapies to effectively treat different subclones of a field. Citation Information: Cancer Res 2009;69(23 Suppl):C53.