Abstract
Low-grade gliomas frequently recur after surgical resection and may undergo malignant progression to a higher grade with a significantly worse prognosis. Understanding the origin and evolution of recurrences is critical for effectively treating residual disease to delay or prevent recurrence. Here, we extend previous work by sequencing the exomes of over 30 initial low-grade gliomas and their patient-matched recurrences to reconstruct the patterns of clonal evolution. We also sequence multiple spatially distinct samples from both initial low-grade and recurrent high-grade tumors to extensively dissect intratumoral heterogeneity. We identify a broad spectrum of genetic relatedness within tumor pairs, with the unexpected loss of canonical driver mutations upon recurrence. Therefore, resected portions of initial tumors can differ dramatically from tumorigenic portions of adjacent residual disease. The identification of common ancestral clones additionally reveals the order in which key driver mutations are acquired, allowing for a model of low-grade astrocytoma gliomagenesis. We have also previously shown that the treatment of low-grade gliomas with temozolomide induces hypermutation and alters the function of key cancer genes and their cognate pathways, potentially driving malignant progression. We extend that finding with an analysis of the evolution and intratumoral heterogeneity of additional hypermutated glioblastoma recurrences. These evolutionary trajectories have immediate ramifications for the use of mutagenic chemotherapies such as temozolomide, and for personalizing therapy to eliminate residual disease.
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