CCRG-05. A UNIFYING AND SELF-REINFORCING MECHANISM OF TUMOR IMMORTALITY IN TERT PROMOTER MUTANT CANCERS

Telomerase Reverse Transcriptase promoter mutations enable tumor cell immortality in millions of cancer patients annually. While prior therapies targeting telomerase lacked tumor selectivity and were poorly tolerated, TERT promoter mutations and their regulation present a unique opportunity for tumor specific reversal of cellular immortality. The two hotspot mutations, G228A and G250A, generate identical de novo E26 transformation specific (ETS) transcription factor binding sites. However, the 28 ETS factors share a similar binding site preference, raising the question of whether all ETS factors can reactivate TERT. In glioblastoma and a few other cancers, we have shown the de novo ETS site along with a nearby native ETS site (ETS-195/200) recruit one ETS factor, the GA-binding protein (GABP) tetramer, to reactivate TERT. This GABP-mediated mechanism may be restricted to specific cancer types and the two hotspot mutations or could be widely relevant to any cancer with a de novo ETS TERT promoter mutation. We have found that the GABP tetramer activates 6 distinct mutant TERT promoters across 16 different cancer types. However, TERT expression is maintained in most tetramer depleted tumor cells as the tetramer is serially replaced by GABP dimers and weakly by a paralogous tetramer complex that increase following disengagement of GABP tetramer-mediated negative feedback loops. Elimination of both the tetramer and dimer reinstates epigenetic repression of TERT, shortens telomeres, and prevents cancer cell division. However, some knockout cancer cells avoid this fate through weak activation of TERT by the paralogous GABP tetramer complex. The compensatory maintenance of TERT expression can be overcome with a dominant negative GABPB1, leading to TERT silencing, evidenced by gene expression and non-invasive metabolic imaging correlates, and telomere shortening in TERT promoter mutant glioblastoma. We are currently investigating the delivery of this dominant negative to tumor cells via clinically approved retroviral replicating vectors.