Alternative Lengthening of Telomeres (ALT) is an aberrant DNA recombination pathway which grants replicative immortality to approximately 10% of all cancers. Despite this high prevalence of ALT in cancer, the mechanism and genetics by which cells activate this pathway remain incompletely understood. A major challenge in dissecting the events that initiate ALT is the extremely low frequency of ALT induction in human cell systems. Guided by the genetic lesions that have been associated with ALT from cancer sequencing studies, we genetically engineered primary human pluripotent stem cells to deterministically induce ALT upon differentiation. Using this genetically defined system, we demonstrate that disruption of the p53 and Rb pathways in combination with ATRX loss-of-function is sufficient to induce all hallmarks of ALT and results in functional immortalization in a cell type-specific manner. We further demonstrate that ALT can be induced in the presence of telomerase, is neither dependent on telomere shortening nor crisis, but is rather driven by continuous telomere instability triggered by the induction of differentiation in ATRX-deficient stem cells.

Mutations in the shelterin protein POT1 are associated with diverse cancers and thought to drive carcinogenesis by impairing POT1s suppression of aberrant telomere elongation. To classify clinical variants of uncertain significance (VUSs) and identify cancer-driving loss-of-function mutations, we developed a locally haploid human stem cell system to evaluate >1900 POT1 mutations, including >600 VUSs. Unexpectedly, many validated familial cancer-associated POT1 (caPOT1) mutations are haplosufficient for cellular viability, indicating that some pathogenic alleles do not act through a loss-of-function mechanism. Instead, POT1s DNA damage response suppression and telomere length control are genetically separable. ATR inhibition enables isolation of frameshift mutants, demonstrating that the only essential function of POT1 is to repress ATR. Furthermore, comparison of caPOT1 and frameshift alleles reveals a class of caPOT1 mutations that elongate telomeres more rapidly than full loss-of-function alleles. This telomere length-promoting activity is independent from POT1s role in overhang sequestration and fill-in synthesis.