Analysis of Ustilago maydis Pot1 reveals context-dependent, dichotomous regulation of homology-directed DNA repair factors by a telomere protein

The telomere G-strand binding protein Pot1 plays multifaceted roles in telomere maintenance and protection. We examined the biochemical activity and genetic mechanisms of Pot1 in Ustilago maydis, a fungal model that recapitulates key features of mammalian telomere regulation. We found that U. maydis Pot1 binds directly to Rad51 and regulates the latter9s strand exchange activity. Deleting an N-terminal domain of Pot1 implicated in Rad51-binding caused telomere shortening, suggesting that Pot1-Rad51 interaction facilitates telomere replication. Depleting Pot1 through transcriptional repression triggered growth arrest as well as rampant recombination, leading to multiple telomere aberrations. In addition, telomere repeat RNAs transcribed from both the G- and C-strand were dramatically up-regulated, and this was accompanied by elevated levels of telomere RNA-DNA hybrids. Telomere abnormalities of pot1-deficient cells were suppressed, and cell viability was rescued by the deletion of rad51 or brh2 (the BRCA2 ortholog), indicating that homology-directed repair (HDR) proteins are key mediators of telomere aberrations and cellular toxicity. Together, these observations underscore the complex physical and functional interactions between Pot1 and DNA repair factors, leading to context-dependent and dichotomous effects of HDR proteins on telomere maintenance and protection.