Abstract
Endogenous DNA damage occurs throughout the cell cycle, with cells responding differently at various stages. The base excision repair (BER) pathway predominantly repairs damaged bases in the genome. While extensively studied in interphase cells, it is unknown if BER operates in mitosis and how apurinic/apyrimidinic (AP) sites, intermediates in the BER pathway that inhibit transcriptional elongation, are processed for post-mitotic gene reactivation. In this study, using an alkaline comet assay, we demonstrate that BER is inefficient in mitosis and that AP endonuclease 1 (APE1), a key BER enzyme, is required for the repair of damage post-mitosis. We previously demonstrated that APE1 is acetylated (AcAPE1) in the chromatin. Using high-resolution microscopy, we show that AcAPE1 remains associated with specific regions in the condensed chromatin in each of the phases of mitosis. This association presumably occurs via the binding of APE1 to the G-quadruplex structure, a non-canonical DNA structure predominantly present in the transcribed gene regions. Additionally, using a nascent RNA detection strategy, we demonstrate that the knockdown of APE1 delayed the rapid post-mitotic transcriptional reactivation of genes. Our findings highlight the functional importance of APE1 in the mitotic chromosomes to facilitate faster repair of endogenous damage and rapid post-mitotic gene reactivation in daughter cells.