Abstract
Uracil is an unavoidable aberrant base in DNA sequences, the repair of which takes place by a highly efficient base excision repair mechanism. The removal of uracil from the genome requires multiple biochemical steps with conformational changes of DNA that inhibit DNA replication and interfere with transcription. However, the relevance of uracil in DNA for cellular physiology and transcriptional regulation is not fully understood. We investigated the functional roles of SMUG1 using knock-down (KD) and knock-out (KO) models. The proliferation ratio of SMUG1 KD and KO cells was decreased compared to WT control cells, and the cell cycle was arrested in the G2/M phases before the transition to mitosis. The apoptotic cell death was increased in KD and KO cell lines through the increase of BAX and active caspase 3 expression. Phospho-gamma-H2AX expression, which reflected accumulated DNA damage, was also increased in KO cells. Moreover, the apoptotic cells by DNA damage accumulation were markedly increased in SMUG1 KD and KO cells after ultraviolet C irradiation. Transcriptomic analysis using RNA-seq revealed that SMUG1 was involved in gene sets expression including cell cycle transition and chromatin silencing. Together, the results implicate SMUG1 as a critical factor in cell cycle and transcriptional regulation.
Highlights
IntroductionBase excision repair (BER) is a highly conserved mechanism from bacteria to humans, and it is essential for repairing endogenous DNA damage, including that caused by alkylation, oxidation, deamination, depurination, and single-strand breaks [2]
In aerobic organisms, such as animals, fungi, and bacteria, reactive oxygen species (ROS) are produced by normal metabolism and cause oxidative damage to DNA [1].Base excision repair (BER) is a highly conserved mechanism from bacteria to humans, and it is essential for repairing endogenous DNA damage, including that caused by alkylation, oxidation, deamination, depurination, and single-strand breaks [2]
We found that Smug1 was downregulated in ultraviolet B (UVB)-irradiated mouse retinas compared with control retinas [13]
Summary
Base excision repair (BER) is a highly conserved mechanism from bacteria to humans, and it is essential for repairing endogenous DNA damage, including that caused by alkylation, oxidation, deamination, depurination, and single-strand breaks [2]. Four different uracil-DNA glycosylase (UDG) genes have been identified, including SMUG1, UNG, TDG, and MBD4. In human cells, TDG and SMUG1 are the major enzymes responsible for the repair of the U:G mismatch caused by spontaneous cytosine deamination, whereas uracil arising in DNA through dUTP misincorporation is mainly dealt with by UNG [11]. SMUG1 is a key enzyme for repairing 5-hydroxymethyluracil, 5formyluracil, 5,6-dihydrouracil, alloxan, and other lesions generated during oxidative base damage induced by ionizing radiation and oxygen free radicals [12]. SMUG1 is involved in DNA repair in damaged cells, the functional role of SMUG1 in recognizing the damaged DNA regions in the genome and repairing mechanisms remains unclear
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