Aprataxin encoded by APTX, which is the human homolog of yeast HNT3, reverses adenylation damages emerged from abortive DNA ligation during ribonucleotide and base excision repair. Thus, it corrects AMP-modified nucleic acid termini and protects genome integrity as a DNA ligase “proofreader”. Role of HNT3, which is a candidate p53-related gene, against DNA oxidative and alkylating damage indicates its antioxidant importance. Besides, previous studies demonstrated that absence of Aprataxin gives rise to ROS generation and oxidative stress in addition to mitochondrial dysfunction. Also, role of Aprataxin in drug and radiotherapy sensitivity was shown in many cancer. Since conformation of cysteine residues in p53 DNA-binding domain can be modified by oxidizing environment, functionality can be influenced by defective APTX. Although p53-Aprataxin interaction has been shown by co-immunoprecipitation, effects of APTX on p53 pathway were not studied. Aim of this study is to investigate Aprataxin-driven changes in p53-regulated processes in p53 wild-type cells through. According to results, Aprataxin overexpression leads to cell cycle arrest in low stress levels. However, it triggers cell death against induced stress in MCF10A cells. Moreover, apoptotic assay on MCF10A APTX Crispr cells indicated elevated level of basal cell death. Also, expression analysis of p53 targets in APTX knockdown MCF7 cells revealed that extrinsic apoptosis pathway might be induced. Consequently, these results help us to gain insight into how Aprataxin affects activity of p53 pathway. Further investigation providing stress accumulation based assays and protein level analysis is needed to figure out whether resulting changes are p53-dependent or not.