Histone lysine methyltransferase G9a (also known as EHMT2) is widely expressed in various tissue. It catalyzes the mono- and di-methylation of lysine 9 on histone H3 N-tail to form transcriptionally inactive heterochromatin and silence gene expression. The G9a plays an important role in cell proliferation, differentiation, and cellular aging. It is reported that G9a is overexpressed in various cancer types and has a positive correlation with cancer cell proliferation and tumor size. In our initial data, which used a breast cancer cell line also has elevated G9a expression as the cell model, G9a was associated with the component of the Minichromosome Maintenance (MCM) complex. In TCGA database analysis, the G9a has positive correlations with MCMs at the transcription expression in breast cancer. The candidate molecule, MCM complex, is a heterohexamer, which is composed of MCM2-7, and a major helicase in DNA replication which is overexpressed in multiple cancers. The purpose of this study is to clarify the crosstalk between the MCM complex and G9a in the proliferation of the cancer cell and get insight into the binding region among them. First, we verified that G9a, as well as MCM, had a positive correlation with DNA synthesis and short-/long-term cell proliferation. Next, we discovered that G9a increased the nuclear distribution of MCMs but did not affect transcription level and subunits association. In addition, the chromatin loading of MCMs was attenuated after knockdown or inhibition of G9a, and the DNA polymerase epsilon which subsequently binds after the MCM complex was also attenuated. To investigate the interaction between G9a and MCMs, we utilized multiple protein-protein interaction analyses to reveal that the ankyrin (ANK) repeat domain of G9a directly interacted with the N-C linker of MCM4. Based on the literature and the prediction software, we suggested that the arginine-methllysine motif of the MCM4 N-C linker may be recognized by the ANK repeat domain of G9a. In conclusion, we discovered that the G9a increased nuclear distribution and chromatin loading of the MCM complex which results in DNA replication and cell proliferation by interacting with MCM4.