DNA N6-methyl-2'-deoxyadenosine (6mdA) is an epigenetic modification in both eukaryotes and bacteria. Here we exploited stable isotope-labeled deoxynucleoside [15N5]-2'-deoxyadenosine ([15N5]-dA) as an initiation tracer and for the first time developed a metabolically differential tracing code for monitoring DNA 6mdA in human cells. We demonstrate that the initiation tracer [15N5]-dA undergoes a specific and efficient adenine deamination reaction leading to the loss the exocyclic amine 15N, and further utilizes the purine salvage pathway to generate mainly both [15N4]-dA and [15N4]-2'-deoxyguanosine ([15N4]-dG) in mammalian genomes. However, [15N5]-dA is largely retained in the genomes of mycoplasmas, which are often found in cultured cells and experimental animals. Consequently, the methylation of dA generates 6mdA with a consistent coding pattern, with a predominance of [15N4]-6mdA. Therefore, mammalian DNA 6mdA can be potentially discriminated from that generated by infecting mycoplasmas. Collectively, we show a promising approach for identification of authentic DNA 6mdA in human cells and determine if the human cells are contaminated with mycoplasmas.