DNA polymerases have long been considered to follow the canonical pathway in which enzyme binds DNA first, then chooses the correct nucleotide by Watson-Crick base pairing. However, recent studies have reported that the noncanonical pathway involving nucleotide prebinding in the absence of DNA can modulate the fidelity of some DNA polymerases. The X-family DNA polymerase Mu (Pol Mu) has Mn2+ specificity for its functions and extremely low fidelity in the presence of Mn2+. Here, we found that Pol Mu can prebind MndNTP in a functionally relevant conformation. Besides, the Mn2+ preference has already exerted at the prebinding stage. A total of 19 structures have been determined in this study to evaluate the structural basis for the noncanonical mechanism in various functions of Pol Mu. Our findings suggest that Pol Mu can be preactivated by prebinding nucleotide in the presence of Mn2+ ion. Moreover, Pol Mu could utilize this noncanonical mechanism as the primary pathway for catalysis. On the other hand, Pol Beta, a high-fidelity DNA polymerase in X-family, is the main enzyme for base excision repair. Pol Beta effectively utilizes the N-helix closure as a conformational selection mechanism to choose the correct incoming nucleotide after DNA binding. Our study showed that Pol Beta has an unexpected affinity to MndNTP in the absence of DNA. The structures of Pol Beta in complex with MndNTP exhibit the conformational changes in D-subdomain for DNA binding and a 70% closed state. The catalytically active conformation may promote mismatch pairing once MndNTP-bound Pol Beta binds to DNA. Besides, our finding can also provide a possible explanation for why Mn2+ reducing the fidelity of DNA polymerases. Overall, this work expands the scale of the noncanonical pathway to include DNA polymerases from high to low fidelity.