Using spatially resolved spectroscopic data from the Mapping Nearby Galaxies at Apache Point Observatory sample, we investigate the parameters influencing the radial gradients of gas-phase metallicity ( ${\rm{\nabla }}\mathrm{log}({\rm{O}}/{\rm{H}})$ ) to determine whether disk formation is primarily driven by coplanar gas inflow or by the independent evolution of distinct regions within the disk. Our results show that ${\rm{\nabla }}\mathrm{log}({\rm{O}}/{\rm{H}})$ strongly correlates with local gas-phase metallicity at a given stellar mass, with steeper gradients observed in metal-poorer disks. This trend supports the coplanar gas inflow scenario, wherein the gas is progressively enriched by in situ star formation as it flows inward. In contrast, the radial gradient of stellar mass surface density shows very weak correlations with ${\rm{\nabla }}\mathrm{log}({\rm{O}}/{\rm{H}})$ , which is inconsistent with the independent evolution mode, where gas inflow, star formation, and metal enrichment occur independently within each annulus of the disk. Furthermore, we find that ${\rm{\nabla }}\mathrm{log}({\rm{O}}/{\rm{H}})$ is also closely correlated with an indicator of local gas turbulence ${\sigma }_{{\rm{gas}}}/{R}_{{\rm{e}}}$ , highlighting the competing roles of turbulence and coplanar inflow in shaping metallicity gradients. Our results provide indirect observational evidence supporting coplanar gas inflow as the driving mechanism for disk evolution.