The fabrication of metalloenzyme-mimetic artificial catalyst is a promising approach to achieve maximum catalytic efficiency, but the rational integration of sophisticatedly optimized primary catalytic sites (PCS) and secondary coordination spheres (SCS) for specific transformation poses a grand challenge. Here in this work, we reported the tailored engineering of Cu PCS and perfluoroalkyl SCS onto zircounium-based framework [UiO-67-(BPY-Cu)-Fx (x = 3, 5, 7, 11)] [BPY=2,2′-bipyridine-5,5′-dicarboxylate] that can be utilized in the highly efficient carboxylic cyclization reaction between propargylamines and flue gas CO2. The perfluoroalkyl groups act as tunable SCS that can facilely adjust the surface electronegativity, hydrophobicity, as well as the CO2 affinity and water vapor-resistance by simply varying the chain length. Meanwhile, the synergy between the Cu PCS and perfluoroalkyl SCS significantly facilitated the cyclization step by stabilizing the critical transition state, leading to the fast cyclization to oxazolidinone ring. Owing to these features, UiO-67-(BPY-Cu)-F7 exhibited remarkable metalloenzyme-mimetic catalytic behavior by greatly facilitating the binding of propargylamines and CO2, promoting the stabilization of the critical transition state to cyclization, and boosting the releasing of oxazolidinones, which have been systematically investigated by the combination of substrates adsorption tests, in situ Fourier Transform Infrared Spectra, Grand Canonical Monte Carlo simulations, density functional theory calculations, etc. Consequently, UiO-67-(BPY-Cu)-F7 showed outstanding catalytic performance in the carboxylic cyclization of propargylamines and flue gas CO2 under ambient conditions, exhibiting 64 times higher turnover frequency (TOF) than that of homogeneous or other MOF catalysts, and exhibiting the highest TOF under similar conditions. The present work not only provides an alternative strategy for the construction of advanced carboxylic cyclization system, but also paves a new direction to the development of CO2 conversion with exceptional activity through the tailored engineering of PCS and SCS in metalloenzyme-mimetic artificial catalyst.