Steric regulation of CRISPR/Cas12a trans-cleavage kinetics via split-activator extensions.
Jianhong Zhang, Xin He, Jing Huang, Cheng Cheng, Guowei He, Ruili Xia, Jun Yang, Jianmei Chen, Lirong Guo, Debing Xiang, Feng Li, Jing Shi, Pu Li
Abstract
Open AccessClustered regularly interspaced short palindromic repeats (CRISPR)/Cas12a holds substantial promise for molecular diagnostics, yet its rapid and uncontrolled activation often results in background leakage and disrupts the coordination of upstream reaction modules. Here, we established a steric-regulation framework that enables predictable tuning of Cas12a trans-cleavage kinetics through rationally engineered extensions on split activators. Systematic analysis of extension orientation, length, and hybridization state revealed quantitative and direction-dependent rules governing steric control of activator assembly and Cas12a activation. Guided by these insights, we integrated the sterically regulated split activator into an entropy-driven DNA circuit to construct a fully one-pot cascaded detection system. The engineered steric barriers effectively suppressed premature activation and established precise kinetic matching between the DNA circuit and Cas12a. The resulting platform achieved a detection limit of 1.24 pM for microRNA-21 and demonstrated high fidelity. This work defines a predictable steric-gating mechanism for Cas12a activation and delivers a nucleic-acid-only regulatory module that can be incorporated into diverse CRISPR architectures, supporting the development of robust, leakage-resistant one-pot diagnostic systems.