RESUMO
In vitro RNA synthesis technologies are crucial in developing therapeutic RNA drugs, such as mRNA vaccines and RNA interference (RNAi) therapies. Enzymatic RNA synthesis, recognized for its sustainability and efficiency, enables the production of extensive RNA sequences under mild conditions. Among the enzymes utilized, T7 RNA polymerase is distinguished by its exceptional catalytic efficiency, enabling the precise and rapid transcription of RNA from DNA templates by recognizing the specific T7 promoter sequence. With the advancement in clinical applications of RNA-based drugs, there is an increasing demand for the synthesis of chemically modified RNAs that are stable and resistant to nuclease degradation. To this end, researchers have applied directed evolution to broaden the enzyme's substrate scope, enhancing its compatibility with non-canonical substrates and reducing the formation of by-products. This review summarizes the progress in engineering T7 RNA polymerase for these purposes and explores prospective developments in the field.
RESUMO
Proteins capable of switching between distinct active states in response to biochemical cues are ideal for sensing and controlling biological processes. Activatable CRISPR-Cas systems are significant in precise genetic manipulation and sensitive molecular diagnostics, yet directly controlling Cas protein function remains challenging. Herein, we explore anti-CRISPR (Acr) proteins as modules to create synthetic Cas protein switches (CasPSs) based on computational chemistry-directed rational protein interface engineering. Guided by molecular fingerprint analysis, electrostatic potential mapping, and binding free energy calculations, we rationally engineer the molecular interaction interface between Cas12a and its cognate Acr proteins (AcrVA4 and AcrVA5) to generate a series of orthogonal protease-responsive CasPSs. These CasPSs enable the conversion of specific proteolytic events into activation of Cas12a function with high switching ratios (up to 34.3-fold). These advancements enable specific proteolysis-inducible genome editing in mammalian cells and sensitive detection of viral protease activities during virus infection. This work provides a promising strategy for developing CRISPR-Cas tools for controllable gene manipulation and regulation and clinical diagnostics.