Modular CRISPR Transcriptional Activators Enabled by RNA-Sensing Guide RNAs in Mammalian Cells and Zebrafish Embryos

The iSBH-sgRNA system could potentially leverage various endogenous RNA biomarkers as triggers, expanding its therapeutic applications significantly. One type of RNA biomarker that could be utilized is long non-coding RNAs (lncRNAs). These lncRNAs play crucial roles in gene regulation and have been implicated in various diseases. By designing iSBH-sgRNAs to detect specific lncRNAs associated with certain diseases, such as cancer or neurodegenerative disorders, the system could enable precise targeting of affected cells for therapeutic interventions. Moreover, microRNAs (miRNAs) could also serve as valuable triggers for the iSBH-sgRNA system. MiRNAs are small non-coding RNAs that regulate gene expression post-transcriptionally and are dysregulated in many diseases. By designing iSBH-sgRNAs to detect disease-specific miRNAs, the system could be used to modulate gene expression in a highly targeted manner, offering potential therapeutic benefits. Furthermore, viral RNAs could be targeted by the iSBH-sgRNA system for antiviral applications. By designing iSBH-sgRNAs to detect viral RNA sequences, the system could be used to activate CRISPR-mediated antiviral responses in infected cells, providing a novel approach to combat viral infections.

To achieve tighter control over CRISPR activity and reduce off-target effects in vivo, the iSBH-sgRNA system could be further optimized in several ways: Enhanced Trigger Specificity: By refining the design of iSBH-sgRNAs to have higher specificity for RNA triggers, the system can minimize off-target effects and ensure precise activation only in the presence of the intended RNA biomarkers. Improved Chemical Modifications: Implementing advanced chemical modifications in iSBH-sgRNAs to enhance stability and prevent degradation by cellular nucleases can improve the overall efficiency and specificity of the system. Optimized Delivery Methods: Developing more efficient delivery methods for iSBH-sgRNAs to ensure uniform distribution and uptake in target tissues can enhance the system's effectiveness and reduce variability in activation levels. Fine-Tuning CRISPR Components: Adjusting the expression levels of CRISPR effectors and reporters, as well as optimizing the choice of CRISPR activators, can help fine-tune the system for optimal performance and minimize off-target effects. Incorporating Feedback Mechanisms: Implementing feedback mechanisms that monitor and regulate CRISPR activity based on the level of RNA triggers detected can provide dynamic control over gene editing processes, further reducing off-target effects.

The RNA-sensing CRISPR technology could open up a wide range of applications beyond gene editing and transcriptional regulation, particularly in the fields of synthetic biology and cellular reprogramming: RNA-Based Logic Circuits: The ability of iSBH-sgRNAs to detect specific RNA triggers could be harnessed to design intricate RNA-based logic circuits for synthetic biology applications, enabling the development of complex cellular computing systems. RNA-Triggered Drug Delivery: By coupling the iSBH-sgRNA system with drug delivery mechanisms, researchers could create RNA-triggered drug release systems that activate therapeutic compounds only in the presence of specific RNA biomarkers, offering targeted and controlled drug delivery. Cell Fate Reprogramming: Leveraging the RNA-sensing capabilities of iSBH-sgRNAs, researchers could explore novel approaches to cellular reprogramming by activating specific gene expression patterns in response to endogenous RNA signals, facilitating the conversion of cell types for regenerative medicine applications. RNA-Based Biosensors: The iSBH-sgRNA system could be adapted to serve as a platform for developing RNA-based biosensors that detect and respond to specific RNA signatures, enabling real-time monitoring of cellular processes and disease biomarkers. Environmental Sensing: By engineering iSBH-sgRNAs to detect environmental RNA triggers, such as pathogen-specific RNA sequences or pollutant-induced RNA changes, the technology could be applied in environmental monitoring and biosafety applications.