Abstract
BACKGROUND: Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-based gene editing has become a promising approach for enhancing traits in aquaculture species. Nevertheless, traditional CRISPR-Cas systems encounter challenges, including significant off-target effects and strict protospacer adjacent motif (PAM) requirements, which constrain their use in crustaceans such as Penaeus monodon. To address these limitations, this research has developed PmMAD7, a codon-optimized CRISPR system specifically designed for P. monodon, which incorporates nuclear localization signals to improve editing efficiency and precision. RESULTS: This research successfully synthesized and delivered PmMAD7 mRNA and crRNAs targeting the ECH1 and AQP4 genes into the hemocytes of P. monodon. Quantitative PCR analysis demonstrated that PmMAD7 achieved significant gene silencing, reducing the expression levels of ECH1 and AQP4 by 81.5% and 78.33%, respectively. Next-generation sequencing confirmed targeted insertions and deletions at the gene loci, with knockout efficiencies of 14.81% for ECH1 and 20.57% for AQP4, which were significantly higher than those obtained with LbCas12a (7.14% and 12.43%, respectively). Furthermore, functional analysis indicated that ECH1 knockout resulted in increased cell volume and mortality, while AQP4 knockout led to decreased cell volume and reduced viability. These specific results highlight the first successful demonstration of MAD7-based genome editing in shrimp. The broader PAM compatibility and enhanced editing efficiency of PmMAD7 provide a versatile platform for gene editing in shrimp. CONCLUSION: PmMAD7 constitutes an enhanced CRISPR editing tool specifically designed for P. monodon, exhibiting superior precision, expanded PAM compatibility, and enhanced editing efficacy relative to conventional Cas12a systems. These results lay the groundwork for the advancement of gene editing applications in crustaceans and contribute to sustainable genetic improvements in aquaculture.