Genome Editing in Zebrafish by ScCas9 Recognizing NNG PAM

Enhanced Genome Editing Activity with Novel Chimeric ScCas9 Variants in Rice

The Streptococcus canis Cas9 protein (ScCas9) recognizes the NNG protospacer adjacent motif (PAM), offering a wider range of targets than that offered by the commonly used S. pyogenes Cas9 protein (SpCas9). However, both ScCas9 and its evolved Sc++ variant still exhibit low genome editing efficiency in plants, particularly at the less preferred NTG and NCG PAM targets. In this study, a chimeric SpcRN++ variant is engineered by grafting the recognition (REC) domain of SpCas9 into the Sc++ variant, incorporating the R221K/N394K mutations, and retaining the positively charged loop of S. anginosus Cas9. The SpcRN++ variant exhibits a higher genome editing capacity and wider target range than the Sc++ variant in rice protoplasts and stable transgenic plants. Further evidence indicates that nSpcRN++-based A3A/Y130F and TadA8e exhibit enhanced cytosine and adenine editing efficiency in plants. Finally, herbicide-resistant rice germplasms are produced by targeting the OsACC gene using nSpcRN++-based adenine base editors. These results demonstrate that SpcRN++ is a powerful tool for genome editing in plants, and this integrative protein engineering strategy holds promise for engineering other Cas9 proteins.

Genetically engineered zebrafish as models of skeletal development and regeneration

Zebrafish (Danio rerio) are aquatic vertebrates with significant homology to their terrestrial counterparts. While zebrafish have a centuries-long track record in developmental and regenerative biology, their utility has grown exponentially with the onset of modern genetics. This is exemplified in studies focused on skeletal development and repair. Herein, the numerous contributions of zebrafish to our understanding of the basic science of cartilage, bone, tendon/ligament, and other skeletal tissues are described, with a particular focus on applications to development and regeneration. We summarize the genetic strengths that have made the zebrafish a powerful model to understand skeletal biology. We also highlight the large body of existing tools and techniques available to understand skeletal development and repair in the zebrafish and introduce emerging methods that will aid in novel discoveries in skeletal biology. Finally, we review the unique contributions of zebrafish to our understanding of regeneration and highlight diverse routes of repair in different contexts of injury. We conclude that zebrafish will continue to fill a niche of increasing breadth and depth in the study of basic cellular mechanisms of skeletal biology.