Genome editing in animals with minimal PAM CRISPR-Cas9 enzymes.

The requirement for Cas nucleases to recognize a specific PAM is a major restriction for genome editing. SpCas9 variants SpG and SpRY, recognizing NGN and NRN PAMs, respectively, have contributed to increase the number of editable genomic sites in cell cultures and plants. However, their use has not been demonstrated in animals.

A Living Organism in your CRISPR Toolbox: Is a Rapid and Efficient Model for Developing CRISPR-Cas Technologies.

The Cas9 nuclease from (SpCas9) is the most popular enzyme for CRISPR technologies. However, considering the wide diversity of microorganisms (discovered and still unknown), a massive number of CRISPR effectors are being and will be identified and characterized in the search of optimal Cas variants for each of the many applications of CRISPR. In this context, a versatile and efficient multicellular system for CRISPR editing such as would be of great help in the development of these effectors.

Efficient Generation of Endogenous Fluorescent Reporters by Nested CRISPR in .

CRISPR-based genome-editing methods in model organisms are evolving at an extraordinary speed. Whereas the generation of deletion or missense mutants is quite straightforward, the production of endogenous fluorescent reporters is more challenging. We have developed Nested CRISPR, a cloning-free ribonucleoprotein-driven method that robustly produces endogenous fluorescent reporters with EGFP, mCherry or wrmScarlet in This method is based on the division of the fluorescent protein (FP) sequence in three fragments.