Optimizing ErCas12a for efficient gene editing in Arabidopsis thaliana.

The ErCas12a nuclease, also known as MAD7, is part of a CRISPR/Cas system from Eubacterium rectale and distantly related to Cas12a nucleases. As it shares only 31% sequence homology with the commonly used AsCas12a, its intellectual property may not be covered by the granted patent rights for Cas12a nucleases. Thus, ErCas12a became an attractive alternative for practical applications. However, the editing efficiency of ErCas12a is strongly target sequence- and temperature-dependent. Therefore, optimization of the enzyme activity through protein engineering is especially attractive for its application in plants, as they are cultivated at lower temperatures. Based on the knowledge obtained from the optimization of Cas12a nucleases, we opted to improve the gene editing efficiency of ErCas12a by introducing analogous amino acid exchanges. Interestingly, neither of these mutations analogous to those in the enhanced or Ultra versions of AsCas12a resulted in significant editing enhancement of ErCas12a in Arabidopsis thaliana. However, two different mutations, V156R and K172R, in putative alpha helical structures of the enzyme showed a detectable improvement in editing. By combining these two mutations, we obtained an improved ErCas12a (imErCas12a) variant, showing several-fold increase in activity in comparison to the wild-type enzyme in Arabidopsis. This variant yields strong editing efficiencies at 22 °C which could be further increased by raising the cultivation temperature to 28 °C and even enabled editing of formerly inaccessible targets. Additionally, no enhanced off-site activity was detected. Thus, imErCas12a is an economically attractive and efficient alternative to other CRISPR/Cas systems for plant genome engineering.

The CRISPR/Cas revolution continues: From efficient gene editing for crop breeding to plant synthetic biology.

Since the discovery that nucleases of the bacterial CRISPR (clustered regularly interspaced palindromic repeat)-associated (Cas) system can be used as easily programmable tools for genome engineering, their application massively transformed different areas of plant biology. In this review, we assess the current state of their use for crop breeding to incorporate attractive new agronomical traits into specific cultivars of various crop plants. This can be achieved by the use of Cas9/12 nucleases for double-strand break induction, resulting in mutations by non-homologous recombination. Strategies for performing such experiments - from the design of guide RNA to the use of different transformation technologies - are evaluated. Furthermore, we sum up recent developments regarding the use of nuclease-deficient Cas9/12 proteins, as DNA-binding moieties for targeting different kinds of enzyme activities to specific sites within the genome. Progress in base deamination, transcriptional induction and transcriptional repression, as well as in imaging in plants, is also discussed. As different Cas9/12 enzymes are at hand, the simultaneous application of various enzyme activities, to multiple genomic sites, is now in reach to redirect plant metabolism in a multifunctional manner and pave the way for a new level of plant synthetic biology.