An optimised CRISPR Cas9 and Cas12a mutagenesis toolkit for Barley and Wheat.

BACKGROUND: CRISPR Cas9 and Cas12a are the two most frequently used programmable nucleases reported in plant systems. There is now a wide range of component parts for both which likely have varying degrees of effectiveness and potentially applicability to different species. Our aim was to develop and optimise Cas9 and Cas12a based systems for highly efficient genome editing in the monocotyledons barley and wheat and produce a user-friendly toolbox facilitating simplex and multiplex editing in the cereal community. RESULTS: We identified a Zea mays codon optimised Cas9 with 13 introns in conjunction with arrayed guides driven by U6 and U3 promoters as the best performer in barley where 100% of T0 plants were simultaneously edited in all three target genes. When this system was used in wheat > 90% of T0 plants were edited in all three subgenome targets. For Cas12a, an Arabidopsis codon optimised sequence with 8 introns gave the best editing efficiency in barley when combined with a tRNA based multiguide array, resulting in 90% mutant alleles in three simultaneously targeted genes. When we applied this Cas12a system in wheat 86% & 93% of T0 plants were mutated in two genes simultaneously targeted. We show that not all introns contribute equally to enhanced mutagenesis when inserted into a Cas12a coding sequence and that there is rationale for including multiple introns. We also show that the combined effect of two features which boost Cas12a mutagenesis efficiency (D156R mutation and introns) is more than the sum of the features applied separately. CONCLUSION: Based on the results of our testing, we describe and provide a GoldenGate modular cloning system for Cas9 and Cas12a use in barley and wheat. Proven Cas nuclease and guide expression cassette options found in the toolkit will facilitate highly efficient simplex and multiplex mutagenesis in both species. We incorporate GRF-GIF transformation boosting cassettes in wheat options to maximise workflow efficiency.

Highly Efficient Gene Knockout in Medicago truncatula Genotype R108 Using CRISPR-Cas9 System and an Optimized Agrobacterium Transformation Method.

Medicago truncatula is the model plant species for studying symbioses with nitrogen-fixing rhizobia and arbuscular mycorrhizae, where edited mutants are invaluable for elucidating the contributions of known genes in these processes. Streptococcus pyogenes Cas9 (SpCas9)-based genome editing is a facile means of achieving loss of function, including where multiple gene knockouts are desired in a single generation. We describe how the user can customize our vector to target single or multiple genes, then how the vector is used to make M. truncatula transgenic plants containing target site mutations. Finally, obtaining transgene-free homozygous mutants is covered.

An Efficient Agrobacterium-Mediated Transformation Protocol for Hexaploid and Tetraploid Wheat.

Wheat, though a key crop plant with considerable influence on world food security, has nonetheless trailed behind other major cereals in the advancement of gene transformation technology for its improvement. New breeding technologies such as genome editing allow precise DNA manipulation, but their potential is limited by low regeneration efficiencies in tissue culture and the lack of transformable genotypes. We developed, in the hexaploid spring wheat cultivar "Fielder," a robust, reproducible Agrobacterium tumefaciens-mediated transformation system with transformation efficiencies of up to 33%. The system requires immature embryos as starting material and includes a centrifugation pretreatment before the inoculation with Agrobacterium. This high-throughput, highly efficient, and repeatable transformation system has been used effectively to introduce genes of interest for overexpression, RNA interference, and CRISPR-Cas-based genome editing. With slight modifications reported here, the standard protocol can be applied to the hexaploid wheat "Cadenza" and the tetraploid durum wheat "Kronos" with efficiencies of up to 4% and 10%, respectively. The system has also been employed to assess the developmental gene fusion GRF-GIF with outstanding results. In our hands, this technology combined with our transformation system improved transformation efficiency to 77.5% in Fielder. This combination should help alleviate the genotype dependence of wheat transformation, allowing new genome-editing tools to be used directly in more elite wheat varieties. © 2021 The Authors. Basic Protocol 1: Growing of donor plants Basic Protocol 2: Transformation of Agrobacterium with vector by electroporation Basic Protocol 3: Starting material collection, sterilization, and embryo inoculation Basic Protocol 4: Selection, regeneration, rooting, and acclimatization of transformants.