The extent of multiallelic, co-editing of LIGULELESS1 in highly polyploid sugarcane tunes leaf inclination angle and enables selection of the ideotype for biomass yield.

Sugarcane (Saccharum spp. hybrid) is a prime feedstock for commercial production of biofuel and table sugar. Optimizing canopy architecture for improved light capture has great potential for elevating biomass yield. LIGULELESS1 (LG1) is involved in leaf ligule and auricle development in grasses. Here, we report CRISPR/Cas9-mediated co-mutagenesis of up to 40 copies/alleles of the putative LG1 in highly polyploid sugarcane (2n = 100-120, x = 10-12). Next generation sequencing revealed co-editing frequencies of 7.4%-100% of the LG1 reads in 16 of the 78 transgenic lines. LG1 mutations resulted in a tuneable leaf angle phenotype that became more upright as co-editing frequency increased. Three lines with loss of function frequencies of ~12%, ~53% and ~95% of lg1 were selected following a randomized greenhouse trial and grown in replicated, multi-row field plots. The co-edited LG1 mutations were stably maintained in vegetative progenies and the extent of co-editing remained constant in field tested lines L26 and L35. Next generation sequencing confirmed the absence of potential off targets. The leaf inclination angle corresponded to light transmission into the canopy and tiller number. Line L35 displaying loss of function in ~12% of the lg1 NGS reads exhibited an 18% increase in dry biomass yield supported by a 56% decrease in leaf inclination angle, a 31% increase in tiller number, and a 25% increase in internode number. The scalable co-editing of LG1 in highly polyploid sugarcane allows fine-tuning of leaf inclination angle, enabling the selection of the ideotype for biomass yield.

CRISPR/Cas9 mediated targeted mutagenesis of LIGULELESS-1 in sorghum provides a rapidly scorable phenotype by altering leaf inclination angle.

Sorghum (Sorghum bicolor L. Moench) is one of the world's most cultivated cereal crops. Biotechnology approaches have great potential to complement traditional crop improvement. Earlier studies in rice and maize revealed that LIGULELESS-1 (LG1) is responsible for formation of the ligule and auricle, which determine the leaf inclination angle. However, generation and analysis of lg1 mutants in sorghum has so far not been described. Here, we describe CRISPR/Cas9 mediated targeted mutagenesis of LG1 in sorghum and phenotypic changes in mono- and bi-allelic lg1 mutants. Genome editing reagents were co-delivered to sorghum (var. Tx430) with the nptII selectable marker via particle bombardment of immature embryos followed by regeneration of transgenic plants. Sanger sequencing confirmed a single nucleotide insertion in the sgRNA LG1 target site. Monoallelic edited plantlets displayed more upright leaves in tissue culture and after transfer to soil when compared to wild type. T1 progeny plants with biallelic lg1 mutation lacked ligules entirely and displayed a more severe reduction in leaf inclination angle than monoallelic mutants. Transgene-free lg1 mutants devoid of the genome editing vector were also recovered in the segregating T1 generation. Targeted mutagenesis of LG1 provides a rapidly scorable phenotype in tissue culture and will facilitate optimization of genome editing protocols. Altering leaf inclination angle also has the potential to elevate yield in high-density plantings.

CRISPR/Cas: a Nobel Prize award-winning precise genome editing technology for gene therapy and crop improvement.

Since it was first recognized in bacteria and archaea as a mechanism for innate viral immunity in the early 2010s, clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein (Cas) has rapidly been developed into a robust, multifunctional genome editing tool with many uses. Following the discovery of the initial CRISPR/Cas-based system, the technology has been advanced to facilitate a multitude of different functions. These include development as a base editor, prime editor, epigenetic editor, and CRISPR interference (CRISPRi) and CRISPR activator (CRISPRa) gene regulators. It can also be used for chromatin and RNA targeting and imaging. Its applications have proved revolutionary across numerous biological fields, especially in biomedical and agricultural improvement. As a diagnostic tool, CRISPR has been developed to aid the detection and screening of both human and plant diseases, and has even been applied during the current coronavirus disease 2019 (COVID-19) pandemic. CRISPR/Cas is also being trialed as a new form of gene therapy for treating various human diseases, including cancers, and has aided drug development. In terms of agricultural breeding, precise targeting of biological pathways via CRISPR/Cas has been key to regulating molecular biosynthesis and allowing modification of proteins, starch, oil, and other functional components for crop improvement. Adding to this, CRISPR/Cas has been shown capable of significantly enhancing both plant tolerance to environmental stresses and overall crop yield via the targeting of various agronomically important gene regulators. Looking to the future, increasing the efficiency and precision of CRISPR/Cas delivery systems and limiting off-target activity are two major challenges for wider application of the technology. This review provides an in-depth overview of current CRISPR development, including the advantages and disadvantages of the technology, recent applications, and future considerations.

Efficient genome editing in wheat using Cas9 and Cpf1 (AsCpf1 and LbCpf1) nucleases.

Genome editing can be used to create new wheat varieties with enhanced performance. Clustered regularly interspaced short palindromic repeat (CRISPR) is a powerful tool for knockout generation, precise modification, multiplex engineering, and the activation and repression of target genes. Targeted mutagenesis via RNA-guided genome editing using type II CRISPR-Cas9 is highly efficient in some plant species, but not in others. One possible solution is to use newly discovered variants of genome editing enzymes such as the class 2 system component Cpf1 (CRISPR from Prevotella and Francisella 1) in place of the more commonly used Cas9. We compared the editing efficiency of Cas9 and two Cpf1 orthologs, AsCpf1 (Acidaminococcus spp. BV3L6) and LbCpf1 (Lachnospiraceae bacterium ND2006) in wheat (Triticum aestivum). LbCpf1 had a higher editing efficiency for the target gene TaPDS than AsCpf1 and Cas9, and Cas9 induced more off-target mutations than AsCpf1 and LbCpf1, suggesting that CRISPR-LbCpf1 is a powerful genome editing tool for polyploid plants such as wheat.

Plant Small Non-coding RNAs and Their Roles in Biotic Stresses.

Non-coding RNAs (ncRNAs) have emerged as critical components of gene regulatory networks across a plethora of plant species. In particular, the 20-30 nucleotide small ncRNAs (sRNAs) play important roles in mediating both developmental processes and responses to biotic stresses. Based on variation in their biogenesis pathways, a number of different sRNA classes have been identified, and their specific functions have begun to be characterized. Here, we review the current knowledge of the biogenesis of the primary sRNA classes, microRNA (miRNA) and small nuclear RNA (snRNA), and their respective secondary classes, and discuss the roles of sRNAs in plant-pathogen interactions. sRNA mobility between species is also discussed along with potential applications of sRNA-plant-pathogen interactions in crop improvement technologies.