Heritable Tissue-Culture-Free Gene Editing in Nicotiana benthamiana through Viral Delivery of SpCas9 and sgRNA

Broadening the Nicotiana benthamiana research toolbox through the generation of dicer-like mutants using CRISPR/Cas9 approaches

RNA silencing in plants plays a pivotal role in various biological processes, including development, epigenetic modifications and stress response. Key components of this network are Dicer-like (DCL) proteins. Nicotiana benthamiana encodes four DCLs, each responsible for the generation of distinct small RNA (sRNA) populations, which regulate different functions. However, elucidating the precise role of each DCL has been proven challenging, as overlapping functions exist within DCLs. In our present study, we have successfully generated dcl2, dcl3 and dcl4 homozygous mutants, employing two different CRISPR/Cas9 approaches. The first approach is based on a transgene-mediated delivery of the single-guide RNA (sgRNA), while the second approach employs a viral vector for sgRNA delivery. By utilizing a suite of screening techniques, including polymerase chain reaction (PCR), T7 endonuclease I (T7E1) assay, high-resolution melt analysis (HRMA) and DNA sequencing, we successfully generated dcl2, dcl3 and dcl4 homozygous mutants harboring identical mutations in every allele. To evaluate these dcl mutants, we examined their sRNA profiles and phenotypes. We further have indications that homozygous mutations of a gene do not always lead to the desired loss-of-function, highlighting the importance of mutant evaluation. dcl mutants represent invaluable tools to explore how overlapping silencing pathways are connected to essential plant functions, including development, stress responses and pathogen defense. Additionally, they hold potential for biotechnological applications, such as crop improvement and gene silencing tools. We anticipate that our study will make significant contributions to enhance understanding of the role of DCLs in plants.

Virus-Induced Genome Editing (VIGE): One Step Away from an Agricultural Revolution

There is currently a worldwide trend towards deregulating the use of genome-edited plants. Virus-induced genome editing (VIGE) is a novel technique that utilizes viral vectors to transiently deliver clustered regularly interspaced short palindromic repeat (CRISPR) components into plant cells. It potentially allows us to obtain transgene-free events in any plant species in a single generation without in vitro tissue culture. This technology has great potential for agriculture and is already being applied to more than 14 plant species using more than 20 viruses. The main limitations of VIGE include insufficient vector capacity, unstable expression of CRISPR-associated (Cas) protein, plant immune reaction, host specificity, and reduced viral activity in meristem. Various solutions to these problems have been proposed, such as fusion of mobile elements, RNAi suppressors, novel miniature Cas proteins, and seed-borne viruses, but the final goal has not yet been achieved. In this review, the mechanism underlying the ability of different classes of plant viruses to transiently edit genomes is explained. It not only focuses on the latest achievements in virus-induced editing of crops but also provides suggestions for improving the technology. This review may serve as a source of new ideas for those planning to develop new approaches in VIGE.

Viral delivery of an RNA-guided genome editor for transgene-free germline editing in Arabidopsis

Genome editing is transforming plant biology by enabling precise DNA modifications. However, delivery of editing systems into plants remains challenging, often requiring slow, genotype-specific methods such as tissue culture or transformation1. Plant viruses, which naturally infect and spread to most tissues, present a promising delivery system for editing reagents. However, many viruses have limited cargo capacities, restricting their ability to carry large CRISPR-Cas systems. Here we engineered tobacco rattle virus (TRV) to carry the compact RNA-guided TnpB enzyme ISYmu1 and its guide RNA. This innovation allowed transgene-free editing of Arabidopsis thaliana in a single step, with edits inherited in the subsequent generation. By overcoming traditional reagent delivery barriers, this approach offers a novel platform for genome editing, which can greatly accelerate plant biotechnology and basic research.

Unlocking the potential of genome editing in agriculture with tissue culture-free techniques

Genome editing holds great promise for enhancing crop traits; however, progress has been slow due to inefficient delivery methods and reliance on tissue culture for regenerating edited plants, which are time-consuming and labor-intensive. To address these limitations, innovative tissue culture-free techniques have been developed, including meristem editing through biolistic-mediated delivery and RNA virus-mediated delivery. New methods for de novo gene-edited meristem induction and root suckering-based cut-dip-budding have also been established. While these approaches show promise, each faces challenges that must be addressed for practical application in crop improvement. We discuss the transformative potential of these techniques for crop improvement and emphasize the need for ongoing research to refine them and maximize their agricultural impact.

Enhancing virus-mediated genome editing for cultivated tomato through low temperature

KEY MESSAGE

Viral vector-mediated gene editing is enhanced for cultivated tomato under low temperature conditions, enabling higher mutation rates, heritable, and virus-free gene editing for efficient breeding. The CRISPR/Cas system, a versatile gene-editing tool, has revolutionized plant breeding by enabling precise genetic modifications. The development of robust and efficient genome-editing tools for crops is crucial for their application in plant breeding. In this study, we highly improved virus-induced genome-editing (VIGE) system for cultivated tomato. Vectors of tobacco rattle virus (TRV) and potato virus X (PVX) were used to deliver sgRNA targeting phytoene desaturase (SlPDS), along with mobile RNA sequences of tFT or tRNAIleu, into Cas9-overexpressing cultivated tomato (S. lycopersicum cv. Moneymaker). Our results demonstrate that low temperature significantly enhanced viral vector-mediated gene editing efficiency in both cotyledons and systemic upper leaves. However, no mutant progeny was obtained from TRV- and PVX301-infected MM-Cas9 plants. To address this challenge, we employed tissue culture techniques and found that low-temperature incubations at the initiation stage of tissue culture lead to enhanced editing efficiency in both vectors, resulting in a higher mutation rate (> 70%) of SlPDS in regenerated plants. Heritable gene-edited and virus-free progenies were successfully identified. This study presents a straightforward approach to enhance VIGE efficiency and the expeditious production of gene-edited lines in tomato breeding.