Loss of OsHRC function confers blast resistance without yield penalty in rice

Exploiting the efficient Exo:Cas12i3-5M fusions for robust single and multiplex gene editing in rice

The development of a single and multiplex gene editing system is highly desirable for either functional genomics or pyramiding beneficial alleles in crop improvement. CRISPR/Cas12i3, which belongs to the Class II Type V-I Cas system, has attracted extensive attention recently due to its smaller protein size and less restricted canonical "TTN" protospacer adjacent motif (PAM). However, due to its relatively lower editing efficiency, Cas12i3-mediated multiplex gene editing has not yet been documented in plants. Here, we fused four 5' exonucleases (Exo) including T5E, UL12, PapE, ME15 to the N terminal of an optimized Cas12i3 variant (Cas12i3-5M), respectively, and systematically evaluated the editing activities of these Exo:Cas12i3-5M fusions across six endogenous targets in rice stable lines. We demonstrated that the Exo:Cas12i3-5M fusions increased the gene editing efficiencies by up to 12.46-fold and 1.25-fold compared with Cas12i3 and Cas12i3-5M, respectively. Notably, the UL12:Cas12i3-5M fusion enabled robust single gene editing with editing efficiencies of up to 90.42%-98.61% across the six tested endogenous genes. We further demonstrated that, although all the Exo:Cas12i5-5M fusions were capable of multiplex gene editing, UL12:Cas12i3-5M exhibited a superior performance in the simultaneous editing of three, four, five or six genes with efficiencies of 82.76%, 61.36%, 52.94%, and 51.06% in rice stable lines, respectively. Together, we evaluated different Exo:Cas12i3-5M fusions systemically and established UL12:Cas12i3-5M as the more robust system for single and multiplex gene editing in rice. The development of an alternative robust single and multiplex gene editing system will enrich plant genome editing toolkits and facilitate pyramiding of agronomically important traits for crop improvement.

CRISPR/Cas9: a sustainable technology to enhance climate resilience in major Staple Crops

Climate change is a global concern for agriculture, food security, and human health. It affects several crops and causes drastic losses in yield, leading to severe disturbances in the global economy, environment, and community. The consequences on important staple crops, such as rice, maize, and wheat, will worsen and create food insecurity across the globe. Although various methods of trait improvements in crops are available and are being used, clustered regularly interspaced short palindromic repeats and CRISPR-associated protein 9 (CRISPR/Cas9) mediated genome manipulation have opened a new avenue for functional genomics and crop improvement. This review will discuss the progression in crop improvement from conventional breeding methods to advanced genome editing techniques and how the CRISPR/Cas9 technology can be applied to enhance the tolerance of the main cereal crops (wheat, rice, and maize) against any harsh climates. CRISPR/Cas endonucleases and their derived genetic engineering tools possess high accuracy, versatile, more specific, and easy to design, leading to climate-smart or resilient crops to combat food insecurity and survive harsh environments. The CRISPR/Cas9-mediated genome editing approach has been applied to various crops to make them climate resilient. This review, supported by a bibliometric analysis of recent literature, highlights the potential target genes/traits and addresses the significance of gene editing technologies in tackling the vulnerable effects of climate change on major staple crops staple such as wheat, rice, and maize.

Genetic engineering, including genome editing, for enhancing broad-spectrum disease resistance in crops

Plant diseases, caused by a wide range of pathogens, severely reduce crop yield and quality, posing a significant threat to global food security. Developing broad-spectrum resistance (BSR) in crops is a key strategy for controlling crop diseases and ensuring sustainable crop production. Cloning disease-resistance (R) genes and understanding their underlying molecular mechanisms provide new genetic resources and strategies for crop breeding. Novel genetic engineering and genome editing tools have accelerated the study and engineering of BSR genes in crops, which is the primary focus of this review. We first summarize recent advances in understanding the plant immune system, followed by an examination of the molecular mechanisms underlying BSR in crops. Finally, we highlight diverse strategies employed to achieve BSR, including gene stacking to combine multiple R genes, multiplexed genome editing of susceptibility genes and promoter regions of executor R genes, editing cis-regulatory elements to fine-tune gene expression, RNA interference, saturation mutagenesis, and precise genomic insertions. The genetic studies and engineering of BSR are accelerating the breeding of disease-resistant cultivars, contributing to crop improvement and enhancing global food security.

Epitranscriptome profiles reveal participation of the RNA methyltransferase gene OsMTA1 in rice seed germination and salt stress response

BACKGROUND

RNA m6A methylation installed by RNA methyltransferases plays a crucial role in regulating plant growth and development and environmental stress responses. However, the underlying molecular mechanisms of m6A methylation involved in seed germination and stress responses are largely unknown. In the present study, we surveyed global m6A methylation in rice seed germination under salt stress and the control (no stress) using an osmta1 mutant and its wild type.

RESULTS

The knockout of OsMTA1 resulted in a decreased level of m6A methylation and delayed seed germination, together with increased oxidative damage in the osmta1-1 mutant, especially under salt stress, indicating that OsMTA1 performs a crucial function in rice seed germination and salt stress response. Comparative analysis of m6A profiling using methylated RNA immunoprecipitation sequencing revealed that a unique set of genes that functioned in seed germination, cell growth, and development, including OsbZIP78 and OsA8, were hypomethylated in osmta1-1 embryos and germinating seeds. Numerous genes involved in plant growth and stress response were hypomethylated in the osmta1-1 mutant during seed germination under salt stress. Further combined analysis of the m6A methylome and transcriptome revealed that the loss of function of OsMTA1 had a more complex impact on gene expression in osmta1-1. Several hypomethylated genes with a negative role in growth and development, such as OsHsfA7 and OsHDAC3, were highly up-regulated in the osmta1-1 mutant under the control condition. In contrast, several hypomethylated genes positively associated with stress response were down-regulated, whereas a different set of hypomethylated genes that functioned as negative regulators of growth and stress response were up-regulated in the osmta1-1 mutant under salt stress. These results further demonstrated that OsMTA1-mediated m6A methylation modulated rice seed germination and salt stress response by regulating transcription of a unique set of genes with diverse functions.

CONCLUSION

Our results reveal a crucial role for the m6A methyltransferase gene OsMTA1 in regulating rice seed germination and salt stress response, and provide candidate genes to assist in breeding new stress-tolerant rice varieties.

Effectors and environment modulating rice blast disease: from understanding to effective control

Rice blast is a highly destructive crop disease that requires the interplay of three essential factors: the virulent blast fungus, the susceptible rice plant, and favorable environmental conditions. Although previous studies have focused mainly on the pathogen and rice, recent research has shed light on the molecular mechanisms by which the blast fungus and environmental conditions regulate host resistance and contribute to blast disease outbreaks. This review summarizes significant achievements in understanding the sophisticated modulation of blast resistance by Magnaporthe oryzae effectors and the dual regulatory mechanisms by which environmental conditions influence rice resistance and virulence of the blast fungus. Furthermore, it emphasizes potential strategies for developing blast-resistant rice varieties to effectively control blast disease.

CRISPR-Cas System, a Possible "Savior" of Rice Threatened by Climate Change: An Updated Review

Climate change has significantly affected agriculture production, particularly the rice crop that is consumed by almost half of the world's population and contributes significantly to global food security. Rice is vulnerable to several abiotic and biotic stresses such as drought, heat, salinity, heavy metals, rice blast, and bacterial blight that cause huge yield losses in rice, thus threatening food security worldwide. In this regard, several plant breeding and biotechnological techniques have been used to raise such rice varieties that could tackle climate changes. Nowadays, gene editing (GE) technology has revolutionized crop improvement. Among GE technology, CRISPR/Cas (Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated protein) system has emerged as one of the most convenient, robust, cost-effective, and less labor-intensive system due to which it has got more popularity among plant researchers, especially rice breeders and geneticists. Since 2013 (the year of first application of CRISPR/Cas-based GE system in rice), several trait-specific climate-resilient rice lines have been developed using CRISPR/Cas-based GE tools. Earlier, several reports have been published confirming the successful application of GE tools for rice improvement. However, this review particularly aims to provide an updated and well-synthesized brief discussion based on the recent studies (from 2020 to present) on the applications of GE tools, particularly CRISPR-based systems for developing CRISPR rice to tackle the current alarming situation of climate change, worldwide. Moreover, potential limitations and technical bottlenecks in the development of CRISPR rice, and prospects are also discussed.