High
yield and superior quality are the main goals pursued by breeders
for crop improvement. However, both of them are complex agronomic
traits controlled by multiple genes, so the simultaneous improvement
of these traits via sexual recombination is time-consuming and direction-uncontrolled.
In this study, to solve this dilemma, we introduced the comparative
genomic analysis based multiplex genome editing system (CG-MGE), a
method for rapid and directional improvement of multiple traits. Application
of this method, association analysis between genotypes and phenotypes
was carried out to mine excellent alleles; subsequently, the rare
excellent alleles of Gn1a, GW2, TGW3, and Chalk5 were simultaneously created
by multiplex genome editing and successfully improved the plant architecture,
grain yield, and quality of a widely cultivated elite rice variety.
Overall, this study provides a method for rapid and directional improvement
of crops, and the application of the CG-MGE will be helpful to accelerate
rational design breeding.
Papain-like cysteine proteases (PLCPs) play an important role in the immune response of plants. In Arabidopsis, several homologous genes are known to be involved in defending against pathogens. However, the effects of PLCPs on diseases that afflict rice are largely unknown. In this study, we show that a PLCP, an oryzain alpha chain precursor (OCP), the ortholog of the Arabidopsis protease RD21 (responsive to dehydration 21), participates in regulating resistance to blast disease with a shorter lesion length characterizing the knockout lines (ocp-ko), generated via CRISPR/Cas9 technology. OCP was expressed in all rice tissues and mainly located in the cytoplasm. We prove that OCP, featuring cysteine protease activity, interacts with OsRACK1A (receptor for activated C kinase 1) and OsSNAP32 (synaptosome-associated protein of 32 kD) physically in vitro and in vivo, and they co-locate in the rice cytoplasm but cannot form a ternary complex. Many genes related to plant immunity were enriched in the ocp-ko1 line whose expression levels changed significantly. The expression of jasmonic acid (JA) and ethylene (ET) biosynthesis and regulatory genes were up-regulated, while that of auxin efflux transporters was down-regulated in ocp-ko1. Therefore, OCP negatively regulates blast resistance in rice by interacting with OsRACK1A or OsSNAP32 and influencing the expression profiles of many resistance-related genes. Moreover, OCP might be the cornerstone of blast resistance by suppressing the activation of JA and ET signaling pathways as well as promoting auxin signaling pathways. Our research provides a comprehensive resource of PLCPs for rice plants in defense against pathogens that is also of potential breeding value.
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