Loss of function of CRT1a (calreticulin) reduces plant susceptibility toVerticillium longisporumin bothArabidopsis thalianaand oilseed rape (Brassica napus)

Pröbsting, Michael; Schenke, Dirk; Hossain, Roxana; Häder, Claudia; Thurau, Tim; Wighardt, Lisa; Schuster, Andrea; Zhou, Zhihan; Ye, Wanzhi; Rietz, Steffen; Leckband, Gunhild; Cai, Daguang

doi:10.1111/pbi.13394

Cited by 49 publications

(30 citation statements)

References 90 publications

(120 reference statements)

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“…It has been used for genome editing in major crops (Ahmar et al, 2020; M. H. U. Khan et al, 2018). It has been efficiently utilized in rapeseed to produce the targeted mutagenesis required to improve agronomic traits, including multilocular silique, plant height and architecture, pod shatter resistance, yellow seeds, fatty acid composition, and disease resistance (Braatz et al, 2017; Hu et al, 2018; Huang et al, 2020; C. Li et al, 2018; Pröbsting et al, 2020; H. Yang, Wu, Tang, Liu, & Dai, 2017; Y. Yang et al, 2018; Zhai et al, 2019, 2020; Zheng et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Targeted mutagenesis of EOD3 gene in Brassica napus L. regulates seed production

Khan

Zhu

et al. 2020

Journal Cellular Physiology

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Seed size and number are central to the evolutionary fitness of plants and are also crucial for seed production of crops. However, the molecular mechanisms of seed production control are poorly understood in Brassica crops. Here, we report the gene cloning, expression analysis, and functional characterization of the EOD3/CYP78A6 gene in rapeseed. BnaEOD3 has four copies located in two subgenomes, which exhibited a steady higher expression during seed development with differential expression among copies. The targeted mutations of BnaEOD3 gene were efficiently generated by stable transformation of the CRISPR/Cas9 (clustered regularly interspaced short palindromic repeat) vector. These mutations were stably transmitted to T 1 and T 2 generations and a large collection of homozygous mutants with combined loss-of-function alleles across four BnaEOD3 copies were created for phenotyping. All mutant T 1 lines had shorter siliques, smaller seeds, and an increased number of seeds per silique, in which the quadrable mutants showed the most significant changes in these traits. Consequently, the seed weight per plant in the quadrable mutants increased by 13.9% on average compared with that of wild type, indicating that these BnaEOD3 copies have redundant functions in seed development in rapeseed. The phenotypes of the different allelic combinations of BnaEOD3 copies also revealed gene functional differentiation among the two subgenomes. Cytological observations indicated that the BnaEOD3 could act maternally to promote cotyledon cell expansion and proliferation to regulate seed growth in rapeseed. Collectively, our findings reveal the quantitative involvement of the different BnaEOD3 copies function in seed development, but also provided valuable resources for rapeseed breeding programs.

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Section: Introductionmentioning

confidence: 99%

Targeted mutagenesis of EOD3 gene in Brassica napus L. regulates seed production

Khan

Zhu

et al. 2020

Journal Cellular Physiology

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“…These hypotheses can be addressed even by smaller breeding companies, because CRISPR/Cas-mediated GE is not that expensive and relatively easy to handle. Importantly, GE techniques allow a very specific KO of certain alleles, whereas a knockdown often causes off-target effects resulting in a different phenotype maybe due to lost genetic compensation ( Gao et al., 2015 ; Unniyampurath et al., 2016 ; Smith et al., 2017 ; Kumar et al., 2018 ; Kim et al., 2019 ; Pröbsting et al., 2020 ). Pathogen resistance is just one important trait that can be addressed with GE in many different crops ( Table 1 ), and CRISPR/Cas is currently also deployed to encounter citrus greening, a bacterial disease threatening sweet orange ( Ledford, 2017 ).…”

Section: Resultsmentioning

confidence: 99%

“…Such an approach was successful to identify CRT1a as a novel susceptibility factor in Brassica napus and Arabidopsis thaliana infected with Verticillium longisporum , albeit its function in endoplasmic reticulum quality control/protein folding could well have secondary effects on the functionality of other yet unknown susceptibility factors. Importantly, the plants appeared to develop normally, because only one “active” CRT1a locus was targeted, whereas other CRT1a, CRT1b, and CRT3 loci were not affected ( Pröbsting et al., 2020 ). Generally, basic research elucidating the molecular mechanisms underlying host-pathogen interactions is also a rich source for several biotechnological applications and resistance resources.…”

Section: Pipeline For Target Gene Identification In Resistance Breedimentioning

confidence: 99%

Applications of CRISPR/Cas to Improve Crop Disease Resistance: Beyond Inactivation of Susceptibility Factors

Schenke

Cai

2020

iScience

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Current crop production systems are prone to increasing pathogen pressure. Fundamental understanding of molecular plant-pathogen interactions, the availability of crop and pathogen genomic information, as well as emerging genome editing permits a novel approach for breeding of crop disease resistance. We describe here strategies to identify new targets for resistance breeding with focus on interruption of the compatible plant-pathogen interaction by CRISPR/ Cas-mediated genome editing. Basically, crop genome editing can be applied in several ways to achieve this goal. The most common approach focuses on the ''simple'' knockout by non-homologous end joining repair of plant susceptibility factors required for efficient host colonization. However, genome rewriting via homology-directed repair or base editing can also prevent host manipulation by changing the targets of pathogen-derived effectors or molecules beyond recognition, which also decreases plant susceptibility. We conclude that genome editing by CRISPR/Cas will become increasingly indispensable to generate in relatively short time beneficial resistance traits in crops to meet upcoming challenges.

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“…In the past eight years, there have been many reports of creating genome-edited plants with resistance to viral, bacterial, and fungal diseases in different plant species using CRISPR/Cas technology ( Zhang et al, 2021 ). These include CRISPR/Cas9 knock-outs of the following genes: mlo for plant resistance to powdery mildew in wheat ( Wang et al, 2014 ), tomato ( Nekrasov et al, 2017 ; Martínez et al, 2020 ) and grapevine ( Wan et al, 2020 ), pmr4 for plant resistance to powdery mildew in tomato (Santillán Martínez et al, 2020), 14-3-3 gene for resistance to Verticillium dahlia in cotton ( Zhang ZN et al, 2018 ), crt1a for resistance to Verticillium longisporum in both Arabidopsis thaliana and oilseed rape ( Pröbsting et al, 2020 ), OsERF922 for resistance to Magnaporthe oryzae in rice ( Wang et al, 2016 ), Clpsk1 for resistance to Fusarium oxysporum f. sp. niveum in watermelon ( Zhang et al, 2020 ), eif4e for resistance to Cucumber vein yellowing virus , Zucchini yellow mosaic virus , and Papaya ring spot mosaic virus‐W in cucumber ( Chandrasekaran et al, 2016 ), CsWRKY22 for resistance to Xanthomonas citri subsp.…”

Section: Crispr/cas Is a Robust And Powerful Tool For Precision Brementioning

confidence: 99%

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

Brant

Budak

et al. 2021

J. Zhejiang Univ. Sci. B

109

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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.

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Loss of function of CRT1a (calreticulin) reduces plant susceptibility toVerticillium longisporumin bothArabidopsis thalianaand oilseed rape (Brassica napus)

Cited by 49 publications

References 90 publications

Targeted mutagenesis of EOD3 gene in Brassica napus L. regulates seed production

Targeted mutagenesis of EOD3 gene in Brassica napus L. regulates seed production

Applications of CRISPR/Cas to Improve Crop Disease Resistance: Beyond Inactivation of Susceptibility Factors

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

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