How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis

How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis

Abstract The breakthrough CRISPR (clustered regularly interspaced short palindromic repeat)/Cas9-mediated genome-editing technology has led to great progress in monocot research; however, several factors need to be considered for the efficient implementation of this technology. To generate genome-ed...

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Main Authors: Jin-Jun Yue, Chwan-Yang Hong, Pengcheng Wei, Yu-Chang Tsai, Choun-Sea Lin
Format: Article
Language:English
Published: SpringerOpen 2020-02-01
Series:Rice
Subjects:
Cas12a
Genome editing
Plant transformation
Promoter
Protoplast
Online Access:https://doi.org/10.1186/s12284-019-0354-2
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spelling doaj-825893b1c78642a2a5d41b7af2f6751e2021-02-07T12:46:41ZengSpringerOpenRice1939-84251939-84332020-02-0113111310.1186/s12284-019-0354-2How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysisJin-Jun Yue0Chwan-Yang Hong1Pengcheng Wei2Yu-Chang Tsai3Choun-Sea Lin4Research Institute of Subtropical Forestry, Chinese Academy of ForestryDepartment of Agricultural Chemistry, College of Bioresources and Agriculture, National Taiwan UniversityKey Laboratory of Rice Genetic Breeding of Anhui Province, Rice Research Institute, Anhui Academy of Agricultural SciencesDepartment of Agronomy, National Taiwan UniversityAgricultural Biotechnology Research Center, Academia SinicaAbstract The breakthrough CRISPR (clustered regularly interspaced short palindromic repeat)/Cas9-mediated genome-editing technology has led to great progress in monocot research; however, several factors need to be considered for the efficient implementation of this technology. To generate genome-edited crops, single guide (sg)RNA and Cas9 DNA are delivered into plant cells and expressed, and the predicted position is targeted. Analyses of successful targeted mutations have revealed that the expression levels, expression timing, and variants of both sgRNA and Cas9 need to be sophisticatedly regulated; therefore, the promoters of these genes and the target site positions are the key factors for genome-editing efficiency. Currently, various vectors and online tools are available to aid sgRNA design. Furthermore, to reduce the sequence limitation of the protospacer adjacent motif (PAM) and for other purposes, many Cas protein variants and base editors can be used in plants. Before the stable transformation of a plant, the evaluation of vectors and target sites is therefore very important. Moreover, the delivery of Cas9-sgRNA ribonucleoproteins (RNPs) is one strategy that can be used to prevent transgene issues with the expression of sgRNA and Cas proteins. RNPs can be used to efficiently generate transgene-free genome-edited crops that can reduce transgene issues related to the generation of genetically modified organisms. In this review, we introduce new techniques for genome editing and identifying marker-free genome-edited mutants in monocot crops. Four topics are covered: the design and construction of plasmids for genome editing in monocots; alternatives to SpCas9; protoplasts and CRISPR; and screening for marker-free CRISPR/Cas9-induced mutants. We have aimed to encompass a full spectrum of information for genome editing in monocot crops.https://doi.org/10.1186/s12284-019-0354-2Cas12aGenome editingPlant transformationPromoterProtoplast
collection DOAJ
language English
format Article
sources DOAJ
author Jin-Jun Yue
Chwan-Yang Hong
Pengcheng Wei
Yu-Chang Tsai
Choun-Sea Lin
spellingShingle Jin-Jun Yue
Chwan-Yang Hong
Pengcheng Wei
Yu-Chang Tsai
Choun-Sea Lin
How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
Rice
Cas12a
Genome editing
Plant transformation
Promoter
Protoplast
author_facet Jin-Jun Yue
Chwan-Yang Hong
Pengcheng Wei
Yu-Chang Tsai
Choun-Sea Lin
author_sort Jin-Jun Yue
title How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
title_short How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
title_full How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
title_fullStr How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
title_full_unstemmed How to start your monocot CRISPR/Cas project: plasmid design, efficiency detection, and offspring analysis
title_sort how to start your monocot crispr/cas project: plasmid design, efficiency detection, and offspring analysis
publisher SpringerOpen
series Rice
issn 1939-8425
1939-8433
publishDate 2020-02-01
description Abstract The breakthrough CRISPR (clustered regularly interspaced short palindromic repeat)/Cas9-mediated genome-editing technology has led to great progress in monocot research; however, several factors need to be considered for the efficient implementation of this technology. To generate genome-edited crops, single guide (sg)RNA and Cas9 DNA are delivered into plant cells and expressed, and the predicted position is targeted. Analyses of successful targeted mutations have revealed that the expression levels, expression timing, and variants of both sgRNA and Cas9 need to be sophisticatedly regulated; therefore, the promoters of these genes and the target site positions are the key factors for genome-editing efficiency. Currently, various vectors and online tools are available to aid sgRNA design. Furthermore, to reduce the sequence limitation of the protospacer adjacent motif (PAM) and for other purposes, many Cas protein variants and base editors can be used in plants. Before the stable transformation of a plant, the evaluation of vectors and target sites is therefore very important. Moreover, the delivery of Cas9-sgRNA ribonucleoproteins (RNPs) is one strategy that can be used to prevent transgene issues with the expression of sgRNA and Cas proteins. RNPs can be used to efficiently generate transgene-free genome-edited crops that can reduce transgene issues related to the generation of genetically modified organisms. In this review, we introduce new techniques for genome editing and identifying marker-free genome-edited mutants in monocot crops. Four topics are covered: the design and construction of plasmids for genome editing in monocots; alternatives to SpCas9; protoplasts and CRISPR; and screening for marker-free CRISPR/Cas9-induced mutants. We have aimed to encompass a full spectrum of information for genome editing in monocot crops.
topic Cas12a
Genome editing
Plant transformation
Promoter
Protoplast
url https://doi.org/10.1186/s12284-019-0354-2
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