Perspectives of CRISPR/Cas-mediated cis-engineering in horticulture: unlocking the neglected potential for crop improvement

Li, Qiang; Sapkota, Manoj; Knaap, Esther van der

doi:10.1038/s41438-020-0258-8

Cited by 56 publications

(39 citation statements)

References 158 publications

(219 reference statements)

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“…Recently, the use of targeted genome editing using clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated protein9 nuclease (Cas9) (CRISPR/Cas) has generated a lot of interest in various fields of plant biology including abiotic stress management [109]. CRISPR/Cas has been adopted in the field of plant developmental biology for characterizing genes as well as to underpin the molecular mechanisms behind various plant traits [110]. It has been used in the model plants such as Arabidopsis and tobacco earlier and likewise, now it is being utilized effectively for crop plants like sorghum, rice, wheat, maize, soybean as well as woody plants.…”

Section: Strategies To Combat Abiotic Stresses In Plantsmentioning

confidence: 99%

Abiotic Stress Responses in Plants: Current Knowledge and Future Prospects

Marothia¹,

Kaur²,

Pati³

2021

Abiotic Stress in Plants

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Exposure to abiotic stresses has become a major threatening factor that hurdles the sustainable growth in agriculture for fulfilling the growing food demand worldwide. A significant decrease in the production of major food crops including wheat, rice, and maize is predicted in the near future due to the combined effect of abiotic stresses and climate change that will hamper global food security. Thus, desperate efforts are necessary to develop abiotic stress-resilient crops with improved agronomic traits. For this, detailed knowledge of the underlying mechanisms responsible for abiotic stress adaptation in plants is must required. Plants being sessile organisms respond to different stresses through complex and diverse responses that are integrated on various whole plants, cellular, and molecular levels. The advanced genetic and molecular tools have uncovered these complex stress adaptive processes and have provided critical inputs on their regulation. The present chapter focuses on understanding the different responses of the plants involved in abiotic stress adaptation and strategies employed to date for achieving stress resistance in plants.

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Section: Strategies To Combat Abiotic Stresses In Plantsmentioning

confidence: 99%

Abiotic Stress Responses in Plants: Current Knowledge and Future Prospects

Marothia¹,

Kaur²,

Pati³

2021

Abiotic Stress in Plants

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“…However, like most plant species, almost no knowledge has been generated regarding the structure of promoters and other regulatory sequences in tomato, and no prior information is currently available for CREs and their interactions in the promoter of SlGABA-T1. Even though prior knowledge would facilitate and speed the process, cis-engineering could be implemented if a multiplexed CRISPR/Cas9 system was developed (Li et al, 2020). For this, we assembled a vector containing four gRNAs that was designed within a region 2 kbp upstream of the SlGABA-T1 start codon and transformed in Micro-Tom (Figure 2A).…”

Section: Alternative Prospects For Gaba Improvement Using Nbptsmentioning

confidence: 99%

“…Many examples have reported that mutations in cis -regulatory elements (CREs) produce significant phenotypic and morphological changes that have been selected during domestication ( Meyer and Purugganan, 2013 ; Swinnen et al., 2016 ). In tomato, changes in CREs and promoter regions were translated in elongated ( SlSUN ) and larger fruits ( FW2.2 , FW3.2 , SlWUS ) or those with improved β-carotene contents ( Slcys-B ) ( van der Knaap et al., 2014 ; Li et al., 2020 ) as just a few relevant examples. However, despite the great potential of this approach, currently, the vast majority of CRISPR/Cas9 studies focus on targeting coding sequences for null allele editing or controlling transcription by activation (CRISPRa) or inhibition (CRISPRi), and only 15 studies so far have reported successful applications of cis -engineering ( Li et al., 2020 ).…”

Section: Alternative Prospects For Gaba Improvement Using Nbptsmentioning

confidence: 99%

“…In tomato, changes in CREs and promoter regions were translated in elongated ( SlSUN ) and larger fruits ( FW2.2 , FW3.2 , SlWUS ) or those with improved β-carotene contents ( Slcys-B ) ( van der Knaap et al., 2014 ; Li et al., 2020 ) as just a few relevant examples. However, despite the great potential of this approach, currently, the vast majority of CRISPR/Cas9 studies focus on targeting coding sequences for null allele editing or controlling transcription by activation (CRISPRa) or inhibition (CRISPRi), and only 15 studies so far have reported successful applications of cis -engineering ( Li et al., 2020 ). One of them was successfully conducted in tomato by cis -engineering the promoters of genes controlling fruit size, inflorescence branching and plant architecture, achieving multiple cis -regulatory alleles with a continuum of quantitative variation ( Rodríguez-Leal et al., 2017 ).…”

Section: Alternative Prospects For Gaba Improvement Using Nbptsmentioning

confidence: 99%

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Challenges and Prospects of New Plant Breeding Techniques for GABA Improvement in Crops: Tomato as an Example

2020

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Over the last seven decades, g-aminobutyric acid (GABA) has attracted great attention from scientists for its ubiquity in plants, animals and microorganisms and for its physiological implications as a signaling molecule involved in multiple pathways and processes. Recently, the food and pharmaceutical industries have also shown significantly increased interest in GABA, because of its great potential benefits for human health and the consumer demand for health-promoting functional compounds, resulting in the release of a plethora of GABA-enriched products. Nevertheless, many crop species accumulate appreciable GABA levels in their edible parts and could help to meet the daily recommended intake of GABA for promoting positive health effects. Therefore, plant breeders are devoting much effort into breeding elite varieties with improved GABA contents. In this regard, tomato (Solanum lycopersicum), the most produced and consumed vegetable worldwide and a fruit-bearing model crop, has received much consideration for its accumulation of remarkable GABA levels. Although many different strategies have been implemented, from classical crossbreeding to induced mutagenesis, new plant breeding techniques (NPBTs) have achieved the best GABA accumulation results in red ripe tomato fruits along with shedding light on GABA metabolism and gene functions. In this review, we summarize, analyze and compare all the studies that have substantially contributed to tomato GABA breeding with further discussion and proposals regarding the most recent NPBTs that could bring this process to the next level of precision and efficiency. This document also provides guidelines with which researchers of other crops might take advantage of the progress achieved in tomato for more efficient GABA breeding programs.

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“…Rapid nucleic acid detection is an important part of many applications in human health and biotechnology, including the identifying of infectious diseases, agricultural pathogens, or circulating DNA or RNA associated with disease. [17][18][19] Standard methods to amplify nucleic acids for detection (such as PCR) are effective but require instrumentation that is not portable, precluding their deployment in the field [20,21]. CRISPR-Cas-based approaches are being tested to treat hereditary, infectious, and many other diseases.…”

Section: Detection Of Nucleic Acids By Crispr-casmentioning

confidence: 99%

<strong>SHERLOCK and DETECTR: CRISPR-Cas Systems as Potential Rapid Diagnostic Tools for Emerging Infectious Diseases and Cancer-Associated Mutations</strong>

Mustafa¹,

Makhawi²

2020

Preprint

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Sensitive and precise nucleic acid detection is critical for clinical diagnostics and biotechnological advancements. Diagnostic in infectious disease field is very unique from diagnosing any other disease, that is time is of the essence; in outbreaks people die even with each passing hour in some cases, if the correct diagnosis wasn't make; for example Zika in particularly is a very challenging virus to diagnose, because it's in very few numbers of copies in the infected person, so it need high sensitive diagnostic approach to spot it, In particular, the advanced tools SHERLOCKv2 and DETECTR, give almost an immediate detection of attomolar amounts of pathogenic nucleic acids with specificity similar to that of PCR but with slight technical settings and that will guide the correct intervention for the patient. SHERLOCKv2 and DETECTR technologies are game changers for our ability to identify infectious disease and rapid detection of tumor DNA or cancer-related viruses with ultra-sensitive tests that don’t require a lot of complicated processing to go through. In this paper, we will review cutting-edge infectious disease diagnosis by CRISPR-Cas systems.

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Perspectives of CRISPR/Cas-mediated cis-engineering in horticulture: unlocking the neglected potential for crop improvement

Cited by 56 publications

References 158 publications

Abiotic Stress Responses in Plants: Current Knowledge and Future Prospects

Abiotic Stress Responses in Plants: Current Knowledge and Future Prospects

Challenges and Prospects of New Plant Breeding Techniques for GABA Improvement in Crops: Tomato as an Example

<strong>SHERLOCK and DETECTR: CRISPR-Cas Systems as Potential Rapid Diagnostic Tools for Emerging Infectious Diseases and Cancer-Associated Mutations</strong>

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