Identification of Leaf Promoters for Use in Transgenic Wheat

Alotaibi, Saqer S.; Sparks, Caroline A.; Parry, M. A. J.; Simkin, Andrew J.; Raines, Christine A.

doi:10.3390/plants7020027

Cited by 17 publications

(18 citation statements)

References 101 publications

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“…The role of modelling in enabling novel targets to be identified will also be crucial given the complexity of the processes involved. To achieve the full potential of these opportunities, the use of new tools, which allow the quick, efficient, and cheap insertion of multiple transgenes into plants, will be paramount (Engler et al , 2008, 2009, 2014; Marillonnet and Werner, 2015; Exposito-Rodriguez et al , 2017), as will be the development of new promoters for use in crop plants, which are currently limited (Mukherjee et al , 2015; Alotaibi et al , 2018). If these opportunities are to be fully exploited, regulations governing the use of genetic modification and genome editing technologies will need to be reviewed.…”

Section: Conclusion and Further Opportunitiesmentioning

confidence: 99%

Feeding the world: improving photosynthetic efficiency for sustainable crop production

Simkin

López-Calcagno

Raines

2019

Journal of Experimental Botany

336

212

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Section: Conclusion and Further Opportunitiesmentioning

confidence: 99%

Feeding the world: improving photosynthetic efficiency for sustainable crop production

Simkin

López-Calcagno

Raines

2019

Journal of Experimental Botany

336

212

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“…pFH54: An Arabidopsis codon optimised Cas9 (pICSL90016) [25] was assembled with an Arabidopsis UBIQUITIN10 promoter-5'UTR (pICSL12015) [25] and a pea 3A 3'UTR-Terminator (pFH44) into the level 1 position 2 acceptor pICH47742 [2] (Addgene ID #48001) using a GG cut-ligation reaction via BsaI-HF®v2. pFH114: The ZmUBIp::BAR:NOSt cassette was amplified using the vector pRRES1.111 [26] with FH443/FH444 primers and the PCR product was assembled into the level 1 position 1 acceptor pICH47732 [2] (Addgene ID #48000) using a GG cut-ligation reaction via BsaI-HF®v2.…”

Section: Level 1 Constructsmentioning

confidence: 99%

A modular cloning toolkit for genome editing in plants

et al. 2020

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Background CRISPR/Cas has recently become a widely used genome editing tool in various organisms, including plants. Applying CRISPR/Cas often requires delivering multiple expression units into plant and hence there is a need for a quick and easy cloning procedure. The modular cloning (MoClo), based on the Golden Gate (GG) method, has enabled development of cloning systems with standardised genetic parts, e.g. promoters, coding sequences or terminators, that can be easily interchanged and assembled into expression units, which in their own turn can be further assembled into higher order multigene constructs. Results Here we present an expanded cloning toolkit that contains 103 modules encoding a variety of CRISPR/Cas-based nucleases and their corresponding guide RNA backbones. Among other components, the toolkit includes a number of promoters that allow expression of CRISPR/Cas nucleases (or any other coding sequences) and their guide RNAs in monocots and dicots. As part of the toolkit, we present a set of modules that enable quick and facile assembly of tRNA-sgRNA polycistronic units without a PCR step involved. We also demonstrate that our tRNA-sgRNA system is functional in wheat protoplasts. Conclusions We believe the presented CRISPR/Cas toolkit is a great resource that will contribute towards wider adoption of the CRISPR/Cas genome editing technology and modular cloning by researchers across the plant science community.

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“…The sgRNA constructs, carrying two sgRNAs each (annotated sequences are available on figshare), were assembled using the pENTR4-sgRNA4 vector as previously described (Zhou et al, 2014). All three sgRNA plasmids were co-delivered along with pCas9- GFP (Zhang et al, 2019) encoding the wheat codonoptimised Cas9 fused in frame at the C-terminus with Green Fluorescent Protein (GFP), and pRRes1.111 (Alotaibi et al, 2018) which directs expression of the bar selectable marker gene into immature wheat embryos of wheat cv. Cadenza using biolistics essentially as described in Sparks and Doherty (2020).…”

Section: Generation Of Wheat Genetic Materialsmentioning

confidence: 99%

Remarkable recent changes in genetic diversity of the avirulence geneAvrStb6in global populations of the wheat pathogenZymoseptoria tritici

Stephens¹,

Ölmez²,

Blyth³

et al. 2020

Preprint

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Septoria tritici blotch (STB), caused by the fungus Zymoseptoria tritici, is one of the most economically important diseases of wheat. Recently, both factors of a gene-for-gene interaction between Z. tritici and wheat, the wheat receptor-like kinase Stb6 and the Z. tritici secreted effector protein AvrStb6, have been identified. Previous analyses revealed a high diversity of AvrStb6 alleles present in historic Z. tritici isolate collections, with up to ~ 18% of analysed isolates possessing the avirulence isoform of AvrStb6 identical to that originally identified in the reference isolate IPO323. With Stb6 present in many commercial wheat cultivars globally, we aimed to assess potential changes in AvrStb6 genetic diversity and the incidence of alleles allowing evasion of Stb6-mediated resistance in more recent Z. tritici populations. Here we show, using targeted re-sequencing of AvrStb6, that this gene is universally present in field isolates sampled from major wheat-growing regions of the world between 2013-2017. However, in contrast to the data from studies of historic isolates, our study revealed a complete absence of the originally described avirulence isoform of AvrStb6 amongst modern Z. tritici isolates. Moreover, a remarkably small number of alleles, each encoding AvrStb6 protein isoforms conditioning virulence on Stb6-containing wheat, were found to predominate among modern Z. tritici isolates. A single virulence isoform of AvrStb6 was found to be particularly abundant throughout the global population. These findings indicate that, despite the ability of Z. tritici to sexually reproduce on resistant hosts, AvrStb6 avirulence alleles tend to be eliminated in subsequent populations.

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Identification of Leaf Promoters for Use in Transgenic Wheat

Cited by 17 publications

References 101 publications

Feeding the world: improving photosynthetic efficiency for sustainable crop production

Feeding the world: improving photosynthetic efficiency for sustainable crop production

A modular cloning toolkit for genome editing in plants

Remarkable recent changes in genetic diversity of the avirulence geneAvrStb6in global populations of the wheat pathogenZymoseptoria tritici

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