Resistance (R) Genes: Applications and Prospects for Plant Biotechnology and Breeding

Pandolfi, Valesca; Ferreira‐Neto, José Ribamar Costa; Silva, Manassés Daniel da; Amorim, Lidiane Lindinalva Barbosa; Wanderley-Nogueira, Ana Carolina; Silva, Roberta Lane de Oliveira; Kido, Ederson Akio; Crovella, Sérgio; Benko‐Iseppon, Ana Maria

doi:10.2174/1389203717666160724195248

Cited by 29 publications

(20 citation statements)

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“…It was estimated that these pathogens have contributed to at least 20% of yield loss in important crops including wheat, rice, maize, potatoes, and soybeans [ 1 , 2 ]. Therefore, diseases caused by pathogenic microorganisms and herbivores are major factors affecting agriculture [ 3 , 4 , 5 , 6 ]. Unlike animals that could escape from predators and pathogens, plants must withstand pathogen attacks at the sites of growth [ 1 , 2 ].…”

Section: Introductionmentioning

confidence: 99%

Update on Cuticular Wax Biosynthesis and Its Roles in Plant Disease Resistance

Wang

Kong

Zhi

et al. 2020

IJMS

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The aerial surface of higher plants is covered by a hydrophobic layer of cuticular waxes to protect plant tissues against enormous environmental challenges including the infection of various pathogens. As the first contact site between plants and pathogens, the layer of cuticular waxes could function as a plant physical barrier that limits the entry of pathogens, acts as a reservoir of signals to trigger plant defense responses, and even gives cues exploited by pathogens to initiate their infection processes. Past decades have seen unprecedented proceedings in understanding the molecular mechanisms underlying the biosynthesis of plant cuticular waxes and their functions regulating plant–pathogen interactions. In this review, we summarized the recent progress in the molecular biology of cuticular wax biosynthesis and highlighted its multiple roles in plant disease resistance against bacterial, fungal, and insect pathogens.

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Section: Introductionmentioning

confidence: 99%

Update on Cuticular Wax Biosynthesis and Its Roles in Plant Disease Resistance

Wang

Kong

Zhi

et al. 2020

IJMS

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“…Presence of both common and population specific QTLs indicates that resistance against Alternaria blight is quantitative and more than one gene potentially governs the resistance [48]. With the modern development of biotechnology, the discovery of resistance (R) and defense-related genes has opened up new scopes for inducing genetic resistance against different biotic and abiotic stresses [49]. Advances in microarray data processing also ease the process of identifying candidate genes in certain physiological processes.…”

Section: Genetics and Genomics Of Alternaria Blight Resistancementioning

confidence: 99%

Epidemiology, Genetics and Resistance of Alternaria Blight in Oilseed Brassica

Jyoti¹,

Sultana²,

Hassan³

et al. 2021

Brassica Breeding and Biotechnology

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Alternaria blight is one of the most deadly diseases of oilseed Brassica. This recalcitrant disease causes up to 50% yield loss across the globe. The disease is mainly caused by Alternaria brassicae and Alternaria brassicicola. These pathogens lack sexual stages and survive as conidia or condiospores on the debris of previous crops and susceptible weeds. Developing resistant oilseed Brassica cultivars to this disease has become a prime concern for researchers over the years. In absence of resistant oilseed Brassica cultivar, identification and introgression of resistance related genes can be a potential source for Alternaria blight resistance. As resistance toward Alternaria blight is governed by polygenes, intercrossing between the tolerant genotypes and subsequent selection will be the most appropriate way to transfer the quantitative resistance. For that reason, future breeding goal should focus on screening of germplasms for selecting genotypes containing resistance genes and structural features that favors resistance, like thick epicuticular wax, biochemical components such as phenols, phytoalexins and lower soluble sugars, reducing sugars and soluble nitrogen. Selected genotypes should be brought under appropriate breeding programs for attaining Alternaria blight resistance.

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“…Transferring R-genes to crops and expressing them in response to biotic stress could improve pathogen resistance, but the number of suitable R-genes is limited and may first require the identification of interacting helper NLRs (Wang et al, 2019). Furthermore, dominant R-gene-mediated resistance is less durable than recessive resistance and is usually restricted to a few race-specific isolates, which can quickly overcome this resistance by their higher mutation rate (Dangl et al, 2013;Pandolfi et al, 2017;Kourelis and van der Hoorn, 2018). Thus, to achieve a more durable resistance, trait stacking/pyramiding has been applied and could be further facilitated by CRISPR/Cas-induced HDR (Pandolfi et al, 2017).…”

Section: Transgenic Approaches Deploying Crispr/cas To Increase Resismentioning

confidence: 99%

“…Furthermore, dominant R-gene-mediated resistance is less durable than recessive resistance and is usually restricted to a few race-specific isolates, which can quickly overcome this resistance by their higher mutation rate (Dangl et al, 2013;Pandolfi et al, 2017;Kourelis and van der Hoorn, 2018). Thus, to achieve a more durable resistance, trait stacking/pyramiding has been applied and could be further facilitated by CRISPR/Cas-induced HDR (Pandolfi et al, 2017). On the other hand, the transfer of PRRs would confer per se a much broader and more durable resistance, which has been successfully shown between Arabidopsis and tomato (Lacombe et al, 2010), rice and banana (Tripathi et al, 2014), or Arabidopsis and wheat (Schoonbeek et al, 2015).…”

Section: Transgenic Approaches Deploying Crispr/cas To Increase Resismentioning

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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Resistance (R) Genes: Applications and Prospects for Plant Biotechnology and Breeding

Cited by 29 publications

References 0 publications

Update on Cuticular Wax Biosynthesis and Its Roles in Plant Disease Resistance

Update on Cuticular Wax Biosynthesis and Its Roles in Plant Disease Resistance

Epidemiology, Genetics and Resistance of Alternaria Blight in Oilseed Brassica

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

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