iTRAQ‐based proteomics of sunflower cultivars differing in resistance to parasitic weed <i>Orobanche cumana</i>

Yang, Chong; Xu, Ling; Zhang, Na; Islam, Faisal; Song, Wenjian; Hu, Luyang; Liú, Dan; Xie, Xiaonan; Zhou, Weijun

doi:10.1002/pmic.201700009

Cited by 33 publications

(29 citation statements)

References 67 publications

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“…Response of the resistant genotype to broomrape race G infection included regulation of pathways associated with energy metabolism, alteration of defense-related proteins that participate in the recognition of the parasite, accumulation of pathogenesis-related proteins, lignin biosynthesis, and detoxification of toxic metabolites. In the susceptible genotypes, the decrease was observed considering the abundance of proteins involved in the biosynthesis as well as the signaling of plant growth regulation [93]. In this study, the molecular basis of sunflower resistance to broomrape has been broken down into steps and explained in detail.…”

Section: Association Of Identified Qtl With Resistance Genes and Funcmentioning

confidence: 96%

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Genetic and Genomic Tools in Sunflower Breeding for Broomrape Resistance

Cvejić

Radanović

Dedić

et al. 2020

Genes

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Broomrape is a root parasitic plant causing yield losses in sunflower production. Since sunflower is an important oil crop, the development of broomrape-resistant hybrids is the prime breeding objective. Using conventional plant breeding methods, breeders have identified resistant genes and developed a number of hybrids resistant to broomrape, adapted to different growing regions worldwide. However, the spread of broomrape into new countries and the development of new and more virulent races have been noted intensively. Recent advances in sunflower genomics provide additional tools for plant breeders to improve resistance and find durable solutions for broomrape spread and virulence. This review describes the structure and distribution of new, virulent physiological broomrape races, sources of resistance for introduction into susceptible cultivated sunflower, qualitative and quantitative resistance genes along with gene pyramiding and marker assisted selection (MAS) strategies applied in the process of increasing sunflower resistance. In addition, it presents an overview of underutilized biotechnological tools, such as phenotyping, -omics, and genome editing techniques, which need to be introduced in the study of sunflower resistance to broomrape in order to achieve durable resistance.

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Section: Association Of Identified Qtl With Resistance Genes and Funcmentioning

confidence: 96%

“…The first study by Yang et al [93] provided an overall insight into compatible and incompatible interaction mechanisms between resistant and susceptible sunflower genotypes and broomrape. Over 3500 proteins were identified in tested sunflower genotypes by iTRAQ analysis.…”

Section: Association Of Identified Qtl With Resistance Genes and Funcmentioning

confidence: 99%

Genetic and Genomic Tools in Sunflower Breeding for Broomrape Resistance

Cvejić

Radanović

Dedić

et al. 2020

Genes

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“…Therefore, the differences in specific enzyme activity among assays are comparable to the abundance differences of DAPs in comparative proteomic analysis. Should specific enzyme activity not agree with enzyme abundance, perhaps enzyme activity can be compared per unit weight of tissue, organ, or whole plant. In addition, EAA was also used to corroborate the results generated by 2D‐DIGE proteomic experiments…”

Section: Status Problems and Trends In Enzyme Activity Assaymentioning

confidence: 99%

On the Promising Role of Enzyme Activity Assay in Interpreting Comparative Proteomic Data in Plants

Niu

Liu

et al. 2018

Proteomics

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Comparative proteomics is widely used to detect protein changes, especially differential abundance proteins (DAPs) that are involved in plant responses to development, disease, or environment. Once DAPs are identified, it is essential to validate any change in their abundance, and their role in the biological process under study. In addition to common confirmation by quantitative RT-PCR, immunoblot, and multiple reaction monitoring analysis, it has been proposed that enzyme activity assay (EAA) can be complementary to the standard proteomics results, especially regarding the elucidation of protein (enzyme) function and the mechanism of enzyme-associated biochemical or metabolic pathways. The enzymes discussed here are the DAPs identified in comparative plant proteomics. Despite the small number of enzymes in a proteome, they often make up a substantial proportion of the DAPs identified in comparative studies. Currently, only a few studies have performed EAA to complement the interpretation of proteomic data, especially activity-based protein profiling. This viewpoint aims to arouse the attention of proteomic researchers on the promising role of EAA in plant proteomics and highlights the need for high-throughput assays of enzyme activities in comparative plant proteomics.

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“…It is the fourth important oilseed crop which contributes to 12% of the edible oil produced globally. However, sunflower production has been threatened by different stresses, among which drought and salinity are two major abiotic constraints [16] and parasitic weed Orobanche cumana is a new emerged biotic issue worldwide [17]. WRKY transcription factors are involved in regulation of plant tolerance to both abiotic and biotic stresses.…”

Section: Introductionmentioning

confidence: 99%

Genome-wide characterization of WRKY gene family in Helianthus annuus L. and their expression profiles under biotic and abiotic stresses

Chong

Islam

et al. 2020

Preprint

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Background: WRKY transcription factors play important roles in various physiological processes and stress responses in flowering plants. However, the information about WRKY genes in Helianthus annuus L. (common sunflower) is limited. Results: Ninety WRKY (HaWRKY) genes were identified and renamed according to their locations on chromosomes. Further phylogenetic analyses classified them into four main groups including a species-specific WKKY group and HaWRKY genes within same group or subgroup generally showed similar exon-intron structures and motif compositions. The tandem and segmental duplication possibly contributed to the diversity and expansion of HaWRKY gene families. Synteny analyses of sunflower WRKY genes provided deep insight to the evolution of HaWRKY genes. Transcriptomic and qRT-PCR analyses of HaWRKY genes displayed distinct expression patterns in different plant tissues, as well as under various abiotic and biotic stresses. Conclusions: Ninety WRKY (HaWRKY) genes were identified from H. annuus L. and classified into four groups. Structures of HaWRKY proteins and their evolutionary characteristics were also investigated. The characterization of HaWRKY genes and their expression profiles under biotic and abiotic stresses in this study provide a foundation for further functional analyses of these genes and will be beneficial to crop improvement.

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iTRAQ‐based proteomics of sunflower cultivars differing in resistance to parasitic weed Orobanche cumana

Cited by 33 publications

References 67 publications

Genetic and Genomic Tools in Sunflower Breeding for Broomrape Resistance

Genetic and Genomic Tools in Sunflower Breeding for Broomrape Resistance

On the Promising Role of Enzyme Activity Assay in Interpreting Comparative Proteomic Data in Plants

Genome-wide characterization of WRKY gene family in Helianthus annuus L. and their expression profiles under biotic and abiotic stresses

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