Manganese accumulation and plant physiology behavior of <i>Camellia oleifera</i> in response to different levels of potassium fertilization

Yu, Fangming; Wang, Xueru; Yao, Yawei; Lin, Jheng-Hua; Huang, Yuanyuan; Xie, Dongyu; Liu, Kehui; Li, Yongguang

doi:10.1080/15226514.2020.1726871

Cited by 10 publications

(4 citation statements)

References 44 publications

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“…Meanwhile, Naciri et al [ 30 ] showed that potassium supplementation improves photosynthesis and promotes chlorophyll synthesis in hydroponic tomato. Similarly, Yu et al [ 31 ] consistently showed that an appropriate K concentration is required for the formation of photosynthetic pigments, non-enzymatic and enzymatic antioxidants, metabolic processes, and nutrient absorption. Song et al [ 32 ] showed that external K supply reduces zinc toxicity on peach seedlings, while enhancing photosynthesis and the antioxidant plant defense system.…”

Section: Discussionmentioning

confidence: 97%

Metabolome and transcriptome profiles in quinoa seedlings in response to potassium supply

et al. 2022

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Background Quinoa (Chenopodium quinoa Willd.) is a herb within the Quinoa subfamily of Amaranthaceae, with remarkable environmental adaptability. Its edible young leaves and grains are rich in protein, amino acids, microorganisms, and minerals. Although assessing the effects of fertilization on quinoa yield and quality has become an intensive area of research focus, the associated underlying mechanisms remain unclear. As one of the three macro nutrients in plants, potassium has an important impact on plant growth and development. In this study, extensive metabolome and transcriptome analyses were conducted in quinoa seedlings 30 days after fertilizer application to characterize the growth response mechanism to potassium. Results The differential metabolites and genes present in the seedlings of white and red quinoa cultivars were significantly enriched in the photosynthetic pathway. Moreover, the PsbQ enzyme on photosystem II and delta enzyme on ATP synthase were significantly down regulated in quinoa seedlings under potassium deficiency. Additionally, the differential metabolites and genes of red quinoa seedlings were significantly enriched in the arginine biosynthetic pathway. Conclusions These findings provide a more thorough understanding of the molecular changes in quinoa seedlings that occur under deficient, relative to normal, potassium levels. Furthermore, this study provides a theoretical basis regarding the importance of potassium fertilizers, as well as their efficient utilization by growing quinoa seedlings.

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Section: Discussionmentioning

confidence: 97%

Metabolome and transcriptome profiles in quinoa seedlings in response to potassium supply

et al. 2022

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“…Leaf Mn concentrations were above the sufficiency range and Mg concentrations below, in particular in the control treatment. Although hops seem somewhat sensitive to Mn toxicity (Afonso, Arrobas, and Rodrigues 2020), applications of K may be able to alleviate the potential damage caused by excess Mn (Yu et al 2020).…”

Section: Discussionmentioning

confidence: 99%

Hop dry matter yield and cone quality responses to amino acid and potassium-rich foliar spray applications

Afonso

Arrobas

Morais

et al. 2021

Journal of Plant Nutrition

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The use of amino acid and K-rich foliar sprays was evaluated in a commercial hop field in North-eastern Portugal. Four applications of an amino acid-rich foliar spray were performed in place of a second side dress N application of ~70 kg N ha À1 , which is usually applied by the farmer. The K-rich foliar spray was applied once at the cone developing stage as a supplement to the farmer's fertilization plan. The amino acid-enriched foliar spray maintained crop dry matter yield at the levels of the control treatment and increased cone alpha-acids concentration (41.8% in 2018 and 9.3% in 2019). Foliar K did not increase cone dry matter yield, cone size or bitter acid concentration. Tissue K concentration was not significantly affected by foliar treatments whereas the application of K seemed to increase N uptake, with leaves and stems being the predominant allocation tissues. Both foliar treatments increased leaf and stem Mg concentrations. The results seem to emphasize the importance of amino acids in the biosynthesis of bitter acids, while K and Zn seemed to play an important secondary role, maybe related to N metabolism and its reduction into amino acids. The concentrations of total phenols in cones and leaves were lower in the foliar treatments in comparison to the control, and the higher values registered in leaves. In this study, the use of amino acids as a foliar spray provided an interesting result, since they maintained cone dry matter yield and increased cone bitter acid concentration with reduced N use.

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“…However, very few studies on nutrient deficiency have been carried out for oiltea-camellia, especially on genetic perspectives. The oiltea-camellia plants have extraordinary Mn accumulation and toleration abilities, and proper application of nitrogen and potassium could enhance the efficiency of Mn phytoremediation ( Li et al., 2019 ; Yu et al., 2019 ; Yu et al., 2020 ). Based on the analysis of degradome, transcriptome and small RNA data, thirty-two deferentially expressed miRNAs under low inorganic phosphate treatment, and three hub target genes ( ARF22 , SCL6 , and WRKY53 ) controlling transcriptomic regulation of low inorganic phosphate stress tolerance were identified ( Chen et al., 2022a ).…”

Section: Genes For Abiotic Stress Tolerance and Biotic Stress Resistancementioning

confidence: 99%

Genomic and genetic advances of oiltea-camellia (Camellia oleifera)

Ye¹,

He²,

Peng³

et al. 2023

Front. Plant Sci.

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Oiltea-camellia (C. oleifera) is a widely cultivated woody oil crop in Southern China and Southeast Asia. The genome of oiltea-camellia was very complex and not well explored. Recently, genomes of three oiltea-camellia species were sequenced and assembled, multi-omic studies of oiltea-camellia were carried out and provided a better understanding of this important woody oil crop. In this review, we summarized the recent assembly of the reference genomes of oiltea-camellia, genes related to economic traits (flowering, photosynthesis, yield and oil component), disease resistance (anthracnose) and environmental stress tolerances (drought, cold, heat and nutrient deficiency). We also discussed future directions of integrating multiple omics for evaluating genetic resources and mining key genes of important traits, and the application of new molecular breeding and gene editing technologies to accelerate the breeding process of oiltea-camellia.

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Manganese accumulation and plant physiology behavior of Camellia oleifera in response to different levels of potassium fertilization

Cited by 10 publications

References 44 publications

Metabolome and transcriptome profiles in quinoa seedlings in response to potassium supply

Metabolome and transcriptome profiles in quinoa seedlings in response to potassium supply

Hop dry matter yield and cone quality responses to amino acid and potassium-rich foliar spray applications

Genomic and genetic advances of oiltea-camellia (Camellia oleifera)

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