Transcriptomic and physiological analyses of Medicago sativa L. roots in response to lead stress

Xu, Bo; Wang, Yingzhe; Zhang, Shichao; Guo, Qiang; Jin, Yan; Chen, Jingjing; Gao, Yunhang; Ma, Huiqin

doi:10.1371/journal.pone.0175307

Cited by 25 publications

(10 citation statements)

References 58 publications

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“…Another aspect of this type of analysis is the translocation or accumulation of toxic elements within the different complex cell structures that make up plant roots. Furthermore, the use of technologies such as microarrays, RNAseq, and wide genome analysis has increased the amount of transcriptomic and genomic information available for plants under metal stress [ 135 , 151 , 152 , 153 , 154 , 155 , 156 , 157 , 158 , 159 ]. When analyzing the different plant transcriptomes under conditions of metal/metalloid stress, conserved trends have been observed.…”

Section: Transcriptomes and Metabolic And Functional Characterization Of Metal-toxicity-related Genesmentioning

confidence: 99%

Metal and Metalloid Toxicity in Plants: An Overview on Molecular Aspects

Angulo-Bejarano

Puente-Rivera

Cruz-Ortega

2021

Plants

179

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Worldwide, the effects of metal and metalloid toxicity are increasing, mainly due to anthropogenic causes. Soil contamination ranks among the most important factors, since it affects crop yield, and the metals/metalloids can enter the food chain and undergo biomagnification, having concomitant effects on human health and alterations to the environment. Plants have developed complex mechanisms to overcome these biotic and abiotic stresses during evolution. Metals and metalloids exert several effects on plants generated by elements such as Zn, Cu, Al, Pb, Cd, and As, among others. The main strategies involve hyperaccumulation, tolerance, exclusion, and chelation with organic molecules. Recent studies in the omics era have increased knowledge on the plant genome and transcriptome plasticity to defend against these stimuli. The aim of the present review is to summarize relevant findings on the mechanisms by which plants take up, accumulate, transport, tolerate, and respond to this metal/metalloid stress. We also address some of the potential applications of biotechnology to improve plant tolerance or increase accumulation.

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Section: Transcriptomes and Metabolic And Functional Characterization Of Metal-toxicity-related Genesmentioning

confidence: 99%

Metal and Metalloid Toxicity in Plants: An Overview on Molecular Aspects

Angulo-Bejarano

Puente-Rivera

Cruz-Ortega

2021

Plants

179

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“…Lead is a very toxic metal for plants with a toxicity threshold of less than one μM, almost as much as mercury (Hg) [Kopittke et al 2010]. Not only does it affect the growth of plants and productivity, but also the food chain, putting the health risk of humans and animals [Khan et al 2019, Sahi et al 2002, Xu et al 2017].…”

Section: Introductionmentioning

confidence: 99%

Lead in Agricultural Soils and Cultivated Pastures Irrigated with River Water Contaminated by Mining Activity

Orellana¹,

Custodio²,

Bastos³

et al. 2019

J. Ecol. Eng.

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Agricultural soils that have been irrigated with the contaminated water from metallurgical mining activities for more than 70 years constitute an environmental problem as well as a concern for food security and human health. The presence of lead in the soil and cultivated pastures is highly dangerous, due to its toxicity, persistence and accumulation in plants and animals (cattle). This element enters the trophic chain of humans due to the intake of meat, milk and its derivatives. The concentration of lead was determined in the soil and the cultivated pastures with Lolium x hybridum Hausskn and Medicago sativa L. The soil and pastures samples collected from plots irrigated with river water contaminated with heavy metals at a depth of 0-20 cm. The content of Pb determined by the atomic absorption spectrophotometry. The results showed the lead concentrations in soil in the range of environmental quality standards for soils according to Peruvian regulations. In the soil with L. x hybridum and M. sativa the average content of lead was 57.17 ± 6.29 mg.kg -1 and 57.19 ± 8.99 mg.kg -1 ; in the above-ground tissues were 1.17 ± 0.69 mg.kg -1 and 1.62 ± 0.68 mg.kg -1 , respectively. In addition, no significant differences were observed in the Pb content in the soil and plant tissues. The bioconcentration factor (BCF) in the above-ground tissues of L. x hybridum and M. sativa was less than one and they were not significant. Therefore, irrigation with long-term contaminated water is not a concern for the farmers in the Mantaro Valley.

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“…The antioxidant enzyme system, including POD, SOD, CAT, and APX, could scavenge excessive ROS and improve plant resistance under various types of abiotic stresses (Yu et al, 2014;Singh et al, 2017;Xu et al, 2017;Ma et al, 2018). Compared with the OE lines, the WT plants showed deeper intense histochemical staining by cold treatment.…”

Section: Discussionmentioning

confidence: 99%

The Overexpression of a Transcription Factor Gene VbWRKY32 Enhances the Cold Tolerance in Verbena bonariensis

et al. 2020

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Cold stress poses a serious threat to the survival and bloom of Verbena bonariensis. The enhancement of the cold tolerance of V. bonariensis is the central concern of our research. The WRKY transcription factor (TF) family was paid great attention to in the field of abiotic stress. The VbWRKY32 gene was obtained from V. bonariensis. The VbWRKY32 predicted protein contained two typical WRKY domains and two C2H2 zinc-finger motifs. Under cold stress, VbWRKY32 in leaves was more greatly induced than that in stems and roots. The overexpression (OE) in V. bonariensis increased cold tolerance compared with wild-type (WT). Under cold stress, the OE lines possessed showed greater recovery after cold-treatment restoration ratios, proline content, soluble sugar content, and activities of antioxidant enzymes than WT; the relative electrolyte conductivity (EL), the accumulation of malondialdehyde (MDA), hydrogen peroxide (H 2 O 2), and superoxide anion (O 2 −) are lower in OE lines than that in WT. In addition, a series of cold-response genes of OE lines were compared with WT. The results revealed that VbWRKY32 worked as a positive regulator by up-regulating transcription levels of cold-responsive genes. The genes above can contribute to the elevation of antioxidant activities, maintain the membrane stability, and raise osmotic regulation ability, leading to the enhancement of the survival capacity under cold stress. According to this work, VbWRKY32 could serve as an essential gene to confer enhanced cold tolerance in plants.

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Transcriptomic and physiological analyses of Medicago sativa L. roots in response to lead stress

Cited by 25 publications

References 58 publications

Metal and Metalloid Toxicity in Plants: An Overview on Molecular Aspects

Metal and Metalloid Toxicity in Plants: An Overview on Molecular Aspects

Lead in Agricultural Soils and Cultivated Pastures Irrigated with River Water Contaminated by Mining Activity

The Overexpression of a Transcription Factor Gene VbWRKY32 Enhances the Cold Tolerance in Verbena bonariensis

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