Main Molecular Pathways Associated with Copper Tolerance Response in Imperata cylindrica by de novo Transcriptome Assembly

Vidal, Catalina; Larama, Giovanni; Riveros, Aníbal; Meneses, Claudio; Cornejo, Pablo

doi:10.3390/plants10020357

Cited by 10 publications

(7 citation statements)

References 64 publications

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“…High Cu concentration damage epidermal cells, reducing mitochondria and inducing cortical cell death [ 17 ]. There are gene families that play a key role in controlling Cu stress [ 19 ], and some of them are related to actin and cytoskeleton formation, metal transporters and superoxide dismutase activity in root tissues [ 20 ]. The root tissues of rice seedlings accumulate over 40% of the Cu present in the medium, and 60% of it was not fully available for transport [ 21 ].…”

Section: Discussionmentioning

confidence: 99%

Tissue Distribution and Biochemical Changes in Response to Copper Accumulation in Erica australis L.

Trigueros

Oliva

2021

Plants

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Copper uptake, accumulation in different tissues and organs and biochemical and physiological parameters were studied in Erica australis treated with different Cu concentrations (1, 50, 100 and 200 µM) under hydroponic culture. Copper treatments led to a significant reduction in growth rate, biomass production and water content in shoots, while photosynthetic pigments did not change. Copper treatments led to an increase in catalase and peroxidase activities. Copper accumulation followed the pattern roots > stems ≥ leaves, being roots the prevalent Cu sink. Analysis by scanning electron microscopy coupled with elemental X-ray analysis (SEM–EDX) showed a uniform Cu distribution in root tissues. On the contrary, in leaf tissues, Cu showed preferential storage in abaxial trichomes, suggesting a mechanism of compartmentation to restrict accumulation in mesophyll cells. The results show that the studied species act as a Cu-excluder, and Cu toxicity was avoided to a certain extent by root immobilization, leaf tissue compartmentation and induction of antioxidant enzymes to prevent cell damage.

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Section: Discussionmentioning

confidence: 99%

Tissue Distribution and Biochemical Changes in Response to Copper Accumulation in Erica australis L.

Trigueros

Oliva

2021

Plants

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“…Most proteins functionally interact with other small and large molecules (including other proteins and metabolites) to maintain cellular homeostasis. Protein–metabolite interactions are vital in cell signaling pathways (Venegas-Molina et al 2023 ). Large-scale proteomics analyses can unravel the networking between proteins and metabolic pathways (Yusuf et al 2022 ), but studies are limited.…”

Section: Advances In Three Major Omics Approaches For Enhancing Metal...mentioning

confidence: 99%

“…Recent developments include chemoproteomic workflows and an interactomics method using nuclear magnetic resonance (NMR) to systematically identify targeted metabolite–protein interactions (Li et al 2022c ). Techniques like limited proteolysis-coupled mass spectrometry (LiP-MS) have also been introduced to identify novel protein–metabolite interactions related to plant regulatory mechanisms (Venegas-Molina et al 2023 ).…”

Section: Advances In Three Major Omics Approaches For Enhancing Metal...mentioning

confidence: 99%

Transcriptomics, proteomics, and metabolomics interventions prompt crop improvement against metal(loid) toxicity

Raza,

Salehi,

Bashir

et al. 2024

Plant Cell Rep

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The escalating challenges posed by metal(loid) toxicity in agricultural ecosystems, exacerbated by rapid climate change and anthropogenic pressures, demand urgent attention. Soil contamination is a critical issue because it significantly impacts crop productivity. The widespread threat of metal(loid) toxicity can jeopardize global food security due to contaminated food supplies and pose environmental risks, contributing to soil and water pollution and thus impacting the whole ecosystem. In this context, plants have evolved complex mechanisms to combat metal(loid) stress. Amid the array of innovative approaches, omics, notably transcriptomics, proteomics, and metabolomics, have emerged as transformative tools, shedding light on the genes, proteins, and key metabolites involved in metal(loid) stress responses and tolerance mechanisms. These identified candidates hold promise for developing high-yielding crops with desirable agronomic traits. Computational biology tools like bioinformatics, biological databases, and analytical pipelines support these omics approaches by harnessing diverse information and facilitating the mapping of genotype-to-phenotype relationships under stress conditions. This review explores: (1) the multifaceted strategies that plants use to adapt to metal(loid) toxicity in their environment; (2) the latest findings in metal(loid)-mediated transcriptomics, proteomics, and metabolomics studies across various plant species; (3) the integration of omics data with artificial intelligence and high-throughput phenotyping; (4) the latest bioinformatics databases, tools and pipelines for single and/or multi-omics data integration; (5) the latest insights into stress adaptations and tolerance mechanisms for future outlooks; and (6) the capacity of omics advances for creating sustainable and resilient crop plants that can thrive in metal(loid)-contaminated environments.

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“…The main groups of secondary plant metabolites, many of which function as EPIs, include phenolics, alkaloids, saponins, terpenes, lipids, and carbohydrates that have been identified using analytical equipment, such as HPLC and MS/MS ( Table 2 ) [ 54 , 55 ]. Exposure to Cu significantly increased the synthesis of phenolic compounds in the shoots of Imperata cylindrica , which is a grass in Chile that grows in soil with varying distributions of Cu contamination [ 56 ]. Under stress conditions, phenols act as chelating metals through hydroxyl and carboxyl groups and inhibit lipid peroxidation by trapping alkoxyl radicals.…”

Section: Secondary Metabolites Production Of Plants As Potential Epismentioning

confidence: 99%

“…Under stress conditions, phenols act as chelating metals through hydroxyl and carboxyl groups and inhibit lipid peroxidation by trapping alkoxyl radicals. Therefore, exposure to toxic elements leads to the formation of reactive oxygen species (ROS), which consequently increases the production of phenolic compounds in plants [ 56 ]. Phenolics from root exudation depend on metal concentrations or plant species [ 57 ].…”

Section: Secondary Metabolites Production Of Plants As Potential Epismentioning

confidence: 99%

Efflux Pump Inhibitors in Controlling Antibiotic Resistance: Outlook under a Heavy Metal Contamination Context

Nguyen

et al. 2023

Molecules

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Multi-drug resistance to antibiotics represents a growing challenge in treating infectious diseases. Outside the hospital, bacteria with the multi-drug resistance (MDR) phenotype have an increased prevalence in anthropized environments, thus implying that chemical stresses, such as metals, hydrocarbons, organic compounds, etc., are the source of such resistance. There is a developing hypothesis regarding the role of metal contamination in terrestrial and aquatic environments as a selective agent in the proliferation of antibiotic resistance caused by the co-selection of antibiotic and metal resistance genes carried by transmissible plasmids and/or associated with transposons. Efflux pumps are also known to be involved in either antibiotic or metal resistance. In order to deal with these situations, microorganisms use an effective strategy that includes a range of expressions based on biochemical and genetic mechanisms. The data from numerous studies suggest that heavy metal contamination could affect the dissemination of antibiotic-resistant genes. Environmental pollution caused by anthropogenic activities could lead to mutagenesis based on the synergy between antibiotic efficacy and the acquired resistance mechanism under stressors. Moreover, the acquired resistance includes plasmid-encoded specific efflux pumps. Soil microbiomes have been reported as reservoirs of resistance genes that are available for exchange with pathogenic bacteria. Importantly, metal-contaminated soil is a selective agent that proliferates antibiotic resistance through efflux pumps. Thus, the use of multi-drug efflux pump inhibitors (EPIs) originating from natural plants or synthetic compounds is a promising approach for restoring the efficacy of existing antibiotics, even though they face a lot of challenges.

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Main Molecular Pathways Associated with Copper Tolerance Response in Imperata cylindrica by de novo Transcriptome Assembly

Cited by 10 publications

References 64 publications

Tissue Distribution and Biochemical Changes in Response to Copper Accumulation in Erica australis L.

Tissue Distribution and Biochemical Changes in Response to Copper Accumulation in Erica australis L.

Transcriptomics, proteomics, and metabolomics interventions prompt crop improvement against metal(loid) toxicity

Efflux Pump Inhibitors in Controlling Antibiotic Resistance: Outlook under a Heavy Metal Contamination Context

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