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Main Authors: Garda, Tamás, Juhász, Gabriella Petra, Kelemen, Adrienn, Mathur, Jaideep, Ujlaky-Nagy, László, Freytag, Csongor, M-Hamvas, Márta, Riba, Milán, Máthé, Csaba
Format: Artículo científico
Language:en
Published: Environmental pollution (Barking, Essex : 1987) 2025
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Online Access:https://pubmed.ncbi.nlm.nih.gov/40609892/
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author Garda, Tamás
Juhász, Gabriella Petra
Kelemen, Adrienn
Mathur, Jaideep
Ujlaky-Nagy, László
Freytag, Csongor
M-Hamvas, Márta
Riba, Milán
Máthé, Csaba
author_facet Garda, Tamás
Juhász, Gabriella Petra
Kelemen, Adrienn
Mathur, Jaideep
Ujlaky-Nagy, László
Freytag, Csongor
M-Hamvas, Márta
Riba, Milán
Máthé, Csaba
Garda, Tamás
Juhász, Gabriella Petra
Kelemen, Adrienn
Mathur, Jaideep
Ujlaky-Nagy, László
Freytag, Csongor
M-Hamvas, Márta
Riba, Milán
Máthé, Csaba
collection PubMed - marine biology
contents Long-term treatments with microcystin-LR and diquat reveal their differences in the induction of oxidative stress responses and mitotic alterations in terms of stress recovery in Arabidopsis roots. Garda, Tamás Juhász, Gabriella Petra Kelemen, Adrienn Mathur, Jaideep Ujlaky-Nagy, László Freytag, Csongor M-Hamvas, Márta Riba, Milán Máthé, Csaba Microcystins Arabidopsis Oxidative Stress Marine Toxins Mitosis Plant Roots Reactive Oxygen Species Diquat Herbicides Phosphorylation Histones Microcystin-LR (MCY-LR), a widespread natural cyanobacterial toxin is a potent inhibitor of type 1 and 2A protein phosphatases (PP1, PP2A), inducing oxidative stress as well. Diquat (DQ) is a herbicide that inhibits electron transport to induce strong oxidative stress. Both compounds are affecting natural environments as well as plant and human health. We conducted a comparative analysis on their long-term (48 h) effects on reactive oxygen species (ROS) production, mitosis and histone H3 phosphorylation in root apical meristems of wild-type and PP2A-related mutants of Arabidopsis thaliana. MCY-LR did not increase ROS levels in any of the genotypes, but increased significantly the activity of ROS scavenging peroxidases (PODs) in Col0. DQ decreased ROS levels, but did not affect PODs. The paradoxical effect of DQ indicated the initiation of cell death processes. Mitosis was not affected by MCY-LR, but inhibited by DQ. Interestingly, MCY-LR as a phosphatase inhibitor did not affect histone H3 phosphorylation in mitotic cells, but DQ had an increasing effect. As we have shown previously, most of the above parameters changed differently at shorter (24 h) exposures: both compounds increased ROS levels in the phosphatase mutants, while POD activities were not affected; inhibition of mitosis or arrests in early mitosis, as well as increases of histone H3 phosphorylation levels occurred in the presence of both compounds. To conclude, Arabidopsis is able of recover partially and transiently from MCY-LR induced stress at long-term exposure, but this is not true for DQ. The environmental relevance of these findings is discussed.
format Artículo científico
id pubmed_40609892
institution PubMed
language en
publishDate 2025
publisher Environmental pollution (Barking, Essex : 1987)
record_format pubmed
spellingShingle Long-term treatments with microcystin-LR and diquat reveal their differences in the induction of oxidative stress responses and mitotic alterations in terms of stress recovery in Arabidopsis roots.
Garda, Tamás
Juhász, Gabriella Petra
Kelemen, Adrienn
Mathur, Jaideep
Ujlaky-Nagy, László
Freytag, Csongor
M-Hamvas, Márta
Riba, Milán
Máthé, Csaba
Microcystins
Arabidopsis
Oxidative Stress
Marine Toxins
Mitosis
Plant Roots
Reactive Oxygen Species
Diquat
Herbicides
Phosphorylation
Histones
Long-term treatments with microcystin-LR and diquat reveal their differences in the induction of oxidative stress responses and mitotic alterations in terms of stress recovery in Arabidopsis roots. Garda, Tamás Juhász, Gabriella Petra Kelemen, Adrienn Mathur, Jaideep Ujlaky-Nagy, László Freytag, Csongor M-Hamvas, Márta Riba, Milán Máthé, Csaba Microcystins Arabidopsis Oxidative Stress Marine Toxins Mitosis Plant Roots Reactive Oxygen Species Diquat Herbicides Phosphorylation Histones Microcystin-LR (MCY-LR), a widespread natural cyanobacterial toxin is a potent inhibitor of type 1 and 2A protein phosphatases (PP1, PP2A), inducing oxidative stress as well. Diquat (DQ) is a herbicide that inhibits electron transport to induce strong oxidative stress. Both compounds are affecting natural environments as well as plant and human health. We conducted a comparative analysis on their long-term (48 h) effects on reactive oxygen species (ROS) production, mitosis and histone H3 phosphorylation in root apical meristems of wild-type and PP2A-related mutants of Arabidopsis thaliana. MCY-LR did not increase ROS levels in any of the genotypes, but increased significantly the activity of ROS scavenging peroxidases (PODs) in Col0. DQ decreased ROS levels, but did not affect PODs. The paradoxical effect of DQ indicated the initiation of cell death processes. Mitosis was not affected by MCY-LR, but inhibited by DQ. Interestingly, MCY-LR as a phosphatase inhibitor did not affect histone H3 phosphorylation in mitotic cells, but DQ had an increasing effect. As we have shown previously, most of the above parameters changed differently at shorter (24 h) exposures: both compounds increased ROS levels in the phosphatase mutants, while POD activities were not affected; inhibition of mitosis or arrests in early mitosis, as well as increases of histone H3 phosphorylation levels occurred in the presence of both compounds. To conclude, Arabidopsis is able of recover partially and transiently from MCY-LR induced stress at long-term exposure, but this is not true for DQ. The environmental relevance of these findings is discussed.
title Long-term treatments with microcystin-LR and diquat reveal their differences in the induction of oxidative stress responses and mitotic alterations in terms of stress recovery in Arabidopsis roots.
topic Microcystins
Arabidopsis
Oxidative Stress
Marine Toxins
Mitosis
Plant Roots
Reactive Oxygen Species
Diquat
Herbicides
Phosphorylation
Histones
url https://pubmed.ncbi.nlm.nih.gov/40609892/