Manganese hyperaccumulation capacity of Ilex paraguariensis A. St. Hil. and occurrence of interveinal chlorosis induced by transient toxicity

Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn and are referred to as hyperaccumulating species. In this study, we evaluated the capacity of Ilex paraguariensis to accumulate Mn and the eff...

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Published inEcotoxicology and environmental safety Vol. 203; p. 111010
Main Authors Magri, Ederlan, Gugelmin, Eduardo Kieras, Grabarski, Felipe Augusto Piacentini, Barbosa, Julierme Zimmer, Auler, André Carlos, Wendling, Ivar, Prior, Stephen Arthur, Valduga, Alice Teresa, Motta, Antônio Carlos Vargas
Format Journal Article
LanguageEnglish
Published Elsevier Inc 15.10.2020
Subjects
Elemental composition
Nutritional imbalance
X-ray microanalysis
Yerba mate
Nutritional imbalance
Elemental composition
X-ray microanalysis
Yerba mate
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Abstract Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn and are referred to as hyperaccumulating species. In this study, we evaluated the capacity of Ilex paraguariensis to accumulate Mn and the effect of excessive concentrations on plant growth and nutrition. For this, a container experiment was conducted using soils from different parent materials (basalt and sandstone), with and without liming, and at six doses of applied Mn (0, 30, 90, 270, 540 and 1,080 mg kg−1). Clonal plants grown for 203 days were harvested to evaluate yield, and leaf tissue samples were evaluated for Mn and other elements. Without liming and with high Mn doses, leaf Mn concentrations reached 13,452 and 12,127 mg kg−1 in sandstone and basalt soils, respectively; concentrations in excess of 10,000 mg kg−1 are characteristic of hyperaccumulating plants. Liming reduced these values to 7203 and 8030 mg kg−1. More plant growth accompanied increased Mn leaf concentrations, with a growth reduction noted at the highest dose in unlimed soils. Elemental distribution showed Mn presence in the mesophyll, primarily in vascular bundles, without high Mn precipitates. Interveinal chlorosis of young leaves associated with high Mn concentration and lower Fe concentrations was observed, especially in sandstone soil without liming. However, the occurrence of this symptom was not associated with decreased plant growth. •Ilex paraguariensis can have leaf Mn concentrations above 10,000 mg kg−1.•Under excess Mn conditions, interveinal chlorosis can appear.•Liming can be used to reduce the concentration of Mn in Ilex paraguariensis leaves.
AbstractList Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn and are referred to as hyperaccumulating species. In this study, we evaluated the capacity of Ilex paraguariensis to accumulate Mn and the effect of excessive concentrations on plant growth and nutrition. For this, a container experiment was conducted using soils from different parent materials (basalt and sandstone), with and without liming, and at six doses of applied Mn (0, 30, 90, 270, 540 and 1,080 mg kg-1). Clonal plants grown for 203 days were harvested to evaluate yield, and leaf tissue samples were evaluated for Mn and other elements. Without liming and with high Mn doses, leaf Mn concentrations reached 13,452 and 12,127 mg kg-1 in sandstone and basalt soils, respectively; concentrations in excess of 10,000 mg kg-1 are characteristic of hyperaccumulating plants. Liming reduced these values to 7203 and 8030 mg kg-1. More plant growth accompanied increased Mn leaf concentrations, with a growth reduction noted at the highest dose in unlimed soils. Elemental distribution showed Mn presence in the mesophyll, primarily in vascular bundles, without high Mn precipitates. Interveinal chlorosis of young leaves associated with high Mn concentration and lower Fe concentrations was observed, especially in sandstone soil without liming. However, the occurrence of this symptom was not associated with decreased plant growth.Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn and are referred to as hyperaccumulating species. In this study, we evaluated the capacity of Ilex paraguariensis to accumulate Mn and the effect of excessive concentrations on plant growth and nutrition. For this, a container experiment was conducted using soils from different parent materials (basalt and sandstone), with and without liming, and at six doses of applied Mn (0, 30, 90, 270, 540 and 1,080 mg kg-1). Clonal plants grown for 203 days were harvested to evaluate yield, and leaf tissue samples were evaluated for Mn and other elements. Without liming and with high Mn doses, leaf Mn concentrations reached 13,452 and 12,127 mg kg-1 in sandstone and basalt soils, respectively; concentrations in excess of 10,000 mg kg-1 are characteristic of hyperaccumulating plants. Liming reduced these values to 7203 and 8030 mg kg-1. More plant growth accompanied increased Mn leaf concentrations, with a growth reduction noted at the highest dose in unlimed soils. Elemental distribution showed Mn presence in the mesophyll, primarily in vascular bundles, without high Mn precipitates. Interveinal chlorosis of young leaves associated with high Mn concentration and lower Fe concentrations was observed, especially in sandstone soil without liming. However, the occurrence of this symptom was not associated with decreased plant growth.
Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn and are referred to as hyperaccumulating species. In this study, we evaluated the capacity of Ilex paraguariensis to accumulate Mn and the effect of excessive concentrations on plant growth and nutrition. For this, a container experiment was conducted using soils from different parent materials (basalt and sandstone), with and without liming, and at six doses of applied Mn (0, 30, 90, 270, 540 and 1,080 mg kg−1). Clonal plants grown for 203 days were harvested to evaluate yield, and leaf tissue samples were evaluated for Mn and other elements. Without liming and with high Mn doses, leaf Mn concentrations reached 13,452 and 12,127 mg kg−1 in sandstone and basalt soils, respectively; concentrations in excess of 10,000 mg kg−1 are characteristic of hyperaccumulating plants. Liming reduced these values to 7203 and 8030 mg kg−1. More plant growth accompanied increased Mn leaf concentrations, with a growth reduction noted at the highest dose in unlimed soils. Elemental distribution showed Mn presence in the mesophyll, primarily in vascular bundles, without high Mn precipitates. Interveinal chlorosis of young leaves associated with high Mn concentration and lower Fe concentrations was observed, especially in sandstone soil without liming. However, the occurrence of this symptom was not associated with decreased plant growth. •Ilex paraguariensis can have leaf Mn concentrations above 10,000 mg kg−1.•Under excess Mn conditions, interveinal chlorosis can appear.•Liming can be used to reduce the concentration of Mn in Ilex paraguariensis leaves.
ArticleNumber 111010
Author Motta, Antônio Carlos Vargas
Magri, Ederlan
Barbosa, Julierme Zimmer
Auler, André Carlos
Wendling, Ivar
Grabarski, Felipe Augusto Piacentini
Prior, Stephen Arthur
Valduga, Alice Teresa
Gugelmin, Eduardo Kieras
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  givenname: Eduardo Kieras
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  givenname: Felipe Augusto Piacentini
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  givenname: André Carlos
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  givenname: Ivar
  surname: Wendling
  fullname: Wendling, Ivar
  email: ivar.wendling@embrapa.br
  organization: Brazilian Agricultural Research Corporation - Embrapa Forestry, Colombo, Paraná, Brazil
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  givenname: Stephen Arthur
  surname: Prior
  fullname: Prior, Stephen Arthur
  email: steve.prior@usda.gov
  organization: USDA-ARS National Soil Dynamics Laboratory, 411 South Donahue Drive, Auburn, AL, USA
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  givenname: Alice Teresa
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  givenname: Antônio Carlos Vargas
  surname: Motta
  fullname: Motta, Antônio Carlos Vargas
  email: mottaufpr@gmail.com
  organization: Department of Soils and Agricultural Engineering, Federal University of Paraná (UFPR), Curitiba, Paraná, Brazil
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Keywords Nutritional imbalance
Elemental composition
X-ray microanalysis
Yerba mate
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Snippet Manganese (Mn) toxicity is common in plants grown on very acid soils. However, some plants species that grow in this condition can take up high amounts of Mn...
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SubjectTerms Elemental composition
Nutritional imbalance
X-ray microanalysis
Yerba mate
Title Manganese hyperaccumulation capacity of Ilex paraguariensis A. St. Hil. and occurrence of interveinal chlorosis induced by transient toxicity
URI https://dx.doi.org/10.1016/j.ecoenv.2020.111010
https://www.proquest.com/docview/2440471747
Volume 203
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