Your search keyword '"Argus Pesqueda"' showing total 5 results

1. Ecometabolomics of plant–herbivore and plant–fungi interactions: a synthesis study

Author

Jordi Sardans, Albert Gargallo‐Garriga, Otmar Urban, Karel Klem, Petr Holub, Ivan A. Janssens, Tom W. N. Walker, Argus Pesqueda, and Josep Peñuelas

Subjects

biotic relationships, ecometabolomics, Ecology, QH540-549.5

Abstract

Abstract The functional adaptive responses of higher plants to biotic interactions with herbivores and fungi have long been topics of research. One constraint to obtaining a comprehensive understanding of the most general plant responses, however, has been the difficulty of studying all plant functional shifts simultaneously due to analytical limitations. Now this is possible with the advent of metabolomics. Using 151 records from the WEB of SCIENCE database, we have analyzed the development and application of metabolomic profiles to ecological studies in the last two decades. We have used meta‐analysis and pathway enrichment analyses to assess the whole set of constitutive and inducible defenses. Constitutive defenses against herbivores were mainly based on a significant high level of the metabolism of several amino acids with parallel increases in the concentrations of flavones (phenolics) and saponins (glycosides). Inducible defenses, though, were mainly based on the increases in concentration of methyl‐ketone, pantothenate, and Coenzyme A. Butyrate metabolism and the mitochondrial electron‐transport chain were upregulated, in agreement with previous reports that herbivory‐activated plant chemical defenses were mainly based on jasmonic acid, salicylic acid, and ethylene‐associated pathways. The metabolic responses/acclimations to pathogenic fungi were mainly linked with increases in aspartate and pyruvate metabolism, the transfer of acetyl groups within mitochondria, and the upregulation of branched‐chain amino acids degradation pathways. These responses/acclimations were accompanied by higher concentrations of the most important groups of secondary metabolites such as phenolics (anthocyanins, flavonoids), quinones, alkaloids, terpenoids, and polyamines and other compounds related to antistress mechanisms such as proline. The leaves of mycorrhized plants accumulated nucleotide sugars, sphingolipids, and methylhistidine. These responses were associated with maintaining the integrity of plant cell membranes under fungal hypha penetration. The responses were accompanied by increases in the concentrations of phenolics, blumenols, and alkaloids and decreases in the concentrations of polyamines, consistent with the mycorrhizal inhibition of polyamines. This summary provides a clear synthesis of the most successful plant strategies selected after millions of years of evolution and will be a very promising tool for the management of crops and ecosystems and for selecting the main lines in breeding studies for future research.

Published

2021

2. Assessing the effects of textile leachates in fish using multiple testing methods: From gene expression to behavior

Author

Bethanie Carney Almroth, Josefin Cartine, Christina Jönander, Max Karlsson, Julie Langlois, Matilda Lindström, Jakob Lundin, Nina Melander, Argus Pesqueda, Ida Rahmqvist, Juliette Renaux, Josefin Roos, Francis Spilsbury, Joel Svalin, Hanne Vestlund, Liqian Zhao, Noomi Asker, Giedrė Ašmonaitė, Lina Birgersson, Tahereh Boloori, Frida Book, Tobias Lammel, and Joachim Sturve

Subjects

Textiles, Leachates, Ecotoxicology, Fish, In vitro, In vivo, Environmental pollution, TD172-193.5, Environmental sciences, GE1-350

Abstract

The textile industry, while of major importance in the world economy, is a toxic industry utilizing and emitting thousands of chemical substances into the aquatic environment. The aim of this project was to study the potentially harmful effects associated with the leaching of chemical residues from three different types of textiles: sportswear, children’s bath towels, and denim using different fish models (cell lines, fish larvae and juvenile fish). A combination of in vitro and in vivo test systems was used. Numerous biomarkers, ranging from gene expression, cytotoxicity and biochemical analysis to behavior, were measured to detect effects of leached chemicals. Principle findings indicate that leachates from all three types of textiles induced cytotoxicity on fish cell lines (RTgill-W1). Leachates from sportswear and towels induced mortality in zebrafish embryos, and chemical residues from sportswear reduced locomotion responses in developing larval fish. Sportswear leachate increased Cyp1a mRNA expression and EROD activity in liver of exposed brown trout. Leachates from towels induced EROD activity and VTG in rainbow trout, and these effects were mitigated by the temperature of the extraction process. All indicators of toxicity tested showed that exposure to textile leachate can cause adverse reactions in fish. These findings suggested that chemical leaching from textiles from domestic households could pose an ecotoxicological threat to the health of the aquatic environment.

Published

2021

3. Reduced methane emissions in former permafrost soils driven by vegetation and microbial changes following drainage

Author

Christoph Keuschnig, Catherine Larose, Mario Rudner, Argus Pesqueda, Stéphane Doleac, Bo Elberling, Robert G. Björk, Leif Klemedtsson, Mats P. Björkman, Ampère, Département Bioingénierie (BioIng), Ampère (AMPERE), École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-École Centrale de Lyon (ECL), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), University of Gothenburg (GU), École polytechnique (X), Center for Permafrost (CENPERM), Department of Geosciences and Natural Resource Management [Copenhagen] (IGN), Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH)-Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH), Gothenburg Global Biodiversity Centre, Research and development projects to future research leaders at FORMAS – Swedish Research Council for Sustainable Development grant agreement 2016-01187 (M.P.B.)Danish National Research Foundation, Center for Permafrost, CENPERM DNRF100 (B.E)The strategic research environment BECC - Biodiversity and Ecosystem services in a Changing Climate, SITES - Swedish Infrastructure for Ecosystem Science and the foundations of H. Ax:son Johnson, Wilhelm & Martina Lundgren, Knut & Alice Wallenberg, and Carl Tryggers, and European Project: 657627,H2020,H2020-MSCA-IF-2014,PERMTHAW(2016)

Subjects

Tundra ecosystems, Global and Planetary Change, post-permafrost soil, Ecology, Arctic Regions, Microbiota, methane, Permafrost, Carbon, Soil, Arctic, climate change, [SDE]Environmental Sciences, Environmental Chemistry, Methane, General Environmental Science

Abstract

In Arctic regions, thawing permafrost soils are projected to release 50 to 250 Gt of carbon by 2100. This data is mostly derived from carbon-rich wetlands, although 71% of this carbon pool is stored in faster-thawing mineral soils, where ecosystems close to the outer boundaries of permafrost regions are especially vulnerable. Although extensive data exists from currently thawing sites and short-term thawing experiments, investigations of the long-term changes following final thaw and co-occurring drainage are scarce. Here we show ecosystem changes at two comparable tussock tundra sites with distinct permafrost thaw histories, representing 15 and 25 years of natural drainage, that resulted in a 10-fold decrease in CH4 emissions (3.2 ± 2.2 vs. 0.3 ± 0.4 mg C-CH4 m−2 day−1), while CO2 emissions were comparable. These data extend the time perspective from earlier studies based on short-term experimental drainage. The overall microbial community structures did not differ significantly between sites, although the drier top soils at the most advanced site led to a loss of methanogens and their syntrophic partners in surface layers while the abundance of methanotrophs remained unchanged. The resulting deeper aeration zones likely increased CH4 oxidation due to the longer residence time of CH4 in the oxidation zone, while the observed loss of aerenchyma plants reduced CH4 diffusion from deeper soil layers directly to the atmosphere. Our findings highlight the importance of including hydrological, vegetation and microbial specific responses when studying long-term effects of climate change on CH4 emissions and underscores the need for data from different soil types and thaw histories.

Published

2022

4. Ecometabolomics of plant–herbivore and plant–fungi interactions: a synthesis study

Author

Karel Klem, Jordi Sardans, Tom W. N. Walker, Petr Holub, Albert Gargallo-Garriga, Josep Peñuelas, Otmar Urban, Argus Pesqueda, and Ivan A. Janssens

Subjects

Chemistry, Herbivore, biotic relationships, ecometabolomics, Ecology, Botany, fungi, Biology, Plant fungi, Ecology, Evolution, Behavior and Systematics, QH540-549.5

Abstract

The functional adaptive responses of higher plants to biotic interactions with herbivores and fungi have long been topics of research. One constraint to obtaining a comprehensive understanding of the most general plant responses, however, has been the difficulty of studying all plant functional shifts simultaneously due to analytical limitations. Now this is possible with the advent of metabolomics. Using 151 records from the WEB of SCIENCE database, we have analyzed the development and application of metabolomic profiles to ecological studies in the last two decades. We have used meta-analysis and pathway enrichment analyses to assess the whole set of constitutive and inducible defenses. Constitutive defenses against herbivores were mainly based on a significant high level of the metabolism of several amino acids with parallel increases in the concentrations of flavones (phenolics) and saponins (glycosides). Inducible defenses, though, were mainly based on the increases in concentration of methyl-ketone, pantothenate, and Coenzyme A. Butyrate metabolism and the mitochondrial electron-transport chain were upregulated, in agreement with previous reports that herbivory-activated plant chemical defenses were mainly based on jasmonic acid, salicylic acid, and ethylene-associated pathways. The metabolic responses/acclimations to pathogenic fungi were mainly linked with increases in aspartate and pyruvate metabolism, the transfer of acetyl groups within mitochondria, and the upregulation of branched-chain amino acids degradation pathways. These responses/acclimations were accompanied by higher concentrations of the most important groups of secondary metabolites such as phenolics (anthocyanins, flavonoids), quinones, alkaloids, terpenoids, and polyamines and other compounds related to antistress mechanisms such as proline. The leaves of mycorrhized plants accumulated nucleotide sugars, sphingolipids, and methylhistidine. These responses were associated with maintaining the integrity of plant cell membranes under fungal hypha penetration. The responses were accompanied by increases in the concentrations of phenolics, blumenols, and alkaloids and decreases in the concentrations of polyamines, consistent with the mycorrhizal inhibition of polyamines. This summary provides a clear synthesis of the most successful plant strategies selected after millions of years of evolution and will be a very promising tool for the management of crops and ecosystems and for selecting the main lines in breeding studies for future research., Ecosphere, 12 (9), ISSN:2150-8925

Published

2021

5. Assessing the effects of textile leachates in fish using multiple testing methods: From gene expression to behavior

Author

Nina Melander, Liqian Zhao, Matilda Lindström, Josefin Roos, Joel Svalin, Tahereh Boloori, Hanne Vestlund, Giedrė Ašmonaitė, Juliette Renaux, Ida Rahmqvist, Tobias Lammel, Frida Book, Francis Spilsbury, Josefine Cartine, Joachim Sturve, Argus Pesqueda, Julie Langlois, Noomi Asker, Lina Birgersson, Jakob Lundin, Max Karlsson, Bethanie Carney Almroth, and Christina Jönander

Subjects

Health, Toxicology and Mutagenesis, Gene Expression, Biology, Ecotoxicology, Environmental pollution, Brown trout, In vitro, In vivo, Gene expression, Toxicity Tests, Animals, GE1-350, Leachate, Food science, Textiles, Public Health, Environmental and Occupational Health, General Medicine, Juvenile fish, Leachates, Ichthyoplankton, Pollution, Environmental sciences, Fish, TD172-193.5, Liver, Oncorhynchus mykiss, Textile Industry, Toxicity, Rainbow trout, Water Pollutants, Chemical

Abstract

The textile industry, while of major importance in the world economy, is a toxic industry utilizing and emitting thousands of chemical substances into the aquatic environment. The aim of this project was to study the potentially harmful effects associated with the leaching of chemical residues from three different types of textiles: sportswear, children’s bath towels, and denim using different fish models (cell lines, fish larvae and juvenile fish). A combination of in vitro and in vivo test systems was used. Numerous biomarkers, ranging from gene expression, cytotoxicity and biochemical analysis to behavior, were measured to detect effects of leached chemicals. Principle findings indicate that leachates from all three types of textiles induced cytotoxicity on fish cell lines (RTgill-W1). Leachates from sportswear and towels induced mortality in zebrafish embryos, and chemical residues from sportswear reduced locomotion responses in developing larval fish. Sportswear leachate increased Cyp1a mRNA expression and EROD activity in liver of exposed brown trout. Leachates from towels induced EROD activity and VTG in rainbow trout, and these effects were mitigated by the temperature of the extraction process. All indicators of toxicity tested showed that exposure to textile leachate can cause adverse reactions in fish. These findings suggested that chemical leaching from textiles from domestic households could pose an ecotoxicological threat to the health of the aquatic environment.

Published

2020