Search

Your search keyword '"Simonin, Marie"' showing total 251 results
Start Over Author "Simonin, Marie"
251 results on '"Simonin, Marie"'

1. Transmission of synthetic seed bacterial communities to radish seedlings: impact on microbiota assembly and plant phenotype

Author

Simonin, Marie, Préveaux, Anne, Marais, Coralie, Garin, Tiffany, Arnault, Gontran, Sarniguet, Alain, and Barret, Matthieu

Subjects
Plant microbiota, Seed-borne bacteria, Core microbiota, Synthetic community, Phytobiome, Pathobiome, Archaeology, CC1-960, Science
Abstract

Seed-borne microorganisms can be pioneer taxa during germination and seedling emergence. Still, the identity and phenotypic effects of these taxa that constitute a primary inoculum of plant microbiota is mostly unknown. Here, we studied the transmission of bacteria from radish seeds to seedlings using the inoculation of individual seed-borne strains and synthetic communities (SynComs) under in vitro conditions. The SynComs were composed of highly abundant and prevalent, sub-dominant, or rare bacterial seed taxa. We monitored the transmission of each strain alone or in communities using gyrB gene amplicon sequencing and assessed their impacts on germination and seedling phenotype. All strains and SynComs successfully colonized seedlings and we were able to reconstruct a richness gradient (6, 8 and 12 strains) on both seeds and seedlings. Stenotrophomonas rhizophila became dominant on seedlings of the three SynComs but most strains had variable transmission success (i.e increasing, stable or decreasing during seed to seedling transition) that also depended on the SynCom richness. Most individual strains had no effect on seedling phenotypes, with the exception of Pseudomonas viridiflava and Paenibacillus sp. which had detrimental effects on germination and seedling development. Abnormal seedling morphologies were also observed with SynComs but their proportions decreased at the highest richness level. Interestingly, some bacterial strains previously identified as core taxa of radish seeds (Pseudomonas viridiflava, Erwinia persicina) were associated with detrimental effects on seedling phenotypes either in isolation or in SynComs. These results confirm that the plant core microbiome includes pathogenic and not only commensal or mutualistic taxa. Altogether, these results show that SynCom inoculation can effectively manipulate seed and seedling microbiota diversity and thus represents a promising tool to better understand the early stages of plant microbiota assembly. This study also highlights strong differences between native seed-borne taxa in the colonization and survival on plant habitats.

Published
2023
Full Text
View/download PDF

4. An extended root phenotype: the rhizosphere, its formation and impacts on plant fitness

Author

de la Fuente Cantó, Carla, Simonin, Marie, King, Eoghan, Moulin, Lionel, Bennett, Malcolm J, Castrillo, Gabriel, and Laplaze, Laurent

Subjects
Plant Biology, Biochemistry and Cell Biology, Biological Sciences, Nutrition, Plant Physiological Phenomena, Plant Roots, Plants, Rhizosphere, Soil Microbiology, root, soil, microbiome, biocontrol, plant nutrition, drought, salinity, rhizosphere, exudates, Plant Biology & Botany, Biochemistry and cell biology, Plant biology
Abstract

Plants forage soil for water and nutrients, whose distribution is patchy and often dynamic. To improve their foraging activities, plants have evolved mechanisms to modify the physicochemical properties and microbial communities of the rhizosphere, i.e. the soil compartment under the influence of the roots. This dynamic interplay in root-soil-microbiome interactions creates emerging properties that impact plant nutrition and health. As a consequence, the rhizosphere can be considered an extended root phenotype, a manifestation of the effects of plant genes on their environment inside and/or outside of the organism. Here, we review current understanding of how plants shape the rhizosphere and the benefits it confers to plant fitness. We discuss future research challenges and how applying their solutions in crops will enable us to harvest the benefits of the extended root phenotype.

Published
2020

13. Biological inhibition of denitrification (BDI): an early plant strategy for Fallopia × bohemica seedling development.

Author

Cantarel, Amélie A M, Signoret, Aymeric, Gervaix, Jonathan, Beligon, Chiquitta, Béraud, Cédric, Boisselet, Christelle, Châtelliers, Charline Creuzé des, Defour, Pauline, Delort, Abigaïl, Lacroix, Elise, Lobreau, Clément, Louvez, Enzo, Marais, Coralie, Simonin, Marie, and Piola, Florence

Subjects
DENITRIFICATION, NITROGEN in soils, NITROGEN cycle, PLANT performance, SOIL structure, SOIL microbiology
Abstract

Background and Aims The successful plant Fallopia  ×  bohemica presents interesting capacities for control of the soil nitrogen cycle at the adult stage, termed biological inhibition of denitrification (BDI). The BDI strategy allows the plant, via the production of secondary metabolites (procyanidins), to compete with the denitrifying microbial community and to divert nitrate from the soil for its benefit. In this study, we analysed whether seedlings of F.  ×  bohemica can implement BDI at the seedling stage. We also determined whether soil nitrogen availability influences the implementation of BDI and seedling growth. Methods We sowed achenes of F.  ×  bohemica in soils representing a nitrogen gradient (six treatments) and harvested seedlings after 20 or 40 days of growth. The denitrification and related microbial communities (i.e. functional gene abundances of nirK and nirS), soil parameters (nitrate content and humidity) and plant performance (biomass, growth and root morphology) were determined. Key Results On soil without addition of nitrogen, BDI was observed after 20 days of growth, whereas a stimulation of denitrification was found after 40 days. The increase of soil N content had few effects on the activity and structure of the soil denitrifying community and on the plant biomasses or the relative growth rates. Correlations between plant and microbial parameters were observed after 20 days of growth, reflecting early and strong chemical interactions between plants and the denitrifying community, which decreased with plant growth after 40 days. Conclusions This study shows that an early BDI enhances the efficiency of nitrogen acquisition in the first weeks of growth, allowing for a conservative root strategy after 40 days. This switch to a conservative strategy involved resource storage, an altered allocation to above- and below-ground parts and an investment in fine roots. It now seems clear that this storage strategy starts at a very young age with early establishment of BDI, giving this clonal plant exceptional capacities for storage and multiplication. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

15. Biological inhibition of denitrification (BDI): an early plant strategy for Fallopia × bohemica seedling development

Author

Cantarel, Amélie A M, primary, Signoret, Aymeric, additional, Gervaix, Jonathan, additional, Beligon, Chiquitta, additional, Béraud, Cédric, additional, Boisselet, Christelle, additional, Creuzé des Châtelliers, Charline, additional, Defour, Pauline, additional, Delort, Abigaïl, additional, Lacroix, Elise, additional, Lobreau, Clément, additional, Louvez, Enzo, additional, Marais, Coralie, additional, Simonin, Marie, additional, and Piola, Florence, additional

Published
2023
Full Text
View/download PDF

21. Density declines, richness increases, and composition shifts in stream macroinvertebrates

Author

Rumschlag, Samantha L., primary, Mahon, Michael B., additional, Jones, Devin K., additional, Battaglin, William, additional, Behrens, Jonny, additional, Bernhardt, Emily S., additional, Bradley, Paul, additional, Brown, Ethan, additional, De Laender, Frederik, additional, Hill, Ryan, additional, Kunz, Stefan, additional, Lee, Sylvia, additional, Rosi, Emma, additional, Schäfer, Ralf, additional, Schmidt, Travis S., additional, Simonin, Marie, additional, Smalling, Kelly, additional, Voss, Kristofor, additional, and Rohr, Jason R., additional

Published
2023
Full Text
View/download PDF

22. Microbial community structure associated with rice roots in contrasting rice agrosystems in western Burkina Faso [P1.1-150]

Author

Barro, Mariam, Wonni, Issa, Simonin, Marie, Kassankogno, Abalo Itolou, Klonowska, Agnieszka, Moulin, Lionel, Béna, Gilles, Somda, Irénée, Brunel, Caroline, Tollenaere, Charlotte, Barro, Mariam, Wonni, Issa, Simonin, Marie, Kassankogno, Abalo Itolou, Klonowska, Agnieszka, Moulin, Lionel, Béna, Gilles, Somda, Irénée, Brunel, Caroline, and Tollenaere, Charlotte

Abstract

Plants recruit soil microorganisms to provide various functions or protection against pathogens. Crop plants and their associated microbial communities are therefore increasingly studied together. However, the mechanisms that control the assembly of the root-associated microbiome remain difficult to disentangle, especially in rice ecosystems, which are poorly studied. Here, we compare the assembly of rice rootassociated microbiota sampled from 19 smallholder fields in the irrigated and rainfed lowlands of Burkina Faso. Using a 16S rRNA gene amplicon and ITS metabarcoding approach, we show that the rice production system is a major factor in the structure of the microbiome in addition to the expected structure by root compartments (root vs. rhizosphere) and geographic areas. In irrigated systems, we found greater diversity of rhizosphere prokaryotic communities and more complex co-occurrence networks, compared to rainfed lowlands, while fungal communities showed an opposite pattern. The main taxa were different between the two systems, and indicator species were identified: mostly within Bacillaceae in the rainfed lowlands, and within Burkholderiaceae and Moraxellaceae in the irrigated areas. Finally, a higher abundance in rainfed lowlands was found for mycorrhizal fungi. Our results highlight profound differences in the microbiome induced by contrasting rice production systems that should therefore be considered for microbial engineering applications.

Published
2023

23. Mean species responses predict effects of environmental change on coexistence

Author

De Laender, Frederik, Carpentier, Camille, Carletti, Timoteo, Song, Chuliang, Rumschlag, Samantha L., Mahon, Michael B., Simonin, Marie, Meszena, Geza, Barabas, György, De Laender, Frederik, Carpentier, Camille, Carletti, Timoteo, Song, Chuliang, Rumschlag, Samantha L., Mahon, Michael B., Simonin, Marie, Meszena, Geza, and Barabas, György

Abstract

Environmental change research is plagued by the curse of dimensionality: the number of communities at risk and the number of environmental drivers are both large. This raises the pressing question if a general understanding of ecological effects is achievable. Here, we show evidence that this is indeed possible. Using theoretical and simulation-based evidence for bi- and tritrophic communities, we show that environmental change effects on coexistence are proportional to mean species responses and depend on how trophic levels on average interact prior to environmental change. We then benchmark our findings using relevant cases of environmental change, showing that means of temperature optima and of species sensitivities to pollution predict concomitant effects on coexistence. Finally, we demonstrate how to apply our theory to the analysis of field data, finding support for effects of land use change on coexistence in natural invertebrate communities., Funding Agencies|FNRS-FRFC [2.5020.11, GEQ U.G006.15, 1610468, RW/GEQ2016 et U]; Hungarian National Research, Development and Innovation Offi [NKFI-123796]; Universite de Namur [2.5020.11, GEQ U.G006.15, 1610468, RW/GEQ2016 et U]; NARC fellowsh; Waalse Gewest [2.5020.11, GEQ U.G006.15, 1610468, RW/GEQ2016 et U]; Hungarian National Research, Development and Innovation Offi [NKFI-123796]; Waalse Gewest [2.5020.11, GEQ U.G006.15, 1610468, RW/GEQ2016 et U]

Published
2023
Full Text
View/download PDF

24. Mean species responses predict effects of environmental change on coexistence.

Author

De Laender, Frederik, Carpentier, Camille, Carletti, Timoteo, Song, Chuliang, Rumschlag, Samantha L., Mahon, Michael B., Simonin, Marie, Meszéna, Géza, and Barabás, György

Subjects
ENVIRONMENTAL research, BIOTIC communities, INVERTEBRATE communities, FOOD chains, SPECIES
Abstract

Environmental change research is plagued by the curse of dimensionality: the number of communities at risk and the number of environmental drivers are both large. This raises the pressing question if a general understanding of ecological effects is achievable. Here, we show evidence that this is indeed possible. Using theoretical and simulation‐based evidence for bi‐ and tritrophic communities, we show that environmental change effects on coexistence are proportional to mean species responses and depend on how trophic levels on average interact prior to environmental change. We then benchmark our findings using relevant cases of environmental change, showing that means of temperature optima and of species sensitivities to pollution predict concomitant effects on coexistence. Finally, we demonstrate how to apply our theory to the analysis of field data, finding support for effects of land use change on coexistence in natural invertebrate communities. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

30. Enrichment in biodiversity and maturation of the soil food web under conservation agriculture is associated with suppression of rice-parasitic nematodes

Author

Masson, Anne-Sophie, primary, Vermeire, Marie-Liesse, additional, Leng, Vira, additional, Simonin, Marie, additional, Tivet, Florent, additional, Nguyen Thi, Hue, additional, Brunel, Caroline, additional, Suong, Malyna, additional, Kuok, Fidero, additional, Moulin, Lionel, additional, and Bellafiore, Stéphane, additional

Published
2022
Full Text
View/download PDF

31. The impact of the rice production system (irrigated vs lowland) on root-associated microbiome from farmer's fields in western Burkina Faso

Author

Barro, Mariam, Wonni, Issa, Simonin, Marie, Kassankogno, Abalo Itolou, Klonowska, Agnieszka, Moulin, Lionel, Béna, Gilles, Somda, Irénée, Brunel, Caroline, Tollenaere, Charlotte, Barro, Mariam, Wonni, Issa, Simonin, Marie, Kassankogno, Abalo Itolou, Klonowska, Agnieszka, Moulin, Lionel, Béna, Gilles, Somda, Irénée, Brunel, Caroline, and Tollenaere, Charlotte

Abstract

Due to their potential applications for food safety, there is a growing interest in rice root-associated microbial communities, but some systems remain understudied. Here, we compare the assemblage of root-associated microbiota in rice sampled in 19 small farmer's fields from irrigated and rainfed lowlands in Burkina Faso, using an amplicon metabarcoding approach of the 16S rRNA gene (prokaryotes, three plant samples per field) and ITS (fungi, one sample per field). In addition to the expected structure by root compartments (root vs rhizosphere) and geographical zones, we showed that the rice production system is a major driver of microbiome structure. In irrigated systems, we found a higher diversity of prokaryotic communities from the rhizosphere and more complex co-occurrence networks, compared to rainfed lowlands, while fungal communities exhibited an opposite pattern (higher richness in rainfed lowlands). Core taxa were different between the two systems, and indicator species were identified: mostly within Bacillaceae in rainfed lowlands, and within Burkholderiaceae and Moraxellaceae in irrigated areas. Finally, a higher abundance in rainfed lowlands was found for mycorrhizal fungi (both compartments) and rhizobia (rhizosphere only). Our results highlight deep microbiome differences induced by contrasted rice production systems that should consequently be considered for microbial engineering applications.

Published
2022

37. Toward a Generalizable Framework of Disturbance Ecology Through Crowdsourced Science

Author

Graham, Emily B., Averill, Colin, Bond-Lamberty, Ben, Knelman, Joseph E., Krause, Stefan, Peralta, Ariane L., Shade, Ashley, Smith, A. Peyton, Cheng, Susan J., Fanin, Nicolas, Freund, Cathryn, Garcia, Patricia E., Gibbons, Sean M., Van Goethem, Marc W., Guebila, Marouen Ben, Kemppinen, Julia, Nowicki, Robert J., Pausas, Juli G., Reed, Samuel P., Rocca, Jennifer, Sengupta, Aditi, Sihi, Debjani, Simonin, Marie, Słowiński, Michał, Spawn, Seth A., Sutherland, Ira, Tonkin, Jonathan D., Wisnoski, Nathan I., Zipper, Samuel C., Staal, Arie, Arora, Bhavna, Oldfield, Callie, Dwivedi, Dipankar, Larson, Erin, Santillan, Ezequiel, Aaron Hogan, J., Atkins, Jeff, Zheng, Jianqiu, Lembrechts, Jonas, Patel, Kaizad, Copes-Gerbitz, Kelsey, Winker, Kevin, Mudge, Laura, Wong, Mark, Nuñez, Martin, Luoto, Miska, Barnes, Rebecca, Spatial Ecology and Global Change, and Environmental Sciences

Subjects
reistance, ecosystem stability, spatioal, compounding disturbances, Temporal, resilience, interacting disturbances, Perturbation
Abstract

Disturbances fundamentally alter ecosystem functions, yet predicting their impacts remains a key scientific challenge. While the study of disturbances is ubiquitous across many ecological disciplines, there is no agreed-upon, cross-disciplinary foundation for discussing or quantifying the complexity of disturbances, and no consistent terminology or methodologies exist. This inconsistency presents an increasingly urgent challenge due to accelerating global change and the threat of interacting disturbances that can destabilize ecosystem responses. By harvesting the expertise of an interdisciplinary cohort of contributors spanning 42 institutions across 15 countries, we identified an essential limitation in disturbance ecology: the word ‘disturbance’ is used interchangeably to refer to both the events that cause, and the consequences of, ecological change, despite fundamental distinctions between the two meanings. In response, we developed a generalizable framework of ecosystem disturbances, providing a well-defined lexicon for understanding disturbances across perspectives and scales. The framework results from ideas that resonate across multiple scientific disciplines and provides a baseline standard to compare disturbances across fields. This framework can be supplemented by discipline-specific variables to provide maximum benefit to both inter- and intra-disciplinary research. To support future syntheses and meta-analyses of disturbance research, we also encourage researchers to be explicit in how they define disturbance drivers and impacts, and we recommend minimum reporting standards that are applicable regardless of scale. Finally, we discuss the primary factors we considered when developing a baseline framework and propose four future directions to advance our interdisciplinary understanding of disturbances and their social-ecological impacts: integrating across ecological scales, understanding disturbance interactions, establishing baselines and trajectories, and developing process-based models and ecological forecasting initiatives. Our experience through this process motivates us to encourage the wider scientific community to continue to explore new approaches for leveraging Open Science principles in generating creative and multidisciplinary ideas.

Published
2021

38. impact of the rice production system (irrigated vs lowland) on root-associated microbiome from farmer's fields in western Burkina Faso.

Author

Barro, Mariam, Wonni, Issa, Simonin, Marie, Kassankogno, Abalo Itolou, Klonowska, Agnieszka, Moulin, Lionel, Béna, Gilles, Somda, Irénée, Brunel, Caroline, and Tollenaere, Charlotte

Subjects
MYCORRHIZAL fungi, FOOD safety, MICROBIAL communities, BACILLACEAE, FARMERS, FUNGAL communities, RICE, COMMUNITIES
Abstract

Due to their potential applications for food safety, there is a growing interest in rice root-associated microbial communities, but some systems remain understudied. Here, we compare the assemblage of root-associated microbiota in rice sampled in 19 small farmer's fields from irrigated and rainfed lowlands in Burkina Faso, using an amplicon metabarcoding approach of the 16S rRNA gene (prokaryotes, three plant samples per field) and ITS (fungi, one sample per field). In addition to the expected structure by root compartments (root vs rhizosphere) and geographical zones, we showed that the rice production system is a major driver of microbiome structure. In irrigated systems, we found a higher diversity of prokaryotic communities from the rhizosphere and more complex co-occurrence networks, compared to rainfed lowlands, while fungal communities exhibited an opposite pattern (higher richness in rainfed lowlands). Core taxa were different between the two systems, and indicator species were identified: mostly within Bacillaceae in rainfed lowlands, and within Burkholderiaceae and Moraxellaceae in irrigated areas. Finally, a higher abundance in rainfed lowlands was found for mycorrhizal fungi (both compartments) and rhizobia (rhizosphere only). Our results highlight deep microbiome differences induced by contrasted rice production systems that should consequently be considered for microbial engineering applications. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

44. Toward a Generalizable Framework of Disturbance Ecology Through Crowdsourced Science

Author

Spatial Ecology and Global Change, Environmental Sciences, Graham, Emily B., Averill, Colin, Bond-Lamberty, Ben, Knelman, Joseph E., Krause, Stefan, Peralta, Ariane L., Shade, Ashley, Smith, A. Peyton, Cheng, Susan J., Fanin, Nicolas, Freund, Cathryn, Garcia, Patricia E., Gibbons, Sean M., Van Goethem, Marc W., Guebila, Marouen Ben, Kemppinen, Julia, Nowicki, Robert J., Pausas, Juli G., Reed, Samuel P., Rocca, Jennifer, Sengupta, Aditi, Sihi, Debjani, Simonin, Marie, Słowiński, Michał, Spawn, Seth A., Sutherland, Ira, Tonkin, Jonathan D., Wisnoski, Nathan I., Zipper, Samuel C., Staal, Arie, Arora, Bhavna, Oldfield, Callie, Dwivedi, Dipankar, Larson, Erin, Santillan, Ezequiel, Aaron Hogan, J., Atkins, Jeff, Zheng, Jianqiu, Lembrechts, Jonas, Patel, Kaizad, Copes-Gerbitz, Kelsey, Winker, Kevin, Mudge, Laura, Wong, Mark, Nuñez, Martin, Luoto, Miska, Barnes, Rebecca, Spatial Ecology and Global Change, Environmental Sciences, Graham, Emily B., Averill, Colin, Bond-Lamberty, Ben, Knelman, Joseph E., Krause, Stefan, Peralta, Ariane L., Shade, Ashley, Smith, A. Peyton, Cheng, Susan J., Fanin, Nicolas, Freund, Cathryn, Garcia, Patricia E., Gibbons, Sean M., Van Goethem, Marc W., Guebila, Marouen Ben, Kemppinen, Julia, Nowicki, Robert J., Pausas, Juli G., Reed, Samuel P., Rocca, Jennifer, Sengupta, Aditi, Sihi, Debjani, Simonin, Marie, Słowiński, Michał, Spawn, Seth A., Sutherland, Ira, Tonkin, Jonathan D., Wisnoski, Nathan I., Zipper, Samuel C., Staal, Arie, Arora, Bhavna, Oldfield, Callie, Dwivedi, Dipankar, Larson, Erin, Santillan, Ezequiel, Aaron Hogan, J., Atkins, Jeff, Zheng, Jianqiu, Lembrechts, Jonas, Patel, Kaizad, Copes-Gerbitz, Kelsey, Winker, Kevin, Mudge, Laura, Wong, Mark, Nuñez, Martin, Luoto, Miska, and Barnes, Rebecca

Published
2021

45. Guided by Microbes : Applying Community Coalescence Principles for Predictive Microbiome Engineering

Author

Rocca, Jennifer D., Muscarella, Mario E., Peralta, Ariane L., Izabel-Shen, Dandan, Simonin, Marie, Rocca, Jennifer D., Muscarella, Mario E., Peralta, Ariane L., Izabel-Shen, Dandan, and Simonin, Marie

Abstract

Every seed germinating in soils, wastewater treatment, and stream confluence exemplify microbial community coalescence—the blending of previously isolated communities. Here, we present theoretical and experimental knowledge on how separated microbial communities mix, with particular focus on managed ecosystems. We adopt the community coalescence framework, which integrates metacommunity theory and meta-ecosystem dynamics, and highlight the prevalence of these coalescence events within microbial systems. Specifically, we (i) describe fundamental types of community coalescences using naturally occurring and managed examples, (ii) offer ways forward to leverage community coalescence in managed systems, and (iii) emphasize the importance of microbial ecological theory to achieving desired coalescence outcomes. Further, considering the massive dispersal events of microbiomes and their coalescences is pivotal to better predict microbial community dynamics and responses to disturbances. We conclude our piece by highlighting some challenges and unanswered question yet to be tackled.

Published
2021
Full Text
View/download PDF

46. Toward a Generalizable Framework of Disturbance Ecology Through Crowdsourced Science

Author

Department of Energy (US), Biological and Environmental Research (US), Graham, Emily B., Averill, Colin, Bond-Lamberty, Ben, Knelman, Joseph E., Krause, Stefan, Peralta, Ariane L., Shade, Ashley, Smith, A. Peyton, Cheng, Susan J., Fanin, Nicolas, Freund, Cathryn, García, Patricia E., Gibbons, Sean M., Goethem, Marc W. van, Guebila, Marouen Ben, Kemppinen, Julia, Nowicki, Robert J., Pausas, J. G., Reed, Samuel P., Rocca, Jennifer, Sengupta, Aditi, Sihi, Debjani, Simonin, Marie, Słowiński, Michał, Spawn, Seth A., Sutherland, Ira, Tonkin, Jonathan D., Wisnoski, Nathan I., Zipper, Samuel C., Department of Energy (US), Biological and Environmental Research (US), Graham, Emily B., Averill, Colin, Bond-Lamberty, Ben, Knelman, Joseph E., Krause, Stefan, Peralta, Ariane L., Shade, Ashley, Smith, A. Peyton, Cheng, Susan J., Fanin, Nicolas, Freund, Cathryn, García, Patricia E., Gibbons, Sean M., Goethem, Marc W. van, Guebila, Marouen Ben, Kemppinen, Julia, Nowicki, Robert J., Pausas, J. G., Reed, Samuel P., Rocca, Jennifer, Sengupta, Aditi, Sihi, Debjani, Simonin, Marie, Słowiński, Michał, Spawn, Seth A., Sutherland, Ira, Tonkin, Jonathan D., Wisnoski, Nathan I., and Zipper, Samuel C.

Abstract

Disturbances fundamentally alter ecosystem functions, yet predicting their impacts remains a key scientific challenge. While the study of disturbances is ubiquitous across many ecological disciplines, there is no agreed-upon, cross-disciplinary foundation for discussing or quantifying the complexity of disturbances, and no consistent terminology or methodologies exist. This inconsistency presents an increasingly urgent challenge due to accelerating global change and the threat of interacting disturbances that can destabilize ecosystem responses. By harvesting the expertise of an interdisciplinary cohort of contributors spanning 42 institutions across 15 countries, we identified an essential limitation in disturbance ecology: the word ‘disturbance’ is used interchangeably to refer to both the events that cause, and the consequences of, ecological change, despite fundamental distinctions between the two meanings. In response, we developed a generalizable framework of ecosystem disturbances, providing a well-defined lexicon for understanding disturbances across perspectives and scales. The framework results from ideas that resonate across multiple scientific disciplines and provides a baseline standard to compare disturbances across fields. This framework can be supplemented by discipline-specific variables to provide maximum benefit to both inter- and intra-disciplinary research. To support future syntheses and meta-analyses of disturbance research, we also encourage researchers to be explicit in how they define disturbance drivers and impacts, and we recommend minimum reporting standards that are applicable regardless of scale. Finally, we discuss the primary factors we considered when developing a baseline framework and propose four future directions to advance our interdisciplinary understanding of disturbances and their social-ecological impacts: integrating across ecological scales, understanding disturbance interactions, establishing baselines and trajectories

Published
2021

50. Towards a generalizable framework of disturbance ecology through crowdsourced science

Author

Garcia, Patricia, Shade, Ashley, Graham, Emily, Rocca, Jennifer, Peralta, Ariane, Nowicki, Rob, Freund, Cathryn, Sengupta, Aditi, Wisnoski, Nathan, Gibbons, Sean, Cheng, Susan, Zipper, Sam, Kemppinen, Julia, Bond-Lamberty, Ben, Smith, A. Peyton, Simonin, Marie, Pausas, Juli, Consortium, Contributor, Guebila, Marouen, Reed, Samuel, Van Goethem, Marc, Słowiński, Michał, Sihi, Debjani, Krause, Stefan, Spawn-Lee, Seth, Averill, Colin, Tonkin, Jonathan, Knelman, Joseph, Fanin, Nicolas, and Sutherland, Ira

Subjects
bepress|Life Sciences|Ecology and Evolutionary Biology|Terrestrial and Aquatic Ecology, bepress|Life Sciences, bepress|Life Sciences|Ecology and Evolutionary Biology
Abstract

Disturbances fundamentally alter ecosystem functions, yet predicting their impacts remains a key scientific challenge. While the study of disturbances is ubiquitous across many ecological disciplines, there is no agreed-upon, cross-disciplinary foundation for discussing or quantifying the complexity of disturbances, and no consistent terminology or methodologies exist. This inconsistency presents an increasingly urgent challenge due to accelerating global change and the threat of interacting disturbances that can destabilize ecosystem responses. By harvesting the expertise of an interdisciplinary cohort of contributors spanning 42 institutions across 15 countries, we identified an essential limitation in disturbance ecology: the word ‘disturbance’ is used interchangeably to refer to both the events that cause, and the consequences of, ecological change, despite fundamental distinctions between the two meanings. In response, we developed a generalized framework of ecosystem disturbances to reconcile this limitation, providing a well-defined lexicon for understanding disturbance across perspectives and scales. The framework results from ideas that resonate across multiple scientific disciplines and provides a baseline standard to compare disturbances across fields. This framework can be supplemented by discipline-specific variables to provide maximum benefit to both inter- and intra-disciplinary research. To support future synthesis or meta-analysis of disturbance research, we also encourage researchers to be explicit in how they define disturbance drivers and impacts, recommend minimum reporting standards that studies should detail about the magnitude, duration, and rate of change of driver and response variables of a disturbance, regardless of scale. We discuss the primary factors we considered when developing a baseline framework and propose four future directions to advance our interdisciplinary understanding of disturbances and their social-ecological impacts: integrating across ecological scales, understanding disturbance interactions, establishing baselines and trajectories, and developing process-based models and ecological forecasting initiatives. Our experience through this process motivates us to encourage the wider scientific community to continue to explore new approaches for leveraging Open Science principles in generating creative and multidisciplinary ideas.

Published
2020

Catalog

Books, media, physical & digital resources
See catalog results