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24 results on '"Happonen, K."'

1. The Arctic plant aboveground biomass synthesis dataset

Author

Berner, L. T., Orndahl, K. M., Rose, M., Tamstorf, M., Arndal, M. F., Alexander, H. D., Humphreys, E. R., Loranty, M.l M., Ludwig, S. M., Nyman, J., Juutinen, S., Aurela, M., Happonen, K., Mikola, J., Mack, M. C., Vankoughnett, M. R., Iversen, C. M., Salmon, V. G., Yang, D., Kumar, J., Grogan, P., Danby, R. K., Scott, N. A., Olofsson, J., Siewert, M. B., Deschamps, L., Lévesque, E., Maire, V., Morneault, A., Gauthier, G., Gignac, C., Boudreau, S., Gaspard, A., Kholodov, A., Bret-Harte, M. S., Greaves, H. E., Walker, D., Gregory, F. M., Michelsen, A., Kumpula, T., Villoslada, M., Ylänne, H., Luoto, M., Virtanen, T., Forbes, B. C., Hölzel, N., Epstein, H., Heim, R. J., Bunn, A., Holmes, R. M., Hung, J. K. Y., Natali, S. M., Virkkala, A.-M., Goetz, S. J., Berner, L. T., Orndahl, K. M., Rose, M., Tamstorf, M., Arndal, M. F., Alexander, H. D., Humphreys, E. R., Loranty, M.l M., Ludwig, S. M., Nyman, J., Juutinen, S., Aurela, M., Happonen, K., Mikola, J., Mack, M. C., Vankoughnett, M. R., Iversen, C. M., Salmon, V. G., Yang, D., Kumar, J., Grogan, P., Danby, R. K., Scott, N. A., Olofsson, J., Siewert, M. B., Deschamps, L., Lévesque, E., Maire, V., Morneault, A., Gauthier, G., Gignac, C., Boudreau, S., Gaspard, A., Kholodov, A., Bret-Harte, M. S., Greaves, H. E., Walker, D., Gregory, F. M., Michelsen, A., Kumpula, T., Villoslada, M., Ylänne, H., Luoto, M., Virtanen, T., Forbes, B. C., Hölzel, N., Epstein, H., Heim, R. J., Bunn, A., Holmes, R. M., Hung, J. K. Y., Natali, S. M., Virkkala, A.-M., and Goetz, S. J.

Abstract

Plant biomass is a fundamental ecosystem attribute that is sensitive to rapid climatic changes occurring in the Arctic. Nevertheless, measuring plant biomass in the Arctic is logistically challenging and resource intensive. Lack of accessible field data hinders efforts to understand the amount, composition, distribution, and changes in plant biomass in these northern ecosystems. Here, we present The Arctic plant aboveground biomass synthesis dataset, which includes field measurements of lichen, bryophyte, herb, shrub, and/or tree aboveground biomass (g m−2) on 2,327 sample plots from 636 field sites in seven countries. We created the synthesis dataset by assembling and harmonizing 32 individual datasets. Aboveground biomass was primarily quantified by harvesting sample plots during mid- to late-summer, though tree and often tall shrub biomass were quantified using surveys and allometric models. Each biomass measurement is associated with metadata including sample date, location, method, data source, and other information. This unique dataset can be leveraged to monitor, map, and model plant biomass across the rapidly warming Arctic.

Published
2024

2. Insufficient arterial driving pressure turns hypoxic microvascular remodeling into a catastrophe

Author

Korpisalo, P, primary, Tarvainen, S, additional, Wirth, G, additional, Juusola, G, additional, Happonen, K, additional, Frimodig, C, additional, Hytonen, J, additional, Taavitsainen, J, additional, Greco, D, additional, Knuuti, J, additional, Hartikainen, J, additional, Laitinen, T, additional, Yla-Herttuala, S, additional, Hakovirta, H, additional, and Makinen, K, additional

Published
2023
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3. Plant traits poorly predict winner and loser shrub species in a warming tundra biome

Author

García Criado, M., Myers-Smith, I.H., Bjorkman, A.D., Normand, S., Blach-Overgaard, A., Thomas, H.J.D., Eskelinen, Anu Maria, Happonen, K., Alatalo, J.M., Anadon-Rosell, A., Aubin, I., te Beest, M., Betway-May, K.R., Blok, D., Buras, A., Cerabolini, B.E.L., Christie, K., Cornelissen, J.H.C., Forbes, B.C., Frei, E.R., Grogan, P., Hermanutz, L., Hollister, R.D., Hudson, J., Iturrate-Garcia, M., Kaarlejärvi, E., Kleyer, M., Lamarque, L.J., Lembrechts, J.J., Lévesque, E., Luoto, M., Macek, P., May, J.L., Prevéy, J.S., Schaepman-Strub, G., Sheremetiev, S.N., Siegwart Collier, L., Soudzilovskaia, N.A., Trant, A., Venn, S.E., Virkkala, A.-M., García Criado, M., Myers-Smith, I.H., Bjorkman, A.D., Normand, S., Blach-Overgaard, A., Thomas, H.J.D., Eskelinen, Anu Maria, Happonen, K., Alatalo, J.M., Anadon-Rosell, A., Aubin, I., te Beest, M., Betway-May, K.R., Blok, D., Buras, A., Cerabolini, B.E.L., Christie, K., Cornelissen, J.H.C., Forbes, B.C., Frei, E.R., Grogan, P., Hermanutz, L., Hollister, R.D., Hudson, J., Iturrate-Garcia, M., Kaarlejärvi, E., Kleyer, M., Lamarque, L.J., Lembrechts, J.J., Lévesque, E., Luoto, M., Macek, P., May, J.L., Prevéy, J.S., Schaepman-Strub, G., Sheremetiev, S.N., Siegwart Collier, L., Soudzilovskaia, N.A., Trant, A., Venn, S.E., and Virkkala, A.-M.

Abstract

Climate change is leading to species redistributions. In the tundra biome, shrubs are generally expanding, but not all tundra shrub species will benefit from warming. Winner and loser species, and the characteristics that may determine success or failure, have not yet been fully identified. Here, we investigate whether past abundance changes, current range sizes and projected range shifts derived from species distribution models are related to plant trait values and intraspecific trait variation. We combined 17,921 trait records with observed past and modelled future distributions from 62 tundra shrub species across three continents. We found that species with greater variation in seed mass and specific leaf area had larger projected range shifts, and projected winner species had greater seed mass values. However, trait values and variation were not consistently related to current and projected ranges, nor to past abundance change. Overall, our findings indicate that abundance change and range shifts will not lead to directional modifications in shrub trait composition, since winner and loser species share relatively similar trait spaces.

Published
2023

4. Geomorphological processes shape plant community traits in the Arctic

Author

Kemppinen, J. (Julia), Niittynen, P. (Pekka), Happonen, K. (Konsta), le Roux, P. C. (Peter C.), Aalto, J. (Juha), Hjort, J. (Jan), Maliniemi, T. (Tuija), Karjalainen, O. (Olli), Rautakoski, H. (Helena), Luoto, M. (Miska), Kemppinen, J. (Julia), Niittynen, P. (Pekka), Happonen, K. (Konsta), le Roux, P. C. (Peter C.), Aalto, J. (Juha), Hjort, J. (Jan), Maliniemi, T. (Tuija), Karjalainen, O. (Olli), Rautakoski, H. (Helena), and Luoto, M. (Miska)

Abstract

Aim: Geomorphological processes profoundly affect plant establishment and distributions, but their influence on functional traits is insufficiently understood. Here, we unveil trait–geomorphology relationships in Arctic plant communities. Location: High-Arctic Svalbard, low-Arctic Greenland and sub-Arctic Fennoscandia. Time period: 2011– 2018. Major taxa studied: Vascular plants. Methods: We collected field-quantified data on vegetation, geomorphological processes, microclimate and soil properties from 5,280 plots and 200 species across the three Arctic regions. We combined these data with database trait records to relate local plant community trait composition to dominant geomorphological processes of the Arctic, namely cryoturbation, deflation, fluvial processes and solifluction. We investigated the relationship between plant functional traits and geomorphological processes using hierarchical generalized additive modelling. Results: Our results demonstrate that community-level traits are related to geomorphological processes, with cryoturbation most strongly influencing both structural and leaf economic traits. These results were consistent across regions, suggesting a coherent biome- level trait response to geomorphological processes. Main conclusions: The results indicate that geomorphological processes shape plant community traits in the Arctic. We provide empirical evidence for the existence of generalizable relationships between plant functional traits and geomorphological processes. The results indicate that the relationships are consistent across these three distinct tundra regions and that geomorphological processes should be considered in future investigations of functional traits.

Published
2022

6. Trait-based responses to land use and canopy dynamics modify long-term diversity changes in forest understories

Author

Happonen, K. (Konsta), Muurinen, L. (Lauralotta), Virtanen, R. (Risto), Kaakinen, E. (Eero), Grytnes, J.-A. (John-Arvid), Kaarlejärvi, E. (Elina), Parisot, P. (Philippe), Wolff, M. (Matias), Maliniemi, T. (Tuija), Happonen, K. (Konsta), Muurinen, L. (Lauralotta), Virtanen, R. (Risto), Kaakinen, E. (Eero), Grytnes, J.-A. (John-Arvid), Kaarlejärvi, E. (Elina), Parisot, P. (Philippe), Wolff, M. (Matias), and Maliniemi, T. (Tuija)

Abstract

Aim: Land use is the foremost cause of global biodiversity decline, but species do not respond equally to land-use practices. Instead, it is suggested that responses vary with species traits, but long-term data on the trait-mediated effects of land use on communities are scarce. Here we study how forest understorey communities have been affected by two land-use practices during 4–5 decades, and whether changes in plant diversity are related to changes in functional composition. Location: Finland. Time period: 1968–2019. Major taxa studied: Vascular plants. Methods: We resurveyed 245 vegetation plots in boreal herb-rich forest understories, and used hierarchical Bayesian linear models to relate changes in diversity, species composition, average plant size, and leaf economic traits to reindeer abundance, forest management intensity, and changes in climate, canopy cover and composition. We also studied the relationship between species evenness and plant size across both space and time. Results: Intensively managed forests decreased in species richness and had increased turnover, but management did not affect functional composition. Increased reindeer densities corresponded with increased leaf dry matter content, evenness and diversity, and decreased height and specific leaf area. Successional development in the canopy was associated with increased specific leaf area and decreased leaf dry matter content and height in the understorey over the study period. Effects of reindeer abundance and canopy density on diversity were partially mediated by vegetation height, which had a negative relationship with evenness across both space and time. Observed changes in climate had no discernible effect on any variable. Main conclusions: Functional traits are useful in connecting vegetation changes to the mechanisms that drive them, and provide unique information compared to turnover and diversity metrics. These trait-dependent selection effects could inform which species be

Published
2021

8. Site fertility drives temporal turnover of vegetation at high latitudes

Author

Maliniemi, T. (Tuija), Happonen, K. (Konsta), Virtanen, R. (Risto), Maliniemi, T. (Tuija), Happonen, K. (Konsta), and Virtanen, R. (Risto)

Abstract

Experimental evidence shows that site fertility is a key modulator underlying plant community changes under climate change. Communities on fertile sites, with species having fast dynamics, have been found to react more strongly to climate change than communities on infertile sites with slow dynamics. However, it is still unclear whether this generally applies to high‐latitude plant communities in natural environments at broad spatial scales. We tested a hypothesis that vegetation of fertile sites experiences greater changes over several decades and thus would be more responsive under contemporary climate change compared to infertile sites that are expected to show more resistance. We resurveyed understorey communities (vascular plants, bryophytes, and lichens) of four infertile and four fertile forest sites along a latitudinal bioclimatic gradient. Sites had remained outside direct human disturbance. We analyzed the magnitude of temporal community turnover, changes in the abundances of plant morphological groups and strategy classes, and changes in species diversity. In agreement with our hypothesis, temporal turnover of communities was consistently greater on fertile sites compared to infertile sites. However, our results suggest that the larger turnover of fertile communities is not primarily related to the direct effects of climatic warming. Furthermore, community changes in both fertile and infertile sites showed remarkable variation in terms of shares of plant functional groups and strategy classes and measures of species diversity. This further emphasizes the essential role of baseline environmental conditions and nonclimatic drivers underlying vegetation changes. Our results show that site fertility is a key determinant of the overall rate of high‐latitude vegetation changes but the composition of plant communities in different ecological contexts is variously impacted by nonclimatic drivers over time.

Published
2019

9. Site fertility drives temporal turnover of vegetation at high latitudes

Author

Maliniemi, T., Happonen, K., Virtanen, Risto, Maliniemi, T., Happonen, K., and Virtanen, Risto

Abstract

Experimental evidence shows that site fertility is a key modulator underlying plant community changes under climate change. Communities on fertile sites, with species having fast dynamics, have been found to react more strongly to climate change than communities on infertile sites with slow dynamics. However, it is still unclear whether this generally applies to high‐latitude plant communities in natural environments at broad spatial scales. We tested a hypothesis that vegetation of fertile sites experiences greater changes over several decades and thus would be more responsive under contemporary climate change compared to infertile sites that are expected to show more resistance. We resurveyed understorey communities (vascular plants, bryophytes, and lichens) of four infertile and four fertile forest sites along a latitudinal bioclimatic gradient. Sites had remained outside direct human disturbance. We analyzed the magnitude of temporal community turnover, changes in the abundances of plant morphological groups and strategy classes, and changes in species diversity. In agreement with our hypothesis, temporal turnover of communities was consistently greater on fertile sites compared to infertile sites. However, our results suggest that the larger turnover of fertile communities is not primarily related to the direct effects of climatic warming. Furthermore, community changes in both fertile and infertile sites showed remarkable variation in terms of shares of plant functional groups and strategy classes and measures of species diversity. This further emphasizes the essential role of baseline environmental conditions and nonclimatic drivers underlying vegetation changes. Our results show that site fertility is a key determinant of the overall rate of high‐latitude vegetation changes but the composition of plant communities in different ecological contexts is variously impacted by nonclimatic drivers over time.

Published
2019

10. Tundra Trait Team:a database of plant traits spanning the tundra biome

Author

Bjorkman, A. D. (Anne D.), Myers-Smith, I. H. (Isla H.), Elmendorf, S. C. (Sarah C.), Normand, S. (Signe), Thomas, H. J. (Haydn J. D.), Alatalo, J. M. (Juha M.), Alexander, H. (Heather), Anadon-Rosell, A. (Alba), Angers-Blondin, S. (Sandra), Bai, Y. (Yang), Baruah, G. (Gaurav), te Beest, M. (Mariska), Berner, L. (Logan), Bjork, R. G. (Robert G.), Blok, D. (Daan), Bruelheide, H. (Helge), Buchwal, A. (Agata), Buras, A. (Allan), Carbognani, M. (Michele), Christie, K. (Katherine), Collier, L. S. (Laura S.), Cooper, E. J. (Elisabeth J.), Cornelissen, J. H. (J. Hans C.), Dickinson, K. J. (Katharine J. M.), Dullinger, S. (Stefan), Elberling, B. (Bo), Eskelinen, A. (Anu), Forbes, B. C. (Bruce C.), Frei, E. R. (Esther R.), Iturrate-Garcia, M. (Maitane), Good, M. K. (Megan K.), Grau, O. (Oriol), Green, P. (Peter), Greve, M. (Michelle), Grogan, P. (Paul), Haider, S. (Sylvia), Hajek, T. (Tomas), Hallinger, M. (Martin), Happonen, K. (Konsta), Harper, K. A. (Karen A.), Heijmans, M. M. (Monique M. P. D.), Henry, G. H. (Gregory H. R.), Hermanutz, L. (Luise), Hewitt, R. E. (Rebecca E.), Hollister, R. D. (Robert D.), Hudson, J. (James), Huelber, K. (Karl), Iversen, C. M. (Colleen M.), Jaroszynska, F. (Francesca), Jimenez-Alfaro, B. (Borja), Johnstone, J. (Jill), Jorgensen, R. H. (Rasmus Halfdan), Kaarlejarvi, E. (Elina), Klady, R. (Rebecca), Klimesova, J. (Jitka), Korsten, A. (Annika), Kuleza, S. (Sara), Kulonen, A. (Aino), Lamarque, L. J. (Laurent J.), Lantz, T. (Trevor), Lavalle, A. (Amanda), Lembrechts, J. J. (Jonas J.), Levesque, E. (Esther), Little, C. J. (Chelsea J.), Luoto, M. (Miska), Macek, P. (Petr), Mack, M. C. (Michelle C.), Mathakutha, R. (Rabia), Michelsen, A. (Anders), Milbau, A. (Ann), Molau, U. (Ulf), Morgan, J. W. (John W.), Morsdorf, M. A. (Martin Alfons), Nabe-Nielsen, J. (Jacob), Nielsen, S. S. (Sigrid Scholer), Ninot, J. M. (Josep M.), Oberbauer, S. F. (Steven F.), Olofsson, J. (Johan), Onipchenko, V. G. (Vladimir G.), Petraglia, A. (Alessandro), Pickering, C. (Catherine), Prevey, J. S. (Janet S.), Rixen, C. (Christian), Rumpf, S. B. (Sabine B.), Schaepman-Strub, G. (Gabriela), Semenchuk, P. (Philipp), Shetti, R. (Rohan), Soudzilovskaia, N. A. (Nadejda A.), Spasojevic, M. J. (Marko J.), Speed, J. D. (James David Mervyn), Street, L. E. (Lorna E.), Suding, K. (Katharine), Tape, K. D. (Ken D.), Tomaselli, M. (Marcello), Trant, A. (Andrew), Treier, U. A. (Urs A.), Tremblay, J.-P. (Jean-Pierre), Tremblay, M. (Maxime), Venn, S. (Susanna), Virkkala, A.-M. (Anna-Maria), Vowles, T. (Tage), Weijers, S. (Stef), Wilmking, M. (Martin), Wipf, S. (Sonja), Zamin, T. (Tara), Bjorkman, A. D. (Anne D.), Myers-Smith, I. H. (Isla H.), Elmendorf, S. C. (Sarah C.), Normand, S. (Signe), Thomas, H. J. (Haydn J. D.), Alatalo, J. M. (Juha M.), Alexander, H. (Heather), Anadon-Rosell, A. (Alba), Angers-Blondin, S. (Sandra), Bai, Y. (Yang), Baruah, G. (Gaurav), te Beest, M. (Mariska), Berner, L. (Logan), Bjork, R. G. (Robert G.), Blok, D. (Daan), Bruelheide, H. (Helge), Buchwal, A. (Agata), Buras, A. (Allan), Carbognani, M. (Michele), Christie, K. (Katherine), Collier, L. S. (Laura S.), Cooper, E. J. (Elisabeth J.), Cornelissen, J. H. (J. Hans C.), Dickinson, K. J. (Katharine J. M.), Dullinger, S. (Stefan), Elberling, B. (Bo), Eskelinen, A. (Anu), Forbes, B. C. (Bruce C.), Frei, E. R. (Esther R.), Iturrate-Garcia, M. (Maitane), Good, M. K. (Megan K.), Grau, O. (Oriol), Green, P. (Peter), Greve, M. (Michelle), Grogan, P. (Paul), Haider, S. (Sylvia), Hajek, T. (Tomas), Hallinger, M. (Martin), Happonen, K. (Konsta), Harper, K. A. (Karen A.), Heijmans, M. M. (Monique M. P. D.), Henry, G. H. (Gregory H. R.), Hermanutz, L. (Luise), Hewitt, R. E. (Rebecca E.), Hollister, R. D. (Robert D.), Hudson, J. (James), Huelber, K. (Karl), Iversen, C. M. (Colleen M.), Jaroszynska, F. (Francesca), Jimenez-Alfaro, B. (Borja), Johnstone, J. (Jill), Jorgensen, R. H. (Rasmus Halfdan), Kaarlejarvi, E. (Elina), Klady, R. (Rebecca), Klimesova, J. (Jitka), Korsten, A. (Annika), Kuleza, S. (Sara), Kulonen, A. (Aino), Lamarque, L. J. (Laurent J.), Lantz, T. (Trevor), Lavalle, A. (Amanda), Lembrechts, J. J. (Jonas J.), Levesque, E. (Esther), Little, C. J. (Chelsea J.), Luoto, M. (Miska), Macek, P. (Petr), Mack, M. C. (Michelle C.), Mathakutha, R. (Rabia), Michelsen, A. (Anders), Milbau, A. (Ann), Molau, U. (Ulf), Morgan, J. W. (John W.), Morsdorf, M. A. (Martin Alfons), Nabe-Nielsen, J. (Jacob), Nielsen, S. S. (Sigrid Scholer), Ninot, J. M. (Josep M.), Oberbauer, S. F. (Steven F.), Olofsson, J. (Johan), Onipchenko, V. G. (Vladimir G.), Petraglia, A. (Alessandro), Pickering, C. (Catherine), Prevey, J. S. (Janet S.), Rixen, C. (Christian), Rumpf, S. B. (Sabine B.), Schaepman-Strub, G. (Gabriela), Semenchuk, P. (Philipp), Shetti, R. (Rohan), Soudzilovskaia, N. A. (Nadejda A.), Spasojevic, M. J. (Marko J.), Speed, J. D. (James David Mervyn), Street, L. E. (Lorna E.), Suding, K. (Katharine), Tape, K. D. (Ken D.), Tomaselli, M. (Marcello), Trant, A. (Andrew), Treier, U. A. (Urs A.), Tremblay, J.-P. (Jean-Pierre), Tremblay, M. (Maxime), Venn, S. (Susanna), Virkkala, A.-M. (Anna-Maria), Vowles, T. (Tage), Weijers, S. (Stef), Wilmking, M. (Martin), Wipf, S. (Sonja), and Zamin, T. (Tara)

Abstract

Motivation: The Tundra Trait Team (TTT) database includes field‐based measurements of key traits related to plant form and function at multiple sites across the tundra biome. This dataset can be used to address theoretical questions about plant strategy and trade‐offs, trait–environment relationships and environmental filtering, and trait variation across spatial scales, to validate satellite data, and to inform Earth system model parameters. Main types of variable contained: The database contains 91,970 measurements of 18 plant traits. The most frequently measured traits (> 1,000 observations each) include plant height, leaf area, specific leaf area, leaf fresh and dry mass, leaf dry matter content, leaf nitrogen, carbon and phosphorus content, leaf C:N and N:P, seed mass, and stem specific density. Spatial location and grain: Measurements were collected in tundra habitats in both the Northern and Southern Hemispheres, including Arctic sites in Alaska, Canada, Greenland, Fennoscandia and Siberia, alpine sites in the European Alps, Colorado Rockies, Caucasus, Ural Mountains, Pyrenees, Australian Alps, and Central Otago Mountains (New Zealand), and sub‐Antarctic Marion Island. More than 99% of observations are georeferenced. Time period and grain: All data were collected between 1964 and 2018. A small number of sites have repeated trait measurements at two or more time periods. Major taxa and level of measurement: Trait measurements were made on 978 terrestrial vascular plant species growing in tundra habitats. Most observations are on individuals (86%), while the remainder represent plot or site means or maximums per species. Software format: csv file and GitHub repository with data cleaning scripts in R; contribution to TRY plant trait database (www.try-db.org) to be included in the next version release.

Published
2018

11. Tundra Trait Team: A database of plant traits spanning the tundra biome

Author

Bjorkman, A.D., Myers-Smith, I.H., Elmendorf, S.C., Normand, S., Thomas, H.J.D., Alatalo, J.M., Alexander, H., Anadon‐Rosell, A., Angers‐Blondin, S., Bai, Y., Baruah, G., te Beest, M., Berner, L., Björk, R.G., Blok, D., Bruelheide, H., Buchwal, A., Buras, A., Carbognani, M., Christie, K., Collier, L.S., Cooper, E.J., Cornelissen, J.H.C., Dickinson, K.J.M., Dullinger, S., Elberling, B., Eskelinen, Anu Maria, Forbes, B.C., Frei, E.R., Iturrate‐Garcia, M., Good, M.K., Grau, O., Green, P., Greve, M., Grogan, P., Haider, S., Hájek, T., Hallinger, M., Happonen, K., Harper, K.A., Heijmans, M.M.P.D., Henry, G.H.R., Hermanutz, L., Hewitt, R.E., Hollister, R.D., Hudson, J., Hülber, K., Iversen, C.M., Jaroszynska, F., Jiménez‐Alfaro, B., Johnstone, J., Jorgensen, R.H., Kaarlejärvi, E., Klady, R., Klimešová, J., Korsten, A., Kuleza, S., Kulonen, A., Lamarque, L.J., Lantz, T., Lavalle, A., Lembrechts, J.J., Lévesque, E., Little, C.J., Luoto, M., Macek, P., Mack, M.C., Mathakutha, R., Michelsen, A., Milbau, A., Molau, U., Morgan, J.W., Mörsdorf, M.A., Nabe-Nielsen, J., Schøler Nielsen, S., Ninot, J.M., Oberbauer, S.F., Olofsson, J., Onipchenko, V.G., Petraglia, A., Pickering, C., Prevéy, J.S., Rixen, C., Rumpf, S.B., Schaepman-Strub, G., Semenchuk, P., Shetti, R., Soudzilovskaia, N.A., Spasojevic, M.J., Speed, J.D.M., Street, L.E., Suding, K., Tape, K.D., Tomaselli, M., Trant, A., Treier, U.A., Tremblay, J.-P., Tremblay, M., Venn, S., Virkkala, A.-M., Bjorkman, A.D., Myers-Smith, I.H., Elmendorf, S.C., Normand, S., Thomas, H.J.D., Alatalo, J.M., Alexander, H., Anadon‐Rosell, A., Angers‐Blondin, S., Bai, Y., Baruah, G., te Beest, M., Berner, L., Björk, R.G., Blok, D., Bruelheide, H., Buchwal, A., Buras, A., Carbognani, M., Christie, K., Collier, L.S., Cooper, E.J., Cornelissen, J.H.C., Dickinson, K.J.M., Dullinger, S., Elberling, B., Eskelinen, Anu Maria, Forbes, B.C., Frei, E.R., Iturrate‐Garcia, M., Good, M.K., Grau, O., Green, P., Greve, M., Grogan, P., Haider, S., Hájek, T., Hallinger, M., Happonen, K., Harper, K.A., Heijmans, M.M.P.D., Henry, G.H.R., Hermanutz, L., Hewitt, R.E., Hollister, R.D., Hudson, J., Hülber, K., Iversen, C.M., Jaroszynska, F., Jiménez‐Alfaro, B., Johnstone, J., Jorgensen, R.H., Kaarlejärvi, E., Klady, R., Klimešová, J., Korsten, A., Kuleza, S., Kulonen, A., Lamarque, L.J., Lantz, T., Lavalle, A., Lembrechts, J.J., Lévesque, E., Little, C.J., Luoto, M., Macek, P., Mack, M.C., Mathakutha, R., Michelsen, A., Milbau, A., Molau, U., Morgan, J.W., Mörsdorf, M.A., Nabe-Nielsen, J., Schøler Nielsen, S., Ninot, J.M., Oberbauer, S.F., Olofsson, J., Onipchenko, V.G., Petraglia, A., Pickering, C., Prevéy, J.S., Rixen, C., Rumpf, S.B., Schaepman-Strub, G., Semenchuk, P., Shetti, R., Soudzilovskaia, N.A., Spasojevic, M.J., Speed, J.D.M., Street, L.E., Suding, K., Tape, K.D., Tomaselli, M., Trant, A., Treier, U.A., Tremblay, J.-P., Tremblay, M., Venn, S., and Virkkala, A.-M.

Abstract

MotivationThe Tundra Trait Team (TTT) database includes field‐based measurements of key traits related to plant form and function at multiple sites across the tundra biome. This dataset can be used to address theoretical questions about plant strategy and trade‐offs, trait–environment relationships and environmental filtering, and trait variation across spatial scales, to validate satellite data, and to inform Earth system model parameters. Main types of variable containedThe database contains 91,970 measurements of 18 plant traits. The most frequently measured traits (> 1,000 observations each) include plant height, leaf area, specific leaf area, leaf fresh and dry mass, leaf dry matter content, leaf nitrogen, carbon and phosphorus content, leaf C:N and N:P, seed mass, and stem specific density. Spatial location and grainMeasurements were collected in tundra habitats in both the Northern and Southern Hemispheres, including Arctic sites in Alaska, Canada, Greenland, Fennoscandia and Siberia, alpine sites in the European Alps, Colorado Rockies, Caucasus, Ural Mountains, Pyrenees, Australian Alps, and Central Otago Mountains (New Zealand), and sub‐Antarctic Marion Island. More than 99% of observations are georeferenced. Time period and grainAll data were collected between 1964 and 2018. A small number of sites have repeated trait measurements at two or more time periods. Major taxa and level of measurementTrait measurements were made on 978 terrestrial vascular plant species growing in tundra habitats. Most observations are on individuals (86%), while the remainder represent plot or site means or maximums per species. Software formatcsv file and GitHub repository with data cleaning scripts in R; contribution to TRY plant trait database (www.try-db.org) to be included in the next version release.

Published
2018

12. Tundra Trait Team: A database of plant traits spanning the tundra biome

Author

Bjorkman, A. D., Myers-Smith, I. H., Elmendorf, S. C., Normand, S., Thomas, H. J. D., Alatalo, J. M., Alexander, H., Anadon-Rosell, A., Angers-Blondin, S., Bai, Y., Baruah, G., te Beest, M., Berner, L., Björk, R. G., Blok, D., Bruelheide, H., Buchwal, A., Buras, A., Carbognani, M., Christie, K., Collier, L. S., Cooper, E. J., Cornelissen, J. H. C., Dickinson, K. J. M., Dullinger, S., Elberling, B., Eskelinen, A., Forbes, B. C., Frei, E. R., Iturrate-Garcia, M., Good, M. K., Grau, O., Green, P., Greve, M., Grogan, P., Haider, S., Hájek, T., Hallinger, M., Happonen, K., Harper, K. A., Heijmans, M. M. P. D., Henry, G. H. R., Hermanutz, L., Hewitt, R. E., Hollister, R. D., Hudson, J., Hülber, K., Iversen, C. M., Jaroszynska, F., Jiménez-Alfaro, B., Johnstone, J., Jorgensen, R. H., Kaarlejärvi, E., Klady, R., Klimešová, J., Korsten, A., Kuleza, S., Kulonen, A., Lamarque, L. J., Lantz, T., Lavalle, A., Lembrechts, J. J., Lévesque, E., Little, C. J., Luoto, M., Macek, P., Mack, M. C., Mathakutha, R., Michelsen, A., Milbau, A., Molau, U., Morgan, J. W., Mörsdorf, M. A., Nabe-Nielsen, J., Nielsen, S. S., Ninot, J. M., Oberbauer, S. F., Olofsson, J., Onipchenko, V. G., Petraglia, A., Pickering, C., Prevéy, J. S., Rixen, C., Rumpf, S. B., Schaepman-Strub, G., Semenchuk, P., Shetti, R., Soudzilovskaia, N. A., Spasojevic, M. J., Speed, J. D. M., Street, L. E., Suding, K., Tape, K. D., Tomaselli, M., Trant, A., Treier, U. A., Tremblay, J. P., Tremblay, M., Venn, S., Virkkala, A. M., Vowles, T., Weijers, S., Wilmking, M., Wipf, S., Zamin, T., Bjorkman, A. D., Myers-Smith, I. H., Elmendorf, S. C., Normand, S., Thomas, H. J. D., Alatalo, J. M., Alexander, H., Anadon-Rosell, A., Angers-Blondin, S., Bai, Y., Baruah, G., te Beest, M., Berner, L., Björk, R. G., Blok, D., Bruelheide, H., Buchwal, A., Buras, A., Carbognani, M., Christie, K., Collier, L. S., Cooper, E. J., Cornelissen, J. H. C., Dickinson, K. J. M., Dullinger, S., Elberling, B., Eskelinen, A., Forbes, B. C., Frei, E. R., Iturrate-Garcia, M., Good, M. K., Grau, O., Green, P., Greve, M., Grogan, P., Haider, S., Hájek, T., Hallinger, M., Happonen, K., Harper, K. A., Heijmans, M. M. P. D., Henry, G. H. R., Hermanutz, L., Hewitt, R. E., Hollister, R. D., Hudson, J., Hülber, K., Iversen, C. M., Jaroszynska, F., Jiménez-Alfaro, B., Johnstone, J., Jorgensen, R. H., Kaarlejärvi, E., Klady, R., Klimešová, J., Korsten, A., Kuleza, S., Kulonen, A., Lamarque, L. J., Lantz, T., Lavalle, A., Lembrechts, J. J., Lévesque, E., Little, C. J., Luoto, M., Macek, P., Mack, M. C., Mathakutha, R., Michelsen, A., Milbau, A., Molau, U., Morgan, J. W., Mörsdorf, M. A., Nabe-Nielsen, J., Nielsen, S. S., Ninot, J. M., Oberbauer, S. F., Olofsson, J., Onipchenko, V. G., Petraglia, A., Pickering, C., Prevéy, J. S., Rixen, C., Rumpf, S. B., Schaepman-Strub, G., Semenchuk, P., Shetti, R., Soudzilovskaia, N. A., Spasojevic, M. J., Speed, J. D. M., Street, L. E., Suding, K., Tape, K. D., Tomaselli, M., Trant, A., Treier, U. A., Tremblay, J. P., Tremblay, M., Venn, S., Virkkala, A. M., Vowles, T., Weijers, S., Wilmking, M., Wipf, S., and Zamin, T.

Abstract

Motivation: The Tundra Trait Team (TTT) database includes field-based measurements of key traits related to plant form and function at multiple sites across the tundra biome. This dataset can be used to address theoretical questions about plant strategy and trade-offs, trait–environment relationships and environmental filtering, and trait variation across spatial scales, to validate satellite data, and to inform Earth system model parameters. Main types of variable contained: The database contains 91,970 measurements of 18 plant traits. The most frequently measured traits (> 1,000 observations each) include plant height, leaf area, specific leaf area, leaf fresh and dry mass, leaf dry matter content, leaf nitrogen, carbon and phosphorus content, leaf C:N and N:P, seed mass, and stem specific density. Spatial location and grain: Measurements were collected in tundra habitats in both the Northern and Southern Hemispheres, including Arctic sites in Alaska, Canada, Greenland, Fennoscandia and Siberia, alpine sites in the European Alps, Colorado Rockies, Caucasus, Ural Mountains, Pyrenees, Australian Alps, and Central Otago Mountains (New Zealand), and sub-Antarctic Marion Island. More than 99% of observations are georeferenced. Time period and grain: All data were collected between 1964 and 2018. A small number of sites have repeated trait measurements at two or more time periods. Major taxa and level of measurement: Trait measurements were made on 978 terrestrial vascular plant species growing in tundra habitats. Most observations are on individuals (86%), while the remainder represent plot or site means or maximums per species. Software format: csv file and GitHub repository with data cleaning scripts in R; contribution to TRY plant trait database (www.try-db.org) to be included in the next version release.

Published
2018

19. The Arctic Plant Aboveground Biomass Synthesis Dataset.

Author

Berner LT, Orndahl KM, Rose M, Tamstorf M, Arndal MF, Alexander HD, Humphreys ER, Loranty MM, Ludwig SM, Nyman J, Juutinen S, Aurela M, Happonen K, Mikola J, Mack MC, Vankoughnett MR, Iversen CM, Salmon VG, Yang D, Kumar J, Grogan P, Danby RK, Scott NA, Olofsson J, Siewert MB, Deschamps L, Lévesque E, Maire V, Morneault A, Gauthier G, Gignac C, Boudreau S, Gaspard A, Kholodov A, Bret-Harte MS, Greaves HE, Walker D, Gregory FM, Michelsen A, Kumpula T, Villoslada M, Ylänne H, Luoto M, Virtanen T, Forbes BC, Hölzel N, Epstein H, Heim RJ, Bunn A, Holmes RM, Hung JKY, Natali SM, Virkkala AM, and Goetz SJ

Subjects
Arctic Regions, Biomass, Ecosystem, Trees, Plants
Abstract

Plant biomass is a fundamental ecosystem attribute that is sensitive to rapid climatic changes occurring in the Arctic. Nevertheless, measuring plant biomass in the Arctic is logistically challenging and resource intensive. Lack of accessible field data hinders efforts to understand the amount, composition, distribution, and changes in plant biomass in these northern ecosystems. Here, we present The Arctic plant aboveground biomass synthesis dataset, which includes field measurements of lichen, bryophyte, herb, shrub, and/or tree aboveground biomass (g m -2 ) on 2,327 sample plots from 636 field sites in seven countries. We created the synthesis dataset by assembling and harmonizing 32 individual datasets. Aboveground biomass was primarily quantified by harvesting sample plots during mid- to late-summer, though tree and often tall shrub biomass were quantified using surveys and allometric models. Each biomass measurement is associated with metadata including sample date, location, method, data source, and other information. This unique dataset can be leveraged to monitor, map, and model plant biomass across the rapidly warming Arctic., (© 2024. The Author(s).)

Published
2024
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20. Critical limb-threatening ischaemia and microvascular transformation: clinical implications.

Author

Tarvainen S, Wirth G, Juusola G, Hautero O, Kalliokoski K, Sjöros T, Nikulainen V, Taavitsainen J, Hytönen J, Frimodig C, Happonen K, Selander T, Laitinen T, Hakovirta HH, Knuuti J, Laham-Karam N, Hartikainen J, Mäkinen K, Ylä-Herttuala S, and Korpisalo P

Subjects
Humans, Rabbits, Animals, Risk Factors, Vascular Endothelial Growth Factor A, Ischemia, Hypoxia, Treatment Outcome, Retrospective Studies, Chronic Disease, Peripheral Arterial Disease therapy
Abstract

Background and Aims: Clinical management of critical limb-threatening ischaemia (CLTI) is focused on prevention and treatment of atherosclerotic arterial occlusions. The role of microvascular pathology in disease progression is still largely unspecified and more importantly not utilized for treatment. The aim of this explorative study was to characterize the role of the microvasculature in CLTI pathology., Methods: Clinical high-resolution imaging of CLTI patients (n = 50) and muscle samples from amputated CLTI limbs (n = 40) were used to describe microvascular pathology of CLTI at the level of resting muscle blood flow and microvascular structure, respectively. Furthermore, a chronic, low arterial driving pressure-simulating ischaemia model in rabbits (n = 24) was used together with adenoviral vascular endothelial growth factor A gene transfers to study the effect of microvascular alterations on muscle outcome., Results: Resting microvascular blood flow was not depleted but displayed decreased capillary transit time (P < .01) in CLTI muscles. Critical limb-threatening ischaemia muscle microvasculature also exhibited capillary enlargement (P < .001) and further arterialization along worsening of myofibre atrophy and detaching of capillaries from myofibres. Furthermore, CLTI-like capillary transformation was shown to worsen calf muscle force production (P < .05) and tissue outcome (P < .01) under chronic ischaemia in rabbits and in healthy, normal rabbit muscle., Conclusions: These findings depict a progressive, hypoxia-driven transformation of the microvasculature in CLTI muscles, which pathologically alters blood flow dynamics and aggravates tissue damage under low arterial driving pressure. Hypoxia-driven capillary enlargement can be highly important for CLTI outcomes and should therefore be considered in further development of diagnostics and treatment of CLTI., (© The Author(s) 2023. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published
2024
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21. Plant traits poorly predict winner and loser shrub species in a warming tundra biome.

Author

García Criado M, Myers-Smith IH, Bjorkman AD, Normand S, Blach-Overgaard A, Thomas HJD, Eskelinen A, Happonen K, Alatalo JM, Anadon-Rosell A, Aubin I, Te Beest M, Betway-May KR, Blok D, Buras A, Cerabolini BEL, Christie K, Cornelissen JHC, Forbes BC, Frei ER, Grogan P, Hermanutz L, Hollister RD, Hudson J, Iturrate-Garcia M, Kaarlejärvi E, Kleyer M, Lamarque LJ, Lembrechts JJ, Lévesque E, Luoto M, Macek P, May JL, Prevéy JS, Schaepman-Strub G, Sheremetiev SN, Siegwart Collier L, Soudzilovskaia NA, Trant A, Venn SE, and Virkkala AM

Subjects
Seeds, Climate Change, Phenotype, Ecosystem, Tundra
Abstract

Climate change is leading to species redistributions. In the tundra biome, shrubs are generally expanding, but not all tundra shrub species will benefit from warming. Winner and loser species, and the characteristics that may determine success or failure, have not yet been fully identified. Here, we investigate whether past abundance changes, current range sizes and projected range shifts derived from species distribution models are related to plant trait values and intraspecific trait variation. We combined 17,921 trait records with observed past and modelled future distributions from 62 tundra shrub species across three continents. We found that species with greater variation in seed mass and specific leaf area had larger projected range shifts, and projected winner species had greater seed mass values. However, trait values and variation were not consistently related to current and projected ranges, nor to past abundance change. Overall, our findings indicate that abundance change and range shifts will not lead to directional modifications in shrub trait composition, since winner and loser species share relatively similar trait spaces., (© 2023. The Author(s).)

Published
2023
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22. Consistent trait-environment relationships within and across tundra plant communities.

Author

Kemppinen J, Niittynen P, le Roux PC, Momberg M, Happonen K, Aalto J, Rautakoski H, Enquist BJ, Vandvik V, Halbritter AH, Maitner B, and Luoto M

Subjects
Antarctic Regions, Arctic Regions, Plants, Ecosystem, Tundra
Abstract

A fundamental assumption in trait-based ecology is that relationships between traits and environmental conditions are globally consistent. We use field-quantified microclimate and soil data to explore if trait-environment relationships are generalizable across plant communities and spatial scales. We collected data from 6,720 plots and 217 species across four distinct tundra regions from both hemispheres. We combined these data with over 76,000 database trait records to relate local plant community trait composition to broad gradients of key environmental drivers: soil moisture, soil temperature, soil pH and potential solar radiation. Results revealed strong, consistent trait-environment relationships across Arctic and Antarctic regions. This indicates that the detected relationships are transferable between tundra plant communities also when fine-scale environmental heterogeneity is accounted for, and that variation in local conditions heavily influences both structural and leaf economic traits. Our results strengthen the biological and mechanistic basis for climate change impact predictions of vulnerable high-latitude ecosystems.

Published
2021
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23. Snow is an important control of plant community functional composition in oroarctic tundra.

Author

Happonen K, Aalto J, Kemppinen J, Niittynen P, Virkkala AM, and Luoto M

Subjects
Finland, Plants, Tundra, Ecosystem, Snow
Abstract

The functional composition of plant communities is a critical modulator of climate change impacts on ecosystems, but it is not a simple function of regional climate. In the Arctic tundra, where climate change is proceeding the most rapidly, communities have not shifted their trait composition as predicted by spatial temperature-trait relationships. Important causal pathways are thus missing from models of trait composition change. Here, we study causes of plant community functional variation in an oroarctic tundra landscape in Kilpisjärvi, Finland. We consider the community-weighted means of plant vegetative height, as well as two traits related to the leaf economic spectrum. Specifically, we model their responses to locally measured summer air temperature, snow conditions, and soil resource levels. For each of the traits, we also quantify the importance of intraspecific trait variation (ITV) for between-community functional differences and trait-environment matching. Our study shows that in a tundra landscape (1) snow is the most influential abiotic variable affecting functional composition, (2) vegetation height is under weak local environmental control, whereas leaf economics is under strong local environmental control, (3) the relative magnitude of ITV differs between traits, and (4) ITV is not very consequential for community-level trait-environment relationships. Our analyses highlight the importance of winter conditions for community functional composition in seasonal areas. We show that winter climate change can either amplify or counter the effects summer warming, depending on the trait.

Published
2019
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24. Site fertility drives temporal turnover of vegetation at high latitudes.

Author

Maliniemi T, Happonen K, and Virtanen R

Abstract

Experimental evidence shows that site fertility is a key modulator underlying plant community changes under climate change. Communities on fertile sites, with species having fast dynamics, have been found to react more strongly to climate change than communities on infertile sites with slow dynamics. However, it is still unclear whether this generally applies to high-latitude plant communities in natural environments at broad spatial scales. We tested a hypothesis that vegetation of fertile sites experiences greater changes over several decades and thus would be more responsive under contemporary climate change compared to infertile sites that are expected to show more resistance. We resurveyed understorey communities (vascular plants, bryophytes, and lichens) of four infertile and four fertile forest sites along a latitudinal bioclimatic gradient. Sites had remained outside direct human disturbance. We analyzed the magnitude of temporal community turnover, changes in the abundances of plant morphological groups and strategy classes, and changes in species diversity. In agreement with our hypothesis, temporal turnover of communities was consistently greater on fertile sites compared to infertile sites. However, our results suggest that the larger turnover of fertile communities is not primarily related to the direct effects of climatic warming. Furthermore, community changes in both fertile and infertile sites showed remarkable variation in terms of shares of plant functional groups and strategy classes and measures of species diversity. This further emphasizes the essential role of baseline environmental conditions and nonclimatic drivers underlying vegetation changes. Our results show that site fertility is a key determinant of the overall rate of high-latitude vegetation changes but the composition of plant communities in different ecological contexts is variously impacted by nonclimatic drivers over time., Competing Interests: None declared., (© 2019 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published
2019
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