Plant functional trait change across a warming tundra biome

Bjorkman, Anne D.; Myers‐Smith, Isla H.; Elmendorf, Sarah C.; Normand, Signe; Rüger, Nadja; Beck, Pieter S. A.; Blach‐Overgaard, Anne; Blok, Daan; Cornelissen, Johannes H. C.; Forbes, Bruce C.; Georges, Damien; Goetz, Scott J.; Guay, Kevin C.; Henry, Gregory H. R.; HilleRisLambers, Janneke; Hollister, Robert D.; Karger, Dirk Nikolaus; Kattge, Jens; Manning, Peter; Prevéy, Janet S.; Rixen, Christian; Schaepman‐Strub, Gabriela; Thomas, Haydn J. D.; Vellend, Mark; Wilmking, Martin; Wipf, Sonja; Carbognani, Michele; Hermanutz, Luise; Lévesque, Esther; Molau, Ulf; Petraglia, Alessandro; Soudzilovskaia, Nadejda A.; Spasojevic, Marko J.; Tomaselli, Marcello; Vowles, Tage; Alatalo, Juha M.; Alexander, Heather D.; Anadon‐Rosell, Alba; Angers‐Blondin, Sandra; Beest, Mariska te; Berner, L. T.; Björk, Robert G.; Buchwał, Agata; Buras, Allan; Christie, Katherine S.; Cooper, Elisabeth J.; Dullinger, Stefan; Elberling, Bo; Eskelinen, Anu; Frei, Esther R.; Grau, Oriol; Grogan, Paul; Hallinger, Martin; Harper, Karen A.; Heijmans, M.M.P.D.; Hudson, James M.; Hülber, Karl; Iturrate-García, Maitane; Iversen, Colleen M.; Jaroszynska, Francesca; Johnstone, Jill F.; Jørgensen, Rasmus Halfdan; Kaarlejärvi, Elina; Klady, Rebecca A; Kuleza, Sara; Kulonen, Aino; Lamarque, Laurent J.; Lantz, Trevor C.; Little, Chelsea J.; Speed, James D. M.; Michelsen, Anders; Milbau, Ann; Nabe‐Nielsen, Jacob; Nielsen, Sigrid Schøler; Ninot, Josep M.; Oberbauer, Steven F.; Olofsson, Johan; Онипченко, В. Г.; Rumpf, Sabine B.; Semenchuk, Philipp; Shetti, Rohan; Collier, Laura Siegwart; Street, Lorna E.; Suding, Katharine N.; Tape, Ken D.; Trant, Andrew J.; Treier, Urs A.; Tremblay, Jean‐Pierre; Tremblay, Maxime; Venn, Susanna; Weijers, Stef; Zamin, Tara; Boulanger-Lapointe, Noémie; Gould, William A.; Hik, David S.; Hofgaard, Annika; Jónsdóttir, Ingibjörg S.; Jorgenson, Janet C.; Klein, Julia A.; Magnússon, Borgþór; Tweedie, C. E.; Wookey, Philip A.; Bahn, Michael; Blonder, Benjamin; Bodegom, Peter M. van; Bond-Lamberty, Benjamin; Campetella, Giandiego; Cerabolini, Bruno E. L.; Chapin, F. Stuart; Cornwell, William K.; Craine, Joseph M.; Dainese, Matteo; Vries, Franciska T. de; Dı́az, Sandra; Enquist, Brian J.; Green, Walton; Milla, Rubén; Niinemets, Ülo; Onoda, Yusuke; Ordóñez, Jenny C.; Ozinga, Wim A.; Peñuelas, Josep; Poorter, Hendrik; Poschlod, Peter; Reich, Peter B.; Sandel, Brody; Schamp, Brandon S.; Sheremetiev, Serge; Weiher, Evan

doi:10.1038/s41586-018-0563-7

Cited by 497 publications

(518 citation statements)

References 85 publications

Supporting

Mentioning

472

Contrasting

Unclassified

Order By: Relevance

“…Hudson et al () found that most species showed increased leaf size and plant height under a warming treatment and that traits related to growth were more affected by warming than leaf nitrogen content. Similarly, Bjorkman et al () found comparable intraspecific responses of plant traits, such as plant height, LA and SLA, to temperature gradients.…”

Section: Discussionmentioning

confidence: 73%

“…While LA tended to increase across all plant species (+19.6% on average), this shift likely resulted from a modification of resource allocation driven by changes in SLA, such as an expansion of the foliar lamina associated with a decrease in leaf thickness. Hence, higher temperature likely enhances plant metabolism, favouring higher rates of cell expansion and facilitating faster production of softer tissues (Atkin, Botman, & Lambers, ; Körner, ); temperature is thus generally positively related to SLA at the intra‐ and interspecific level (Bjorkman et al, ; Woodward, ). Hudson et al () found that most species showed increased leaf size and plant height under a warming treatment and that traits related to growth were more affected by warming than leaf nitrogen content.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Plant physical and chemical traits associated with herbivory in situ and under a warming treatment

et al. 2019

View full text Add to dashboard Cite

Plants protect themselves against herbivore attacks with physical traits and toxic secondary metabolites. Levels of plant defences and herbivore performance might shift under climate warming, particularly in alpine habitats, where herbivore pressure is currently low. Plant responses to warming should be driven by species‐specific shifts in physical and chemical defence traits. We investigated the association between plant leaf physical and chemical traits and herbivory under current and warmer climates in three grasslands along a subalpine to alpine gradient. Specifically, we measured the rate of in situ natural herbivory, and performed bioassays to measure overall plant species‐level resistance using the extreme generalist non‐native caterpillar Spodoptera littoralis. We simulated warmer conditions by using open‐top chambers and assessed the effect of warming on leaf physical and chemical traits, and how trait changes affect caterpillar performance. Natural herbivory and caterpillar performance were associated with plant physical traits, including specific leaf area, and with ordination axes representing dimensions of the plant chemical profile. We found that the warming treatment independently decreased the number of distinct chemical compounds per species, and marginally increased specific leaf area. Changes in leaf functional traits were not systematically associated with changes in caterpillar performance. Synthesis. Plant physical traits and chemical profiles are both related to natural herbivory and plant resistance against Spodoptera littoralis. While leaf physical and chemical traits of high elevation plants were modified by the warming treatment, these changes did not result in predictable effects on plant resistance against herbivores.

show abstract

Section: Discussionmentioning

confidence: 73%

Section: Discussionmentioning

confidence: 99%

Plant physical and chemical traits associated with herbivory in situ and under a warming treatment

et al. 2019

View full text Add to dashboard Cite

show abstract

“…In a manipulative experiment in a salt marsh in Georgia, USA, Dai and Wiegert () have shown that the productivity of S. alterniflora significantly increases after N addition, and that 79% of this increment is explained by leaf area, while just 21% is explained by leaf N. These results suggest that, in salt marshes, size‐related traits are more sensitive to geographic variation in exogenous nutrient inputs than leaf economic traits (e.g., SLA, leaf N and P) (Bjorkman et al. ). These size‐related traits potentially play a significant role in conferring a competitive advantage.…”

Section: Discussionmentioning

confidence: 99%

Human eutrophication drives biogeographic salt marsh productivity patterns in China

Líu

Liu

et al. 2019

Ecological Applications

View full text Add to dashboard Cite

Salt marshes are important natural carbon sinks with a large capacity to absorb exogenous nutrient inputs. The effects of nutrients on biogeographic productivity patterns, however, have been poorly explored in salt marshes. We conducted field surveys to examine how complex environments affect productivity of two common salt marsh plants, invasive Spartina alterniflora and native Phragmites australis, along an 18,000‐km latitudinal gradient on the Chinese coastline. We harvested peak aboveground biomass as a proxy for productivity, and measured leaf functional traits (e.g., leaf area, specific leaf area [SLA], leaf nitrogen [N] and phosphorus [P]), soil nutrients (dissolved inorganic N [DIN] and available P [AP]), and salinity. We compiled data on mean annual temperature (MAT) and exogenous nutrients (both N and P). Then, we examined how these abiotic factors affect salt marsh productivity using both linear mixed effect models and structural equation modeling. Using a trait‐based approach, we also examined how salt marsh productivity responds to changing environments across latitude. Exogenous nutrients (both N and P), compared with temperature and other variables (e.g., DIN, AP, salinity), were the dominant factors in explaining the biogeographic productivity patterns of both S. alterniflora and P. australis. Leaf size‐related traits (e.g., leaf area), rather than leaf economic traits (e.g., SLA, leaf N and P), can be used to indicate the positive effects of exogenous nutrients on the productivity of these two species. Our results demonstrated that human eutrophication surpassed temperature as the major driver of biogeographic salt marsh productivity pattern, challenging current models in which biogeographic productivity pattern is primarily controlled by temperature. Our findings have potential broad implications for the management of S. alterniflora, which is a global invader, as it has benefited from coastal eutrophication. Furthermore, exogenous nutrient availability and leaf size need to be integrated into earth system models that are used to predict global plant productivity in salt marshes.

show abstract

“…This ‘traits manifesto’ (Reich, ) has seen a dramatic rise in popularity in recent years, improving our understanding of community assembly (Siefert et al ., ) and ecosystem responses to warming (Soudzilovskaia et al ., ). However, progress is hampered by fundamental unknowns regarding the nature of trait variation and physiological tradeoffs (Siefert et al ., ; Díaz et al ., ; Shipley et al ., ), by issues of prediction across scales (Messier et al ., ), and by uneven data coverage among traits, species, and ecosystems (Iversen et al ., ; Jetz et al ., ; Bjorkman et al ., ,b). For trait‐based ecology to reach its full potential, trait–function relationships must be tested across the world's biomes, including in our planet's most extreme environments.…”

Section: Introductionmentioning

confidence: 99%

Plant traits inform predictions of tundra responses to global change

2018

Self Cite

View full text Add to dashboard Cite

Contents Summary1742I.Introduction1742II.The global context of tundra trait variation1743III.The current state of knowledge on trait change in the tundra biome1744IV.The links between traits and ecosystem functions1744V.Future priorities for tundra trait research1746VI.Conclusions1746References1747 Summary In the rapidly warming tundra biome, plant traits provide an essential link between ongoing vegetation change and feedbacks to key ecosystem functions. However, only recently have comprehensive trait data been compiled for tundra species and sites, allowing us to assess key elements of functional responses to global change. In this review, we summarize trait‐based research in tundra ecosystems, with a focus on three components: plant trait variation and how it compares with global patterns; shifts in community‐level traits in response to environmental change; and the use of traits to understand and predict ecosystem function. Quantifying patterns and trends in plant traits will allow us to better project the consequences of environmental change for the ecology and functioning of tundra ecosystems.

show abstract

Plant functional trait change across a warming tundra biome

Cited by 497 publications

References 85 publications

Plant physical and chemical traits associated with herbivory in situ and under a warming treatment

Plant physical and chemical traits associated with herbivory in situ and under a warming treatment

Human eutrophication drives biogeographic salt marsh productivity patterns in China

Plant traits inform predictions of tundra responses to global change

Contact Info

Product

Resources

About