INTRODUCTION
Climatic warming impacts the functioning of ecosystems directly by affecting plant and microbial physiological processes that drive elemental cycling and indirectly by altering the phenotypes and performance of species, which in turn affects the composition and relative abundance of species, and their associated traits, within communities. Designing and implementing experiments that allow us to test, understand, and predict the impacts of both the direct and indirect effects of warming on community and ecosystem properties and processes across space and time is critical. There are now numerous experiments that manipulate air or soil temperature and measure associated community- and ecosystem-level responses (Song et al., 2019; van Wijk et al., 2003), each providing mechanistic insights into the ecological responses to temperature in different locations. Because such warming experiments are often costly, they are typically conducted at single sites (Borer et al., 2014; Henry & Molau, 1997), which potentially hampers our ability to make generalizable predictions about the impact of warming. Ideally, experiments would be replicated at multiple sites across multiple climatic or temperature regimes to gain a better understanding of the impacts of warming at a global scale (Elmendorf et al., 2015; Song et al., 2019). In addition, multiple-site comparisons are usually only explored via meta-analyses, which can be limited by a lack of statistical power and high Type II Error resulting from combining studies with very different methodologies and measurements, approaches to the problem, and means of experimental warming.
Climate change is not the only driver of changes in community-level traits, community structure, and ecosystem function. Dominant species, typically defined as those that are abundant and have large impacts on community dynamics and ecosystem function, are also the subject of much experimental work (Avolio et al., 2019). Changes in the abundance or identity of dominant species can have cascading impacts on species, community dynamics, and ecosystem processes (Díaz et al., 2007; Sasaki & Lauenroth, 2011). For example, in some grassland ecosystems, dominant grasses offset the negative effects of species loss by promoting overall ecosystem productivity, providing short-term resistance to declines in ecosystem function associated with nonrandom species loss (Grime, 1998; Smith & Knapp, 2003). In other systems, dominant species can suppress the biomass of the subdominant plant community and influence overall community composition (Hillebrand et al., 2008).
Increases in both air and soil temperature directly impact the physiology of individual organisms, such as photosynthetic rates (e.g., (Reich et al., 2018) and microbial metabolic activity (Bai et al., 2013; Cavicchioli et al., 2019)), shaping how species interact with one another, ultimately scaling to influence important ecosystem functions, such as carbon and nutrient cycling and storage. Warming-induced changes in community composition are often associated with shifts in species-specific functional traits (Bjorkman et al., 2018), which can have cascading consequences for ecosystem carbon and nutrient dynamics (Liu et al., 2018). The relative importance of these drivers—the loss of dominant species and climate—and how they modify interactions and shape community composition may change across space, from field site to field site, and through time. Therefore, developing frameworks that enable ecologists to explore long- and short-term responses to warming across ecosystems is critical.
Previous studies have shown that shifts in the functional traits of communities, especially plants, can lead to dramatic alterations in the dynamics and functioning of ecosystems (Bello et al., 2010; Diaz et al., 2004; Lavorel & Garnier, 2002; Lavorel & Grigulis, 2012). Therefore, the indirect impacts of warming on ecosystem functions (e.g., C dynamics) can be greater than the direct effects on the performance of individual organisms (Niu et al., 2011; Wipf & Rixen, 2010). The effect of shifts in plant community composition on ecosystem properties and processes can be especially pronounced if the loss of dominant species, and their associated traits, occurs (Avolio et al., 2019; Grime, 1998; Smith & Knapp, 2003). While not always the case (Díaz et al., 2007; Isbell et al., 2017; McLaren & Turkington, 2010), dominant species tend to have large and cascading influences on communities and ecosystems, often proportional to the large fraction of community biomass they make up (Avolio et al., 2019). For this reason, dominant species identity, as well as the evenness of plant communities, can be important predictors of gross respiration and photosynthesis in plant communities (Heskel et al., 2013; Orwin et al., 2014). Understanding, testing, and modeling the interactive influence of the separate and interactive effects of climatic change and shifts in plant community and trait composition on ecosystem function is critical to predicting the impact of climate change on communities and ecosystems.
Despite the multitude of warming experiments and dozens of dominant species removal experiments conducted to date (Avolio et al., 2019; Song et al., 2019), there are still significant challenges in understanding and predicting how background climate may mediate the influence of warming and species losses on the functioning of ecosystems in different environmental contexts. Put another way, is the impact of a 2°C increase in temperature the same in a cold, dry ecosystem as in a warmer and wetter ecosystem? Do dominant species exert more influence in benign environments than in stressful environments? One way to test this would be to conduct experiments along climatic gradients or in sites where climate at least differs systematically (Fukami & Wardle, 2005). This could be achieved by setting up experiments that combine warming with the removal of dominant species along gradients, or at sites representative of the climatic end members of a given gradient (i.e., high- and low-elevation sites), especially in multiple regions around the world. Such a design will not only enhance our understanding of the influences of the individual and interactive effects of climatic change and associated changes in community and trait composition on ecosystem functioning but will also allow us to better predict how and why these effects may be shaped by multiple unique climate combinations and to investigate mechanisms of global relevance regardless of biogeographic history or phylogenetic or environmental contexts or legacies. However, studies exploring the consequences of warming-associated shifts in species interactions across multiple sites are rare (but see Song et al., 2019).
While manipulating the direct and indirect effects of climate change at a global scale in a single project is challenging, we outline a new network of experiments and observations that, together with the use of causal models, will foster a comprehensive and predictive understanding of the impacts of warming on communities and ecosystem function, and how these effects differ among contrasting locations. Here, we first highlight the power of harnessing natural, systematic variation in temperature by working along elevational gradients in mountain systems. Next, we review some of the strengths and weaknesses of experimental approaches used to understand the impacts of climatic warming. We then discuss emerging statistical approaches that help us explore causal networks of direct and indirect effects of experimental manipulations such as warming and dominant species removal on communities and ecosystems. Finally, we demonstrate this approach by way of example, introducing a globally distributed network of experiments explicitly designed to test the direct and indirect effects of warming and species removal on community structure and ecosystem function across contrasting mountain systems.
The warming and species removal in mountains (WaRM) network is a novel approach that (1) uses low- and high-elevation sites that differ in temperature by approximately 2°C, (2) establishes dominant species removals and passive warming chambers (increasing air temperature ~2°C) to simulate short-term warming and shifts in species interactions, and (3) crosses experimental warming and species removals to explore the interactive effects of these treatments. This distributed experiment in 10 mountain ecosystems around the world (see Figure 1) will enable us to explore interactions among drivers and response variables in a way that will help us better understand and predict the direct and indirect effects of global warming on contrasting mountain ecosystems.
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HARNESSING NATURAL ENVIRONMENTAL GRADIENTS TO BETTER UNDERSTAND THE IMPACTS OF ENVIRONMENTAL CHANGE ON PLANT COMMUNITIES AND ECOSYSTEM FUNCTION
For over 160 years, studies in ecology and evolution have employed environmental gradients to help understand how natural communities respond to macroclimate (e.g., von Humboldt 1849). Elevational gradients capture variation in temperature, soil age and type, disturbance regimes, and land-use histories and have yielded important insights into how organisms, communities, and ecosystems vary with climatic and other abiotic conditions (Martinez-Almoyna et al., 2019; Mayor et al., 2017; Rogora et al., 2018). Comparisons along elevational gradients, and between two points across elevational gradients, can also be used to explore the impact of temperature on the properties of species and communities and the functioning of ecosystems (Kivlin et al., 2014; Read et al., 2014) provided that the environmental factors, such as precipitation and aridity, that co-vary with elevation (Körner, 2007) are accounted for. For example, Mayor et al. (2017) showed clear shifts in leaf nitrogen to phosphorus ratios with declining temperature along elevational gradients around the world. Mayor et al. (2017) also showed that the indirect effects of elevation-associated changes in temperature, mediated via plant nutrient responses, were associated with changes in belowground abiotic and biotic properties across regions. In a classic study Illustrating how species interactions may vary with elevation, Callaway et al. (2002) conducted a removal experiment at 10 mountain sites around the world to demonstrate that positive interactions among species are more common in stressful, high-elevation sites, but that competitive interactions are more common at less stressful, low-elevation sites. An ability to understand, and contrast, ecosystem responses at high- and low-elevation sites, can lead to key insights at both local (Sundqvist et al., 2020) and global (e.g., Mayor et al., 2017) scales. Thus, elevational gradients, which allow us to capture environmental heterogeneity, serve as powerful study systems for understanding both longer-term, as well as larger-scale, community and ecosystem responses to environmental change (Fukami & Wardle, 2005; Walker et al., 2010).
While observational gradient studies are powerful tools in ecology, they make it difficult to disentangle or isolate the role of specific abiotic and biotic factors in driving observed patterns. Moreover, many environmental factors such as temperature, moisture, soil age, and soil depth may vary with elevation, often not in synchrony (Körner, 2007) or concurrently across elevational gradients. This lack of uniformity in environmental conditions along gradients may lead to contrasting findings among studies and may complicate meta-analyses that do not consider how such factors vary idiosyncratically with elevation. For example, studies exploring how temperature drives soil microbial biomass and community structure, or the temperature sensitivity of soil processes along elevational gradients, have yielded variable results (Carey et al., 2016; He et al., 2020), which limits our understanding of what drivers affect soil carbon stocks across contrasting ecosystems. In water-limited ecosystems, for example, precipitation rather than temperature may exert the strongest influence on community and ecosystem properties and processes along environmental gradients (Bradford et al., 2017; McCain, 2007; Sundqvist et al., 2013). In some instances, no discernible elevation-linked drivers of ecosystem functioning or community composition are found among elevational gradients at a global scale (Hendershot et al., 2017). One way to harness the power of environmental gradients, and to overcome some of their limitations, is to use experimental infrastructure in combination with the gradient approach (Fukami & Wardle, 2005). Combining observational work that captures environmental heterogeneity (natural experiments) with manipulative experiments, and “mega-analysis” (i.e., analysis of the same experiment across sites, see [Kleyer et al., 2012]) enables researchers to harness the power of each of these individual approaches to better understand the impacts of warming on systems across space and through time (Borer et al., 2014; Elmendorf et al., 2015; Elmendorf, Henry, Hollister, Bjork, Bjorkman, et al., 2012).
MANIPULATIVE CLIMATE CHANGE EXPERIMENTS AND THE EFFECTS OF ENVIRONMENTAL HETEROGENEITY AND CHANGE ON COMMUNITY AND ECOSYSTEM PROPERTIES AND PROCESSES
Experiments that manipulate abiotic conditions or reciprocally transplant individuals (e.g., Alexander et al., 2016; Nooten et al., 2017) are powerful tools that can be used to understand and predict the effects of environmental change on biological communities and ecosystems. Over the past few decades, the application of manipulative global change experiments has grown exponentially (Borer et al., 2014; Song et al., 2019). However, using experiments alone to understand community- and ecosystem-level responses to warming may underestimate the effects of warming, as manipulative experiments are often executed at small spatial scales, and across relatively short time scales, which cannot accurately reflect the accumulated changes that are expected from warming at the decadal scale (Kröel-Dulay et al., 2022; Wolkovich et al., 2012). For instance, a recent study found that natural rainfall seasonality constrained the response of biomass production to CO2 fertilization in temperate grasslands worldwide, suggesting that the positive response of biomass production to rising atmospheric CO2 concentrations may be substantially less than originally predicted (Hovenden et al., 2019). Thus, there is a need for manipulative experiments that span larger abiotic gradients to understand the effects of climatic change on community and ecosystem properties and processes.
Increasing surface air and soil temperatures directly impact plant physiology and community dynamics as well as the soil microbial community structure and functioning (which is an important mediator of climate), though the direction and/or magnitude of the effect has been shown to vary considerably across ecosystems and spatiotemporal scales (Bradford et al., 2017; Carey et al., 2016; Crowther et al., 2016; Elmendorf, Henry, Hollister, Björk, Bjorkman, et al., 2012; Liu et al., 2018; Zavaleta et al., 2003). Generally, experimental warming leads to reductions in plant diversity and sometimes idiosyncratic changes in plant community composition (Cowles et al., 2016; Wu et al., 2011). However, some experimental work has found no effect of warming on plant communities or effects that are mediated by other abiotic or biotic factors (Báez et al., 2013; Zavaleta et al., 2003). Similarly, warming stimulates soil respiration at some sites, but several studies have shown neutral or negative responses to warming, thought to be attributable to moisture limitation (Suseela et al., 2012), changes in microbial community composition and functioning (Castro et al., 2010; Zumsteg et al., 2013), or acclimatization (Luo et al., 2001; Melillo et al., 2017). A better understanding of the interaction between warming, abiotic conditions, and community and ecosystem properties, as well as the context-dependency of these factors and interactions, is necessary for us to model, predict, and adapt to global change.
In addition to manipulating abiotic conditions, explicitly testing the effects of shifts in species dominance and relative abundance with warming is critical to our overall understanding of both the direct and indirect effects of global change on biological communities and ecosystem functioning (Alexander et al., 2016). Though nondominant species can exert important effects on ecosystem functioning (Isbell et al., 2017; Jain et al., 2014; Peltzer et al., 2009), theory and experimental evidence suggest that dominant plant species typically play the largest role in shaping community composition and ecosystem dynamics. For example, in grasslands, dominant species often drive productivity (Orwin et al., 2014; Smith & Knapp, 2003). Furthermore, responses of ecosystem processes to experimental removal of dominant plant species and plant functional groups aboveground can be mediated by factors such as soil fertility and plant productivity (Fanin et al., 2018, 2019; Kardol et al., 2018) both of which can decline with elevation (Bryant et al., 2008). Collectively, these studies suggest that the responses of dominant plant species to warming, and their concomitant effects on ecosystem function, may vary across wider temperature gradients, which are often absent from site-level manipulative climate change experiments.
THE
Study system
The WaRM network consists of 20 study sites distributed in ten mountain locations over five continents (North America, South America, Europe, and Austral-Asia) ranging in latitude from 39° S to 68° N (Figure 1a; Table 1). Each of the ten locations has a high- and a low-elevation site, where the difference in elevation between the two sites ranges from 252 m to 804 m (Table 1), with an average of 514 m between high- and low-elevation sites across the network. During the growing season, the warmest study location is in Patagonia, Argentina, where mean summertime temperature is 15.5 and 14.2°C at the low- and high-elevation sites, respectively (Figure 2a; Table 1). The coldest study site (both growing season and wintertime temperatures) is the high site in Haibei, China, where mean summertime temperature is 5.3°C (Figure 2a and Figure S1; Table 1). Patagonia, Argentina, is the driest study location with a mean growing season precipitation of 66.5 mm at the low-elevation site, while the wettest study location is Davos, Switzerland, where mean growing season precipitation is 453 mm (Table 1). Study locations varied by both summer and winter temperature and precipitation patterns, defined by warmest and coldest quarter temperatures and precipitation values (Figure 2a and Figure S1). While some sites receive fairly consistent precipitation across the year (e.g., New Zealand), others rely more heavily on summertime precipitation (e.g., China) or wintertime precipitation (e.g., Argentina) (Figure 2a and Figure S1). For wintertime precipitation and temperature, we relied on the WorldClim database in the absence of site-level data, which does not allow us to differentiate between elevations for five of our study sites, though we would expect slightly colder temperatures at the high-elevation sites with more nuanced shifts in precipitation. We selected each of the 20 elevation sites so that they were devoid of trees, hence in full sunlight. We also selected the high- and low-elevation sites within each study location in such a way as to minimize between-site differences in aspect, slope, geology, plant growth form, and hydrology, in order to best isolate the impact of climate between elevations.
TABLE 1 List of the location of the ten study locations within the Warming and species Removal in Mountains (WaRM) network, their elevation, local climate (Hijmans et al., 2012 and plot-level sensors; mean summertime (growing season) temperature (MST) and mean summertime (growing season) precipitation (MSP)) and soil properties (pH and C:N), and dominant vascular species at each site. At each high- and low-elevation site within each study location, experimental warming by open-top chambers (see Figure 1) is crossed with a removal of the dominant species listed at each site.
| Country | Study location | Year of establishment | Elevation (m a.s.l.) | Latitude | Longitude | MST (°C) | MSP (mm) | Soil pH | Soil C:N | Dominant vascular plant species (removed) | Growth form |
| Sweden | Abisko | 2014 | 894 | 68.294 | 19.099 | 9.7 | 300 | 3.31 | 19.17 | Empetrum hermaphroditum | Woody evergreen |
| 498 | 68.314 | 19.163 | 12.9 | 300 | 3.25 | 48.82 | Empetrum hermaphroditum | Woody evergreen | |||
| Greenland | Narsarsuaq | 2015 | 450 | 61.155 | −45.379 | 11.8 | 244 | 3.80 | 40.47 | Betula glandulosa | Woody deciduous |
| 50 | 61.183 | −45.370 | 12.8 | 264 | 5.46 | 21.72 | Betula glandulosa | Woody deciduous | |||
| Canada | Kluane Lake, Yukon | 2015 | 1900 | 60.954 | −138.423 | 11.0 | 186 | 6.91 | 20.83 | Carex consimilis | Sedge |
| 1431 | 60.979 | −138.408 | 12.5 | 186 | 4.96 | 12.46 | Salix reticulata | Woody | |||
| France | Lautaret | 2017 | 2460 | 45.054 | 6.401 | 8.4 | 354 | 4.13 | 12.78 | Trifolium alpinum | Forb |
| 1900 | 45.040 | 6.419 | 8.4 | 354 | 4.91 | 12.84 | Patzkea paniculata | Grass | |||
| Switzerland | Davos | 2014 | 2353 | 46.774 | 9.857 | 7.95 | 453 | 3.39 | 21.41 | Vaccinium uliginosum | Woody deciduous |
| 2101 | 46.775 | 9.863 | 7.22 | 453 | 3.08 | 25.85 | Vaccinium uliginosum | Woody deciduous | |||
| USA | Colorado | 2013 | 3460 | 38.992 | −107.067 | 10.9 | 151 | 4.53 | 12.23 | Juncus drummondii | |
| 2740 | 38.715 | −106.823 | 14.9 | 143 | 6.21 | 11.81 | Wyethia amplexicaulis | ||||
| China | Haibei | 2014 | 4004 | 37.707 | 101.372 | 5.3 | 301 | 5.72 | 8.80 | Kobresia pygmaea | |
| 3200 | 37.617 | 101.2 | 10.4 | 275 | 6.33 | 10.55 | Stipa aliena | ||||
| Australia | Tasmania | 2015 | 890 | −42.090 | 147.088 | 11.7 | 160 | 4.60 | 15.80 | Poa gunni | C3 grass |
| 440 | −42.343 | 147.341 | 13.9 | 134 | 4.96 | 15.17 | Austrostipa sp. | C3 grass | |||
| Argentina | Bariloche, Patagonia | 2016 | 1321 | −41.654 | −71.073 | 14.2 | 62 | 5.58 | 6.29 | Acaena splendens | Woody |
| 772 | −40.998 | −71.088 | 15.5 | 71 | 5.73 | 4.14 | Papostipa speciosa | Grass | |||
| New Zealand | Mt. Ruapehu, Tukino | 2015 | 1611 | −39.278 | 175.626 | 12.4 | 150 | 4.54 | 2.48 | Gaultheria collensoi | Woody |
| 1071 | −39.294 | 175.726 | 14.5 | 150 | 4.84 | 10.98 | Calluna vulgaris | Woody |
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Experimental design
From 2013 to 2017, we established experimental plots at a high and a low site in each of the ten study locations (Figure 1a; Table 1) to take advantage of long-term climatic and other differences between low (typically warmer) and high (typically colder) elevation sites. In 2013, we established a site in the United States of America in the Colorado Rockies. In 2014, we established sites at four locations—in Australia in Tasmania, China on the Tibetan Plateau in Haibei, Sweden at Abisko, and Switzerland at Davos. In 2015, we added sites in Argentina near Bariloche in Argentinian Patagonia, Canada in Kluane Lake in the Yukon Territory, Greenland at Narsarsuaq, and New Zealand near Mt. Ruapehu, Tukino. In 2017, we added a final site in Lautaret, France (Figure 1). During the first year at each of the sites, a 2 × 2 factorial warming × plant species removal experiment at both low and high elevations was installed. We established a total of 32, 1.5 m diameter plots centered on an area of 2 m × 2 m at each elevation site, resulting in a total of 64 plots at each location (except for at Abisko, Sweden, where a total of 40 plots were installed; 20 at each elevation site). Prior to treatment application, we conducted visual estimation of percent cover of all species in each plot. This visual estimation of plant species cover was followed by randomly assigning plots at each of the elevation sites within each location to one of the four treatments (in a 2 × 2 factorial design: Control (not warmed, dominant species not removed), Removal (not warmed, dominant species removed), Warming (warmed, dominant species present), and Warming × Removal (warmed, dominant species removed; n = 8 of each at all elevational sites, except for at Abisko, Sweden where n = 5)).
To experimentally raise temperature in plots assigned with a warming treatment, we used transparent hexagonal open-top chambers (OTCs) with an inside diameter of 1.5 m and a height of ~65 cm. Open-top chambers are commonly used in climate change experiments to raise temperature in remote areas (Elmendorf, Henry, Hollister, Bjork, Boulanger-Lapointe, et al., 2012). We used iButtons (Thermochron & Hygrochron ibuttons, Maxim Integrated Corp., San Jose, CA, USA) placed in the center of each plot, to continuously measure air and soil temperature, as well as (in some plots) air humidity at 5 cm aboveground, and belowground, in each plot over each growing season. Across all sites, the OTCs raised the growing season mean air temperature by ~2°C and soil temperature by ~1°C (Figure 1b–e). Mean (and max) air temperature across all sites was 14.0°C (28.1°C) in warmed plots versus 12.9°C (25.0°C) in control plots. Mean (and max) soil temperature in warmed plots was 11.9°C (16.3°C) and was 11.0°C (15.3°C) in control plots. At each site, we defined dominant species as those that made up most of the total percent plant cover at that site. The identity of the dominant species often varied between high- and low-elevation sites within a region and included grasses, dicots, or shrubs across a variety of families; this variation in the identity (and functional group and phylogenetic context) lets us explore whether dominant species, regardless of identity, have comparable effects across disparate regions. However, the Greenland, Sweden, and Switzerland sites removed the same species at high and low elevations (Table 1). Regardless of its taxonomic identity, we were interested in the functional effect of the dominant species at each site because dominant species most commonly have the strongest effects on community and ecosystem dynamics (Avolio et al., 2019; Grime, 1977). Dominant species removal was conducted by hand-clipping to ground level, and clipping was maintained as necessary throughout the duration of the experiment, with all removed biomass then being dried and weighed.
Baseline data
Prior to the establishment of the experiments at each site, we collected baseline data including soil total carbon, total nitrogen and pH in addition to plant diversity measured by visual estimation of percent cover as described above (Figure 2a–e). Soil samples (n = 5 per elevational site per location) for initial site characterization were taken to a depth of 5 cm with a soil corer of 5–10 cm in diameter to minimize compaction. The specific corer dimensions as well as the number of composited cores and the total depth of each sample varied by location, and the volumes of soil collected were recorded and used to calculate accurate bulk densities. Each volumetric sample was air-dried, and soil pH was analyzed following a protocol developed by (Minasny et al., 2011). Total soil C and N were analyzed on subsamples of the same soil samples via combustion (Leco CN628). Soil pH varied by country—and within some countries between high-elevation and low-elevation sites—ranging from roughly 3.5 in Switzerland to roughly 7 in Canada. We used visually estimates of plant community composition and plant species richness, and we found that plant species richness differed by site (Figure 2d), ranging from 7 and 16 total species at the low- and high-elevation Argentinian sites, respectively, to 66 and 68 total species at the low- and high-elevation Australian sites, respectively (Figure 2d).
We measured air and soil temperature at the plot level for most study locations and coupled those data with precipitation data derived from WorldClim (along with WorldClim-derived temperature data for Australia, China, and France where plot-level data were not available). Sites varied in abiotic conditions (Figure 2a–c); some sites would appear to be more temperature-limited (e.g., China, France, and Switzerland) and some more water-limited (e.g., Argentina, Australia, and the United States).
Following experimental establishment, we collected data designed to ask and answer questions, and test hypotheses, about the role of warming and dominant plant species, and their interaction (see Table 2), on plant and soil communities and ecosystem functioning across contrasting elevational sites around the world. The core data we collected are as follows: soil moisture, soil respiration, pH, total soil carbon and nitrogen, net ecosystem exchange, ecosystem respiration, water use efficiency, gross primary productivity, plant community composition, a suite of plant functional traits, and the normalized difference vegetation index (NDVI) derived from reflectance data as an indicator of aboveground biomass or “greenness” (Rouse et al., 1974). We laid out three overarching questions: (1) How does warming, the loss of dominant species, and the interaction between those two factors impact biodiversity, species interactions, phenology, and the functioning of montane ecosystems (e.g., the pools and fluxes of carbon and nitrogen)? (2) How does background climatic variation influence the impacts of warming and the loss of dominant species on communities and ecosystems? And (3) Are the impacts of warming and the loss of dominant species context-dependent or are there generalizable patterns (e.g., is the impact of a 2°C increase in temperature the same in a cold, dry ecosystem as in a warmer and wetter ecosystem)?
TABLE 2 Selection of the foundational questions that the WaRM network is designed to ask and explore
| Key Questions |
| 1. How does warming, the loss of dominant species, and the interaction between those two factors impact biodiversity, species interactions, phenology, and the functioning of montane ecosystems (e.g., the pools and fluxes of carbon and nitrogen)? |
| 2. How does background climatic variation influence the impacts of warming and the loss of dominant species on communities and ecosystems? |
| 3. Are the impacts of warming and the loss of dominant species context-dependent or are there generalizable patterns (e.g., is the impact of a 2°C increase in temperature the same in a cold, dry ecosystem as in a warmer and wetter ecosystem)? |
Analysis potential
The WaRM network serves as a replicated, distributed global change experiment that combines the manipulation of temperature and shifts in species dominance with elevational gradients (high and low sites) at ten locations across the globe. Observational gradients and experimental techniques are useful tools for measuring and predicting the consequences of global climate change, particularly when used in combination, but statistical techniques enable us to explore interactions and indirect effects in ways that help us better understand the complex community and ecosystem responses to global environmental change in contrasting environmental settings. Integrating observational, experimental, and statistical techniques may be the most effective strategy for understanding the impact of global change on biological communities and ecosystems. For example, structural equation modeling (SEM) is a powerful multivariate statistical tool (Grace et al., 2012) that enables the testing of the indirect and direct effects of warming and elevation on plant community composition and ecosystem function (Figure 3), explicitly addressing our key questions and hypotheses (see Figure 3). Ongoing climatic change and predictions of average global surface temperatures rising by at least 2°C (and probably considerably more) by the year 2100 (IPCC, 2014) provide an impetus for a better understanding of how long-term, large-scale variation in climate influences community and ecosystem processes. SEMs are one potentially useful statistical tool to address questions about how warming may impact biological communities and whole ecosystem functioning. Moving forward, incorporating a wide range of multivariate statistical techniques, such as SEM, linear mixed-effects models, Bayesian analyses and generalized linear models, with data from manipulative experiments distributed across natural gradients in contrasting environments is a powerful approach to mechanistically understand relationships between communities and ecosystems, and the services derived from ecosystems, undergoing global change.
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MOVING FORWARD
The empirical data generated from the WaRM project can enable a more comprehensive understanding of the impacts of environmental change and species loss on biological communities and ecosystems, and they will help inform and parameterize models about the future of biodiversity, ecosystem functioning, and carbon cycling in contrasting mountain ecosystems around the globe. The fields of biodiversity and ecosystem modeling have developed greatly over the past few decades (Chaplin-Kramer et al., 2017; Jetz et al., 2019; Thuiller et al., 2019). However, a functional trait-based approach is needed to bridge the gap between these fields and to simultaneously refine ecosystem models, thereby improving the utility and predictive power of biodiversity forecasts (Funk et al., 2017; van der Plas et al., 2020; Violle et al., 2007). By exploring relationships between species identity and ecosystem functioning, and how the traits of individual organisms may respond to environmental change and in turn affect ecosystems, we may be able to better understand the way ecosystems are structured and predict how they will function in future. Linking experimental manipulations to forecasts of how functional traits impact ecosystem function can be informative, though rarely done, and is a fruitful path forward.
Manipulative experiments are constructed to test mechanisms and thus are often focused on relatively small spatial and temporal scales, limiting the ability to forecast from their data. Now with increased opportunities for international collaboration, it is possible to coordinate networks of manipulative ecological experiments that run simultaneously at macroecological scales (Borer et al., 2014; Fraser et al., 2012; Nogues-Bravo & Rahbek, 2011). Data from such experiments are more suitable for larger-scale modeling approaches, especially in community and ecosystem ecology. By combining work along environmental gradients with formal experimental approaches that manipulate both the abiotic environment and interactions among neighbors, we are able to capitalize on the advantages of both approaches (Fukami & Wardle, 2005). Indeed, we suggest that similar distributed network in other systems would be an important step forward for predicting how global change and the reorganization of communities interact to shape ecosystem function.
AUTHOR CONTRIBUTIONS
Case M. Prager: Conceptualization (supporting); data curation (equal); formal analysis (equal); investigation (equal); project administration (supporting); supervision (supporting); writing – original draft (lead); writing – review and editing (lead). Aimee Classen: Conceptualization (lead); funding acquisition (lead); investigation (equal); methodology (equal); project administration (equal); resources (equal); supervision (equal); writing – original draft (equal); writing – review and editing (equal). Maja Sundqvist: Conceptualization (equal); investigation (equal); methodology (equal); project administration (supporting); resources (supporting); supervision (supporting); writing – original draft (supporting); writing – review and editing (equal). M Noelia Barrios-Garcia: Conceptualization (supporting); investigation (equal); methodology (supporting); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Erin Cameron: Formal analysis (supporting); investigation (supporting); resources (supporting); writing – review and editing (equal). Litong Chen: Investigation (supporting); project administration (supporting); resources (supporting); supervision (supporting); writing – review and editing (equal). Chelsea Chisholm: Conceptualization (supporting); formal analysis (supporting); investigation (equal); project administration (supporting); resources (supporting); supervision (supporting); writing – review and editing (equal). Tom Crowther: Conceptualization (supporting); funding acquisition (supporting); investigation (supporting); methodology (supporting); project administration (supporting); resources (supporting); writing – original draft (supporting); writing – review and editing (equal). Julie Deslippe: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Karl Grigulis: Investigation (supporting); project administration (supporting); resources (supporting); supervision (supporting); writing – review and editing (supporting). Jin-Sheng He: Conceptualization (equal); formal analysis (equal); funding acquisition (supporting); investigation (lead); methodology (equal); project administration (equal); resources (equal); supervision (equal); writing – review and editing (equal). Jeremiah Henning: Data curation (supporting); formal analysis (supporting); project administration (supporting); writing – review and editing (equal). Mark Hovenden: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Toke T. Thomas Hoye: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Xin Jing: Formal analysis (supporting); investigation (supporting); project administration (supporting); writing – review and editing (equal). Sandra Lavorel: Investigation (equal); project administration (supporting); resources (supporting); writing – review and editing (equal). Jennie McLaren: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Dan Metcalfe: Investigation (supporting); project administration (supporting); writing – review and editing (equal). Greg Newman: Conceptualization (supporting); data curation (equal); formal analysis (equal); investigation (supporting); methodology (supporting); project administration (supporting); writing – review and editing (equal). Marie Louise Nielsen: Data curation (equal); formal analysis (equal); investigation (equal). Christian Rixen: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Quentin Read: Data curation (supporting); formal analysis (supporting); investigation (supporting); writing – review and editing (equal). Kenna Rewcastle: Data curation (supporting); formal analysis (supporting); investigation (supporting); writing – review and editing (equal). Mariano Rodriguez Cabal: Conceptualization (equal); funding acquisition (supporting); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). David A. Wardle: Conceptualization (equal); project administration (supporting); supervision (supporting); writing – review and editing (equal). Sonia Wipf: Conceptualization (equal); investigation (equal); methodology (equal); project administration (equal); resources (supporting); supervision (equal); writing – review and editing (equal). Nate J Sanders: Conceptualization (lead); data curation (equal); formal analysis (equal); funding acquisition (lead); investigation (equal); methodology (equal); project administration (lead); resources (lead); supervision (lead); writing – original draft (equal); writing – review and editing (equal).
ACKNOWLEDGMENT
We thank our reviewers for very helpful comments and edits to the manuscript. This network was formed with the support by a Semper Ardens grant from the Carlsberg Foundation (N.J.S.).
CONFLICT OF INTEREST
The authors declare that they have no conflict of interest.
DATA AVAILABILITY STATEMENT
The data that support this work are presented in Table 1 of this manuscript.
Alexander, J. M., Diez, J. M., Hart, S. P., & Levine, J. M. (2016). When climate reshuffles competitors: A call for experimental macroecology. Trends in Ecology & Evolution, 31, 831–841.
Avolio, M. L., Forrestel, E. J., Chang, C. C., La Pierre, K. J., Burghardt, K. T., & Smith, M. D. (2019). Demystifying dominant species. New Phytologist, 223, 1106–1126.
Báez, S., Collins, S. L., Pockman, W. T., Johnson, J. E., & Small, E. E. (2013). Effects of experimental rainfall manipulations on Chihuahuan Desert grassland and shrubland plant communities. Oecologia, 172, 1117–1127.
Bai, E., Li, S., Xu, W., Li, W., Dai, W., & Jiang, P. (2013). A meta‐analysis of experimental warming effects on terrestrial nitrogen pools and dynamics. New Phytologist, 199, 441–451.
Bjorkman, A. D., Myers‐Smith, I. H., Elmendorf, S. C., Normand, S., Rüger, N., Beck, P. S. A., Blach‐Overgaard, A., Blok, D., Cornelissen, J. H. C., Forbes, B. C., Georges, D., Goetz, S. J., Guay, K. C., Henry, G. H. R., HilleRisLambers, J., Hollister, R. D., Karger, D. N., Kattge, J., Manning, P., … Weiher, E. (2018). Plant functional trait change across a warming tundra biome. Nature, 562, 57–62.
Borer, E. T., Harpole, W. S., Adler, P. B., Lind, E. M., Orrock, J. L., Seabloom, E. W., & Smith, M. D. (2014). Finding generality in ecology: a model for globally distributed experiments. Methods in Ecology and Evolution, 5, 65–73.
Bradford, M. A., Ciska Veen, G. F., Bonis, A., Bradford, E. M., Classen, A. T., Cornelissen, J. H. C., Crowther, T. W., De Long, J. R., Freschet, G. T., Kardol, P., Manrubia‐Freixa, M., Maynard, D. S., Newman, G. S., Logtestijn, R. S. P., Viketoft, M., Wardle, D. A., Wieder, W. R., Wood, S. A., & van der Putten, W. H. (2017). A test of the hierarchical model of litter decomposition. Nature Ecology & Evolution, 1, 1836–1845.
Bryant, J. A., Lamanna, C., Morlon, H., Kerkhoff, A. J., Enquist, B. J., & Green, J. L. (2008). Microbes on mountainsides: Contrasting elevational patterns of bacterial and plant diversity. Proceedings of the National Academy of Sciences, 105, 11505–11511.
Callaway, R., Brooker, R., Choler, P., Kikvidze, Z., Lortie, C. J., Michalet, R., Paolini, L., Pugnaire, F. I., Newingham, B., Aschehoug, E. T., Armas, C., Kikodze, D., & Cook, B. J. (2002). Positive interactions among alpine plants increase with stress. Nature, 417, 844–848. https://doi.org/10.1038/nature00812
Carey, J. C., Tang, J., Templer, P. H., Kroeger, K. D., Crowther, T. W., Burton, A. J., Dukes, J. S., Emmett, B., Frey, S. D., Heskel, M. A., Jiang, L., Machmuller, M. B., Mohan, J., Panetta, A. M., Reich, P. B., Reinsch, S., Wang, X., Allison, S. D., Bamminger, C., … Tietema, A. (2016). Temperature response of soil respiration largely unaltered with experimental warming. Proceedings of the National Academy of Sciences, 113, 13797–13802.
Castro, H. F., Classen, A. T., Austin, E. E., Norby, R. J., & Schadt, C. W. (2010). Soil microbial community responses to multiple experimental climate change drivers. Applied and Environmental Microbiology, 76, 999–1007.
Cavicchioli, R., Ripple, W. J., Timmis, K. N., Azam, F., Bakken, L. R., Baylis, M., Behrenfeld, M. J., Boetius, A., Boyd, P. W., Classen, A. T., Crowther, T. W., Danovaro, R., Foreman, C. M., Huisman, J., Hutchins, D. A., Jansson, J. K., Karl, D. M., Koskella, B., Mark Welch, D. B., … Webster, N. S. (2019). Scientists' warning to humanity: Microorganisms and climate change. Nature Reviews Microbiology, 17, 569–586.
Chaplin‐Kramer, R., Sim, S., Hamel, P., Bryant, B., Noe, R., Mueller, C., Rigarlsford, G., Kulak, M., Kowal, V., Sharp, R., Clavreul, J., Price, E., Polasky, S., Ruckelshaus, M., & Daily, G. (2017). Life cycle assessment needs predictive spatial modelling for biodiversity and ecosystem services. Nature Communications, 8, 15065.
Cowles, J. M., Wragg, P. D., Wright, A. J., Powers, J. S., & Tilman, D. (2016). Shifting grassland plant community structure drives positive interactive effects of warming and diversity on aboveground net primary productivity. Global Change Biology, 22, 741–749.
Crowther, T. W., Todd‐Brown, K. E. O., Rowe, C. W., Wieder, W. R., Carey, J. C., Machmuller, M. B., Snoek, B. L., Fang, S., Zhou, G., Allison, S. D., Blair, J. M., Bridgham, S. D., Burton, A. J., Carrillo, Y., Reich, P. B., Clark, J. S., Classen, A. T., Dijkstra, F. A., Elberling, B., … Bradford, M. A. (2016). Quantifying global soil carbon losses in response to warming. Nature, 540, 104–108.
De Bello, F., Lavergne, S., Meynard, C. N., Lepš, J., & Thuiller, W. (2010). The partitioning of diversity: Showing Theseus a way out of the labyrinth. Journal of Vegetation Science, 21, 992–1000. https://doi.org/10.1111/j.1654‐1103.2010.01195.x
Diaz, S., Hodgson, J., Thompson, K., Cabido, M., Cornelissen, J., Jalili, A., Montserrat‐Martí, G., Grime, J., Zarrinkamar, F., Asri, Y., Band, S., Basconcelo, S., Castro‐Díez, P., Funes, G., Hamzehee, B., Khoshnevi, M., Pérez‐Harguindeguy, N., Pérez‐Rontomé, M., Shirvany, F., … Zak, M. (2004). The plant traits that drive ecosystems: Evidence from three continents. Journal of Vegetation Science, 15, 295–304. https://doi.org/10.1111/j.1654‐1103.2004.tb02266.x
Díaz, S., Lavorel, S., de Bello, F., Quétier, F., Grigulis, K., & Robson, T. M. (2007). Incorporating plant functional diversity effects in ecosystem service assessments. Proceedings of the National Academy of Sciences of the United States of America, 104, 20684–20689.
Elmendorf, S. C., Henry, G. H. R., Hollister, R. D., Björk, R. G., Bjorkman, A. D., Callaghan, T. V., Collier, L. S., Cooper, E. J., Cornelissen, J. H. C., a Day, T., Fosaa, A. M., Gould, W. a., Grétarsdóttir, J., Harte, J., Hermanutz, L., Hik, D. S., Hofgaard, A., Jarrad, F., Jónsdóttir, I. S., … Wookey, P. a. (2012). Global assessment of experimental climate warming on tundra vegetation: Heterogeneity over space and time. Ecology Letters, 15, 164–175.
Elmendorf, S. C., Henry, G. H. R., Hollister, R. D., Bjork, R. G., Boulanger‐Lapointe, N., Cooper, E. J., Cornelissen, J. H. C., Day, T. A., Dorrepaal, E., Elumeeva, T. G., Gill, M., Gould, W. A., Harte, J., Hik, D. S., Hofgaard, A., Johnson, D. R., Johnstone, J. F., Jonsdottir, I. S., Jorgenson, J. C., … Wipf, S. (2012). Plot‐scale evidence of tundra vegetation change and links to recent summer warming. Nature Climate Change, 2, 453–457.
Elmendorf, S. C., Henry, G. H. R., Hollister, R. D., Fosaa, A. M., Gould, W. A., Hermanutz, L., Hofgaard, A., Jónsdóttir, I. S., Jorgenson, J. C., Lévesque, E., Magnusson, B., Molau, U., Myers‐Smith, I. H., Oberbauer, S. F., Rixen, C., Tweedie, C. E., & Walker, M. D. (2015). Experiment, monitoring, and gradient methods used to infer climate change effects on plant communities yield consistent patterns. Proceedings of the National Academy of Sciences, 112, 448–452.
Fanin, N., Gundale, M. J., Farrell, M., Ciobanu, M., Baldock, J. A., Nilsson, M.‐C., Kardol, P., & Wardle, D. A. (2018). Consistent effects of biodiversity loss on multifunctionality across contrasting ecosystems. Nature Ecology & Evolution, 2, 269–278.
Fanin, N., Kardol, P., Farrell, M., Kempel, A., Ciobanu, M., Nilsson, M.‐C., Gundale, M. J., & Wardle, D. A. (2019). Effects of plant functional group removal on structure and function of soil communities across contrasting ecosystems. Ecology Letters, 22, 1095–1103.
Fraser, L. H., Henry, H. A. L., Carlyle, C. N., White, S. R., Beierkuhnlein, C., Cahill, J. F. Jr, Casper, B. B., Cleland, E., Collins, S. L., Dukes, J. S., Knapp, A. K., Lind, E., Long, R., Luo, Y., Reich, P. B., Smith, M. D., Sternberg, M., & Turkington, R. (2012). Coordinated distributed experiments: An emerging tool for testing global hypotheses in ecology and environmental science. Department of Forestry & Natural Resources Faculty Publications. Paper 14. https://doi.org/10.1890/110279
Fukami, T., & Wardle, D. A. (2005). Long‐term ecological dynamics: Reciprocal insights from natural and anthropogenic gradients. Proceedings of the Royal Society B: Biological Sciences, 272, 2105–2115.
Funk, J. L., Larson, J. E., Ames, G. M., Butterfield, B. J., Cavender‐Bares, J., Firn, J., Laughlin, D. C., Sutton‐Grier, A. E., Williams, L., & Wright, J. (2017). Revisiting the holy grail: Using plant functional traits to understand ecological processes. Biological Reviews, 92, 1156–1173.
Grace, J. B., Schoolmaster, D. R., Guntenspergen, G. R., Little, A. M., Mitchell, B. R., Miller, K. M., & Schweiger, E. W. (2012). Guidelines for a graph‐theoretic implementation of structural equation modeling. Ecosphere, 3, art73.
Grime, J. P. (1977). Evidence for existence of three primary strategies in plants and its relevance to ecological and evolutionary theory. American Naturalist, 111, 1169–1194.
Grime, J. P. (1998). Benefits of plant diversity to ecosystems: Immediate, filter and founder effects. Journal of Ecology, 86, 902–910.
He, X., Hou, E., Veen, G. F., Ellwood, M. D. F., Dijkstra, P., Sui, X., Zhang, S., Wen, D., & Chu, C. (2020). Soil microbial biomass increases along elevational gradients in the tropics and subtropics but not elsewhere. Global Ecology and Biogeography, 29, 345–354.
Hendershot, J. N., Read, Q. D., Henning, J. A., Sanders, N. J., & Classen, A. T. (2017). Consistently inconsistent drivers of microbial diversity and abundance at macroecological scales. Ecology, 98, 1757–1763.
Henry, G. H. R., & Molau, U. (1997). Tundra plants and climate change: The international tundra experiment (ITEX). Global Change Biology, 3, 1–9.
Hijmans, R. J., Cameron, S. E., Parra, J. L., Jones, P. G., & Jarvis, A. (2012). Very high resolution interpolated climate surfaces for global land areas. International Journal of Climatology, 25, 1965–1978 (for WorldClim 2018 database citation).
Hillebrand, H., Bennett, D. M., & Cadotte, M. W. (2008). Consequences of dominance: A review of evenness effects on local and regional ecosystem processes. Ecology, 89, 1510–1520.
Heskel, M., Greaves, H., Kornfeld, A., Gough, L., Atkin, O. K., Turnbull, M. H., Shaver, G., & Griffin, K. L. (2013). Differential physiological responses to environmental change promote woody shrub expansion. Ecology and Evolution, 3(5), 1149–1162.
Hovenden, M. J., Leuzinger, S., Newton, P. C. D., Fletcher, A., Fatichi, S., Lüscher, A., Reich, P. B., Andresen, L. C., Beier, C., Blumenthal, D. M., Chiariello, N. R., Dukes, J. S., Kellner, J., Hofmockel, K., Niklaus, P. A., Song, J., Wan, S., Classen, A. T., & Langley, J. A. (2019). Globally consistent influences of seasonal precipitation limit grassland biomass response to elevated CO2. Nature Plants, 5, 167–173.
IPCC. (2014). Climate Change 2014: Synthesis Report. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Core Writing Team, R.K. Pachauri and L.A. Meyer (eds.)]. IPCC 151 pp.
Isbell, F., Gonzalez, A., Loreau, M., Cowles, J., Díaz, S., Hector, A., Mace, G. M., Wardle, D. A., O'Connor, M. I., Duffy, J. E., Turnbull, L. A., Thompson, P. L., & Larigauderie, A. (2017). Linking the influence and dependence of people on biodiversity across scales. Nature, 546, 65–72.
Jain, M., Flynn, D. F. B., Prager, C. M., Hart, G. M., DeVan, C. M., Ahrestani, F. S., Palmer, M. I., Bunker, D. E., Knops, J. M. H., Jouseau, C. F., & Naeem, S. (2014). The importance of rare species: a trait‐based assessment of rare species contributions to functional diversity and possible ecosystem function in tall‐grass prairies. Ecology and Evolution, 4, 104–112.
Jetz, W., McGeoch, M. A., Guralnick, R., Ferrier, S., Beck, J., Costello, M. J., Fernandez, M., Geller, G. N., Keil, P., Merow, C., Meyer, C., Muller‐Karger, F. E., Pereira, H. M., Regan, E. C., Schmeller, D. S., & Turak, E. (2019). Essential biodiversity variables for mapping and monitoring species populations. Nature Ecology & Evolution, 3, 539–551.
Kardol, P., Fanin, N., & Wardle, D. A. (2018). Long‐term effects of species loss on community properties across contrasting ecosystems. Nature, 557, 710–713.
Kivlin, S. N., Winston, G. C., Goulden, M. L., & Treseder, K. K. (2014). Environmental filtering affects soil fungal community composition more than dispersal limitation at regional scales. Fungal Ecology, 12, 14–25.
Kleyer, M., Dray, S., Bello, F., Lepš, J., Pakeman, R. J., Strauss, B., Thuiller, W., & Lavorel, S. (2012). Assessing species and community functional responses to environmental gradients: Which multivariate methods? Journal of Vegetation Science, 23, 805–821.
Körner, C. (2007). The use of ‘altitude’ in ecological research. Trends in Ecology & Evolution, 22, 569–574.
Kröel‐Dulay, G., Mojzes, A., Szitár, K., Bahn, M., Batáry, P., Beier, C., Bilton, M., de Boeck, H. J., Dukes, J. S., Estiarte, M., Holub, P., Jentsch, A., Schmidt, I. K., Kreyling, J., Reinsch, S., Larsen, K. S., Sternberg, M., Tielbörger, K., Tietema, A., … Peñuelas, J. (2022). Field experiments underestimate aboveground biomass response to drought. Nature Ecology & Evolution, 6, 540–545. https://doi.org/10.1038/s41559‐022‐01685‐3
Lavorel, S., & Garnier, E. (2002). Predicting changes in community composition and ecosystem functioning from plant traits: Revisiting the Holy Grail. Functional Ecology, 16, 545–556. https://doi.org/10.1046/j.1365‐2435.2002.00664.x
Lavorel, S., & Grigulis, K. (2012). How fundamental plant functional trait relationships scale‐up to trade‐offs and synergies in ecosystem services. Journal of Ecology, 100, 128–140. https://doi.org/10.1111/j.1365‐2745.2011.01914.x
Liu, H., Mi, Z., Lin, L., Wang, Y., Zhang, Z., Zhang, F., Wang, H., Liu, L., Zhu, B., Cao, G., Zhao, X., Sanders, N. J., Classen, A. T., Reich, P. B., & He, J.‐S. (2018). Shifting plant species composition in response to climate change stabilizes grassland primary production. Proceedings of the National Academy of Sciences, 115, 4051–4056.
Luo, Y., Wan, S., Hui, D., & Wallace, L. L. (2001). Acclimatization of soil respiration to warming in a tall grass prairie. Nature, 413, 622–625.
Martinez‐Almoyna, C., Thuiller, W., Chalmandrier, L., Ohlmann, M., Foulquier, A., Clément, J.‐C., Zinger, L., & Münkemüller, T. (2019). Multi‐trophic β‐diversity mediates the effect of environmental gradients on the turnover of multiple ecosystem functions. Functional Ecology, 33, 2053–2064.
Mayor, J. R., Sanders, N. J., Classen, A. T., Bardgett, R. D., Clément, J.‐C., Fajardo, A., Lavorel, S., Sundqvist, M. K., Bahn, M., Chisholm, C., Cieraad, E., Gedalof, Z., Grigulis, K., Kudo, G., Oberski, D. L., & Wardle, D. A. (2017). Elevation alters ecosystem properties across temperate treelines globally. Nature, 542, 91–95.
McCain, C. M. (2007). Could temperature and water availability drive elevational species richness patterns? A global case study for bats. Global Ecology and Biogeography, 16, 1–13.
McLaren, J. R., & Turkington, R. (2010). Ecosystem properties determined by plant functional group identity. Journal of Ecology, 98, 459–469. https://doi.org/10.1111/j.1365‐2745.2009.01630.x
Melillo, J. M., Frey, S. D., DeAngelis, K. M., Werner, W. J., Bernard, M. J., Bowles, F. P., Pold, G., Knorr, M. A., & Grandy, A. S. (2017). Long‐term pattern and magnitude of soil carbon feedback to the climate system in a warming world. Science, 358, 101–105.
Minasny, B., McBratney, A. B., Brough, D. M., & Jacquier, D. (2011). Models relating soil pH measurements in water and calcium chloride that incorporate electrolyte concentration. European Journal of Soil Science, 62, 728–732.
Niu, S., Xing, X., Zhang, Z., Xia, J., Zhou, X., Song, B., Li, L., & Wan, S. (2011). Water‐use efficiency in response to climate change: from leaf to ecosystem in a temperate steppe. Global Change Biology, 17, 1073–1082. https://doi.org/10.1111/j.1365‐2486.2010.02280.x
Nogues‐Bravo, D., & Rahbek, C. (2011). Communities under climate change. Science, 334(6059), 1070–1071. https://doi.org/10.1126/science.121483
Nooten, S. S., & Andrew, N. R. (2017). Transplant experiments – a powerful method to study climate change impacts. In S. N. Johnson & T. H. Jones (Eds.), Global Climate Change and Terrestrial Invertebrates. https://doi.org/10.1002/9781119070894.ch4
Orwin, K. H., Ostle, N., Wilby, A., & Bardgett, R. D. (2014). Effects of species evenness and dominant species identity on multiple ecosystem functions in model grassland communities. Oecologia, 174, 979–992.
Peltzer, D. A., Bellingham, P. J., Kurokawa, H., Walker, L. R., Wardle, D. A., & Yeates, G. W. (2009). Punching above their weight: Low‐biomass non‐native plant species alter soil properties during primary succession. Oikos, 118, 1001–1014.
Read, Q. D., Moorhead, L. C., Swenson, N. G., Bailey, J. K., & Sanders, N. J. (2014). Convergent effects of elevation on functional leaf traits within and among species. Functional Ecology, 28, 37–45.
Reich, P. B., Sendall, K. M., Stefanski, A., Rich, R. L., Hobbie, S. E., & Montgomery, R. A. (2018). Effects of climate warming on photosynthesis in boreal tree species depend on soil moisture. Nature, 562, 263–267.
Rogora, M., Frate, L., Carranza, M. L., Freppaz, M., Stanisci, A., Bertani, I., Bottarin, R., Brambilla, A., Canullo, R., Carbognani, M., Cerrato, C., Chelli, S., Cremonese, E., Cutini, M., Di Musciano, M., Erschbamer, B., Godone, D., Iocchi, M., Isabellon, M., … Matteucci, G. (2018). Assessment of climate change effects on mountain ecosystems through a cross‐site analysis in the Alps and Apennines. Science of the Total Environment, 624, 1429–1442.
Rouse, J. W., Haas, R. H., Schell, J. A., & Deering, D. W. (1974). Monitoring vegetation systems in the Great Plains with ERTS. In S. C. Freden, E. P. Mercanti, & M. Becker (Eds.), Third Earth Resources Technology Satellite–1 Syposium. Volume I: Technical Presentations, NASA SP‐351 (pp. 309–317). NASA.
Sasaki, T., & Lauenroth, W. (2011). Dominant species, rather than diversity, regulates temporal stability of plant communities. Oecologia, 166, 761–768.
Smith, M. D., & Knapp, A. K. (2003). Dominant species maintain ecosystem function with non‐random species loss. Ecology Letters, 6, 509–517.
Song, J., Wan, S., Piao, S., Knapp, A. K., Classen, A. T., Vicca, S., Ciais, P., Hovenden, M. J., Leuzinger, S., Beier, C., Kardol, P., Xia, J., Liu, Q., Ru, J., Zhou, Z., Luo, Y., Guo, D., Adam Langley, J., Zscheischler, J., … Zheng, M. (2019). A meta‐analysis of 1,119 manipulative experiments on terrestrial carbon‐cycling responses to global change. Nature Ecology & Evolution, 3, 1309–1320.
Sundqvist, M. K., Sanders, N. J., Dorrepaal, E., Lindén, E., Metcalfe, D. B., Newman, G. S., Olofsson, J., Wardle, D. A., & Classen, A. T. (2020). Responses of tundra plant community carbon flux to experimental warming, dominant species removal and elevation. Functional Ecology, 34, 1497–1506.
Sundqvist, M. K., Sanders, N. J., & Wardle, D. A. (2013). Community and ecosystem responses to elevational gradients: Processes, mechanisms, and insights for global change. Annual Review of Ecology, Evolution, and Systematics, 44, 261–280.
Suseela, V., Conant, R. T., Wallenstein, M. D., & Dukes, J. S. (2012). Effects of soil moisture on the temperature sensitivity of heterotrophic respiration vary seasonally in an old‐field climate change experiment. Global Change Biology, 18, 336–348. https://doi.org/10.1111/j.1365‐2486.2011.02516.x
Thuiller, W., Guéguen, M., Renaud, J., Karger, D. N., & Zimmermann, N. E. (2019). Uncertainty in ensembles of global biodiversity scenarios. Nature Communications, 10, 1446.
van der Plas, F., Schröder‐Georgi, T., Weigelt, A., Barry, K., Meyer, S., Alzate, A., Barnard, R. L., Buchmann, N., de Kroon, H., Ebeling, A., Eisenhauer, N., Engels, C., Fischer, M., Gleixner, G., Hildebrandt, A., Koller‐France, E., Leimer, S., Milcu, A., Mommer, L., … Wirth, C. (2020). Plant traits alone are poor predictors of ecosystem properties and long‐term ecosystem functioning. Nature Ecology & Evolution, 4, 1602–1611.
van Wijk, M. T., Williams, M., Gough, L., Hobbie, S. E., & Shaver, G. R. (2003). Luxury consumption of soil nutrients: a possible competitive strategy in above‐ground and below‐ground biomass allocation and root morphology for slow‐growing arctic vegetation? Journal of Ecology, 91, 664–676.
Violle, C., Navas, M. L., Vile, D., Kazakou, E., Fortunel, C., Hummel, I., & Garnier, E. (2007). Let the concept of trait be functional! Oikos, 116, 882–892.
von Humboldt, A. (1849). Aspects of nature, in different lands and different climates; with scientific elucidations, Vol. II. Transl. EJ Sabine. Longman, Brown, Green, Longmans, John Murray 347 pp.
Walker, L. R., Wardle, D. A., Bardgett, R. D., & Clarkson, B. D. (2010). The use of chronosequences in studies of ecological succession and soil development. Journal of Ecology, 98, 725–736.
Wipf, S., & Rixen, C. (2010). A review of snow manipulation experiments in Arctic and alpine tundra ecosystems. Polar Research, 29, 95–109. https://doi.org/10.1111/j.1751‐8369.2010.00153.x
Wolkovich, E. M., Cook, B. I., Allen, J. M., Crimmins, T. M., Betancourt, J. L., Travers, S. E., Pau, S., Regetz, J., Davies, T. J., Kraft, N. J. B., Ault, T. R., Bolmgren, K., Mazer, S. J., McCabe, G. J., McGill, B. J., Parmesan, C., Salamin, N., Schwartz, M. D., & Cleland, E. E. (2012). Warming experiments underpredict plant phenological responses to climate change. Nature, 485, 494–497.
Wu, Z., Dijkstra, P., Koch, G. W., Peñuelas, J., & Hungate, B. A. (2011). Responses of terrestrial ecosystems to temperature and precipitation change: a meta‐analysis of experimental manipulation. Global Change Biology, 17, 927–942.
Zavaleta, E. S., Shaw, M. R., Chiariello, N. R., Thomas, B. D., Cleland, E. E., Field, C. B., & Mooney, H. A. (2003). Grassland responses to three years of elevated temperature, CO(2), precipitation, and N deposition. Ecological Monographs, 73, 585–604.
Zumsteg, A., Bååth, E., Stierli, B., Zeyer, J., & Frey, B. (2013). Bacterial and fungal community responses to reciprocal soil transfer along a temperature and soil moisture gradient in a glacier forefield. Soil Biology and Biochemistry, 61, 121–132.
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Abstract
A growing body of work examines the direct and indirect effects of climate change on ecosystems, typically by using manipulative experiments at a single site or performing meta‐analyses across many independent experiments. However, results from single‐site studies tend to have limited generality. Although meta‐analytic approaches can help overcome this by exploring trends across sites, the inherent limitations in combining disparate datasets from independent approaches remain a major challenge. In this paper, we present a globally distributed experimental network that can be used to disentangle the direct and indirect effects of climate change. We discuss how natural gradients, experimental approaches, and statistical techniques can be combined to best inform predictions about responses to climate change, and we present a globally distributed experiment that utilizes natural environmental gradients to better understand long‐term community and ecosystem responses to environmental change. The warming and (species) removal in mountains (WaRM) network employs experimental warming and plant species removals at high‐ and low‐elevation sites in a factorial design to examine the combined and relative effects of climatic warming and the loss of dominant species on community structure and ecosystem function, both above‐ and belowground. The experimental design of the network allows for increasingly common statistical approaches to further elucidate the direct and indirect effects of warming. We argue that combining ecological observations and experiments along gradients is a powerful approach to make stronger predictions of how ecosystems will function in a warming world as species are lost, or gained, in local communities.
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Details
; Classen, Aimee T. 2
; Sundqvist, Maja K. 3 ; Barrios‐Garcia, Maria Noelia 4 ; Cameron, Erin K. 5 ; Chen, Litong 6 ; Chisholm, Chelsea 7 ; Crowther, Thomas W. 7 ; Deslippe, Julie R. 8 ; Grigulis, Karl 9 ; He, Jin‐Sheng 10
; Henning, Jeremiah A. 11
; Hovenden, Mark 12 ; Høye, Toke T. Thomas 13
; Jing, Xin 14 ; Lavorel, Sandra 9 ; McLaren, Jennie R. 15 ; Metcalfe, Daniel B. 16 ; Newman, Gregory S. 17 ; Nielsen, Marie Louise 13 ; Rixen, Christian 18 ; Read, Quentin D. 19 ; Rewcastle, Kenna E. 20 ; Rodriguez‐Cabal, Mariano 21 ; Wardle, David A. 22
; Wipf, Sonja 23 ; Sanders, Nathan J. 2 1 Ecology and Evolutionary Biology Department, University of Michigan, Ann Arbor, Michigan, USA, The Rocky Mountain Biological Laboratory, Crested Butte, Colorado, USA
2 Ecology and Evolutionary Biology Department, University of Michigan, Ann Arbor, Michigan, USA, The Rocky Mountain Biological Laboratory, Crested Butte, Colorado, USA, Natural History Museum of Denmark, University of Copenhagen, Copenhagen, Denmark
3 Natural History Museum of Denmark, University of Copenhagen, Copenhagen, Denmark, Department of Forest Ecology and Management, Swedish University of Agricultural Sciences, Umeå, Sweden
4 CONICET, CENAC‐APN, San Carlos de Bariloche, Rio Negro, Argentina, Rubenstein School of Environment and Natural Resources, University of Vermont, Burlington, Vermont, USA
5 Department of Environmental Science, Saint Mary's University, Halifax, Nova Scotia, Canada
6 Qinghai Provincial Key Laboratory of Restoration Ecology of Cold Area and Key Laboratory of Adaptation and Evolution of Plant Biota, Northwest Institute of Plateau Biology, Chinese Academy of Sciences, Xining, China
7 Department of Environment Systems Science, Institute of Integrative Biology, ETH Zürich, Zürich, Switzerland
8 Centre for Biodiversity and Restoration Ecology, School of Biological Sciences, Victoria University of Wellington, Wellington, New Zealand
9 Laboratoire d'Ecologie Alpine, Université Grenoble Alpes – CNRS – Université Savoie Mont‐Blanc, Grenoble, France
10 Department of Ecology, College of Urban and Environmental Sciences, Peking University, Beijing, China
11 The Rocky Mountain Biological Laboratory, Crested Butte, Colorado, USA, Department of Biology, University of South Alabama, Mobile, Alabama, USA
12 Biological Sciences, School of Natural Sciences, University of Tasmania, Hobart, Tasmania, Australia
13 Department of Ecoscience and Arctic Research Centre, Aarhus University, Aarhus C, Denmark
14 Natural History Museum of Denmark, University of Copenhagen, Copenhagen, Denmark, State Key Laboratory of Grassland Agro‐Ecosystems, and College of Pastoral Agriculture Science and Technology, Lanzhou University, Lanzhou, Gansu, China
15 Department of Biological Sciences, University of Texas at El Paso, El Paso, Texas, USA
16 Department of Ecology and Environmental Science, Umeå University, Umeå, Sweden
17 Department of Biology, University of Oklahoma, Norman, Oklahoma, USA
18 Mountain Ecosystems Group, WSL Institute for Snow and Avalanche Research SLF, Davos Dorf, Switzerland
19 The Rocky Mountain Biological Laboratory, Crested Butte, Colorado, USA, National Socio‐Environmental Synthesis Center, Annapolis, Maryland, USA
20 Rubenstein School of Environment and Natural Resources, University of Vermont, Burlington, Vermont, USA
21 Rubenstein School of Environment and Natural Resources, University of Vermont, Burlington, Vermont, USA, Grupo de Ecología de Invasiones, INIBIOMA, CONICET, Universidad Nacional del Comahue, San Carlos de Bariloche, Argentina
22 Asian School of the Environment, Nanyang Technological University, Singapore, Singapore
23 Department of Biology, University of Oklahoma, Norman, Oklahoma, USA, Department of Research and Monitoring, Chastè Planta‐Wildenberg, Zernez, Switzerland