Simulated migration in a long-term climate change experiment: invasions impeded by dispersal limitation, not biotic resistance

Moser, Barbara; Fridley, Jason D.; Askew, Andrew P.; Grime, J. P.

doi:10.1111/j.1365-2745.2011.01841.x

Cited by 22 publications

(16 citation statements)

References 29 publications

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“…These factors likely ensured an abundant seed supply of tall and fast-growing annual grasses and forbs to our infertile grassland habitats, as evidenced by the fact that the watered and fertilized plots went through nearly complete species turnover and that it was these species rather than residents that dominated the biomass response. This result is consistent with previous studies that link cross-habitat movement of propagules to the maintenance of productivity and diversity (55)(56)(57), and responsiveness of communities to climate change (13,58).…”

Section: Discussionsupporting

confidence: 93%

Resource colimitation governs plant community responses to altered precipitation

Eskelinen

Harrison

2015

Proc. Natl. Acad. Sci. U.S.A.

112

117

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Ecological theory and evidence suggest that plant community biomass and composition may often be jointly controlled by climatic water availability and soil nutrient supply. To the extent that such colimitation operates, alterations in water availability caused by climatic change may have relatively little effect on plant communities on nutrient-poor soils. We tested this prediction with a 5-y rainfall and nutrient manipulation in a semiarid annual grassland system with highly heterogeneous soil nutrient supplies. On nutrient-poor soils, rainfall addition alone had little impact, but rainfall and nutrient addition synergized to cause large increases in biomass, declines in diversity, and near-complete species turnover. Plant species with resource-conservative functional traits (low specific leaf area, short stature) were replaced by species with resource-acquisitive functional traits (high specific leaf area, tall stature). On nutrient-rich soils, in contrast, rainfall addition alone caused substantial increases in biomass, whereas fertilization had little effect. Our results highlight that multiple resource limitation is a critical aspect when predicting the relative vulnerability of natural communities to climatically induced compositional change and diversity loss.biodiversity | climate change | resource colimitation | functional traits | low-productivity ecosystems C urrent and predicted climatic changes are expected to considerably alter the water balance experienced by terrestrial ecosystems. Climate change can lead to increases or decreases in mean annual rainfall, shifts in seasonal and annual rainfall variability, changes in the frequency and magnitude of extreme precipitation events, shifts from snow to rain, declining snowpack, and temperature-driven increases in the climatic water deficit (1-3). These water-related changes are expected to exert dramatic impacts on the primary productivity, species composition, trophic relationships, diversity, and ecosystem functioning of natural communities (4-8), especially in arid and semiarid ecosystems (9-11). Water-related climatic changes are expected to outweigh the direct effects of increased temperatures on many natural communities (12). Despite the pervasiveness of the projected ecological impacts of changed water availability, very little is known about the factors that make some natural communities more vulnerable or resistant than others (13,14). An important step toward improving downscaled forecasts of climate change impacts on natural communities is to test explicit, theorybased predictions about the effects of altered water availability.Because water is a resource for plants, the concept of limiting resources is a potentially important principle for making successful predictions about altered water availability. Classically, "Liebig's law of the minimum" suggests that plant productivity is limited by the single resource that is in scarcest supply relative to demand (15). This theory was developed for agricultural systems, and although its simple logi...

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Section: Discussionsupporting

confidence: 93%

Resource colimitation governs plant community responses to altered precipitation

Eskelinen

Harrison

2015

Proc. Natl. Acad. Sci. U.S.A.

112

117

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“…However, the possible impact of climate change on plant distributions depends on several natural and anthropogenic factors, such as the rate of climatic change, landscape fragmentation, seed availability, resource availability, dispersal capabilities of individual species and interactions with land use (Walther et Moen et al, 2004). Besides, successful poleward shifts of plant species ranges will depend on interactions between migrating species and the communities they invade (Moser et al, 2011). In Arctic terrestrial ecosystems, geographical barriers such as the distribution of landmasses and separation by seas, will affect the northwards shift in vegetation zones (Callaghan et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Impacts of Climate Change on Vegetation Distribution No. 1 -- Climate Change Induced Vegetation Shifts in the Palearctic Region

Garamvölgyi¹

2013

Appl Ecol Env Res

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Abstract. Global average temperature has increased and precipitation pattern has altered over the past 100 years due to increases in greenhouse gases. These changes will alter numerous site factors and biochemical processes of vegetative communities such as nutrient and water availability, permafrost thawing, fire regime, biotic interactions and invasion. As a consequence, climate change is expected to alter distribution ranges of many species and communities as well as boundaries of biomes. Shifting of species and vegetation zones northwards and upwards in elevation has already been observed. Besides, several experiments have been conducted and simulations have been run all over the world in order to predict possible range shifts and ecological risks. In this paper, we review literature available in Web of Science on Europe and boreal Eurasia and give an overview of observed and predicted changes in vegetation in these regions. The main trends include advance of the tree line, reduction of the alpine vegetation belt, drought risk, forest diebacks, a shift from coniferous forests to deciduous forests and invasion. It is still controversial if species migration will be able to keep pace with climate change.

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“…Climate changes are also associated with changes in the distribution of vegetation species [19], [20], [21], which might significantly modify the availability of feeding resources in terrestrial and adjacent aquatic ecosystems, because the consumption of the leaves of riparian trees by the shredder species constitutes a major allochtonous trophic resource for temperate stream ecosystems [22], [23]. In addition, the shredder leaf consumption rate is influenced by leaf characteristics [24], [25].…”

Section: Introductionmentioning

confidence: 99%

Effect of Climate-Related Change in Vegetation on Leaf Litter Consumption and Energy Storage by Gammarus pulex from Continental or Mediterranean Populations

et al. 2013

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As a consequence of global warming, it is important to characterise the potential changes occurring for some functional processes through the intra-specific study of key species. Changes in species distribution, particularly when key or engineer species are affected, should contribute to global changes in ecosystem functioning. In this study, we examined the potential consequences induced by global warming on ecosystem functioning in term of organic matter recycling. We compared consumption of leaf litter by some shredder populations (Gammarus pulex) between five tree species inhabiting continental (i.e., the northern region of the Rhône River Valley) and/or Mediterranean (i.e., the southern region of the Rhône River Valley) conditions. To consider any potential adaptation of the gammarid population to vegetation in the same climate conditions, three populations of the key shredder Gammarus pulex from the northern region and three from the southern region of the Rhône River Valley were used. We experimentally compared the effects of the geographical origin of both the gammarid populations and the leaf litter species on the shredding activity and the physiological state of animals (through body triglyceride content). This study demonstrated that leaf toughness is more important than geographical origin for determining shredder leaf litter consumption. The overall consumption rate of the gammarid populations from the southern region of Rhône Valley was much higher than that of the populations from the northern region, but no clear differences between the origins of the leaf litter (i.e., continental vs. Mediterranean) were observed. The northwards shift of G. pulex populations adapted to warmer conditions might significantly modify organic matter recycling in continental streams. As gammarid populations can demonstrate local adaptations to certain leaf species as a trophic resource, changes in riparian vegetation associated with climate change might locally affect the leaf litter degradation process by this shredder.

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Simulated migration in a long-term climate change experiment: invasions impeded by dispersal limitation, not biotic resistance

Cited by 22 publications

References 29 publications

Resource colimitation governs plant community responses to altered precipitation

Resource colimitation governs plant community responses to altered precipitation

Impacts of Climate Change on Vegetation Distribution No. 1 -- Climate Change Induced Vegetation Shifts in the Palearctic Region

Effect of Climate-Related Change in Vegetation on Leaf Litter Consumption and Energy Storage by Gammarus pulex from Continental or Mediterranean Populations

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