Contrasting effects of water and nutrient additions on grassland communities: A global meta‐analysis

DeMalach, Niv; Zaady, Eli; Kadmon, Ronen

doi:10.1111/geb.12603

Cited by 60 publications

(65 citation statements)

References 58 publications

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“…In our experiment, water was applied in the middle of the growing season (July and August); future experiments should investigate whether earlier water addition reduces plant diversity in the semi‐arid steppe we studied, as suggested by the phenology hypothesis. Note that adding N and water together removed the positive effect of water addition on species richness in our experiment, which is consistent with the finding of a recent meta‐analysis (DeMalach et al., ). One possible explanation for this result is that increased photosynthetic rate after N addition led to greater transpiration rate and more rapid depletion of water from the rooting zone and therefore reduced soil moisture (Harpole et al., ; Zavaleta et al., ), counteracting the effect of direct water addition.…”

Section: Discussionsupporting

confidence: 92%

“…The generality of our findings, nevertheless, remains to be assessed by future studies. We hope our work will stimulate the rapid emergence of these studies, given a number of field experiments similar to ours have already been conducted (reviewed by DeMalach et al., ).…”

Section: Discussionmentioning

confidence: 83%

“…Fertilization studies in N‐limiting systems have found that increases in N availability tend to have positive effects on primary productivity, but negative effects on plant species richness (Bobbink, Hornung, Roelofs, Hornungt, & Roelofst, ; DeMalach, Zaady, & Kadmon, ; Gough, Osenberg, Gross, & Collins, ; Harpole et al., ; Suding et al., ). Water addition also often results in increases in primary production, whereas its effects on plant species richness are varied (DeMalach, Zaady, & Kadmon, ; Knapp & Smith, ; Yang et al., ). Notably, much research on N and water addition effects has focused on ecosystem‐level responses (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Nitrogen fertilization, not water addition, alters plant phylogenetic community structure in a semi‐arid steppe

Yang

Tan

et al. 2017

Journal of Ecology

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Anthropogenic environmental changes, such as nitrogen (N) enrichment and alteration in precipitation regimes, significantly influence ecosystems world‐wide. However, we know little about whether and how these changes alter the phylogenetic properties of ecological communities. Based on a 7‐year field experiment in the temperate semi‐arid steppe of Inner Mongolia, China, we investigated the influence of increased N and precipitation on plant phylogenetic structure and phylogenetic patterns of species colonization and extinction. Our study demonstrated that N and water addition influenced different aspects of plant community structure. Water addition increased plant species richness by preventing species extinction and facilitating species colonization, without altering community phylogenetic structure. In contrast, N addition did not alter species richness, but promoted the colonization of species distantly related to the residents, changing community phylogenetic structure from being neutral to overdispersion. We also found evidence for abundance‐based extinction where rarer species were at greater risk of extinction, and functional trait‐based species extinction where shorter statured plants and shallower rooted plants were at greater risk of extinction. Synthesis. Our study provides the first experimental evidence that plant phylogenetic community structure responds differently to different aspects of global changes. Importantly, the colonization of non‐resident species, rather than the extinction of resident species, contributed predominantly to changes in plant community phylogenetic structure in response to N amendment. Our findings highlight the importance of considering species phylogenetic relationships for a more complete understanding of anthropogenic influences on ecological communities.

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Section: Discussionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

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Nitrogen fertilization, not water addition, alters plant phylogenetic community structure in a semi‐arid steppe

Yang

Tan

et al. 2017

Journal of Ecology

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“…In contrast to the rainout shelter‐induced decrease in species richness, our water addition treatment did not alter productivity, yet increased species richness. A recent meta‐analysis of 41 grassland experiments (involving a wide range of climatic and soil environments) reported no statistically significant effect of water addition on species richness (DeMalach et al., ). However, two other experiments in temperate‐mesic old‐field vegetation also found that species richness was increased by water addition (Sternberg, Brown, Masters, & Clarke, ; Stevens, Shirk, & Steiner, ).…”

Section: Discussionmentioning

confidence: 99%

“…These studies used a wide variety of experimental designs (e.g., some with just added water, just reduced water, or both, and some also included nutrient fertilizer treatments), variable durations of treatment applications (one year vs. multi‐year), and sites from a wide range of climatic zones, soil types, and vegetation successional stages — including forest, shrubland, grassland, tundra, desert and agricultural fields. Not surprisingly, therefore, it is difficult to make meaningful comparisons of results between studies, and to draw overall conclusions (Beier et al., ; DeMalach et al., ; Hoover, Wilcox, & Young, ; Knapp et al., ; Wu et al., ).…”

Section: Introductionmentioning

confidence: 99%

Summer precipitation limits plant species richness but not overall productivity in a temperate mesic old‐field meadow

Serafini

Grogan

Aarssen

2019

J Vegetation Science

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Question Water availability is a primary regulator of plant productivity and species richness in arid and semi‐arid ecosystems, but its influence in other habitats is much less clear partly because experimental manipulations of water are relatively rare. How important is soil moisture availability relative to other key environmental factors in determining plant species biomass and diversity in temperate mesic grasslands? Location An old‐field meadow in southeastern Ontario, Canada. Methods We established a long‐term factorial field experiment to investigate how variation in soil water (achieved by rainout shelters and water additions), nutrients (NPK fertilizer additions), and above‐ground herbivory (deer fence exclosures), interact as regulators of plant production, species richness, and species composition. Above‐ground biomass for each species was determined in replicate plots (1 m2, n = 10) after five years of treatment applications. Results The rainout shelters reduced community shoot biomass by 35% relative to ambient (control) plots, with no influence of the fertiliser. To our surprise, however, the fertiliser enhanced community biomass in the ambient and water addition plots to a similar extent. Species richness and Shannon diversity were increased by water addition, but reduced by the rainout shelters and by fertilisation. Total species richness across all replicate plots was 60% higher in the water addition treatment, and almost halved in the water‐reduced treatment. In contrast to the above, the exclosures had negligible impacts on these community variables. Conclusions Together, these results suggest that in old‐field meadow grasslands: (a) shoot productivity is primarily limited by soil nutrient supply except under drought conditions when water availability becomes the primary constraint; (b) the two main soil resources for plants — water and nutrients — affect productivity and species richness/composition in fundamentally different ways; and (c) future increases in summer soil aridity and anthropogenic nitrogen deposition may interact to reduce vegetation productivity and diversity in temperate mesic ecosystems.

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Water availability modifies productivity response to biodiversity and nitrogen in long‐term grassland experiments

Kazanski

Cowles

Dymond

et al. 2021

Ecological Applications

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Diversity and nitrogen addition have positive relationships with plant productivity, yet climate‐induced changes in water availability threaten to upend these established relationships. Using long‐term data from three experiments in a mesic grassland (ranging from 17 to 34 yr of data), we tested how the effects of species richness and nitrogen addition on community‐level plant productivity changed as a function of annual fluctuations in water availability using growing season precipitation and the Standardized Precipitation‐Evapotranspiration Index (SPEI). While results varied across experiments, our findings demonstrate that water availability can magnify the positive effects of both biodiversity and nitrogen addition on productivity. These results suggest that productivity responses to anthropogenic species diversity loss and increasing nitrogen deposition could depend on precipitation regimes, highlighting the importance of testing interactions between multiple global change drivers.

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Contrasting effects of water and nutrient additions on grassland communities: A global meta‐analysis

Cited by 60 publications

References 58 publications

Nitrogen fertilization, not water addition, alters plant phylogenetic community structure in a semi‐arid steppe

Nitrogen fertilization, not water addition, alters plant phylogenetic community structure in a semi‐arid steppe

Summer precipitation limits plant species richness but not overall productivity in a temperate mesic old‐field meadow

Water availability modifies productivity response to biodiversity and nitrogen in long‐term grassland experiments

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