Cascading effects of induced terrestrial plant defences on aquatic and terrestrial ecosystem function

Jackrel, Sara L.; Wootton, J. Timothy

doi:10.1098/rspb.2014.2522

Cited by 28 publications

(34 citation statements)

References 55 publications

(77 reference statements)

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“…We found ellagitannin, diarylheptanoid and flavonoid variation were all correlated with leaf traits, such as thickness and nutrients that are well-known to affect consumers (Coley 1980, Mattson 1980, Jackrel and Wootton 2015. But our results from both leaf pack and diet experiments suggest ellagitannin content is a greater predictor of ecosystem processes than nutrients (Appendix S2: Table S4), and therefore warrants further study into plant production pathways of these compounds and the ecological implications of relative nutrient vs. defense compound content in red alder and other plants.…”

Section: Discussionmentioning

confidence: 82%

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Intraspecific leaf chemistry drives locally accelerated ecosystem function in aquatic and terrestrial communities

Jackrel

Morton

Wootton

2016

Ecology

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Resource patchiness influences consumer foraging, movement, and physiology. Fluxes across ecosystem boundaries can extend these effects to otherwise distinct food webs. Intraspecific diversity of these cross-ecosystem subsidies can have large consequences for recipient systems. Here, we show intraspecific variation in leaf defensive chemistry of riparian trees drives local adaptation among terrestrial and riverine decomposers that consume shed leaf litter. We found extensive geographic structuring of ellagitannins, diarylheptanoids, and flavonoids in red alder trees. Ellagitannins, particularly those with strong oxidative activity, drive aquatic leaf decomposition. Further, spatial variation in these leaf components drives local ecological matching: in experiments using artificial food sources distinguished only by the chemical content of individual trees, we found decomposers both on land and in rivers more quickly consumed locally derived food sources. These results illustrate that terrestrial processes can change the chemistry of cross-ecosystem subsidies in ways that ultimately alter ecosystem function in donor and recipient systems.

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Section: Discussionmentioning

confidence: 82%

“…To measure phosphorus we used an ashing, acid-hydrolysis, and phosphomolybdate-blue spectrophotometric protocol (Jackrel and Wootton 2015). The reproducibility was 0.11‰ for 13 C and 0.17‰ for 15 N, and cocoa powder and glutamic acid were used as isotopic controls.…”

Section: Cnp Measurementsmentioning

confidence: 99%

Intraspecific leaf chemistry drives locally accelerated ecosystem function in aquatic and terrestrial communities

Jackrel

Morton

Wootton

2016

Ecology

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“…This was not an issue in our experiment as leaves were placed above the bankfull edge of the stream and received water only via a watering can or precipitation. Alder leaves are a common target of herbivorous insects (Jackrel and Wootton 2015), and with a high N content and specific leaf area, alder leaf litter is an easily accessible and nutritious resource for detritivorous invertebrates and microbes (Zukswert and Prescott 2017). Water can promote mass loss by leaching, and in red alder, this can be significant; Zukswert and Prescott (2017) saw a leaching mass loss of about 10% from red alder leaves when placed in a forest within Vancouver, BC.…”

Section: Discussionmentioning

confidence: 99%

Experimental test of water, nutrients, and microclimate on leaf litter mass loss in headwater riparian forests

Ramey

Richardson

2018

Ecosphere

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Leaf litter decomposition is an essential function in forest ecosystems, and riparian areas may contribute to faster rates of litter mass loss due to higher moisture and nutrient levels in riparian than upland soils. We experimentally tested whether mass loss of red alder leaf litter was (1) greater closer to the stream than further away and (2) increased by nutrient and water additions in riparian habitat near four headwater streams in southwestern British Columbia. We set up blocks of nine transects extending from the bankfull edge of the stream into upland habitat. Leaf litter bags were placed at 1, 5, 10, 20, and 40 m from the stream along each transect, and data loggers recorded ambient air temperature and relative humidity at each distance. Litterbags received either water or fertilizer additions, both, or neither along each transect. Four trials were run which varied in duration (3 months to 1 yr). Relative humidity was on average 2.6% higher, air temperature 0.25°C lower, and vapor pressure deficit 0.14 kPa lower at 1 m from the stream compared to distances further upland. The addition of water significantly increased litter mass loss by 0.14 g (4%) on average than control litterbags. The addition of fertilizer was a significant factor in some trials but not in others, and its effect on mass loss varied. Although distance from the stream was not a significant parameter in the averaged models for each trial, it was in several top models. We conclude that (1) riparian communities within 1 m of the stream experience a different microclimate during the warmer, drier summer than those communities further upland, though this was not generally reflected in alder mass loss rates, and (2) water was a primary limiting factor to alder leaf mass loss in our study sites.

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“…The majority of these inputs are comprised of senesced, uneaten plant-litter, roots, and root exudates (Cebrian, 2004;Pollierer et al, 2007;Pangesti et al, 2013;Jackrel and Wootton, 2015). Thus, it is widely assumed that herbivores primarily affect the way SFWs regulate biogeochemical processes by altering the quantity and quality of plant-derived organics inputs to soils (Bardgett and Wardle, 2010).…”

Section: Main Textmentioning

confidence: 98%

Fear and below-ground food-webs

Hawlena

Zaguri

2016

Soil Biology and Biochemistry

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Cascading effects of induced terrestrial plant defences on aquatic and terrestrial ecosystem function

Cited by 28 publications

References 55 publications

Intraspecific leaf chemistry drives locally accelerated ecosystem function in aquatic and terrestrial communities

Intraspecific leaf chemistry drives locally accelerated ecosystem function in aquatic and terrestrial communities

Experimental test of water, nutrients, and microclimate on leaf litter mass loss in headwater riparian forests

Fear and below-ground food-webs

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