TY - JOUR
T1 - Root stress and nitrogen deposition
T2 - Consequences and research priorities
AU - Smithwick, Erica A.H.
AU - Eissenstat, David M.
AU - Lovett, Gary M.
AU - Bowden, Richard D.
AU - Rustad, Lindsey E.
AU - Driscoll, Charles T.
PY - 2013/2
Y1 - 2013/2
N2 - Stress within tree roots may influence whole-tree responses to nutrient deficiencies or toxic ion accumulation, but the mechanisms that govern root responses to the belowground chemical environment are poorly quantified. Currently, root production is modeled using rates of forest production and stoichiometry, but this approach alone may be insufficient to forecast variability in forest responses when physical and chemical stressors alter root lifespan, rooting depth or mycorrhizal colonization directly. Here, we review key research priorities for improving predictions of tree responses to changes in the belowground biogeochemical environment resulting from nitrogen deposition, including: limits of the optimum allocation paradigm, root physiological stress and lifespan, contingency effects that determine threshold responses across broad gradients, coupled water-biogeochemical interactions on roots, mycorrhizal dynamics that mediate root resilience and model frameworks to better simulate root feedbacks to aboveground function. We conclude that models incorporating physiological feedbacks, dynamic responses to coupled stressors, mycorrhizal interactions, and which challenge widely-accepted notions of optimum allocation, can elucidate potential thresholds of tree responses to biogeochemical stressors. Emphasis on comparative studies across species and environmental gradients, and which incorporates insights at the cellular and ecosystem level, is critical for forecasting whole-tree responses to altered biogeochemical landscapes.
AB - Stress within tree roots may influence whole-tree responses to nutrient deficiencies or toxic ion accumulation, but the mechanisms that govern root responses to the belowground chemical environment are poorly quantified. Currently, root production is modeled using rates of forest production and stoichiometry, but this approach alone may be insufficient to forecast variability in forest responses when physical and chemical stressors alter root lifespan, rooting depth or mycorrhizal colonization directly. Here, we review key research priorities for improving predictions of tree responses to changes in the belowground biogeochemical environment resulting from nitrogen deposition, including: limits of the optimum allocation paradigm, root physiological stress and lifespan, contingency effects that determine threshold responses across broad gradients, coupled water-biogeochemical interactions on roots, mycorrhizal dynamics that mediate root resilience and model frameworks to better simulate root feedbacks to aboveground function. We conclude that models incorporating physiological feedbacks, dynamic responses to coupled stressors, mycorrhizal interactions, and which challenge widely-accepted notions of optimum allocation, can elucidate potential thresholds of tree responses to biogeochemical stressors. Emphasis on comparative studies across species and environmental gradients, and which incorporates insights at the cellular and ecosystem level, is critical for forecasting whole-tree responses to altered biogeochemical landscapes.
KW - Allocation
KW - Aluminum (Al)
KW - Drought
KW - Model
KW - Nitrogen deposition
KW - Root biogeochemical stress
KW - Root lifespan
KW - Threshold
UR - http://www.scopus.com/inward/record.url?scp=84872160382&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84872160382&partnerID=8YFLogxK
U2 - 10.1111/nph.12081
DO - 10.1111/nph.12081
M3 - Review article
C2 - 23418632
AN - SCOPUS:84872160382
SN - 0028-646X
VL - 197
SP - 712
EP - 719
JO - New Phytologist
JF - New Phytologist
IS - 3
ER -