Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Abstract: Elevated atmospheric carbon dioxide (eCO2) concentrations and nitrogen (N) enrichment are known to enhance plant productivity and invasion. However, the implications of their interactive effects for plant productivity are not well understood, especially at the stand scale, presumably because morphological and physiological responses to these global change factors are rarely studied together in the field or assessed at the stand level. We first determined how leaf‐level morphological and physiological traits re… Show more

“…We did not expect eCO 2 to alter stomatal length, as this has not been observed in other studies (e.g., Haworth et al, 2013), except for those encompassing evolutionary to geologic timescales (Franks et al, 2009). We expected eCO 2 and N enr to have an additive effect on photosynthetic CO 2 assimilation, as previously demonstrated (e.g., Mozdzer and Caplan, 2018). Finally, under the assumption that changes to stomatal morphology underlie P. australis ’ growth responses to global change, we expected eCO 2 and N enr to have similarly additive effects on relationships between stomatal characteristics, maximal stomatal conductance, and photosynthesis.…”

“…Despite the key role of stomata in mediating gas exchange, prior studies have not connected stomatal morphology of P. australis directly to its strong physiological response to eCO 2 and N enr . For example, Mozdzer and Caplan (2018) reported eCO 2 and N enr effects on stomatal characteristics and rates of photosynthesis but did not examine the relationship between them.…”

Responses of stomatal features and photosynthesis to porewater N enrichment and elevated atmospheric CO₂inPhragmites australis, the common reed

“…We did not expect eCO 2 to alter stomatal length, as this has not been observed in other studies (e.g., Haworth et al, 2013), except for those encompassing evolutionary to geologic timescales (Franks et al, 2009). We expected eCO 2 and N enr to have an additive effect on photosynthetic CO 2 assimilation, as previously demonstrated (e.g., Mozdzer and Caplan, 2018). Finally, under the assumption that changes to stomatal morphology underlie P. australis ’ growth responses to global change, we expected eCO 2 and N enr to have similarly additive effects on relationships between stomatal characteristics, maximal stomatal conductance, and photosynthesis.…”

“…Despite the key role of stomata in mediating gas exchange, prior studies have not connected stomatal morphology of P. australis directly to its strong physiological response to eCO 2 and N enr . For example, Mozdzer and Caplan (2018) reported eCO 2 and N enr effects on stomatal characteristics and rates of photosynthesis but did not examine the relationship between them.…”

Responses of stomatal features and photosynthesis to porewater N enrichment and elevated atmospheric CO₂inPhragmites australis, the common reed

“…, van Kleunen et al. , Mozdzer and Caplan ), but the strong aboveground bias has meant that inferences do not necessarily encompass the full range of trait‐mediated dynamics. Investigations focusing on root traits explicitly could therefore yield additional insight into the means by which belowground foraging strategies influence species dynamics.…”

Fine‐root traits are linked to species dynamics in a successional plant community

“…However, several or even most impacts are likely mediated through physiological mechanisms such as stress responses to perceived predation threats by invasive predators (Preisser and Bolnick ), reductions in food resources in the presence of invasive competitors (Lennox et al. ), and changes in energetic demands triggered by invasion‐mediated alterations of an organism's physical environment (increased shade, denser vegetation, increasing salinity; e.g., Funk , Mozdzer and Caplan ). These stress responses precede population declines in many instances, potentially providing a way to assess the impacts of invasive species mechanistically across multiple spatial and biological scales, and such responses may also provide an opportunity for managers to preemptively intervene and avoid negative impacts.…”

Toward “Rules” for Studying Biological Invasions