ID:
publications-1807
Type:
Peer reviewed articles
Year:
2020
Authors:
Han Wang, Owen K. Atkin, Trevor F. Keenan, Nicholas G. Smith, Ian J. Wright, Keith J. Bloomfield, Jens Kattge, Peter B. Reich, I. Colin Prentice
Title:
Acclimation of leaf respiration consistent with optimal photosynthetic capacity
Venue/Journal:
Global Change Biology
DOI:
10.1111/gcb.14980
Research type:
Uncategorized
Water System:
River Basins
Technical Focus:
Abstract:
AbstractPlant respiration is an important contributor to the proposed positive global carbonâcycle feedback to climate change. However, as a major component, leaf mitochondrial (âdarkâ) respiration (Rd) differs among species adapted to contrasting environments and is known to acclimate to sustained changes in temperature. No accepted theory explains these phenomena or predicts its magnitude. Here we propose that the acclimation of Rd follows an optimal behaviour related to the need to maintain longâterm average photosynthetic capacity (Vcmax) so that available environmental resources can be most efficiently used for photosynthesis. To test this hypothesis, we extend photosynthetic coâordination theory to predict the acclimation of Rd to growth temperature via a link to Vcmax, and compare predictions to a global set of measurements from 112 sites spanning all terrestrial biomes. This extended coâordination theory predicts that fieldâmeasured Rd and Vcmax accessed at growth temperature (Rd,tg and Vcmax,tg) should increase by 3.7% and 5.5% per degree increase in growth temperature. These acclimated responses to growth temperature are less steep than the corresponding instantaneous responses, which increase 8.1% and 9.9% per degree of measurement temperature for Rd and Vcmax respectively. Dataâfitted responses proof indistinguishable from the values predicted by our theory, and smaller than the instantaneous responses. Theory and data are also shown to agree that the basal rates of both Rd and Vcmax assessed at 25°C (Rd,25 and Vcmax,25) decline by ~4.4% per degree increase in growth temperature. These results provide a parsimonious general theory for Rd acclimation to temperature that is simplerâand potentially more reliableâthan the plant functional typeâbased leaf respiration schemes currently employed in most ecosystem and landâsurface models.
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