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Article Abstract
Grasses are exceptionally productive, yet their hydraulic adaptation is paradoxical. Among C grasses, a high photosynthetic rate (A) may depend on higher vein density (D) and hydraulic conductance (K). However, the higher D of C grasses suggests a hydraulic surplus, given their reduced need for high K resulting from lower stomatal conductance (g). Combining hydraulic and photosynthetic physiological data for diverse common garden C and C species with data for 332 species from the published literature, and mechanistic modeling, we validated a framework for linkages of photosynthesis with hydraulic transport, anatomy, and adaptation to aridity. C and C grasses had similar K in our common garden, but C grasses had higher K than C species in our meta-analysis. Variation in K depended on outside-xylem pathways. C grasses have high K : g, which modeling shows is essential to achieve their photosynthetic advantage. Across C grasses, higher A was associated with higher K, and adaptation to aridity, whereas for C species, adaptation to aridity was associated with higher K : g. These associations are consistent with adaptation for stress avoidance. Hydraulic traits are a critical element of evolutionary and ecological success in C and C grasses and are crucial avenues for crop design and ecological forecasting.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11798900 | PMC |
| http://dx.doi.org/10.1111/nph.20341 | DOI Listing |
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