Traits that distinguish dominant species across aridity gradients differ from those that respond to soil moisture

• Published in: Oecologia Vol. 201; no. 2; pp. 311 - 322
• Main Authors: Griffin-Nolan, Robert J., Felton, Andrew J., Slette, Ingrid J., Smith, Melinda D., Knapp, Alan K.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.02.2023; Springer; Springer Nature B.V
• Subjects: Aridity; Availability; Biomass; Biomedical and Life Sciences; Dominant species; Ecology; Ecosystem; Ecosystems; Grasses; Grasslands; Hydrology/Water Resources; Leaves; Life Sciences; Moisture effects; Moisture resistance; Morphology; Net Primary Productivity; Physiological Ecology–Original Research; Plant Leaves - physiology; Plant Sciences; Poaceae - physiology; Prairies; Primary production; Soil; Soil moisture; Soil resistance; Turgor; Water; Water - physiology; Water availability; Water potential; Root traits; Leaf hydraulics; Grass; Drought; Primary production
• ISSN: 0029-8549; 1432-1939
• DOI: 10.1007/s00442-023-05315-y

Many plant traits respond to changes in water availability and might be useful for understanding ecosystem properties such as net primary production (NPP). This is especially evident in grasslands where NPP is water-limited and primarily determined by the traits of dominant species. We measured root and shoot morphology, leaf hydraulic traits, and NPP of four dominant North American prairie grasses in response to four levels of soil moisture in a greenhouse experiment. We expected that traits of species from drier regions would be more responsive to reduced water availability and that this would make these species more resistant to low soil moisture than species from wetter regions. All four species grew taller, produced more biomass, and increased total root length in wetter treatments. Each species reduced its leaf turgor loss point (TLP) in drier conditions, but only two species (one xeric, one mesic) maintained leaf water potential above TLP. We identified a suite of traits that clearly distinguished species from one another, but, surprisingly, these traits were relatively unresponsive to reduced soil moisture. Specifically, more xeric species produced thinner roots with higher specific root length and had a lower root mass fraction. This suggest that root traits are critical for distinguishing species from one another but might not respond strongly to changing water availability, though this warrants further investigation in the field. Overall, we found that NPP of these dominant grass species responded similarly to varying levels of soil moisture despite differences in species morphology, physiology, and habitat of origin.