Abstract
Aboveground growth of C4plants responds more strongly to atmospheric CO2 concentration when soil water is limiting rather than abundant. Whether the same is true of root growth and morphology, however, remains to be evaluated. We investigated interactive effects of CO2 and soil water on root growth and morphology of two C4 grasses. Seedlings of the dominant C4 grasses from tallgrass prairie, Schizachyrium scoparium and Andropogon gerardii, were grown for 8 weeks in an elongated, controlled environment chamber at CO2 concentrations of 368 (ambient) and 203 (subambient) μmol mol−1. Seedlings were maintained at either high (ca. 90%) or low (ca. 50%) soil relative water holding capacity (RWC). Both root and shoot systems of C4 grass seedlings responded similarly to CO2 enrichment irrespective of whether soil water was limiting or abundant. Root growth was affected primarily by increased RWC (40–51% increases) and secondarily by higher CO2 (15–27% increases). The relative distribution of root surface area, number of root tips and length and volume of roots were significantly affected by CO2 enrichment with proportional increases of 55–61%, 39-52%, 50–55% and 53–58%, respectively, occurring in very fine (0–0.3 mm) roots. The indirect effect of CO2 enrichment on conservation of soil water in grasslands may be as important as direct photosynthetic response effects in the CO2-induced enhancement of whole-plant growth in C4 grasses.
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Derner, J., Polley, H., Johnson, H. et al. Root system response of C4 grass seedlings to CO2 and soil water. Plant and Soil 231, 97–104 (2001). https://doi.org/10.1023/A:1010306720328
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DOI: https://doi.org/10.1023/A:1010306720328