Abstract
Plants growing in dense stands may not equally acquire or utilize extra carbon gained in elevated CO2. As a result, reproductive differences between dominant and subordinate plants may be altered under rising CO2 conditions. We hypothesized that elevated CO2 would enhance the reproductive allocation of shaded, subordinate Ambrosia artemisiifolia L. (Asteraceae) individuals more than that of light-saturated dominants. We grew stands of A. artemisiifolia at either 360 or 720 μL L−1 CO2 levels and measured the growth and reproductive responses of competing individuals. To test whether elevated CO2 altered size and reproductive inequalities within stands, we compared stand-level coefficients of variation (CV) in height growth and final shoot, root, and reproductive organ biomasses. Elevated CO2 enhanced biomass and reduced the CV for all aspects of plant growth, especially reproductive biomass. Allocation to reproduction was higher in the elevated CO2 than in the ambient treatment, and this difference was more pronounced in small, rather than large plant positive relationships between the CV and total stand productivity declined under elevated CO2, indicating that growth enhancements to smaller plants diminished the relative biomass advantages of larger plants in increasingly crowded conditions. We conclude that elevated CO2 stimulates stand-level reproduction while CO2-induced growth gains of subordinate A. artemisiifolia plants minimize differences in the reproductive output of small and large plants. Thus, more individuals are likely to produce greater amounts of seeds and pollen in future populations of this allergenic weed.
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Acknowledgements
The authors gratefully acknowledge D. Ackerly, A. Ellison, J. Hadley, T. Seidler, and two anonymous reviewers for comments on the manuscript; R. Stomberg for technical assistance; and B. DeGasperis, J. Petzold, and J. Tran for outstanding research assistance. Logistical support was provided by Harvard University’s Concord Field Station and the Harvard Forest. We also thank I. Stinson and BDG for editorial assistance. This research was funded by NSF Grant#9983079 to FAB. The experiments comply with current US laws governing biological research.
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Stinson, K.A., Bazzaz, F.A. CO2 enrichment reduces reproductive dominance in competing stands of Ambrosia artemisiifolia (common ragweed). Oecologia 147, 155–163 (2006). https://doi.org/10.1007/s00442-005-0250-x
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DOI: https://doi.org/10.1007/s00442-005-0250-x