Annals of Botany 84: 279-288, 1999
© 1999 Annals of Botany Company
Growth Responses of C4Grasses of Contrasting Origin to Elevated CO2
Department of Biology, University of Missouri-St. Louis, 8001 Natural Bridge Road, St. Louis, MO, 63121, USA Clark Science Center, Smith College, Northampton, MA, 01063, USA Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, Massachusetts, 02138, USA
November 10, 1998 ; December 18, 1998 . April 14, 1999
Nine grass species representing three independent origins of the C4photosynthetic pathway were grown at ambient (350 ppm) and elevated (700 ppm) CO2and were harvested after flowering. Setaria andArundinella are both members of the subfamily Panicoideae, and represent a single origin of the pathway. Aristida and Stipagrostis are sister genera in the subfamily Aristidoideae (formerly classified in subfamily Arundinoideae), and represent a second origin. Sporobolus, a member of the subfamily Chloridoideae, represents the third. By investigating two genera each within Panicoideae and Aristidoideae, we test the hypothesis that genera sharing the same origin of C4respond similarly. To explore variation among congeneric species, five species of Setaria were also examined to test the hypothesis that congeneric species have similar responses. Plant height and numbers of tillers, branches and inflorescences were measured, both over time and at final harvest. Biomass of roots, shoots, and inflorescences was also measured. Members of the Aristidoideae were generally significantly larger in elevated CO2, as indicated by measurements of biomass and plant height, whereas representatives of the Panicoideae varied considerably in their response. The two subfamilies differed significantly in their responses to elevated CO2and this effect outweighed any effect of CO2alone.Sporobolus, though equally distantly related to Panicoideae and Aristidoideae, had a CO2response similar to that of some panicoid species. Even within the genus Setaria, some species were significantly smaller at elevated than at ambient CO2, whereas others were larger. This may reflect diversity in internal regulation rather than acclimation or changes in source-sink allocation of carbon. The variation complicates any prediction of responses of C4plants to future atmospheric change. Comparison of closely related species, however, may well lead to intriguing new insights into how regulatory pathways of CO2assimilation are modified during evolution. Copyright 1999 Annals of Botany Company
Aristida, Arundinella, C4photosynthesis, CO2, global change, Poaceae,Setaria , Sporobolus, Stipagrostis.