Our understanding of the effects of elevated atmospheric CO 2 , singly and in combination with other environmental changes, on plant-soil interactions is incomplete. Elevated CO 2 effects on C 4 plants, though smaller than on C 3 species, are mediated mostly via decreased stomatal conductance and thus water loss. Therefore, we characterized the interactive effect of elevated CO 2 and drought on soil microbial communities associated with a dominant C 4 prairie grass, Andropogon gerardii Vitman. Elevated CO 2 and drought both affected resources available to the soil microbial community. For example, elevated CO 2 increased the soil C:N ratio and water content during drought, whereas drought alone decreased both. Drought significantly decreased soil microbial biomass. In contrast, elevated CO 2 increased biomass while ameliorating biomass decreases that were induced under drought. Total and active direct bacterial counts and carbon substrate use (overall use and number of used sources) increased significantly under elevated CO 2 . Denaturing gradient gel electrophoresis analysis revealed that drought and elevated CO 2 , singly and combined, did not affect the soil bacteria community structure. We conclude that elevated CO 2 alone increased bacterial abundance and microbial activity and carbon use, probably in response to increased root exudation. Elevated CO 2 also limited drought-related impacts on microbial activity and biomass, which likely resulted from decreased plant water use under elevated CO 2 . These are among the first results showing that elevated CO 2 and drought work in opposition to modulate plant-associated soil-bacteria responses, which should then influence soil resources and plant and ecosystem function.Key words: denaturing gradient gel electrophoresis; drought; elevated CO 2 ; soil microbial communities. During the last nine decades, the atmospheric concentration of CO 2 has increased by 36%, primarily as a result of anthropogenic activities (IPCC 2007). Increased atmospheric CO 2 concentration and related environmental changes (e.g. warming and decreased/increased precipitation) can influence the biological processes of plants and soil microorganisms inhabiting diverse ecosystems (Zak et al. 1993(Zak et al. , 2000 Kandeler et al. 1998 C 3 and C 4 photosynthetic metabolism, though photosynthetic and growth increases are generally larger in C 3 species (e.g., Sage and Monson 1999; Ehleringer et al. 2002;Wang et al. 2008 and references therein). In C 3 species, increased growth under elevated CO 2 is primarily due to decreased photorespiration (photosynthetic fixation of O 2 rather than CO 2 ), while in C 4 species, increased growth under elevated CO 2 is primarily due to decreased stomatal conductance and transpiration, which decreases soil water use (this also occurs in C 3 species).As with most terrestrial ecosystems, grasslands will be impacted by future global environmental and climate changes, including elevated CO 2 (Fay et al. 2003), and this will have importance to the global eco...
