The consequences of elevated CO2 on plant growth have been well studied on
individual plants. The response of a more complex system with several plant
s interacting is less understood-a situation that limits our capacity to pr
edict the response of natural plant communities. In this study we analyzed
the effect of CO2 enrichment on intergenotypic competition in Arabidopsis t
haliana. Seeds of five: genotypes collected from different natural populati
ons were used. Each genotype was cultivated in a pure stand and in a mixtur
e with each of the other four genotypes in two CO2 conditions (ambient and
elevated). At harvest time, genotype fitness was estimated by the number of
fruits and seeds produced per plant. At current levels of CO2, genotypes p
erformed better in a pure stand than in a mixture. Kin selection, associate
d with the low seed dispersal and autogamous reproductive regime of A. thal
iana, is invoked to explain these positive responses among plants of simila
r genotype. Surprisingly, in a high-CO2 atmosphere (700 muL/L) the reverse
situation was observed: plants performed better in mixtures than in pure st
ands. Positive frequency dependent selection under ambient CO2 concentratio
n became negative under elevated CO2, which could lead more easily to the m
aintenance of genetic variation. This hypothesis was tested with a simple m
odel of competition. At equilibrium, the simulation did not show coexistenc
e among more genotypes under elevated CO2 than under ambient CO2 concentrat
ion. However, this study allows predictions about evolutionary trajectories
under high CO2 conditions. In A. thaliana, genotypes that will maintain th
e most their ability to grow well in pure stand should be selected under in
creasing CO2.