Response of an Arabidopsis mutant to elevated CO2 concentration
HAO Lin1, XU Xin1, CAO Jun2
1. Department of Environmental Science, Shenyang Normal University, Shenyang 110034, China; 2. Institute of Applied Ecology, Chinese Acedemy of Sciences, Shenyang 110016, China
HAO Lin, XU Xin, CAO Jun. Response of an Arabidopsis mutant to elevated CO2 concentration[J]. Chinese Journal of Applied Ecology, 2003, (12): 2359-2360.
[1] Chen LQ, Hu CY, Gaboury L, et al. 2001. Assessing the potential for the stomatal characters of extant and fossil Ginkgo leaves to signal atmospheric CO2 change. Am J Bot, 88:1309~1315 [2] DeLucia EH, Hamilton JG, Naidu SL, et al. 1999. Net primary production of a forest ecosystem with experimental CO2 enrichment.Science, 284:1177~1179 [3] Gray JE, Holroyd GH, van der Lee FM, et al. 2000. The HIC signalling pathway links CO2 perception to stornatal development. Nature,408:713~716 [4] Hao L (郝林). 1999. Arabidopsis-An excellent experimental material for plant developmental biology and molecular biology.PlantPhysiolCommu(植物生理通讯),35(3):218~220(inChinese) [5] Hu S, Chapin Ⅲ, Firestone H, et al. 2001. Nitrogen limitation of microbial decomposition in a grassland under elevated CO2. Nature,409:188~191 [6] Jones TH, Thompson LJ, Lawton JH, et al. 1998. Impacts of rising atmospheric car:bon dioxide on model terrestrialecosystems. Science, 280: 441~443 [7] LaDesu SL, Clark JS. 2001. Rising CO2 levels and the fecundity of forest trees. Science, 292: 95~98 [8] Tangley L. 2001. High CO2 levels may give fast-growing trees an edge. Science, 292: 36~37 [9] Woodward FI. 1987. Stomatal numbers are sensitive to CO2 increases from pre-industrial levels. Nature, 327: 617~618 [10] Woodward FI and Kelly CK. 1995. The influence of CO2 concentration on stomatal density. New Phytol, 131:311~327 [11] Zhang Z-L(张志良). 1990. Experimental Guide of Plant Physiology. Beijing: Higher Education Press. (in Chinese)