Thilakarathne Chamindathee L, Tausz-Posch Sabine, Cane Karen, Norton Robert M, Tausz Michael, Seneweera Saman
Department of Agriculture and Food Systems, Melbourne School of Land and Environment, The University of Melbourne, Private Box 260, Horsham, Vic. 3400, Australia.
Department of Primary Industries, Horsham, Vic. 3400, Australia.
Funct Plant Biol. 2013 Mar;40(2):185-194. doi: 10.1071/FP12057.
In order to investigate the underlying physiological mechanism of intraspecific variation in plant growth and yield response to elevated CO2 concentration [CO2], seven cultivars of spring wheat (Triticum aestivum L.) were grown at either ambient [CO2] (~384μmolmol-1) or elevated [CO2] (700μmolmol-1) in temperature controlled glasshouses. Grain yield increased under elevated [CO2] by an average of 38% across all seven cultivars, and this was correlated with increases in both spike number (productive tillers) (r=0.868) and aboveground biomass (r=0.942). Across all the cultivars, flag leaf photosynthesis rate (A) increased by an average of 57% at elevated [CO2]. The response of A to elevated [CO2] ranged from 31% (in cv. H45) to 75% (in cv. Silverstar). Only H45 showed A acclimation to elevated [CO2], which was characterised by lower maximum Rubisco carboxylation efficiency, maximum electron transport rate and leaf N concentration. Leaf level traits responsible for plant growth, such as leaf mass per unit area (LMA), carbon (C), N content on an area basis ([N]LA) and the C:N increased at elevated [CO2]. LMA stimulation ranged from 0% to 85% and was clearly associated with increased [N]LA. Both of these traits were positively correlated with grain yield, suggesting that differences in LMA play an important role in determining the grain yield response to elevated [CO2]. Thus increased LMA can be used as a new trait to select cultivars for a future [CO2]-rich atmosphere.
为了探究植物生长和产量对二氧化碳浓度升高([CO₂])种内变异的潜在生理机制,在温度可控的温室中,将七个春小麦(Triticum aestivum L.)品种种植于环境[CO₂](约384μmol·mol⁻¹)或升高的[CO₂](700μmol·mol⁻¹)条件下。在升高的[CO₂]条件下,所有七个品种的谷物产量平均增加了38%,这与穗数(有效分蘖)增加(r = 0.868)和地上生物量增加(r = 0.942)相关。在所有品种中,旗叶光合速率(A)在升高的[CO₂]条件下平均增加了57%。A对升高的[CO₂]的响应范围为31%(品种H45)至75%(品种Silverstar)。只有H45表现出A对升高的[CO₂]的适应性,其特征是最大羧化效率、最大电子传递速率和叶片氮浓度较低。与植物生长相关的叶片水平性状,如单位面积叶质量(LMA)、碳(C)、基于面积的氮含量([N]LA)和C:N在升高的[CO₂]条件下增加。LMA的增幅范围为0%至85%,且与[N]LA的增加明显相关。这两个性状均与谷物产量呈正相关,表明LMA的差异在决定谷物产量对升高的[CO₂]的响应中起重要作用。因此,增加的LMA可作为一个新性状,用于选择适合未来高[CO₂]大气环境的品种。