Lucia Evan H De, Whitehead David, Clearwater Michael J
University of Illinois, Department of Plant Biology and Program in Ecology and Evolutionary Biology, Urbana, IL 61801, USA. Corresponding author; email;
Landcare Research, PO Box 69, Lincoln 8152, New Zealand.
Funct Plant Biol. 2003 Jan;30(12):1197-1204. doi: 10.1071/FP03141.
The capacity to conduct CO from the intercellar spaces in leaves to the site of fixation (mesophyll conductance, g) may pose a significant limitation to photosynthesis. Dacrydium cupressinum Sol. ex Lamb. (rimu), a native conifer of New Zealand, and other members of the Podocarpaceae evolved during the Jurassic when the partial pressure of CO exceeded 200 Pa. This species has low rates of photosynthesis and high levels of leaf nitrogen, which have led to the hypothesis that low g restricts photosynthesis. Mesophyll conductance was estimated from gas-exchange and fluorescence measurements for this and other co-occurring tree species [Prumnopitys ferruginea D.Don (miro), Weinmannia racemosa L.f. (kāmahi), Meterosideros umbellata Cav. (rata)]. Pinus radiata D. Don (radiata pine) and Phaseolus vulgaris L. (bean) were included to provide comparisons with a rapidly growing tree and herbaceous plant with relatively high photosynthetic rates. Mesophyll conductance was not statistically different among indigenous tree species but was lowest for D. cupressinum. This species also had the lowest ratio of mesophyll to stomatal conductance, g / g and was the only species where the decline in partial pressure of CO was greater from the intercellular air space to the site of fixation (16.3 Pa) than between the bulk air and the intercellular spaces (8.8 Pa), providing support for the hypotheses that low g limits photosynthesis in this species. As a group, conifers had marginally lower g and g / g ratio than angiosperms, but this difference was strongly influenced by the high values for Phaseolus vulgaris. That co-occurring members of the Podocarpaceae operated differently suggests that low g may reflect a response to evolutionary pressures other than high atmospheric CO partial pressure.
将二氧化碳从叶片细胞间隙传导至固定位点的能力(叶肉导度,g)可能对光合作用构成重大限制。新西兰本土针叶树芮木泪柏(Dacrydium cupressinum Sol. ex Lamb.)以及罗汉松科的其他成员在侏罗纪时期演化而来,当时二氧化碳分压超过200帕。该物种光合作用速率较低且叶片氮含量较高,这导致了低叶肉导度限制光合作用的假说。通过气体交换和荧光测量估算了芮木泪柏以及其他共生树种[斐济罗汉松(Prumnopitys ferruginea D.Don)、总序水丝梨(Weinmannia racemosa L.f.)、伞房状铁心木(Meterosideros umbellata Cav.)]的叶肉导度。纳入辐射松(Pinus radiata D. Don)和菜豆(Phaseolus vulgaris L.)以与光合速率相对较高的快速生长树木和草本植物进行比较。本土树种之间的叶肉导度在统计学上无差异,但芮木泪柏的叶肉导度最低。该物种的叶肉导度与气孔导度之比g / g也最低,并且是唯一一个二氧化碳分压从细胞间隙到固定位点的下降幅度(16.3帕)大于从大气到细胞间隙的下降幅度(8.8帕)的物种,这为低叶肉导度限制该物种光合作用的假说提供了支持。作为一个群体,针叶树的叶肉导度和g / g比略低于被子植物,但这种差异受到菜豆高值的强烈影响。罗汉松科共生成员的运作方式不同表明,低叶肉导度可能反映了对除高大气二氧化碳分压之外的进化压力的响应。
