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气孔 CO2 代用指标在高大气 CO2 浓度下不会饱和:来自南洋杉科针叶树气孔指数响应的证据。

The stomatal CO2 proxy does not saturate at high atmospheric CO2 concentrations: evidence from stomatal index responses of Araucariaceae conifers.

机构信息

CNR-Istituto di Biometeorologia (IBIMET), Firenze, Italy.

出版信息

Oecologia. 2011 Sep;167(1):11-9. doi: 10.1007/s00442-011-1969-1. Epub 2011 Apr 3.

DOI:10.1007/s00442-011-1969-1
PMID:21461935
Abstract

The inverse relationship between the number of stomata on a leaf surface and the atmospheric carbon dioxide concentration ([CO(2)]) in which the leaf developed allows plants to optimise water-use efficiency (WUE), but it also permits the use of fossil plants as proxies of palaeoatmospheric [CO(2)]. The ancient conifer family Araucariaceae is often represented in fossil floras and may act as a suitable proxy of palaeo-[CO(2)], yet little is known regarding the stomatal index (SI) responses of extant Araucariaceae to [CO(2)]. Four Araucaria species (Araucaria columnaris, A. heterophylla, A. angustifolia and A. bidwillii) and Agathis australis displayed no significant relationship in SI to [CO(2)] below current ambient levels (~380 ppm). However, representatives of the three extant genera within the Araucariaceae (A. bidwillii, A. australis and Wollemia nobilis) all exhibited significant reductions in SI when grown in atmospheres of elevated [CO(2)] (1,500 ppm). Stomatal conductance was reduced and WUE increased when grown under elevated [CO(2)]. Stomatal pore length did not increase alongside reduced stomatal density (SD) and SI in the three araucariacean conifers when grown at elevated [CO(2)]. These pronounced SD and SI reductions occur at higher [CO(2)] levels than in other species with more recent evolutionary origins, and may reflect an evolutionary legacy of the Araucariaceae in the high [CO(2)] world of the Mesozoic Era. Araucariacean conifers may therefore be suitable stomatal proxies of palaeo-[CO(2)] during periods of "greenhouse" climates and high [CO(2)] in the Earth's history.

摘要

叶片表面的气孔数量与叶片发育时的大气二氧化碳浓度([CO2])呈反比,这使得植物能够优化水利用效率(WUE),但也允许使用化石植物作为古大气[CO2]的替代物。古松柏科植物常常在化石植物群中出现,可能是古[CO2]的合适替代物,但对于现生松柏科植物的气孔指数(SI)对[CO2]的响应却知之甚少。四种南洋杉物种(南洋杉柱、南洋杉杂种、南洋杉狭叶和南洋杉比氏)和澳洲贝壳杉显示,在当前环境水平(约 380 ppm)以下,SI 与[CO2]之间没有显著关系。然而,南洋杉科的三个现生属(南洋杉比氏、澳洲贝壳杉和沃尔利松)的代表在高[CO2](1500 ppm)环境中生长时,SI 均显著降低。在高[CO2]环境下生长时,气孔导度降低,WUE 增加。当在高[CO2]环境下生长时,三个南洋杉科针叶树的气孔密度(SD)和 SI 降低,而气孔孔径并没有增加。与具有较近进化起源的其他物种相比,这些明显的 SD 和 SI 降低发生在更高的[CO2]水平,这可能反映了南洋杉科在中生代高[CO2]世界中的进化遗产。因此,南洋杉科针叶树可能是古[CO2]时期“温室”气候和地球历史上高[CO2]的合适气孔替代物。

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2
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Am J Bot. 1998 Nov;85(11):1507-16.
3
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4
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5
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6
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7
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8
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4
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Am J Bot. 2009 Oct;96(10):1779-86. doi: 10.3732/ajb.0800410. Epub 2009 Sep 3.
5
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6
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9
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New Phytol. 2009 Aug;183(3):839-847. doi: 10.1111/j.1469-8137.2009.02844.x. Epub 2009 Apr 23.
10
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