具有天冬酸代谢(CAM)光合作用的植物在热带和亚热带强降雨雨林的发生。

Q4 Agricultural and Biological Sciences Taiwan Journal of Forest Science Pub Date : 2010-03-01 DOI:10.7075/TJFS.201003.0003
C. Martin
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引用次数: 7

摘要

天冬酸代谢(CAM)是一种光合作用途径,通过限制气孔开放来保存水分,从而将水分流失到夜间。因此,发现干旱地区的植物区系中含有大量CAM植物就不足为奇了。此外,CAM在热带和亚热带水丰富的附生植物中也很常见。尽管存在后者,但有证据表明,相对较短的干旱时期,加上这种附生植物不寻常的形态和/或微生境,构成了足够大的压力,CAM途径被证明是高度适应的。在年降雨量极高的热带和亚热带雨林,即年降雨量超过4米的热带和亚热带雨林,CAM的适应意义更难解释。这篇综述探讨了为解释这个明显的难题而提出的各种假设。这些假设包括:1。CAM允许附生CAM植物利用夜间在其宿主树的树冠中高浓度的大气二氧化碳;2. 即使在这样的雨林中,无雨期也足够长和/或频繁,CAM作为一种水资源保护适应证明是有利的。3.许多CAM植物在白天和晚上吸收二氧化碳的能力在这样的环境中是有利的。4. CAM光合组织中白天二氧化碳水平的增加可以防止光抑制,并使白天的二氧化碳损失最小化。5. CAM光合组织的高酸含量,至少在一天的早些时候,阻碍了草食。6. 据报道,至少一种附生CAM植物叶片湿润后对CO2吸收的刺激在这样的高降雨环境中是有利的。7. 在至少一种CAM植物中观察到的对必需元素的低需求增加了这些植物的营养效率,这是适应降雨过多的雨林的,因此,叶组织的营养浸出水平很高。8. 由渗透驱动的高组织含水量导致的灌流在几个方面对CAM植物有益。9. 附生CAM植物很好地适应了阴凉的微生境,包括对高降雨雨林的多云环境的有价值的适应。10. 在这些环境中,CAM对这些植物没有好处,至少有三个可能的原因。所有这些假设在过去的研究中很少得到检验。因此,所有这些都需要进一步调查。
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The occurrence of plants with crassulacean acid metabolism (CAM) photosynthesis in tropical and subtropical rain forests with very high rainfall.
Crassulacean acid metabolism (CAM) is a photosynthetic pathway that conserves water by restricting stomatal opening, hence water loss, to the night. Thus, it is not surprising to find that floras of arid regions include a large number of CAM plants. In addition, CAM is common among epiphytes in tropical and subtropical environments, where water is plentiful. Despite the latter, evidence exists that comparatively short periods of drought, coupled with the unusual morphology and/or microhabitat of such epiphytes, comprise stress substantial enough that the CAM pathway proves highly adaptive. It is more difficult to explain the adaptive significance of CAM in tropical and subtropical rain forests with exceedingly high annual rainfall, i.e., in excess of 4 meters per year. This review explores a variety of hypotheses proffered as explanations for this apparent conundrum. Such hypotheses include: 1. CAM allows an epiphytic CAM plant to capitalize on the high concentrations of atmospheric CO2 at night in the canopies of its host trees; 2. even in such rain forests, rainless periods are long enough and/or frequent enough that CAM proves advantageous as a water conservation adaptation. 3. The ability of many CAM plants to assimilate CO2 during both the day and night is advantageous in such environments. 4. The increase in daytime CO2 levels in CAM photosynthetic tissue prevents photoinhibition and minimizes CO2 losses during the day. 5. The high acid content of CAM photosynthetic tissue, at least early in the day, deters herbivory. 6. The stimulation of CO2 uptake following wetting of the leaves reported for at least one epiphytic CAM plant is advantageous in such high-rainfall environments. 7. The low demand for essential elements observed in at least one CAM plant increases the nutrient efficiency of such plants, which is adaptive in rain forests with excessive rainfall and, hence, high levels of nutrient leaching from the leaf tissues. 8. Guttation resulting from osmotically-driven high tissue water contents benefits CAM plants several ways. 9. Epiphytic CAM plants are well-adapted to shady microhabitats, comprising a valuable adaptation to the cloudy environment of high-rainfall rain forests. 10. CAM is not beneficial for such plants in these environments for at least 3 possible reasons. All of the hypotheses have only rarely been examined in past studies. Thus, all are in need of further investigation.
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来源期刊
Taiwan Journal of Forest Science
Taiwan Journal of Forest Science Agricultural and Biological Sciences-Forestry
CiteScore
0.20
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期刊介绍: The Taiwan Journal of Forest Science is an academic publication that welcomes contributions from around the world. The journal covers all aspects of forest research, both basic and applied, including Forest Biology and Ecology (tree breeding, silviculture, soils, etc.), Forest Management (watershed management, forest pests and diseases, forest fire, wildlife, recreation, etc.), Biotechnology, and Wood Science. Manuscripts acceptable to the journal include (1) research papers, (2) research notes, (3) review articles, and (4) monographs. A research note differs from a research paper in its scope which is less-comprehensive, yet it contains important information. In other words, a research note offers an innovative perspective or new discovery which is worthy of early disclosure.
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