毛竹及其变种叶片化学计量与养分重吸收效率

郭雯; 漆良华; 雷刚; 胡璇; 张建; 舒琪; 商泽安

doi:10.12302/j.issn.1000-2006.201910034

郭雯, 漆良华, 雷刚, 胡璇, 张建, 舒琪, 商泽安

南京林业大学学报（自然科学版） ›› 2021, Vol. 45 ›› Issue (1) : 79-85.

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南京林业大学学报（自然科学版） ›› 2021, Vol. 45 ›› Issue (1) : 79-85. DOI: 10.12302/j.issn.1000-2006.201910034

研究论文

毛竹及其变种叶片化学计量与养分重吸收效率

郭雯 ¹ ,
漆良华 ¹^,²^,^* ,
雷刚 ¹^,²^,³ ,
胡璇 ¹ ,
张建 ¹ ,
舒琪 ¹ ,
商泽安 ¹

作者信息 +

Leaf stoichiometry and nutrient reabsorption efficiency of Phyllostachys edulis and its varieties

GUO Wen ¹ ,
QI Lianghua ¹^,²^,^* ,
LEI Gang ¹^,²^,³ ,
HU Xuan ¹ ,
ZHANG Jian ¹ ,
SHU Qi ¹ ,
SHANG Ze’an ¹

Author information +

文章历史 +

摘要

【目的】评价毛竹(Phyllostachys edulis)及其变种叶片养分重吸收效率,旨在揭示主要养分元素的生态适应机制,以期为毛竹及其变种的可持续经营提供科学依据。【方法】以毛竹及其变种[黄槽毛竹(P. edulis cv. Luteosulcata)、花毛竹(P. edulis cv. Tao Kiang)、厚壁毛竹(P. edulis cv. Pachyloen)、金丝毛竹(P. edulis cv. Gracilis)]为研究对象,分析不同竹龄(1、3、5 a)叶片化学计量特征与养分重吸收效率。【结果】毛竹及其变种C、N 含量差异较小,P含量波动性较大。不同竹种相同竹龄立竹间成熟叶和凋落叶C、N、P含量差异性较大,1年生竹种叶片养分含量较高,随着竹龄增加,竹种适应能力逐渐下降。毛竹及其变种相同年龄立竹间、同一变种不同年龄立竹间叶片化学计量比存在一定差异性。1、3、5年生花毛竹叶片N、P重吸收效率较高,年龄对除厚壁毛竹外的其他毛竹及其变种叶片N重吸收效率影响呈现先升后降趋势,而不同年龄毛竹及其变种叶片P重吸收效率波动性较大。【结论】研究区毛竹及其变种生长受P元素的限制,毛竹及其变种随竹龄的增加适应能力有所变化,花毛竹适应性较强,厚壁毛竹则对土壤的依赖性较大。

Abstract

【Objective】 The objective of this work was to evaluate the nutrient reabsorption efficiency of Phyllostachys edulis and its varieties, and to identify the ecological adaptation mechanism of the main nutrient elements. This will provide a scientific basis for the sustainable management of P. edulis and its varieties. 【Method】In this study, the leaf stoichiometric characteristics and nutrient reabsorption efficiency of P. edulis and its varieties (P. edulis cv. Luteosulcata, P. edulis cv. Tao Kiang, P. edulis cv. Pachyloen, and P. edulis cv. Gracilis) were analyzed at different ages (1, 3, 5 a). 【Result】 The content of carbon and nitrogen in the leaves of P. edulis and its varieties varied slightly, while the content of phosphorus fluctuated greatly. The contents of C, N and P in the leaves of different bamboo species at the same age were significantly different. The nutrient content in leaves of 1-year bamboo was relatively high. With an increase in age, the adaptability of bamboo gradually decreased. There were some differences in the leaf stoichiometric ratio between P. edulis and its varieties at the same age and between the same variety at different ages. The reabsorption efficiency of N and P in the leaves of P. edulis at different ages was higher. The effect of age on the N reabsorption efficiency of leaves of P. edulis and its varieties increased at first and then decreased, but the P reabsorption efficiency of bamboo leaves fluctuated greatly at different ages. 【Conclusion】 The growth of P. edulis and its varieties was limited by the P element, and the adaptability changed with an increase in age for P. edulis and its varieties. P. edulis cv. Tao Kiang showed strong adaptability, while P. edulis cv. Pachyloen had the opposite trait.

导出引用

郭雯, 漆良华, 雷刚, 等. 毛竹及其变种叶片化学计量与养分重吸收效率[J]. 南京林业大学学报（自然科学版）. 2021, 45(1): 79-85 https://doi.org/10.12302/j.issn.1000-2006.201910034

GUO Wen, QI Lianghua, LEI Gang, et al. Leaf stoichiometry and nutrient reabsorption efficiency of Phyllostachys edulis and its varieties[J]. JOURNAL OF NANJING FORESTRY UNIVERSITY. 2021, 45(1): 79-85 https://doi.org/10.12302/j.issn.1000-2006.201910034

中图分类号： S718

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Nutrient resorption in plants influences nutrient availability and cycling and is a key process in biogeochemical models. Improved estimates of resorption parameters are needed for predicting long-term primary productivity and for improving such models. Currently, most models assume a value of 50% resorption for nitrogen (N) and phosphorus (P) and lack resorption data for other nutrients and for specific vegetation types. We provide global estimates of resorption efficiencies and nutrient concentrations for carbon (C), N, and P and the first global-scale estimates for essential nutrients such as potassium (K), calcium (Ca), and magnesium (Mg). We also examine leaf mass loss during senescence (LML) globally and for different plant types, thus defining a mass loss correction factor (MLCF) needed to quantify unbiased resorption values. We used a global meta-analysis of 86 studies and; similar to 1000 data points across climates for green and senesced leaves in six plant types: ferns, forbs, graminoids, conifers, and evergreen and deciduous woody angiosperms. In general, N and P resorption differed significantly from the commonly used global value of 50% (62.1%, 64.9%, respectively; P, 0.05). Ca, C, and Mg showed lower average resorptions of 10.9%, 23.2%, and 28.6%, respectively, while K had the highest resorption, at 70.1%. We also found that resorption of all nutrients except Ca depended on leaf nutrient-status; globally, C, N, P, K, and Mg showed a decrease in resorption with increased nutrient status. On average, global leaf mass loss was 24.2%. Overall, our resorption data differ substantially from commonly assumed values and should help improve ecological theory and biogeochemical and land-surface models.

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Foliar nitrogen to phosphorus (N:P) ratios are widely used to indicate soil nutrient availability and limitation, but the foliar ratios of woody plants have proven more complicated to interpret than ratios from whole biomass of herbaceous species. This may be related to tissues in woody species acting as nutrient reservoirs during active growth, allowing maintenance of optimal N:P ratios in recently produced, fully expanded leaves (i.e., "new" leaves, the most commonly sampled tissue). Here we address the hypothesis that N:P ratios of newly expanded leaves are less sensitive indicators of soil nutrient availability than are other tissue types in woody plants. Seedlings of five naturally established tree species were harvested from plots receiving two years of fertilizer treatments in a lowland tropical forest in the Republic of Panama. Nutrient concentrations were determined in new leaves, old leaves, stems, and roots. For stems and roots, N:P ratios increased after N addition and decreased after P addition, and trends were consistent across all five species. Older leaves also showed strong responses to N and P addition, and trends were consistent for four of five species. In comparison, overall N:P ratio responses in new leaves were more variable across species. These results indicate that the N:P ratios of stems, roots, and older leaves are more responsive indicators of soil nutrient availability than are those of new leaves. Testing the generality of this result could improve the use of tissue nutrient ratios as indices of soil nutrient availability in woody plants.

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https://www.ncbi.nlm.nih.gov/pubmed/27788438

本文引用 [1] 摘要

Leymus chinensis is the most promising grass species for salt-alkaline grassland restoration in northern China. However, little information exists concerning the role of arbuscular mycorrhizal (AM) symbiosis in the adaptation of seedlings to salt-alkali stress, particularly under increased nitrogen deposition, which has become a major environmental problem throughout the world. In this study, Leymus chinensis seedlings were cultivated in soil with 0, 100 and 200mM NaCl/NaHCO3 under two forms of nitrogen (10mM NH4NO3 or NH4Cl: NH4NO3=3:1), and the root colonization, growth and photosynthetic characteristics of the seedlings were measured. The results showed that the colonization rate and intensity decreased with increasing salt-alkali stress and were much lower under alkali stress. The nitrogen treatments also decreased the colonization, particularly under the NH4(+)-N treatment. Compared with the non-mycorrhizal controls, mycorrhizal seedlings generally presented higher plant biomass, photosynthetic parameters and contents of photosynthetic pigments under stresses, and the inhibitive effects of alkali stress were substantially stronger. In addition, both nitrogen forms decreased the physiological indexes compared with those of the AM seedlings. Our results suggest that salt stress and alkali stress are significantly different and that the salt-alkali tolerance of Leymus chinensis seedlings could be enhanced by associations with arbuscular mycorrhizal fungi, in which would yield better plant growth and photosynthesis. Excessive nitrogen in the soil affects mycorrhizal colonization and thereby inhibits the growth and photosynthetic ability of the seedlings.