Your search keyword '"nutrition resorption"' showing total 4 results

1. Influence of frost on nutrient resorption during leaf senescence in a mangrove at its latitudinal limit of distribution.

Author

Wenqing Wang, Siyang You, Yunbo Wang, Li Huang, and Mao Wang

Subjects

*FROST, *RESORPTION (Physiology), *ABSORPTION (Physiology), *AGING in plants, *PLANT development, *PLANT physiology, *MANGROVE plants, LEAF growth

Abstract

The latitudinal distribution of mangrove species is limited mainly by low temperature. Leaf scorch and massive leaf fall are the predominant symptoms of frost damage. Nutrient resorption during leaf senescence is an important adaptation mechanism of mangroves. Abnormal defoliation disturbs nutrient resorption. We evaluated the effects of frost on nutrient loss of mangroves and the protective effects of warmer seawater inundation on reducing nutrient loss. On January 14, 2009, the most cold-tolerant mangrove Kandelia obovata at its naturally latitudinal limit (Fuding, China, 27°17′N) was exposed to freezing temperature (−2.4°C) for 4 h (minimum −2.8°C). The freezing air temperature occurred during flood tide, resulting that the flooded shoots were protected by warmer seawater. Frost caused 31.3% and 13.0% defoliation on the exposed shoots and the flooded shoots, respectively. Frost restricted nutrient resorption during leaf senescence. K. obovata resorbed 61% N and 42% P during normal leaf senescence, respectively. However, frost-damaged leaves only resorbed 13% N and 10% P during the course, respectively. Foliar N:P molar ratios were <31, suggesting N limitation. Tidal inundation can partially protect mangroves from frost damage. Reduced nutrient resorption efficiency and massive leaf fall caused by frost add pressure to mangroves under nutrient limitation at their latitudinal limits. [ABSTRACT FROM AUTHOR]

Published

2011

2. Nitrogen and Phosphorus Resorption in Relation to Nutrition Limitation along the Chronosequence of Black Locust (Robinia pseudoacacia L.) Plantation

Author

Gaihe Yang, Fazhu Zhao, Xianfang Li, Chengjie Ren, Xinhui Han, Wei Zhang, Jian Deng, Dan Zhang, and Sha Wang

Subjects

0106 biological sciences, plant-soil feedback, Chronosequence, chemistry.chemical_element, 010603 evolutionary biology, 01 natural sciences, Nutrient, Animal science, Ecological stoichiometry, Ecosystem, Robinia pseudoacacia L, ecological stoichiometry, biology, Phosphorus, Robinia, Forestry, 04 agricultural and veterinary sciences, lcsh:QK900-989, biology.organism_classification, Resorption, stand age, chemistry, 040103 agronomy & agriculture, lcsh:Plant ecology, 0401 agriculture, forestry, and fisheries, nutrition resorption, Locust

Abstract

Plant nitrogen (N) and phosphorus (P) resorption is an important strategy to conserve N and P in the face of nutrient limitation. However, little is known about the variation of N and P resorption efficiency (NRE and PRE) and their correlation with leaves and soil C:N:P stoichiometry in black locust forests (Robinia pseudoacacia L.) of different ages. In this study, we measured C, N, and P concentrations in soil, green leaves, and senesced leaves from black locust forests of different ages (i.e, 10-, 20-, 30-, 36-, and 45-year-old), and calculated the NRE, PRE, and C:N:P stoichiometry ratios. The NRE and PRE tended to increase and then decrease with stand age, ranging from 46.8% to 57.4% and from 37.4% to 58.5%, with averages of 52.61 and 51.89, respectively. The PRE:NRE decreased with increased stand ages. The C:P and N:P of soil and green leaves increased with stand ages, indicating the increase of P limitation. In the senesced leaves, C:P and N:P were lower than in green leaves and first increased and then decreased with stand age. The PRE was significantly negatively correlated with the C:P and N:P of soil and green leaves. The NRE was significantly correlated with the C concentration of green leaves, P of the senesced leaves, and C:N. Results suggested that the NRE and PRE responded differently to soil and plant nutrients in black locust forests of different ages. In addition, the black locust plantations would alter the conservation and use strategy of nutrients in the ecosystem through a plant-mediated pathway. Future studies should elucidate the central nutrient utilization strategy of black locust in response to a nutrient-poor environment and determine how it is involved in regulating nutrient resorption.

Published

2019

3. Nitrogen and Phosphorus Resorption in Relation to Nutrition Limitation along the Chronosequence of Black Locust (Robinia pseudoacacia L.) Plantation.

Author

Deng, Jian, Wang, Sha, Ren, Chengjie, Zhang, Wei, Zhao, Fazhu, Li, Xianfang, Zhang, Dan, Han, Xinhui, and Yang, Gaihe

Subjects

BLACK locust, PLANT nutrients, PHOSPHORUS, NITROGEN, FORESTS & forestry

Abstract

Plant nitrogen (N) and phosphorus (P) resorption is an important strategy to conserve N and P in the face of nutrient limitation. However, little is known about the variation of N and P resorption efficiency (NRE and PRE) and their correlation with leaves and soil C:N:P stoichiometry in black locust forests (Robinia pseudoacacia L.) of different ages. In this study, we measured C, N, and P concentrations in soil, green leaves, and senesced leaves from black locust forests of different ages (i.e, 10-, 20-, 30-, 36-, and 45-year-old), and calculated the NRE, PRE, and C:N:P stoichiometry ratios. The NRE and PRE tended to increase and then decrease with stand age, ranging from 46.8% to 57.4% and from 37.4% to 58.5%, with averages of 52.61 and 51.89, respectively. The PRE:NRE decreased with increased stand ages. The C:P and N:P of soil and green leaves increased with stand ages, indicating the increase of P limitation. In the senesced leaves, C:P and N:P were lower than in green leaves and first increased and then decreased with stand age. The PRE was significantly negatively correlated with the C:P and N:P of soil and green leaves. The NRE was significantly correlated with the C concentration of green leaves, P of the senesced leaves, and C:N. Results suggested that the NRE and PRE responded differently to soil and plant nutrients in black locust forests of different ages. In addition, the black locust plantations would alter the conservation and use strategy of nutrients in the ecosystem through a plant-mediated pathway. Future studies should elucidate the central nutrient utilization strategy of black locust in response to a nutrient-poor environment and determine how it is involved in regulating nutrient resorption. [ABSTRACT FROM AUTHOR]

Published

2019

4. Influence of frost on nutrient resorption during leaf senescence in a mangrove at its latitudinal limit of distribution

Author

Wang, Wenqing, You, Siyang, Wang, Yunbo, Huang, Li, and Wang, Mao

Published

2011