Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China
Silica (Si) is a basic nutrient requirement for many aquatic organisms and its biogeochemical cycle plays an important role in estuarine coastal ecosystems. However, little is known about the role Si plays during plant–plant interactive processes in the marsh ecosystems. Here, variations in biomass,...
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doaj-562d27a672ce4041a5220958d06ff4702020-11-25T01:13:36ZengPeerJ Inc.PeerJ2167-83592019-07-017e721810.7717/peerj.7218Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast ChinaHui Gao0Shuijing Zhai1Zhigao Sun2Juan Liu3Chuan Tong4School of Geographical Sciences, Key Laboratory of Humid Subtropical Eco-geographical Process, Ministry of Education, Fujian Normal University, Fuzhou, ChinaSchool of Geographical Sciences, Key Laboratory of Humid Subtropical Eco-geographical Process, Ministry of Education, Fujian Normal University, Fuzhou, ChinaSchool of Geographical Sciences, Key Laboratory of Humid Subtropical Eco-geographical Process, Ministry of Education, Fujian Normal University, Fuzhou, ChinaInnovation Center and Key Laboratory of Water Quality and Reservation in the Pearl River Delta, Institute of Environmental Research At Greater Bay, School of Environmental Science and Engineering, Guangzhou University, Guangzhou, ChinaSchool of Geographical Sciences, Key Laboratory of Humid Subtropical Eco-geographical Process, Ministry of Education, Fujian Normal University, Fuzhou, ChinaSilica (Si) is a basic nutrient requirement for many aquatic organisms and its biogeochemical cycle plays an important role in estuarine coastal ecosystems. However, little is known about the role Si plays during plant–plant interactive processes in the marsh ecosystems. Here, variations in biomass, biogenic silica (BSi) content, and available Si content of Cyperus malaccensis-dominated marshes, Phragmites australis-dominated marshes, and their ecotonal marshes were studied in the Shanyutan marsh in the Min River estuary, China. Results showed that C. malaccensis and P. australis biomass in ecotones was lower than those in typical communities by 46.4% and 46.3%, respectively. BSi content in aboveground organs of C. malaccensis and culms and roots of P. australis was lower in ecotones than in typical communities, whereas BSi content in other organs showed the opposite trend. Biomass allocation in C. malaccensis and P. australis roots in ecotones was higher by 56.9% and 19.5%, respectively, and BSi stock in C. malaccensis and P. australis roots was higher than that in typical communities by 120.9% and 18.9%, respectively. Available Si content in ecotonal marsh soils was 12.6% greater than that in typical communities. Thus, the two plant species may use different strategies for Si accumulation and allocation in ecotones to adapt to the competitive environment. P. australis may expand primarily via occupation of wider aboveground space, thereby increasing the Si accumulation capacity in aboveground organs. Meanwhile, C. malaccensis may increase the Si allocation capacity of its roots to withstand the pressure from P. australis. This study will provide new insights into marsh plant competition from the perspective of Si, which can also benefit plant management in marsh ecosystems.https://peerj.com/articles/7218.pdfVariationSilicaEcotoneCompetitionMarshMin River estuary |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Hui Gao Shuijing Zhai Zhigao Sun Juan Liu Chuan Tong |
| spellingShingle |
Hui Gao Shuijing Zhai Zhigao Sun Juan Liu Chuan Tong Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China PeerJ Variation Silica Ecotone Competition Marsh Min River estuary |
| author_facet |
Hui Gao Shuijing Zhai Zhigao Sun Juan Liu Chuan Tong |
| author_sort |
Hui Gao |
| title |
Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China |
| title_short |
Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China |
| title_full |
Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China |
| title_fullStr |
Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China |
| title_full_unstemmed |
Differences in biomass and silica content in typical plant communities with ecotones in the Min River estuary of southeast China |
| title_sort |
differences in biomass and silica content in typical plant communities with ecotones in the min river estuary of southeast china |
| publisher |
PeerJ Inc. |
| series |
PeerJ |
| issn |
2167-8359 |
| publishDate |
2019-07-01 |
| description |
Silica (Si) is a basic nutrient requirement for many aquatic organisms and its biogeochemical cycle plays an important role in estuarine coastal ecosystems. However, little is known about the role Si plays during plant–plant interactive processes in the marsh ecosystems. Here, variations in biomass, biogenic silica (BSi) content, and available Si content of Cyperus malaccensis-dominated marshes, Phragmites australis-dominated marshes, and their ecotonal marshes were studied in the Shanyutan marsh in the Min River estuary, China. Results showed that C. malaccensis and P. australis biomass in ecotones was lower than those in typical communities by 46.4% and 46.3%, respectively. BSi content in aboveground organs of C. malaccensis and culms and roots of P. australis was lower in ecotones than in typical communities, whereas BSi content in other organs showed the opposite trend. Biomass allocation in C. malaccensis and P. australis roots in ecotones was higher by 56.9% and 19.5%, respectively, and BSi stock in C. malaccensis and P. australis roots was higher than that in typical communities by 120.9% and 18.9%, respectively. Available Si content in ecotonal marsh soils was 12.6% greater than that in typical communities. Thus, the two plant species may use different strategies for Si accumulation and allocation in ecotones to adapt to the competitive environment. P. australis may expand primarily via occupation of wider aboveground space, thereby increasing the Si accumulation capacity in aboveground organs. Meanwhile, C. malaccensis may increase the Si allocation capacity of its roots to withstand the pressure from P. australis. This study will provide new insights into marsh plant competition from the perspective of Si, which can also benefit plant management in marsh ecosystems. |
| topic |
Variation Silica Ecotone Competition Marsh Min River estuary |
| url |
https://peerj.com/articles/7218.pdf |
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