Effects of Different Hydrological Conditions on the Taxonomic Structure and Functional Traits of Mollusk Communities in a Large Floodplain Wetland

Overview

Journal Ecol Evol

Date 2024 May 28

PMID 38803609

Authors

Yao Zhang

Thibault Datry

Qingji Zhang

Xiaolong Wang

Xianling Xiang

Zhijun Gong

Yongjiu Cai

Affiliations

Soon will be listed here.

Abstract

Floodplain wetlands are critical to the conservation of aquatic biodiversity and the ecological integrity of river networks. However, increasing drought severity and frequency caused by climate change can reduce floodplain wetlands' resistance and recovery capacities. Mollusks, which are common inhabitants of floodplain wetlands, are among the most vulnerable species to drought. However, the response of mollusk communities to drought has received little attention. Here, we investigated how the structure and functional traits of mollusk communities changed in response to varying hydrological conditions, including a flash drought (FD) in the Poyang Lake floodplain wetland. Our findings showed that FD strongly reduced mollusk abundance and biomass, decreased both α- and β-diversity, and resulted in the extinction of bivalve taxa. A sudden shift in community trait structure was discovered due to the extinction of many species. These traits, which include deposit feeding, crawling, scraping, aerial respiration, and dormancy, help mollusks survive in FD and tolerate completely dry out of their Changhuchi habitat. Finally, we discovered that dissolved oxygen was an important controlling variable for mollusk communities during drought. Our findings provide a scientific basis for the management and conservation of floodplain wetland biodiversity in the context of increasing drought frequency and intensity.

Citing Articles

Effects of different hydrological conditions on the taxonomic structure and functional traits of mollusk communities in a large floodplain wetland.

Zhang Y, Datry T, Zhang Q, Wang X, Xiang X, Gong Z Ecol Evol. 2024; 14(5):e11466.

PMID: 38803609 PMC: 11128460. DOI: 10.1002/ece3.11466.

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