Patterns and drivers of beta diversity of subtidal macrobenthos community on the eastern coast of Laizhou Bay

doi:10.17520/biods.2021388

Abstract

Abstract:

Aims The formation and maintenance mechanism of the beta diversity pattern of biological communities have always been the focus and core of community ecology. However, the patterns and drivers of the beta diversity in marine ecosystems are still unclear, especially in marine benthic ecosystems in China. By studying the relationship of beta diversity (taxonomic- and functional trait-based) and its turnover and nestedness components of subtidal macrobenthos communities with environmental variables and spatial distance, we aimed to reveal the underlying processes of community assembly on the eastern coast of Laizhou Bay and provide guidance for studying the beta diversity of macrobenthos communities in other regions.

Methods We sampled the macrobenthic organisms and corresponding environmental data (e.g., water temperature, salinity, dissolved oxygen, and sediment factors) at 15 stations in the subtidal zone on the eastern coast of Laizhou Bay. We collected six biological traits i.e., adult body size, habitat position, living habit, mobility, feeding habit and AZTI’s marine biotic index (AMBI) ecological groups for all sampled macrobenthos species. We calculated the taxonomic and functional trait beta diversity of macrobenthic communities and quantified the relative contributions of turnover and nestedness to beta diversity. In addition, the Mantel test and multiple regression on distance matrices (MRM) analysis were employed to determine the effect of environmental variables and spatial distance on the taxonomic and functional trait beta diversity and their components of macrobenthic communities.

Results We recorded 75 macrobenthos species in the study area, which was dominated by polychaetes (61.33%), followed by crustaceans (17.33%) and mollusks (14.67%). Both the taxonomic and functional beta diversity of macrobenthic communities on the eastern coast of Laizhou Bay were high and dominated by the turnover component. This indicates that there were large differences in the composition of species and functional traits of the macrobenthos in the study area, which were caused by the replacement of species and/or functional traits in space or between communities. (2) Spatial geographical distance had no significant effect on the taxonomic and functional beta diversity and their components of macrobenthic communities (Mantel test, P > 0.05), indicating that the impact of dispersal limitation on macrobenthic communities was small. (3) Multiple regression on distance matrices (MRM) analysis showed that sediment-related environmental factors, namely total organic matter (TOM) and silt content, are the main factors driving the taxonomic beta diversity of macrobenthic communities, while the functional trait beta diversity was significantly affected by TOM.

Conclusion Our results support that environmental filtrating was the dominant ecological process structuring macrobenthic communities, both in taxonomic and functional trait composition, in the subtidal zone on the eastern coast of Laizhou Bay. These findings highlight the need to examine both taxonomic and functional diversity to understand the mechanisms that govern the assembly of macrobenthos communities in subtidal zones. In addition, this study may have profound implications for understanding the macrobenthos community assembly in other sea areas in China.

Key words: beta diversity, macrozoobenthos, biological traits, environmental filtrating, community assembly

Jianyu Dong, Xin Sun, Qipeng Zhan, Yuyang Zhang, Xiumei Zhang. Patterns and drivers of beta diversity of subtidal macrobenthos community on the eastern coast of Laizhou Bay[J]. Biodiv Sci, 2022, 30(3): 21388.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021388

https://www.biodiversity-science.net/EN/Y2022/V30/I3/21388

Figures/Tables 4

Fig. 1 The richness of macrobenthos community at each site on the eastern coast of Laizhou Bay

Fig. 2 Taxonomic and functional trait beta diversity and its components (turnover and nestedness). A, Taxonomic beta diversity; B, Functional beta diversity. The points represent the data of the pairwise sites. The larger black points represent the mean values of turnover, nestedness, and similarity (1 - βsor).

Table 1 The results of taxonomic and functional trait beta diversity and its components with environmental factors based on multiple regression on distance matrices (MRM)

	系数 Coefficient			截距 Intercept	R²	P
	水深 Depth (m)	总有机质 Total organic matter (%)	粉砂 Silt (%)	截距 Intercept	R²	P
分类β多样性 Taxonomic beta diversity (^Tβ_sor)	-	0.0727**	0.0735**	0.7883***	0.4559	0.0001
周转组分 Turnover (^Tβ_sim)	-	-	0.1004**	0.7243**	0.2355	0.0070
嵌套组分 Nestedness (^Tβ_sne)	-	-	-0.0216*	0.0640*	0.0859	0.0353
功能性状β多样性 Functional trait beta diversity (^Fβ_sor)	-0.0400	0.0643*	-	0.8340*	0.1847	0.0487
周转组分 Turnover (^Fβ_sim)	-	-	-	-	-	-
嵌套组分 Nestedness (^Fβ_sne)	-	-	-	-	-	-

Fig. 3 The relationship of taxonomic and functional trait beta diversity and its components (turnover and nestedness) of macrobenthic communities with difference in geographic distance

References 63

[1]	Anderson MJ, Crist TO, Chase JM, Vellend M, Inouye BD, Freestone AL, Sanders NJ, Cornell HV, Comita LS, Davies KF, Harrison SP, Kraft NJB, Stegen JC, Swenson NG (2011) Navigating the multiple meanings of β diversity: A roadmap for the practicing ecologist. Ecology Letters, 14, 19-28. DOI PMID
[2]	Barros F, Blanchet H, Hammerstrom K, Sauriau PG, Oliver J (2014) A framework for investigating general patterns of benthic β-diversity along estuaries. Estuarine, Coastal and Shelf Science, 149, 223-231. DOI URL
[3]	Bartoń K (2020) MuMIn: Multi-Model Inference. R package version 1.43.17. https://CRAN.R-project.org/package=MuMIn . (accessed on 2021-05-14)
[4]	Baselga A (2010) Partitioning the turnover and nestedness components of beta diversity. Global Ecology and Biogeography, 19, 134-143. DOI URL
[5]	Baselga A (2012) The relationship between species replacement, dissimilarity derived from nestedness, and nestedness. Global Ecology and Biogeography, 21, 1223-1232. DOI URL
[6]	Baselga A, Orme D, Villeger S, Bortoli JD, Leprieur F, Logez M (2021) betapart: Partitioning Beta Diversity into Turnover and Nestedness Components. R package version 1.5.4. https://CRAN.R-project.org/package=betapart . (accessed on 2021-05-16)
[7]	Beauchard O, Veríssimo H, Queirós AM, Herman PMJ (2017) The use of multiple biological traits in marine community ecology and its potential in ecological indicator development. Ecological Indicators, 76, 81-96. DOI URL
[8]	Bender MG, Leprieur F, Mouillot D, Kulbicki M, Parravicini V, Pie MR, Barneche DR, Oliveira-Santos LGR, Floeter SR (2017) Isolation drives taxonomic and functional nestedness in tropical reef fish faunas. Ecography, 40, 425-435. DOI URL
[9]	Bevilacqua S, Plicanti A, Sandulli R, Terlizzi A (2012) Measuring more of β-diversity: Quantifying patterns of variation in assemblage heterogeneity. An insight from marine benthic assemblages. Ecological Indicators, 18, 140-148. DOI URL
[10]	Bevilacqua S, Terlizzi A (2020) Nestedness and turnover unveil inverse spatial patterns of compositional and functional β-diversity at varying depth in marine benthos. Diversity and Distributions, 26, 743-757. DOI URL
[11]	Bivand R, Lewin-Koh N (2020) maptools: Tools for Handling Spatial Objects. R package version 1.0-1. https://CRAN.R-project.org/package=maptools . (accessed on 2021-05-15)
[12]	Boyé A, Thiébaut É, Grall J, Legendre P, Broudin C, Houbin C le Garrec V, Maguer M, Droual G, Gauthier O (2019) Trait-based approach to monitoring marine benthic data along 500 km of coastline. Diversity and Distributions, 25, 1879-1896. DOI URL
[13]	Chen GG, Wang WQ, Liu Y, Zhang YM, Ma W, Xin K, Wang M (2019) Uncovering the relative influences of space and environment in shaping the biogeographic patterns of mangrove mollusk diversity. ICES Journal of Marine Science, 77, 30-39. DOI URL
[14]	Chen SB, Ouyang ZY, Xu WH, Xiao Y (2010) A review of beta diversity studies. Biodiversity Science, 18, 323-335. (in Chinese with English abstract) DOI
	[ 陈圣宾, 欧阳志云, 徐卫华, 肖燚 (2010) Beta多样性研究进展. 生物多样性, 18, 323-335.] DOI
[15]	Chevenet F, Dolédec S, Chessel D (1994) A fuzzy coding approach for the analysis of long-term ecological data. Freshwater Biology, 31, 295-309. DOI URL
[16]	Dong JY, Sun X, Zhang YY, Zhan QP, Zhang XM (2021a) Assessing benthic habitat ecological quality using four benthic indices in the coastal waters of Sanshandao, Laizhou Bay, China. Ecological Indicators, 129, 107980. DOI URL
[17]	Dong JY, Zhao LL, Sun X, Hu CY, Wang YH, Li WT, Zhang PD, Zhang XM (2021b) Response of macrobenthic communities to heavy metal pollution in Laoshan Bay, China: A trait-based method. Marine Pollution Bulletin, 167, 112292. DOI URL
[18]	Dray S, Dufour AB (2007) The ade 4 package: Implementing the duality diagram for ecologists. Journal of Statistical Software, 22, 1-20.
[19]	Dunnington D (2021) ggspatial: Spatial Data Framework for ggplot2. R package version 1.1.5. https://CRAN.R-project. org/package=ggspatial . (accessed on 2021-05-21)
[20]	Goslee SC, Urban DL (2007) The ecodist package for dissimilarity-based analysis of ecological data. Journal of Statistical Software, 22, 1-19.
[21]	Gray JS (2000) The measurement of marine species diversity, with an application to the benthic fauna of the Norwegian continental shelf. Journal of Experimental Marine Biology and Ecology, 250, 23-49. DOI URL
[22]	Greve M, Gremmen NJM, Gaston KJ, Chown SL (2005) Nestedness of Southern Ocean island biotas: Ecological perspectives on a biogeographical conundrum. Journal of Biogeography, 32, 155-168. DOI URL
[23]	Harrell FE, Dupont C (2021) Hmisc: Harrell Miscellaneous. R package version 4.5-0. https://CRAN.R-project.org/package=Hmisc . (accessed on 2021-05-23)
[24]	Harrison S, Ross SJ, Lawton JH (1992) Beta diversity on geographic gradients in Britain. Journal of Animal Ecology, 61, 151-158. DOI URL
[25]	Hu CY, Dong JY, Gao LJ, Yang XL, Wang Z, Zhang XM (2019) Macrobenthos functional trait responses to heavy metal pollution gradients in a temperate lagoon. Environmental Pollution, 253, 1107-1116. DOI URL
[26]	Laliberté E, Legendre P (2010) A distance-based framework for measuring functional diversity from multiple traits. Ecology, 91, 299-305. PMID
[27]	Lam-Gordillo O, Baring R, Dittmann S (2020) Ecosystem functioning and functional approaches on marine macrobenthic fauna: A research synthesis towards a global consensus. Ecological Indicators, 115, 106379. DOI URL
[28]	Legendre P (2014) Interpreting the replacement and richness difference components of beta diversity. Global Ecology and Biogeography, 23, 1324-1334. DOI URL
[29]	Lennon JJ, Koleff P, Greenwood JJD, Gaston KJ (2001) The geographical structure of British bird distributions: Diversity, spatial turnover and scale. Journal of Animal Ecology, 70, 966-979. DOI URL
[30]	Li XZ (2011) An overview of studies on marine macrobenthic biodiversity from Chinese waters: Principally from the Yellow Sea. Biodiversity Science, 19, 676-684. (in Chinese with English abstract) DOI URL
	[ 李新正 (2011) 我国海洋大型底栖生物多样性研究及展望: 以黄海为例. 生物多样性, 19, 676-684.] DOI
[31]	Li YF, Du FY, Wang LG, Wang XH, Ning JJ (2018) Effects of the sediment type on ecological functions of macrobenthos in the intertidal zones of Sanya Bay. Journal of Fisheries of China, 42, 1559-1571. (in Chinese with English abstract)
	[ 李亚芳, 杜飞雁, 王亮根, 王雪辉, 宁加佳 (2018) 底质类型对三亚湾潮间带大型底栖动物生态功能的影响. 水产学报, 42, 1559-1571.]
[32]	Lichstein JW (2007) Multiple regression on distance matrices: A multivariate spatial analysis tool. Plant Ecology, 188, 117-131. DOI URL
[33]	Liu RY (2008) Checklist of Marine Biota of China Seas. Science Press, Beijing. (in Chinese)
	[ 刘瑞玉 (2008) 中国海洋生物名录. 科学出版社, 北京.]
[34]	MarLIN (2006) BIOTIC-Biological Traits Information Catalogue. https://www.marlin.ac.uk/biotic . (accessed on 2021-04-12)
[35]	Mumby PJ (2001) Beta and habitat diversity in marine systems: A new approach to measurement, scaling and interpretation. Oecologia, 128, 274-280. DOI URL
[36]	Niu KC, Liu YN, Shen ZH, He FL, Fang JY (2009) Community assembly: The relative importance of neutral theory and niche theory. Biodiversity Science, 17, 579-593. (in Chinese with English abstract) DOI URL
	[ 牛克昌, 刘怿宁, 沈泽昊, 何芳良, 方精云 (2009) 群落构建的中性理论和生态位理论. 生物多样性, 17, 579-593.] DOI
[37]	Oksanen J, Blanchet FG, Friendly M, Kindt R, Legendre P, McGlinn D, Minchin PR, O’Hara RB, Simpson GL, Solymos P, Stevens MHH, Szoecs E, Wagner H (2019) vegan: Community Ecology Package. R package version 2.5-6. https://CRAN.R-project.org/package=vegan . (accessed on 2021-05-28)
[38]	Paradis E, Schliep K (2018) ape 5.0: An environment for modern phylogenetics and evolutionary analyses in R. Bioinformatics, 35, 526-528.
[39]	Pitacco V, Mistri M, Aleffi IF, Lardicci C, Prato S, Tagliapietra D, Munari C (2019) Spatial patterns of macrobenthic alpha and beta diversity at different scales in Italian transitional waters (central Mediterranean). Estuarine, Coastal and Shelf Science, 222, 126-138. DOI URL
[40]	Podani J, Ricotta C, Schmera D (2013) A general framework for analyzing beta diversity, nestedness and related community-level phenomena based on abundance data. Ecological Complexity, 15, 52-61. DOI URL
[41]	Polytraits Team (2020) Polytraits: A Database on Biological Traits of Polychaetes. http://polytraits.lifewatchgreece.eu . (accessed on 2021-04-12)
[42]	R Core Team (2019) R: A Language and Environment for Statistical Computing. R version 3.6.2 Vienna, Austria: R Foundation for Statistical Computing. . (accessed on 2020-01-10)
[43]	Saracho Bottero MA, Jaubet ML, Llanos EN, Becherucci ME, Elías R, Garaffo GV (2020) Spatial-temporal variations of a SW Atlantic macrobenthic community affected by a chronic anthropogenic disturbance. Marine Pollution Bulletin, 156, 111189. DOI URL
[44]	Si XF, Baselga A, Leprieur F, Song X, Ding P (2016) Selective extinction drives taxonomic and functional alpha and beta diversities in island bird assemblages. Journal of Animal Ecology, 85, 409-418. DOI URL
[45]	Si XF, Zhao YH, Chen CW, Ren P, Zeng D, Wu LB, Ding P (2017) Beta-diversity partitioning: Methods, applications and perspectives. Biodiversity Science, 25, 464-480. (in Chinese with English abstract) DOI URL
	[ 斯幸峰, 赵郁豪, 陈传武, 任鹏, 曾頔, 吴玲兵, 丁平 (2017) Beta多样性分解: 方法、应用与展望. 生物多样性, 25, 464-480.] DOI
[46]	Socolar JB, Gilroy JJ, Kunin WE, Edwards DP (2016) How should beta-diversity inform biodiversity conservation? Trends in Ecology & Evolution, 31, 67-80. DOI URL
[47]	Soininen J, Heino J, Wang JJ (2018) A meta-analysis of nestedness and turnover components of beta diversity across organisms and ecosystems. Global Ecology and Biogeography, 27, 96-109. DOI URL
[48]	Su GH, Xu J, Akasaka M, Molinos JG, Matsuzaki SIS (2015) Human impacts on functional and taxonomic homogenization of plateau fish assemblages in Yunnan, China. Global Ecology and Conservation, 4, 470-478. DOI URL
[49]	Villéger S, Mason NWH, Mouillot D (2008) New multidimensional functional diversity indices for a multifaceted framework in functional ecology. Ecology, 89, 2290-2301. DOI URL
[50]	Wang W (2019) The Impacts of Environmental Change on the Biogeographic Patterns of Rocky Shore Macrobenthos along China’s Coast. PhD dissertation, Xiamen University, Xiamen. (in Chinese with English abstract)
	[ 王伟 (2019) 环境变化对我国岩相潮间带大型底栖生物地理格局的影响. 博士学位论文, 厦门大学, 厦门.]
[51]	Wang XB, Lü XT, Yao J, Wang ZW, Deng Y, Cheng WX, Zhou JZ, Han XG (2017) Habitat-specific patterns and drivers of bacterial β-diversity in China’s drylands. The ISME Journal, 11, 1345-1358. DOI URL
[52]	Wang YP, Bao YX, Yu MJ, Xu GF, Ding P (2010) Nestedness for different reasons: The distributions of birds, lizards and small mammals on Islands of an inundated lake. Diversity and Distributions, 16, 862-873. DOI URL
[53]	Whittaker RH (1960) Vegetation of the Siskiyou Mountains, Oregon and California. Ecological Monographs, 30, 279- 338. DOI URL
[54]	Wickham H (2016) Ggplot2: Elegant Graphics for Data Analysis. Springer, New York,
[55]	Williams PH (1996) Mapping variations in the strength and breadth of biogeographic transition zones using species turnover. Proceedings of the Royal Society B: Biological Sciences, 263, 579-588.
[56]	Witman JD, Etter RJ, Smith F (2004) The relationship between regional and local species diversity in marine benthic communities: A global perspective. Proceedings of the National Academy of Sciences, USA, 101, 15664-15669.
[57]	Yang DJ, Sun RP (1988) The Polychaetes in Coastal Waters of China. China Agriculture Press, Beijing. (in Chinese)
	[ 杨德渐, 孙瑞平 (1988) 中国近海环节多毛动物. 农业出版社, 北京.]
[58]	Yang DJ, Wang YL (1996) Marine Invertebrates in Northern China. Higher Education Press, Beijing. (in Chinese)
	[ 杨德渐, 王永良 (1996) 中国北部海洋无脊椎动物. 高等教育出版社, 北京.]
[59]	Yao ZL, Wen HD, Deng Y, Cao M, Lin LX (2020) Driving forces underlying the beta diversity of tree species in subtropical mid-mountain moist evergreen broad-leaved forests in Ailao Mountains. Biodiversity Science, 28, 445-454. (in Chinese with English abstract) DOI URL
	[ 姚志良, 温韩东, 邓云, 曹敏, 林露湘 (2020) 哀牢山亚热带中山湿性常绿阔叶林树种beta多样性格局形成的驱动力. 生物多样性, 28, 445-454.] DOI
[60]	Yu GC (2020) scatterpie: Scatter Pie Plot. R package version 0.1.5. https://CRAN.R-project.org/package=scatterpie . (accessed on 2021-05-16)
[61]	Zhang CL, Chen Y, Xu BD, Xue Y, Ren YP (2019) How to predict biodiversity in space? An evaluation of modelling approaches in marine ecosystems. Diversity and Distributions, 25, 1697-1708. DOI URL
[62]	Zhang D, Wan FY, Chu L, Yan YZ (2018) Longitudinal patterns in α and β diversity of the taxonomic and functional organizations of stream fish assemblages in the Qingyi River. Biodiversity Science, 26, 1-13. (in Chinese with English abstract) DOI
	[ 张东, 宛凤英, 储玲, 严云志 (2018) 青弋江鱼类分类群和功能群的α和β多样性纵向梯度格局. 生物多样性, 26, 1-13.] DOI
[63]	Zhao YQ, Zeng JN, Gao AG, Chen QZ, Liao YB, Shou L (2009) Community pattern and diversity of macrozoobenthos in an intertidal flat, Jiaojiang Estuary. Biodiversity Science, 17, 303-309. (in Chinese with English abstract) DOI URL
	[ 赵永强, 曾江宁, 高爱根, 陈全震, 廖一波, 寿鹿 (2009) 椒江口滩涂大型底栖动物群落格局与多样性. 生物多样性, 17, 303-309.] DOI