Abstract
The functional parameters, i.e., the estimated equilibrium species number (S eq ), the colonization rate constant, and the time taken to reach 90 % of S eq (T 90 ), of microperiphyton fauna have been widely used to determine the water quality status in aquatic ecosystems. The objective of this investigation was to develop a protocol for determining functional parameters of microperiphyton fauna in colonization surveys for marine bioassessment based on rarefaction and regression analyses. The temporal dynamics in species richness of microperiphyton fauna during the colonization period was analyzed based on a dataset of periphytic ciliates in Chinese coastal waters of the Yellow Sea. The results showed that (1) based on observed species richness and estimated maximum species numbers, a total of 16 glass slides were required in order to achieve coefficients of variation of <5 % in the functional parameters; (2) the rarefied average species richness and functional parameters showed weak sensitivity to sampling effort; (3) the temporal variations in average species richness were well-fitted to the MacArthur-Wilson model; and (4) the sampling effort of ~8 glass slides was sufficient to achieve coefficients of variation of <5 % in equilibrium average species number (AvS eq ), colonization rate (AvG), and the time to reach 90 % of AvS eq (AvT 90 ) based on the average species richness. The findings suggest that the AvS eq , AvG, and AvT 90 values based on rarefied average species richness of microperiphyton might be used as reliable ecological indicators for the bioassessment of marine water quality in coastal habitats.
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References
Cairns J Jr, Henebry MS (1982) Interactive and noninteractive protozoa colonization process. In: Cairns J Jr (ed) Artificial substrates. Ann Arbor Science Publishers, Ann Arbor
Clarke K, Lewis M, Ostendorf B (2011) Additive partitioning of rarefaction curves: Removing the influence of sampling on species-diversity in vegetation surveys. Ecol Indic 11:132–139
Colwell RK, Mao CX, Chang J (2004) Interpolating, extrapolating, and comparing incidence-based species accumulation curves. Ecology 85:2717–2727
Crist TO, Veech JA (2006) Additive partitioning of rarefaction curves and species-area relationships: unifying alpha-, beta- and gamma-diversity with sample size and habitat area. Ecol Lett 9:923–932
Flather CH (1996) Fitting species-accumulation functions and assessing regional land use impacts on avian diversity. J Biogeogr 23:155–168
Franco C, Esteban G, Téllez C (1998) Colonization and succession of ciliated protozoa associated with submerged leaves in a river. Limnologica 28:275–283
Gotelli NJ, Colwell RK (2001) Quantifying biodiversity: procedures and pitfalls in the measurement and comparison of species richness. Ecol Lett 4:379–391
Kathol M, Norf H, Arndt H, Weitere M (2009) Effects of temperature increase on the grazing of planktonic bacteria by biofilm-dwelling consumers. Aquat Microb Ecol 55:65–79
Khatoon H, Yusoff FM, Banerjee S, Shariff M, Mohamed S (2007) Use of periphytic cyanobacterium and mixed diatoms coated substrate for improving water quality, survival and growth of Penaeus monodon Fabricius postlarvae. Aquaculture 27:196–205
MacArthur R, Wilson EO (1967) The theory of island biogeography. Princeton University Press, Princeton, 203 pp
Mao CX, Colwell RK, Chang J (2005) Estimating the species accumulation curve using mixtures. Biometrics 61:433–441
Morin S, Pesce S, Tlili A, Coste M, Montuelle B (2010) Recovery potential of periphytic communities in a river impacted by a vineyard watershed. Ecol Indic 10:419–426
Norf H, Arndt H, Weitere M (2009) Effects of resource supplements on mature ciliate biofilms: an empirical test using a new type of flow cell. Biofouling 25:769–778
Railkin AI (1998) The pattern of recovery of disturbed microbial communities inhabiting hard substrates. Hydrobiologia 385:47–57
Risse-Buhl U, Küsel K (2009) Colonization dynamics of biofilm associated ciliate morphotypes at different flow velocities. Eur J Protistol 45:64–76
Song W, Warren A, Hu X (2009) Free-living Ciliates in the Bohai and Yellow Seas. China. Science Press (in both Chinese and English), Beijing
Strüder-Kypke MC (1999) Periphyton and sephagnicolous protists of dystrophic bog lakes (Brandenburg, Germany) I. Annual cycles, distribution and comparison to other lakes. Limnologica 29:393–406
Whittaker RH (1972) Evolution and measurement of species diversity. Taxon 21:213–251
Xu H, Min GS, Choi JK, Jung JH, Park MH (2009) Approach to analyses of periphytic ciliate colonization for monitoring water quality using a modified artificial substrate in Korean coastal waters. Mar Pollut Bull 58:1278–1285
Xu H, Zhang W, Jiang Y, Zhu M, Al-Rasheid KAS, Warren A, Song W (2011) An approach to determining sampling effort for analyzing biofilm-dwelling ciliate colonization using an artificial substratum in coastal waters. Biofouling 27:357–366
Xu H, Zhang W, Jiang Y, Zhu M, Al-Rasheid KAS (2012a) Influence of sampling sufficiency on biodiversity analysis of microperiphyton communities for marine bioassessment. Environ Sci Pollut Res 19:540–549
Xu H, Zhang W, Jiang Y, Zhu M, Al-Rasheid KAS (2012b) Sampling sufficiency for analyzing taxonomic relatedness of periphytic ciliate communities using an artificial substratum in coastal waters. J Sea Res 72:22–27
Xu H, Zhang W, Jiang Y, Zhu M, Al-Rasheid KAS (2012c) An approach to analyzing influence of enumeration time periods on detecting ecological features of microperiphyton communities for marine bioassessment. Ecol Indic 18:50–57
Xu H, Zhang W, Jiang Y, Yang EJ (2014) Use of biofilm-dwelling ciliate communities to determine environmental quality status of coastal water. Sci Total Environ 470–471:511–518
Zhang W, Xu H, Jiang Y, Zhu M, Al-Rasheid KAS (2012a) Colonization dynamics in trophic-functional structure of periphytic protist communities in coastal waters. Mar Biol 159:735–748
Zhang W, Xu H, Jiang Y, Zhu M, Al-Rasheid KAS (2012b) Influence of enumeration time periods on analyzing colonization features and taxonomic relatedness of periphytic ciliate communities using an artificial substratum for marine bioassessment. Environ Sci Pollut Res 19:3619–3627
Zhang W, Xu H, Jiang Y, Zhu M, Al-Rasheid KAS (2013) Colonization dynamics of periphytic ciliate communities on an artificial substratum in coastal waters of the yellow Sea. J Mar Biol Assoc UK 93:57–68
Acknowledgments
This work was supported by “The Natural Science Foundation of China” (project number: 41,076,089), and Scholarship Award for Excellent Doctoral Student granted by Chinese Ministry of Education. Special thanks are due to Dr. Mingzhuang Zhu and Dr. Yong Jiang, Institute of Evolution and Marine Biodiversity, Ocean University of China, China, for their help with sampling and sample processing.
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Responsible editor: Robert Duran
G. Xu and X. Zhong are co-first authors.
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Xu, G., Zhong, X., Wang, Y. et al. An approach to determining functional parameters of microperiphyton fauna in colonization surveys for marine bioassessment based on rarefaction curves. Environ Sci Pollut Res 21, 13461–13469 (2014). https://doi.org/10.1007/s11356-014-3293-x
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DOI: https://doi.org/10.1007/s11356-014-3293-x