. 2022 Feb;28(4):1402-1413.

doi: 10.1111/gcb.15989. Epub 2021 Dec 3.

Microalgae colonization of different microplastic polymers in experimental mesocosms across an environmental gradient

Veronica Nava¹, Miguel G Matias^{2

3}, Andreu Castillo-Escrivà³, Beata Messyasz⁴, Barbara Leoni¹

Affiliations

¹ Department of Earth and Environmental Sciences, University of Milano-Bicocca, Milano, Italy.
² Department of Biogeografía y Cambio Global, Museo Nacional de Ciencias Naturales, CSIC, Madrid, Spain.
³ MED-Mediterranean Institute for Agriculture, Environment and Development, Rui Nabeiro Biodiversity Chair, Universidade de Évora, Évora, Portugal.
⁴ Department of Hydrobiology, Institute of Environmental Biology, Adam Mickiewicz University in Poznan, Poznań, Poland.

PMID: 34773676
PMCID: PMC9299714
DOI: 10.1111/gcb.15989

Microalgae colonization of different microplastic polymers in experimental mesocosms across an environmental gradient

Veronica Nava et al. Glob Chang Biol. 2022 Feb.

. 2022 Feb;28(4):1402-1413.

doi: 10.1111/gcb.15989. Epub 2021 Dec 3.

Authors

Veronica Nava¹, Miguel G Matias^{2

3}, Andreu Castillo-Escrivà³, Beata Messyasz⁴, Barbara Leoni¹

Affiliations

¹ Department of Earth and Environmental Sciences, University of Milano-Bicocca, Milano, Italy.
² Department of Biogeografía y Cambio Global, Museo Nacional de Ciencias Naturales, CSIC, Madrid, Spain.
³ MED-Mediterranean Institute for Agriculture, Environment and Development, Rui Nabeiro Biodiversity Chair, Universidade de Évora, Évora, Portugal.
⁴ Department of Hydrobiology, Institute of Environmental Biology, Adam Mickiewicz University in Poznan, Poznań, Poland.

PMID: 34773676
PMCID: PMC9299714
DOI: 10.1111/gcb.15989

Abstract

A variety of organisms can colonize microplastic surfaces through biofouling processes. Heterotrophic bacteria tend to be the focus of plastisphere research; however, the presence of epiplastic microalgae within the biofilm has been repeatedly documented. Despite the relevance of biofouling in determining the fate and effects of microplastics in aquatic systems, data about this process are still scarce, especially for freshwater ecosystems. Here, our goal was to evaluate the biomass development and species composition of biofilms on different plastic polymers and to investigate whether plastic substrates exert a strong enough selection to drive species sorting, overcoming other niche-defining factors. We added microplastic pellets of high-density polyethylene (HDPE), polyethylene terephthalate (PET), and a mix of the two polymers in 15 lentic mesocosms in five different locations of the Iberian Peninsula, and after one month, we evaluated species composition and biomass of microalgae developed on plastic surfaces. Our results, based on 45 samples, showed that colonization of plastic surfaces occurred in a range of lentic ecosystems covering a wide geographical gradient and different environmental conditions (e.g., nutrient concentration, conductivity, macrophyte coverage). We highlighted that total biomass differed based on the polymer considered, with higher biomass developed on PET substrate compared to HDPE. Microplastics supported the growth of a rich and diversified community of microalgae (242 species), with some cosmopolite species. However, we did not observe species-specificity in the colonization of the different plastic polymers. Local species pool and nutrient concentration rather than polymeric composition seemed to be the determinant factor defying the community diversity. Regardless of specific environmental conditions, we showed that many species could coexist on the surface of relatively small plastic items, highlighting how microplastics may have considerable carrying capacity, with possible consequences on the wider ecological context.

Keywords: biofouling; epiplastic community; periphyton; phytobenthos; plastic colonization; plastisphere.

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Conflict of interest statement

The authors declare that there is no conflict of interest.

Figures

**FIGURE 1**
(a) Study area with location of the sites in which mesocosms are deployed. (b) Example picture of freshwater mesocosms (1000 L tanks). (c) Schematic representation of the 5 sites selected for our experiment, the 15 mesocosms (with three enclosures each), and the resulting 45 samples (of which 15 with HDPE, 15 with MIX, and 15 with PET)

**FIGURE 2**
Tukey boxplot of (a) density (cell cm⁻²), and (b) biomass (µg cm⁻²) of microalgae for different sites on the two plastic polymers and the “MIX” treatment. MR, Murcia; TL, Toledo; EV, Evora; PT, Porto; JC, Jaca

**FIGURE 3**
Alpha‐diversity for different plastic types expressed as number of species (“Species number”), Shannon index (“Shannon index”), inverse of Simpson index (“Inverse Simpson”), and Pielou's evenness index (“Pielou's evenness”)

**FIGURE 4**
Heatmap visualizing the biomass distribution of genera of microalgae across the samples. Only genera that were identified in at least 10% of the samples (n = 5) are reported. Biomass data were log₁₀(x + 1) transformed before plotting. Clusters have been calculated based on Bray‐Curtis distance. Clusters of samples (row cluster) have been calculated considering all the genera identified. The corresponding phylum for each genus is given in brackets: “Cya” Cyanobacteria, “B” Bacillariophyta, “Chl” Chlorophyta, “Cha” Charophyta, “E” Euglenozoa, “O” Ochrophyta, “Cry” Cryptophyta, and “M” Miozoa

**FIGURE 5**
(a) Non‐metric multidimensional scaling (NMDS) run on species‐level microalgae biomass with vectors of significant environmental variables. Vectors are significant at p < .05 (solid arrows) and p < .10 (dashed arrows). “PO4”: phosphate concentration; “NH4”: ammonium concentration; “SiO4”: silicate concentration; “NO3”: nitrate concentration; “% macrophyte”: coverage of macrophyte in percentage. (b) Surface fitting for the PO₄ ³⁻ concentration (bin width = 0.5)

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References

1. Abreu, I. , Ribeiro, H. , & Cunha, M. (2003). An Aeropalynological study of the Porto region (Portugal). Aerobiologia, 19(3), 235–241. 10.1023/B:AERO.0000006573.12721.e6 - DOI
1. Algarte, V. M. , Siqueira, T. , Landeiro, V. L. , Rodrigues, L. , Bonecker, C. C. , Rodrigues, L. C. , Santana, N. F. , Thomaz, S. M. , & Bini, L. M. (2017). Main predictors of periphyton species richness depend on adherence strategy and cell size. PLoS One, 12(7), e0181720. 10.1371/journal.pone.0181720 - DOI - PMC - PubMed
1. Alonso‐Sarría, F. , Martínez‐Hernández, C. , Romero‐Díaz, A. , Cánovas‐García, F. , & Gomariz‐Castillo, F. (2016). Main environmental features leading to recent land abandonment in murcia region (Southeast Spain). Land Degradation & Development, 27(3), 654–670. 10.1002/ldr.2447 - DOI
1. Amaral‐Zettler, L. A. , Zettler, E. R. , & Mincer, T. J. (2020). Ecology of the plastisphere. Nature Reviews Microbiology, 18(3), 139–151. 10.1038/s41579-019-0308-0 - DOI - PubMed
1. Amaral‐Zettler, L. A. , Zettler, E. R. , Slikas, B. , Boyd, G. D. , Donald, W. , Morrall, C. E. , Proskurowski, G. , & Mincer, T. J. (2015). The biogeography of the Plastisphere: Implications for policy. Frontiers in Ecology and the Environment, 13(10), 541–546. 10.1890/150017 - DOI

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Microalgae colonization of different microplastic polymers in experimental mesocosms across an environmental gradient

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Microalgae colonization of different microplastic polymers in experimental mesocosms across an environmental gradient

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