Species turnover underpins the effect of elevated CO2 on biofilm communities through early succession

Ro J. Allen , Tina C. Summerfield , Ben P. Harvey , Sylvain Agostini , Samuel P.S. Rastrick , Jason M. Hall-Spencer , Linn J. Hoffmann
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引用次数: 1

Abstract

Biofilms harbour a wealth of microbial diversity and fulfil key functions in coastal marine ecosystems. Elevated carbon dioxide (CO2) conditions affect the structure and function of biofilm communities, yet the ecological patterns that underpin these effects remain unknown. We used high-throughput sequencing of the 16S and 18S rRNA genes to investigate the effect of elevated CO2 on the early successional stages of prokaryotic and eukaryotic biofilms at a CO2 seep system off Shikine Island, Japan. Elevated CO2 profoundly affected biofilm community composition throughout the early stages of succession, leading to greater compositional homogeneity between replicates and the proliferation of the potentially harmful algae Prymnesium sp. and Biddulphia biddulphiana. Species turnover was the main driver of differences between communities in reference and high CO2 conditions, rather than differences in richness or evenness. Our study indicates that species turnover is the primary ecological pattern that underpins the effect of elevated CO2 on both prokaryotic and eukaryotic components of biofilm communities, indicating that elevated CO2 conditions represent a distinct niche selecting for a distinct cohort of organisms without the loss of species richness.

物种更替通过早期演替支持CO2升高对生物膜群落的影响
生物膜蕴藏着丰富的微生物多样性,在沿海海洋生态系统中发挥着关键作用。二氧化碳浓度升高会影响生物膜群落的结构和功能,但支撑这些影响的生态模式尚不清楚。我们利用16S和18S rRNA基因的高通量测序,在日本Shikine岛附近的CO2渗透系统中研究了升高的CO2对原核和真核生物膜早期连续阶段的影响。在演为的早期阶段,CO2的升高深刻地影响了生物膜群落的组成,导致重复之间的组成同质性增强,并导致潜在有害藻类Prymnesium sp.和Biddulphia biddulphiana的增殖。物种更替是参考和高CO2条件下群落间差异的主要驱动因素,而不是丰富度或均匀度的差异。我们的研究表明,物种更替是支撑二氧化碳升高对生物膜群落原核和真核成分影响的主要生态模式,表明二氧化碳升高代表了一种独特的生态位选择,而不会损失物种丰富度。
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