Abstract
Invasive plants have extensive impacts on ecosystem function and biodiversity globally. Our inability to manage invasive species stems in part from a lack of understanding of the processes that control their successful establishment and spread. To date, studies have largely considered how above-ground processes control native/invasive plant interactions. Emerging research from terrestrial and wetland ecosystems demonstrates that below-ground processes under microbial control can determine the outcome of interactions between native and invasive plants. Whether sediment microbes modify the success of invasive macrophytes in marine ecosystems is untested, despite marine sediment microbes controlling many ecological processes (e.g. nutrient cycling) comparable to those in terrestrial ecosystems. We first show that sediment bacterial communities differ between the native seagrass Zostera capricorni and the invasive alga Caulerpa taxifolia and that those differences relate to functional changes in sulfur cycling between the macrophytes. Second, by experimentally manipulating the microbial communities we show that intact microbial communities in Z. capricorni sediments provide biotic resistance by reducing C. taxifolia fragment growth 119% compared to when they are inactive, and intact microbial communities in C. taxifolia sediments have positive feedbacks by increasing fragment growth 200%. Thus, similar to terrestrial ecosystems, microorganisms appear to indirectly control the success of invasive macrophytes in marine ecosystems.
Highlights
Understanding the processes driving the establishment and spread of invasive plants is one of the great challenges for managing global biodiversity
Studies conducted at multiple sites in Australia and the Mediterranean show that sediments colonised by the invasive alga Caulerpa taxifolia – one of the 100 most invasive species in the world12 – are often hypoxic, and have higher total sulphide pools and higher levels of acid volatile sulphides compared to sediments in native seagrass competitors and unvegetated sediments[13,14,15,16,17,18,19,20]
We used 16S rRNA gene sequencing to determine if the structure of bacterial communities differed in sediment beds of C. taxifolia and the native seagrass Zostera muelleri subsp. capricorni (Asch.)
Summary
Bacterial communities from each of three sediment types were diverse, with 3040 ± 29 (mean and SD), 3111 ± 46 and 2968 ± 276 OTUs observed in unvegetated, C. taxifolia and Z. capricorni sediments, respectively. Sediments occupied by C. taxifolia had a marked enrichment in OTUs belonging to the phylum Delta-proteobacteria, including the family Desulfobulbaceae and the genus Desulfococcus (Figs 1, 3 and S3) This family and the genus are generally associated with the reduction of sulfate, sulfite, thiosulfate or sulfur in anaerobic environments[25] and would be driving the production of H2S as previously observed in C. taxifolia sediments by chemical analysis[13, 16, 26]. Sediments occupied by Z. capricorni had greater abundances of members of the Gamma- and Epsilon-proteobacteria, the latter including the genus Sulfurimonas These bacteria have been identified in the oxidation of sulfur in aerobic environments with the production of sulfate[23]. A full understanding of the importance of microorganisms in mediating the success of invasive species is essential in defining invasion risks to soft-sediment marine ecosystems
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