Abstract
Surfaces of marine macrophytes are inhabited by diverse microbial communities. Most studies focusing on epiphytic communities of macrophytes did not take into account temporal changes or applied low sampling frequency approaches. The seasonal dynamics of epiphytic microbial communities was determined in a meadow of Cymodocea nodosa invaded by Caulerpa cylindracea and in a monospecific settlement of C. cylindracea at monthly intervals. For comparison the ambient prokaryotic picoplankton community was also characterized. At the OTU level, the microbial community composition differed between the ambient water and the epiphytic communities exhibiting host-specificity. Also, successional changes were observed connected to the macrophyte growth cycle. Taxonomic analysis, however, showed similar high rank taxa (phyla and classes) in the ambient water and the epiphytic communities, with the exception of Desulfobacterota, which were only found on C. cylindracea. Cyanobacteria showed seasonal changes while other high rank taxa were present throughout the year. In months of high Cyanobacteria presence the majority of cyanobacterial sequences were classified as Pleurocapsa. Phylogenetic groups present throughout the year (e.g., Saprospiraceae, Rhodobacteraceae, members without known relatives within Gammaproteobacteria, Desulfatitalea, and members without known relatives within Desulfocapsaceae) constituted most of the sequences, while less abundant taxa showed seasonal patterns connected to the macrophyte growth cycle. Taken together, epiphytic microbial communities of the seagrass C. nodosa and the macroalga C. cylindracea appear to be host-specific and contain taxa that undergo successional changes.
Highlights
Marine macrophytes are important ecosystem engineers forming close associations with microorganisms belonging to all three domains of life (Egan et al, 2013; Tarquinio et al, 2019)
A total of 35 samples originating from epiphytic archeal and bacterial communities associated with surfaces of the seagrass C. nodosa and the macroalga C. cylindracea were analyzed
Higher values were found for C. cylindracea than for C. nodosa (Number of operational taxonomic units (OTUs), 1,063.7 ± 210.6 OTUs) and lowest values were obtained for the microbial community of the ambient seawater (Number of OTUs, 531.0 ± 143.9 OTUs; Kruskal-Wallis, p < 0.0001) (Supplementary Figure 2 and Supplementary Tables 2, 3)
Summary
Marine macrophytes (seagrasses and macroalgae) are important ecosystem engineers forming close associations with microorganisms belonging to all three domains of life (Egan et al, 2013; Tarquinio et al, 2019). Macrophytes can promote growth of associated microbes by nutrient exudation (Wood and Hayasaka, 1981), while in return microorganisms may support macrophyte performance through improved nutrient availability (Nielsen et al, 2001; de Oliveira et al, 2012), phytohormone production (Matsuo et al, 2003; Celdran et al, 2012), and protection from toxic compounds (Küsel et al, 2006), oxidative stress (Sanchez-Amat et al, 2010), biofouling organisms (Dobretsov and Qian, 2002), and pathogens (Penesyan et al, 2009) Besides these positive interactions, macrophytes can negatively impact the associated microbes by producing reactive oxygen species (Weinberger, 2007) and secondary metabolites (Saha et al, 2011)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
