PT  - JOURNAL ARTICLE
AU  - Joeselle M. Serrana
AU  - Bin Li
AU  - Tetsuya Sumi
AU  - Yasuhiro Takemon
AU  - Kozo Watanabe
TI  - Profiling the microbial community structure and functional diversity of a dam-regulated river undergoing gravel bar restoration
AID  - 10.1101/2020.01.25.919381
DP  - 2020 Jan 01
TA  - bioRxiv
PG  - 2020.01.25.919381
4099  - http://biorxiv.org/content/early/2020/01/25/2020.01.25.919381.short
4100  - http://biorxiv.org/content/early/2020/01/25/2020.01.25.919381.full
AB  - Background River restoration efforts are expected to influence and change the diversity and functions of microbial communities following the recovery of habitat characteristics in the river ecosystem. The recreation or restoration of gravel bars in the Trinity River in California aims to rehabilitate the environmental heterogeneity downstream of the dam impounded channel. Here, we profiled the community composition, estimated diversity, and annotated putative metabolic functions of the sediment microbial communities to assess whether the construction and restoration of gravel bars in the Trinity River in California enhanced environmental heterogeneity, with the increase in the microbial beta diversity of these in-channel structures against the free-flowing reach of the main channel with comparison to its undisturbed tributaries.Results Microbial community composition of the free-flowing (i.e., no gravel bars) communities were relatively closer regardless of dam influence, whereas the Trinity River gravel bar and tributaries’ gravel bar communities were highly dissimilar. Proteobacteria, Bacteroidetes, and Acidobacteria were the highly abundant sediment microbial phyla on most sites, specifically in the Trinity River gravel bar communities. Putative functional annotation of microbial taxa revealed that chemoheterotrophy and aerobic chemoheterotrophy were the most prevalent microbial processes, with the Trinity River gravel bars having relatively higher representations. The considerably large abundance of heterotrophic taxa implies that gravel bars provide suitable areas for heterotrophic microorganisms with metabolic functions contributing to the net respiration in the river.Conclusions Our results provide supporting evidence on the positive impact of habitat restoration being conducted in the Trinity River with the non-dam influenced, undisturbed tributaries as the basis of comparison. Gravel bar recreation and restoration contributed to the increased microbial biodiversity through the restoration of environmental heterogeneity at the river scale. We provided valuable insights into the potential microbial processes in the sediment that might be contributing to the biogeochemical processes carried out by the microbial communities in the Trinity River. The significant positive correlation between the functional diversity of the identified microbial taxa and beta diversity suggests that differences in the detected metabolic functions were closely related to dissimilarities in community composition.TRRPTrinity River Restoration Program;TTrinity River;RReference tributaries;BGravel bar;FFree-flowing segment;UZUp-welling zone of gravel bar;DZDown-welling of gravel bar;USupstream of free-flowing segment;DSdownstream of free-flowing segment;DODissolved oxygen;NH4-NAmmonium nitrogen;NO3-NNitrate nitrogen;AFDMAsh-free dry mass;TSSTotal suspended solids;ASVsAmplicon sequence variants;FAPROTAXFunctional annotation of prokaryotic taxa;VIFVariance inflation factors;NMDSNonmetric multidimensional scaling;dbRDADistance-based redundancy analysis;PCoAPrincipal coordinates analysis;ANOSIManalysis of similarity;PERMANOVAPermutational multivariate analysis of variance.