Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - WOR-2-8_12 metagenome

Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - WOR-3-8_10 metagenome

Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - WOR-1-36_30 metagenome

Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - WOR-2-30_32 metagenome

Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - WOR-1-52-54 metagenome

Project description:Marine sediment microbial communities from White Oak River estuary, North Carolina - itags targeted loci environmental

Project description:Marine subseafloor sediment microbial communities, sample from White Oak River Estuary, NC, USA 14E metagenome

Project description:To characterize the taxonomic and functional diversity of biofilms on plastics in marine environments, plastic pellets (PE and PS, ø 3mm) and wooden pellets (as organic control) were incubated at three stations: at the Baltic Sea coast in Heiligendamm (coast), in a dead branch of the river Warnow in Warnemünde (inlet), and in the Warnow estuary (estuary). After two weeks of incubation, all pellets were frozen for subsequent metagenome sequencing and metaproteomic analysis. Biofilm communities in the samples were compared on multiple levels: a) between the two plastic materials, b) between the individual incubation sites, and c) between the plastic materials and the wooden control. Using a semiquantitative approach, we established metaproteome profiles, which reflect the dominant taxonomic groups as well as abundant metabolic functions in the respective samples.

Project description:White Oak River sediments Metagenome

Project description:The objective was to identify functional genes encoded by Fungi and fungal-like organisms to assess putative ecological roles Using the GeoChip microarray, we detected fungal genes involved in the complete assimilation of nitrate and the degradation of lignin, as well as evidence for Partitiviridae (a mycovirus) that likely regulates fungal populations in the marine environment. These results demonstrate the potential for fungi to degrade terrigenously-sourced molecules, such as permafrost and compete with algae for nitrate during blooms. Ultimately, these data suggest that marine fungi could be as important in oceanic ecosystems as they are in freshwater environments.