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1. Beyond dikarya: 28S metabarcoding uncovers cryptic fungal lineages across a tidal estuary

   https://doi.org/10.1186/s40793-025-00786-3  

   Thompson, Madeleine A; Lazo-Murphy, Birch Maxwell; Pfirrmann, Bruce W; Strosnider, William_H J; Pinckney, James L; Peng, Xuefeng (October 2025, Environmental Microbiome)

   Fungi are key drivers of biogeochemical processes, yet marine fungi remain understudied and under-characterized due to primer biases and database gaps. In this study, we conducted a metabarcoding survey targeting the small and large subunit rRNA genes and the internal transcribed spacer region of fungi (18S, 28S, and ITS2) in the sediment and surface water of salt and brackish marshes in the North Inlet—Winyah Bay estuarine system (Georgetown, South Carolina, USA). The universal 18S/16S primer set (515F-Y and 926R) identified few fungal taxa. The ITS2 primer set (ITS3mix and ITS4) revealed high diversity among Dikarya but failed to capture the full extent of early diverging fungi (EDF). In contrast, the 28S primer set (LR0R and LF402) excelled at identifying EDF lineages, including Chytridiomycota, Mucoromycota, Zoopagomycota, and Blastocladiomycota, many of which dominated the brackish marsh sampling site but were less prevalent in the salt marsh sampling sites. Over half of the fungal OTUs identified by the 28S primer set were from EDF lineages. Copy-normalized 28S qPCR showed that EDF were more abundant in brackish sediments than in the salt marsh. Several putative denitrifying fungi, primarily species from Trichoderma and Purpureocillium, were also detected, suggesting overlooked functional guilds that may contribute to estuarine nitrogen cycling. A FUNGuild analysis found that most lineages were saprotrophic. Overall, our findings show that EDF are key contributors to community differences across salinity gradients and may play more important functional roles in coastal biogeochemistry than is currently understood. The 28S primer set is ideal for marine fungal metabarcoding because it provides comprehensive taxonomic coverage and enables phylogenetic analysis. 

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2. Heterogeneous landscape promotes distinct microbial communities in an imperiled scrub ecosystem

   https://doi.org/10.1080/00275514.2023.2258268  

   David, Aaron S.; Hernandez, Damian J.; Menges, Eric S.; Sclater, Vivienne L.; Afkhami, Michelle E.; Searcy, Christopher A. (November 2023, Mycologia)

   Habitat heterogeneity is a key driver of biodiversity of macroorganisms, yet how heterogeneity structures belowground microbial communities is not well understood. Importantly, belowground microbial communities may respond to any number of abiotic, biotic, and spatial drivers found in heterogeneous environments. Here, we examine potential drivers of prokaryotic and fungal communities in soils across the heterogenous landscape of the imperiled Florida scrub, a pyrogenic ecosystem where slight differences in elevation lead to large changes in water and nutrient availability and vegetation composition. We employ a comprehensive, large-scale sampling design to characterize the communities of prokaryotes and fungi associated with three habitat types and two soil depths (crust and subterranean) to evaluate (i) differences in microbial communities across these heterogeneous habitats, (ii) the relative roles of abiotic, biotic, and spatial drivers in shaping community structure, and (iii) the distribution of fungal guilds across these habitats. We sequenced soils from 40 complete replicates of habitat × soil depth combinations and sequenced the prokaryotic 16S and fungal internal transcribed spacer (ITS) regions using Illumina MiSeq. Habitat heterogeneity generated distinct communities of soil prokaryotes and fungi. Spatial distance played a role in structuring crust communities, whereas subterranean microbial communities were primarily structured by the shrub community, whose roots they presumably interacted with. This result helps to explain the unexpected transition we observed between arbuscular mycorrhiza–dominated soils at low-elevation habitats to ectomycorrhiza-dominated soils at high-elevation habitats. Our results challenge previous notions of environmental determinism of microbial communities and generate new hypotheses regarding symbiotic relationships across heterogeneous environments. 

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3. Size fractionation informs microbial community composition and interactions in the eastern tropical North Pacific Ocean

   https://doi.org/10.1093/femsmc/xtae028  

   Thompson, Madeleine A; Valentine, David L; Peng, Xuefeng (September 2024, FEMS Microbes)

   Abstract Marine microorganisms are drivers of biogeochemical cycles in the world’s oceans, including oxygen minimum zones (OMZs). Using a metabarcoding survey of the 16S rRNA gene, we investigated prokaryotic communities, as well as their potential interactions with fungi, at the coastal, offshore, and peripheral OMZ of the eastern tropical North Pacific. Water samples were collected along a vertical oxygen gradient, and large volumes were filtered through three size fractions, 0.22, 2, and 22 µm. The changes in community composition along the oxygen gradient were driven by Planctomycetota, Bacteroidota, Verrucomicrobiota, and Gammaproteobacteria; most are known degraders of marine polysaccharides and usually associated with the large particle-associated (LPA) community. The relative abundance of Nitrososphaerota, Alphaproteobacteria, Actinomycetota, and Nitrospinota was high in free-living and small particle-associated (SPA) communities. Network analyses identified putative interactions between fungi and prokaryotes in the particle-associated fractions, which have been largely overlooked in the ocean. In the SPAnetwork analysis, fungal amplicon sequence variants (ASVs) had exclusively negative connections with SAR11 nodes. In the LPA network analysis, fungal ASVs displayed both negative and positive connections with Pseudomonadota, SAR324, and Thermoplasmatota. Our findings demonstrate the utility of three-stage size-fractioned filtration in providing novel insights into marine microbial ecology. 

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4. Mill dams impact microbiome structure and depth distribution in riparian sediments

   https://doi.org/10.3389/fmicb.2023.1161043  

   Kan, Jinjun; Peck, Erin K.; Zgleszewski, Laura; Peipoch, Marc; Inamdar, Shreeram (June 2023, Frontiers in Microbiology)

   Introduction Damming has substantially fragmented and altered riverine ecosystems worldwide. Dams slow down streamflows, raise stream and groundwater levels, create anoxic or hypoxic hyporheic and riparian environments and result in deposition of fine sediments above dams. These sediments represent a good opportunity to study human legacies altering soil environments, for which we lack knowledge on microbial structure, depth distribution, and ecological function. Methods Here, we compared high throughput sequencing of bacterial/ archaeal and fungal community structure (diversity and composition) and functional genes (i.e., nitrification and denitrification) at different depths (ranging from 0 to 4 m) in riparian sediments above breached and existing milldams in the Mid-Atlantic United States. Results We found significant location- and depth-dependent changes in microbial community structure. Proteobacteria, Bacteroidetes, Firmicutes, Actinobacteria, Chloroflexi, Acidobacteria, Planctomycetes, Thaumarchaeota, and Verrucomicrobia were the major prokaryotic components while Ascomycota, Basidiomycota, Chytridiomycota, Mortierellomycota, Mucoromycota, and Rozellomycota dominated fungal sequences retrieved from sediment samples. Ammonia oxidizing genes ( amo A for AOA) were higher at the sediment surface but decreased sharply with depth. Besides top layers, denitrifying genes ( nos Z) were also present at depth, indicating a higher denitrification potential in the deeper layers. However, these results contrasted with in situ denitrification enzyme assay (DEA) measurements, suggesting the presence of dormant microbes and/or other nitrogen processes in deep sediments that compete with denitrification. In addition to enhanced depth stratification, our results also highlighted that dam removal increased species richness, microbial diversity, and nitrification. Discussion Lateral and vertical spatial distributions of soil microbiomes (both prokaryotes and fungi) suggest that not only sediment stratification but also concurrent watershed conditions are important in explaining the depth profiles of microbial communities and functional genes in dammed rivers. The results also provide valuable information and guidance to stakeholders and restoration projects. 

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5. Diversity at single nucleotide to pangenome scales among sulfur cycling bacteria in salt marshes

   https://doi.org/10.1128/aem.00988-23  

   Pérez Castro, Sherlynette; Peredo, Elena L.; Mason, Olivia U.; Vineis, Joseph; Bowen, Jennifer L.; Mortazavi, Behzad; Ganesh, Anakha; Ruff, S. Emil; Paul, Blair G.; Giblin, Anne E.; et al (November 2023, Applied and Environmental Microbiology)

   Glass, Jennifer B. (Ed.)

   ABSTRACT Sulfur-cycling microbial communities in salt marsh rhizosphere sediments mediate a recycling and detoxification system central to plant productivity. Despite the importance of sulfur-cycling microbes, their biogeographic, phylogenetic, and functional diversity remain poorly understood. Here, we use metagenomic data sets from Massachusetts (MA) and Alabama (AL) salt marshes to examine the distribution and genomic diversity of sulfur-cycling plant-associated microbes. Samples were collected from sediments underSporobolus alterniflorusandSporobolus pumilusin separate MA vegetation zones, and underS. alterniflorusandJuncus roemerianusco-occuring in AL. We grouped metagenomic data by plant species and site and identified 38 MAGs that included pathways for sulfate reduction or sulfur oxidation. Phylogenetic analyses indicated that 29 of the 38 were affiliated with uncultivated lineages. We showed differentiation in the distribution of MAGs between AL and MA, betweenS. alterniflorusandS. pumilusvegetation zones in MA, but no differentiation betweenS. alterniflorusandJ. roemerianusin AL. Pangenomic analyses of eight ubiquitous MAGs also detected site- and vegetation-specific genomic features, including varied sulfur-cycling operons, carbon fixation pathways, fixed single-nucleotide variants, and active diversity-generating retroelements. This genetic diversity, detected at multiple scales, suggests evolutionary relationships affected by distance and local environment, and demonstrates differential microbial capacities for sulfur and carbon cycling in salt marsh sediments. IMPORTANCESalt marshes are known for their significant carbon storage capacity, and sulfur cycling is closely linked with the ecosystem-scale carbon cycling in these ecosystems. Sulfate reducers are key for the decomposition of organic matter, and sulfur oxidizers remove toxic sulfide, supporting the productivity of marsh plants. To date, the complexity of coastal environments, heterogeneity of the rhizosphere, high microbial diversity, and uncultured majority hindered our understanding of the genomic diversity of sulfur-cycling microbes in salt marshes. Here, we use comparative genomics to overcome these challenges and provide an in-depth characterization of sulfur-cycling microbial diversity in salt marshes. We characterize communities across distinct sites and plant species and uncover extensive genomic diversity at the taxon level and specific genomic features present in MAGs affiliated with uncultivated sulfur-cycling lineages. Our work provides insights into the partnerships in salt marshes and a roadmap for multiscale analyses of diversity in complex biological systems. 

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