Your search keyword '"Sollai, M."' showing total 3 results

1. Network analysis of 16S rRNA sequences suggests microbial keystone taxa contribute to marine N2O cycling.

Author

Jameson, Brett D., Murdock, Sheryl A., Ji, Qixing, Stevens, Catherine J., Grundle, Damian S., and Kim Juniper, S.

Subjects

RIBOSOMAL RNA, MICROBIAL enzymes, SULFUR cycle, MICROBIAL communities, NITROUS oxide, FUNCTIONAL groups

Abstract

The mechanisms by which large-scale microbial community function emerges from complex ecological interactions between individual taxa and functional groups remain obscure. We leveraged network analyses of 16S rRNA amplicon sequences obtained over a seven-month timeseries in seasonally anoxic Saanich Inlet (Vancouver Island, Canada) to investigate relationships between microbial community structure and water column N2O cycling. Taxa separately broadly into three discrete subnetworks with contrasting environmental distributions. Oxycline subnetworks were structured around keystone aerobic heterotrophs that correlated with nitrification rates and N2O supersaturations, linking N2O production and accumulation to taxa involved in organic matter remineralization. Keystone taxa implicated in anaerobic carbon, nitrogen, and sulfur cycling in anoxic environments clustered together in a low-oxygen subnetwork that correlated positively with nitrification N2O yields and N2O production from denitrification. Close coupling between N2O producers and consumers in the anoxic basin is indicated by strong correlations between the low-oxygen subnetwork, PICRUSt2-predicted nitrous oxide reductase (nosZ) gene abundances, and N2O undersaturation. This study implicates keystone taxa affiliated with common ODZ groups as a potential control on water column N2O cycling and provides a theoretical basis for further investigations into marine microbial interaction networks. Network analysis of 16S rRNA-sequencing data collected over six months in the Sannich Inlet on Vancouver Island, Canada, suggests keystone microbial taxa that might contribute to water column N2O production and accumulation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Early human impact on lake cyanobacteria revealed by a Holocene record of sedimentary ancient DNA.

Author

Nwosu, Ebuka Canisius, Brauer, Achim, Monchamp, Marie-Eve, Pinkerneil, Sylvia, Bartholomäus, Alexander, Theuerkauf, Martin, Schmidt, Jens-Peter, Stoof-Leichsenring, Kathleen R., Wietelmann, Theresa, Kaiser, Jerome, Wagner, Dirk, and Liebner, Susanne

Subjects

FOSSIL DNA, CYANOBACTERIAL toxins, HOLOCENE Epoch, LAKE ecology, COMMUNITIES, LAKES, CYANOBACTERIA, MICROCYSTINS

Abstract

Sedimentary DNA-based studies revealed the effects of human activity on lake cyanobacteria communities over the last centuries, yet we continue to lack information over longer timescales. Here, we apply high-resolution molecular analyses on sedimentary ancient DNA to reconstruct the history of cyanobacteria throughout the Holocene in a lake in north-eastern Germany. We find a substantial increase in cyanobacteria abundance coinciding with deforestation during the early Bronze Age around 4000 years ago, suggesting increased nutrient supply to the lake by local communities settling on the lakeshore. The next substantial human-driven increase in cyanobacteria abundance occurred only about a century ago due to intensified agricultural fertilisation which caused the dominance of potentially toxic taxa (e.g., Aphanizomenon). Our study provides evidence that humans began to locally impact lake ecology much earlier than previously assumed. Consequently, managing aquatic systems today requires awareness of the legacy of human influence dating back potentially several millennia. Analysis of sedimentary DNA through time in a German lake shows a spike in cyanobacteria abundance coinciding with human activity in the Bronze Age. [ABSTRACT FROM AUTHOR]

Published

2023

3. Network analysis of 16S rRNA sequences suggests microbial keystone taxa contribute to marine N2O cycling

Author

Jameson, Brett D., Murdock, Sheryl A., Ji, Qixing, Stevens, Catherine J., Grundle, Damian S., and Kim Juniper, S.

Published

2023