Yunyun Fu scite author profile

Genes encoding gene transfer agent (GTA) particles are well conserved in bacteria of the order Rhodobacterales. Members of this order are abundant in diverse marine environments, frequently accounting for as much as 25% of the total bacterial community. Conservation of the genes encoding GTAs allows their use as diagnostic markers of Rhodobacterales in biogeographical studies. The first survey of the diversity of Rhodobacterales based on the GTA major capsid gene was conducted in a warm temperate estuarine ecosystem, the Chesapeake Bay, but the biogeography of Rhodobacterales has not been explored extensively. This study investigates Rhodobacterales diversity in the cold subarctic water near Newfoundland, Canada. Our results suggest that the subarctic region of the North Atlantic contains diverse Rhodobacterales communities in both winter and summer, and that the diversity of the Rhodobacterales community in the summer Newfoundland coastal water is higher than that found in the Chesapeake Bay, in either the summer or winter. Approximately one-third of GTA sequences retrieved from the subarctic waters were most closely related to those from bacteria isolated from sea ice or cold regions. Distinguishable diversity patterns were found between the temperate and subarctic waters, providing further support for niche adaptation of specific Rhodobacterales members to unique environments. We also demonstrate that a number of Rhodobacterales strains, from both the subarctic and temperate locations, express the GTA major capsid protein. This provides robust evidence that the widespread conservation of GTA genes in the Rhodobacterales may result in the production of functionally similar and active GTA systems in these bacteria in different environments.

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Water mass and depth determine the distribution and diversity ofRhodobacteralesin an Arctic marine system

Keats

Rivkin

et al. 2013

FEMS Microbiol Ecol

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Marine Rhodobacterales are recognized as a widespread, abundant, and metabolically versatile bacterial group in the world's oceans. They also show a nearly universal conservation of the genes for production of gene transfer agents (GTAs), virus-like particles that mediate genetic exchange between cells. It is not yet clear what factors determine the distribution of the various taxonomic subgroups of this order. To address this question, we analyzed the Rhodobacterales communities in 10 seawater samples from northern Baffin Bay collected during September 2008. A conserved gene from the GTA gene cluster was used to characterize the Rhodobacterales community structure. A total of 320 clones from 10 clone libraries were sequenced, and 22 operational taxonomic units representing putative species and 13 clusters representing putative genera were identified. A cluster related to Octadecabacter comprised 59% of total clones from the northern Baffin Bay. Phylogenetic analysis of the clones showed that the Rhodobacterales communities had distinct compositions in the different water masses that were sampled. A change in community structure related to depth was also observed. Therefore, in northern Baffin Bay where two ocean currents meet and mix, the Rhodobacterales community structures were primarily determined by water mass and depth.

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Effects of Vertical Water Mass Segregation on Bacterial Community Structure in the Beaufort Sea

Rivkin

Lang

2019

Microorganisms

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The Arctic Ocean is one of the least well-studied marine microbial ecosystems. Its low-temperature and low-salinity conditions are expected to result in distinct bacterial communities, in comparison to lower latitude oceans. However, this is an ocean currently in flux, with climate change exerting pronounced effects on sea-ice coverage and freshwater inputs. How such changes will affect this ecosystem are poorly constrained. In this study, we characterized the bacterial community compositions at different depths in both coastal, freshwater-influenced, and pelagic, sea-ice-covered locations in the Beaufort Sea in the western Canadian Arctic Ocean. The environmental factors controlling the bacterial community composition and diversity were investigated. Alphaproteobacteria dominated the bacterial communities in samples from all depths and stations. The Pelagibacterales and Rhodobacterales groups were the predominant taxonomic representatives within the Alphaproteobacteria. Bacterial communities in coastal and offshore samples differed significantly, and vertical water mass segregation was the controlling factor of community composition among the offshore samples, regardless of the taxonomic level considered. These data provide an important baseline view of the bacterial community in this ocean system that will be of value for future studies investigating possible changes in the Arctic Ocean in response to global change and/or anthropogenic disturbance.

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Yunyun Fu

High diversity of Rhodobacterales in the subarctic North Atlantic Ocean and gene transfer agent protein expression in isolated strains

Water mass and depth determine the distribution and diversity ofRhodobacteralesin an Arctic marine system

Effects of Vertical Water Mass Segregation on Bacterial Community Structure in the Beaufort Sea

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