Culturable Rhodobacter and Shewanella species are abundant in estuarine turbidity maxima of the Columbia River
Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non-events in the Columbia River. Most probable number (MPN) counts of Mn-oxidizing or Mn-reducing heterotrophs were not s...
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Published in: | Environmental microbiology Vol. 13; no. 3; pp. 589 - 603 |
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Blackwell Publishing Ltd
01-03-2011
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Abstract | Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non-events in the Columbia River. Most probable number (MPN) counts of Mn-oxidizing or Mn-reducing heterotrophs were not statistically different from that of other heterotrophs (10³-10⁴ cells ml⁻¹) when grown in defined media, but counts of Mn oxidizers were significantly lower in nutrient-rich medium (13 cells ml⁻¹). MPN counts of Mn oxidizers were also significantly lower on Mn(III)-pyrophosphate and glycerol (21 cells ml⁻¹). Large numbers of Rhodobacter spp. were cultured from dilutions of 10⁻² to 10⁻⁵, and many of these were capable of Mn(III) oxidation. Up to c. 30% of the colonies tested LBB positive, and all 77 of the successfully sequenced LBB positive colonies (of varying morphology) yielded sequences related to Rhodobacter spp. qPCR indicated that a cluster of Rhodobacter isolates and closely related strains (95-99% identity) represented approximately 1-3% of the total Bacteria, consistent with clone library results. Copy numbers of SSU rRNA genes for either Rhodobacter spp. or Bacteria were four to eightfold greater during ETM events compared with non-events. Strains of a Shewanella sp. were retrieved from the highest dilutions (10⁻⁵) of Mn reducers, and were also capable of Mn oxidation. The SSU rRNA gene sequences from these strains shared a high identity score (98%) with sequences obtained in clone libraries. Our results support previous findings that ETMs are zones with high microbial activity. Results indicated that Shewanella and Rhodobacter species were present in environmentally relevant concentrations, and further demonstrated that a large proportion of culturable bacteria, including Shewanella and Rhodobacter spp., were capable of Mn cycling in vitro. |
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AbstractList | Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non-events in the Columbia River. Most probable number (MPN) counts of Mn-oxidizing or Mn-reducing heterotrophs were not statistically different from that of other heterotrophs (10
3
–10
4
cells ml
−1
) when grown in defined media, but counts of Mn oxidizers were significantly lower in nutrient-rich medium (13 cells ml
−1
). MPN counts of Mn oxidizers were also significantly lower on Mn(III)-pyrophosphate and glycerol (21 cells ml
−1
). Large numbers of
Rhodobacter
spp. were cultured from dilutions of 10
−2
to 10
−5
, and many of these were capable of Mn(III) oxidation. Up to
c
. 30% of the colonies tested LBB positive, and all 77 of the successfully sequenced LBB positive colonies (of varying morphology) yielded sequences related to
Rhodobacter
spp. qPCR indicated that a cluster of
Rhodobacter
isolates and closely related strains (95–99% identity) represented approximately 1–3% of the total
Bacteria
, consistent with clone library results. Copy numbers of SSU rRNA genes for either
Rhodobacter
spp. or
Bacteria
were four to eightfold greater during ETM events compared with non-events. Strains of a
Shewanella
sp. were retrieved from the highest dilutions (10
−5
) of Mn reducers, and were also capable of Mn oxidation. The SSU rRNA gene sequences from these strains shared a high identity score (98%) with sequences obtained in clone libraries. Our results support previous findings that ETMs are zones with high microbial activity. Results indicated that
Shewanella
and
Rhodobacter
species were present in environmentally relevant concentrations, and further demonstrated that a large proportion of culturable bacteria, including
Shewanella
and
Rhodobacter
spp., were capable of Mn cycling
in vitro
. Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non-events in the Columbia River. Most probable number (MPN) counts of Mn-oxidizing or Mn-reducing heterotrophs were not statistically different from that of other heterotrophs (103-104 cellsml-1) when grown in defined media, but counts of Mn oxidizers were significantly lower in nutrient-rich medium (13 cellsml-1). MPN counts of Mn oxidizers were also significantly lower on Mn(III)-pyrophosphate and glycerol (21 cellsml-1). Large numbers of Rhodobacter spp. were cultured from dilutions of 10-2 to 10-5, and many of these were capable of Mn(III) oxidation. Up to c. 30% of the colonies tested LBB positive, and all 77 of the successfully sequenced LBB positive colonies (of varying morphology) yielded sequences related to Rhodobacter spp. qPCR indicated that a cluster of Rhodobacter isolates and closely related strains (95-99% identity) represented approximately 1-3% of the total Bacteria, consistent with clone library results. Copy numbers of SSU rRNA genes for either Rhodobacter spp. or Bacteria were four to eightfold greater during ETM events compared with non-events. Strains of a Shewanella sp. were retrieved from the highest dilutions (10-5) of Mn reducers, and were also capable of Mn oxidation. The SSU rRNA gene sequences from these strains shared a high identity score (98%) with sequences obtained in clone libraries. Our results support previous findings that ETMs are zones with high microbial activity. Results indicated that Shewanella and Rhodobacter species were present in environmentally relevant concentrations, and further demonstrated that a large proportion of culturable bacteria, including Shewanella and Rhodobacter spp., were capable of Mn cycling in vitro. Summary Measurements of dissolved, ascorbate‐reducible and total Mn by ICP‐OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non‐events in the Columbia River. Most probable number (MPN) counts of Mn‐oxidizing or Mn‐reducing heterotrophs were not statistically different from that of other heterotrophs (103–104 cells ml−1) when grown in defined media, but counts of Mn oxidizers were significantly lower in nutrient‐rich medium (13 cells ml−1). MPN counts of Mn oxidizers were also significantly lower on Mn(III)‐pyrophosphate and glycerol (21 cells ml−1). Large numbers of Rhodobacter spp. were cultured from dilutions of 10−2 to 10−5, and many of these were capable of Mn(III) oxidation. Up to c. 30% of the colonies tested LBB positive, and all 77 of the successfully sequenced LBB positive colonies (of varying morphology) yielded sequences related to Rhodobacter spp. qPCR indicated that a cluster of Rhodobacter isolates and closely related strains (95–99% identity) represented approximately 1–3% of the total Bacteria, consistent with clone library results. Copy numbers of SSU rRNA genes for either Rhodobacter spp. or Bacteria were four to eightfold greater during ETM events compared with non‐events. Strains of a Shewanella sp. were retrieved from the highest dilutions (10−5) of Mn reducers, and were also capable of Mn oxidation. The SSU rRNA gene sequences from these strains shared a high identity score (98%) with sequences obtained in clone libraries. Our results support previous findings that ETMs are zones with high microbial activity. Results indicated that Shewanella and Rhodobacter species were present in environmentally relevant concentrations, and further demonstrated that a large proportion of culturable bacteria, including Shewanella and Rhodobacter spp., were capable of Mn cycling in vitro. Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM) events, compared with non-events in the Columbia River. Most probable number (MPN) counts of Mn-oxidizing or Mn-reducing heterotrophs were not statistically different from that of other heterotrophs (10³-10⁴ cells ml⁻¹) when grown in defined media, but counts of Mn oxidizers were significantly lower in nutrient-rich medium (13 cells ml⁻¹). MPN counts of Mn oxidizers were also significantly lower on Mn(III)-pyrophosphate and glycerol (21 cells ml⁻¹). Large numbers of Rhodobacter spp. were cultured from dilutions of 10⁻² to 10⁻⁵, and many of these were capable of Mn(III) oxidation. Up to c. 30% of the colonies tested LBB positive, and all 77 of the successfully sequenced LBB positive colonies (of varying morphology) yielded sequences related to Rhodobacter spp. qPCR indicated that a cluster of Rhodobacter isolates and closely related strains (95-99% identity) represented approximately 1-3% of the total Bacteria, consistent with clone library results. Copy numbers of SSU rRNA genes for either Rhodobacter spp. or Bacteria were four to eightfold greater during ETM events compared with non-events. Strains of a Shewanella sp. were retrieved from the highest dilutions (10⁻⁵) of Mn reducers, and were also capable of Mn oxidation. The SSU rRNA gene sequences from these strains shared a high identity score (98%) with sequences obtained in clone libraries. Our results support previous findings that ETMs are zones with high microbial activity. Results indicated that Shewanella and Rhodobacter species were present in environmentally relevant concentrations, and further demonstrated that a large proportion of culturable bacteria, including Shewanella and Rhodobacter spp., were capable of Mn cycling in vitro. |
Author | Simon, H. M. Baptista, A. M. Murphy, D. Bräuer, S. L. Adams, C. Kranzler, K. Zuber, P. Xu, M. Tebo, B. M. |
AuthorAffiliation | 3 Center for Coastal Margin Observation and Prediction, Oregon Health & Science University, Beaverton, OR 97006, USA 1 Department of Biology, Appalachian State University, Boone, NC 28608, USA 2 Division of Environmental and Biomolecular Systems, Oregon Health & Science University, Beaverton, OR 97006, USA |
AuthorAffiliation_xml | – name: 3 Center for Coastal Margin Observation and Prediction, Oregon Health & Science University, Beaverton, OR 97006, USA – name: 2 Division of Environmental and Biomolecular Systems, Oregon Health & Science University, Beaverton, OR 97006, USA – name: 1 Department of Biology, Appalachian State University, Boone, NC 28608, USA |
Author_xml | – sequence: 1 fullname: Bräuer, S.L – sequence: 2 fullname: Adams, C – sequence: 3 fullname: Kranzler, K – sequence: 4 fullname: Murphy, D – sequence: 5 fullname: Xu, M – sequence: 6 fullname: Zuber, P – sequence: 7 fullname: Simon, H.M – sequence: 8 fullname: Baptista, A.M – sequence: 9 fullname: Tebo, B.M |
BackLink | https://www.ncbi.nlm.nih.gov/pubmed/20977571$$D View this record in MEDLINE/PubMed |
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Snippet | Measurements of dissolved, ascorbate-reducible and total Mn by ICP-OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM)... Summary Measurements of dissolved, ascorbate‐reducible and total Mn by ICP‐OES revealed significantly higher concentrations during estuarine turbidity maxima... Measurements of dissolved, ascorbate‐reducible and total Mn by ICP‐OES revealed significantly higher concentrations during estuarine turbidity maxima (ETM)... |
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SubjectTerms | Bacteria - classification Bacteria - genetics Bacteria - isolation & purification Manganese - metabolism Oxidation-Reduction Phylogeny Rhodobacter Rhodobacter - classification Rhodobacter - isolation & purification Rhodobacter - metabolism Rivers - microbiology Shewanella Shewanella - classification Shewanella - isolation & purification Shewanella - metabolism |
Title | Culturable Rhodobacter and Shewanella species are abundant in estuarine turbidity maxima of the Columbia River |
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