Experimental insights into the importance of aquatic bacterial community composition to the degradation of dissolved organic matter

Logue, Jürg Brendan; Stedmon, Colin A.; Kellerman, Anne M.; Nielsen, Nikoline Juul; Andersson, Anders F.; Laudon, Hjalmar; Lindström, Eva S.; Kritzberg, Emma S.

doi:10.1038/ismej.2015.131

Cited by 401 publications

(255 citation statements)

References 53 publications

(34 reference statements)

Supporting

Mentioning

245

Contrasting

Order By: Relevance

“…In addition, many sequenced phylotypes, such as Nitrospira sp, Stenotrophomonas sp and Methylobac-5 terium sp have been associated with degradation capabilities (Cycoń et al, 2017;Daims et al, 2001;Wang et al, 2015). In short, the MAR microbial ecosystem studied in this work presents many more phylotypes than previous studies reported in groundwater systems (Logue et al, 2015), and thus, MAR can be considered an efficient remediation system.…”

Section: Matching Groundwater Model Ecological Disturbance Principlementioning

confidence: 71%

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Barba¹,

Folch²,

Gaju³

et al. 2018

Preprint

View full text Add to dashboard Cite

Abstract. Managed Aquifer Recharge (MAR) is a worldwide used technique to increase the availability of water resources.We study how MAR modifies microbial ecosystems, and its implications for enhancing biodegradation processes to eventually improve groundwater quality. We compare soil and groundwater samples taken from a MAR facility located in NE Spain during recharge (with the facility operating continuously for several months) and after four months of no recharge. The study demonstrates a strong correlation between soil and water microbial prints with respect to sampling location along the mapped 5 infiltration path. In particular, managed recharge practices disrupt groundwater ecosystems by modifying diversity indices and the composition of microbial communities, indicating that infiltration favors the growth of certain populations. Analysis of the genetic profiles showed the presence of nine different bacterial phyla in the facility, revealing high biological diversity at the highest taxonomic range. In fact, the microbial population patterns under recharge conditions agree with the Intermediate Disturbance Hypothesis. Moreover, DNA sequence analysis of excised DGGE band patterns revealed the existence of indicator 10 species linked to MAR, most notably Dehalogenimonas sp, Nitrospira sp and Vogesella sp. Our real facility multidisciplinary study (hydrological, geochemical and microbial), involving soil and groundwater samples, support that MAR is a naturallybased, passive, and efficient technique with broad implications for the biodegradation of pollutants dissolved in water.

show abstract

Section: Matching Groundwater Model Ecological Disturbance Principlementioning

confidence: 71%

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Barba¹,

Folch²,

Gaju³

et al. 2018

Preprint

View full text Add to dashboard Cite

show abstract

“…S3), indicated that soil extract additions selected for copiotrophic bacteria, rare under oligotrophic conditions, but preponderant during periods of high allochthonous loadings. This agrees with previous observations from field (Crump et al ., 2003; Roiha et al ., 2011) and laboratory experiments (Logue et al ., 2016) showing that rapid shifts in community composition take place upon soil organic matter input. The loss and prevalence of the taxa determined in our study may be explained by their different functional adaptability, including differences in resource affinities (Cottrell & Kirchman, 2000; Salcher et al ., 2011; Heinrich et al ., 2013), physiological characteristics (Hahn & Pöckl, 2005; Šimek et al ., 2006) and genetic composition (Bauer et al ., 2006; Gómez‐Pereira et al ., 2012; Teeling et al ., 2012; Tveit et al ., 2013).…”

Section: Discussionmentioning

confidence: 99%

“…The loss and prevalence of the taxa determined in our study may be explained by their different functional adaptability, including differences in resource affinities (Cottrell & Kirchman, 2000; Salcher et al ., 2011; Heinrich et al ., 2013), physiological characteristics (Hahn & Pöckl, 2005; Šimek et al ., 2006) and genetic composition (Bauer et al ., 2006; Gómez‐Pereira et al ., 2012; Teeling et al ., 2012; Tveit et al ., 2013). Further, changes in lake bacterial community composition have been attributed not only to the differential response of individual bacterial taxa to DOM inputs, but also to the introduction of soil bacteria with allochthonous sources or to incubation effects (Crump et al ., 2003; Logue et al ., 2016). In our experiments, however, the addition of soil‐borne bacteria with the soil extracts was not confirmed when using staining techniques and microscopy.…”

Section: Discussionmentioning

confidence: 99%

“…Nevertheless, the degree of response clearly differed between locations (SAA vs. GKS) and soil treatments (local vs. foreign soil treatment in SAA). The patterns observed in substrate uptake rates were most likely the result of differences in initial bacterioplankton community composition (Logue et al ., 2016), DOC lability (Kalbitz et al ., 2003; Berggren et al ., 2009) and nutrient (or rather P) availability (Moran & Hodson, 1990; Olsen et al ., 2002). For instance, total dissolved phosphorus concentrations were three times lower in the local and in the foreign soil treatments in GKS than in SAA (Table S1).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Climate‐related changes of soil characteristics affect bacterial community composition and function of high altitude and latitude lakes

Rofner

Peter

Catalán

et al. 2016

Global Change Biology

View full text Add to dashboard Cite

Lakes at high altitude and latitude are typically unproductive ecosystems where external factors outweigh the relative importance of in‐lake processes, making them ideal sentinels of climate change. Climate change is inducing upward vegetation shifts at high altitude and latitude regions that translate into changes in the pools of soil organic matter. Upon mobilization, this allochthonous organic matter may rapidly alter the composition and function of lake bacterial communities. Here, we experimentally simulate this potential climate‐change effect by exposing bacterioplankton of two lakes located above the treeline, one in the Alps and one in the subarctic region, to soil organic matter from below and above the treeline. Changes in bacterial community composition, diversity and function were followed for 72 h. In the subarctic lake, soil organic matter from below the treeline reduced bulk and taxon‐specific phosphorus uptake, indicating that bacterial phosphorus limitation was alleviated compared to organic matter from above the treeline. These effects were less pronounced in the alpine lake, suggesting that soil properties (phosphorus and dissolved organic carbon availability) and water temperature further shaped the magnitude of response. The rapid bacterial succession observed in both lakes indicates that certain taxa directly benefited from soil sources. Accordingly, the substrate uptake profiles of initially rare bacteria (copiotrophs) indicated that they are one of the main actors cycling soil‐derived carbon and phosphorus. Our work suggests that climate‐induced changes in soil characteristics affect bacterioplankton community structure and function, and in turn, the cycling of carbon and phosphorus in high altitude and latitude aquatic ecosystems.

show abstract

“…These groups are considered to be opportunistic bacteria in surface waters, and they responded rapidly to the enrichment derived from copepod excretion. Several studies have suggested that enrichment experiments tend to enhance the abundance of microorganisms rarely found in nature, but that have opportunistic and copiotrophic qualities that allow them to rapidly adapt to changes in environmental conditions, outcompeting abundant groups in the field (Nelson and Wear, 2014;Pedler et al, 2014;Logue et al, 2016). Lauro et al (2009) argued that copiotroph bacteria have a higher genetic potential to sense and rapidly respond to a sudden nutrient influx, compared to the more widely distributed oligotrophic bacteria.…”

Section: Bacterial Response To the Copepod Excretion Productsmentioning

confidence: 99%

Dissolved Compounds Excreted by Copepods Reshape the Active Marine Bacterioplankton Community Composition

et al. 2017

View full text Add to dashboard Cite

Copepods are important suppliers of bioreactive compounds for marine bacteria through fecal pellet production, sloppy feeding, and the excretion of dissolved compounds. However, the interaction between copepods and bacteria in the marine environment is poorly understood. We determined the nitrogen and phosphorus compounds excreted by copepods fed with two natural size-fractionated diets (<20-and 20-150-µm) in the upwelling zone of central/southern Chile in late summer and spring. We then assessed the biogeochemical response of the bacterial community and its structure, in terms of total and active cells, to enrichment by copepod-excreted dissolved compounds. Results revealed that copepods actively excreted nitrogen and phosphorus compounds, mainly in the form of ammonium and dissolved organic phosphorus (DOP), reaching excretion rates of 2.6 and 0.05 µmol L −1 h −1 , respectively. In both periods, the maximum excretion rates were associated with the 20-150-µm size fraction, but particularly during spring, when a higher organic matter quality was observed in excretion products compared to late summer. There were higher excretion rates of dissolved free amino acids (DFAAs) from copepods fed with the <20-µm size fraction, mainly histidine (HIS) in late summer and glutamic acid (GLU) in spring. A shift in the composition of the active bacterial community was observed between periods and treatments, which was associated with the response of the common seawater surface phyla Proteobacteria and Bacteroidetes. The specific bacterial activity (16S rRNA:rDNA) suggested a different response to the two size-fractionated diets. In late summer, Betaproteobacteria and Bacteroidetes were stimulated by the treatment enriched with excretion products derived from the 20-150-µm and <20-µm size fractions, respectively. In spring, Alphaproteobacteria were active in the treatment enriched with the excretion products of copepods fed with the <20-µm size fraction, whereas they were inhibited in the treatment enriched with excretion products in the 20-150-µm size fraction. Our findings indicate that different Valdés et al. Copepod Excretion and Bacterial Community Structure copepod diets can have a significant impact on the quantity and quality of their excretion compounds, which can subsequently generate shifts in the active bacterial composition. The bacterial response is probably associated with common-opportunistic sea surface microbes that are adapted to rapidly reacting to environmental offers.

show abstract

Experimental insights into the importance of aquatic bacterial community composition to the degradation of dissolved organic matter

Cited by 401 publications

References 53 publications

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Climate‐related changes of soil characteristics affect bacterial community composition and function of high altitude and latitude lakes

Dissolved Compounds Excreted by Copepods Reshape the Active Marine Bacterioplankton Community Composition

Contact Info

Product

Resources

About