Shifts in soil bacterial communities associated with the potato rhizosphere in response to aromatic sulfonate amendments

Desulfonation is an important process in the sulfur cycle, through which organic sulfur compounds are mineralized, releasing S. Desulfonating bacteria are known to respond to inorganic S soil amendments. However, the extent to which these communities shift as a response to the addition of organic sulfur in the soil remains elusive. Here, we investigated how amendments of soil with inorganic or organic sulfur compounds influence the bacterial communities associated with potato, in a microcosm experiment. The soil was amended with two doses of linear alkylbenzene sulfonate (LAS), here used as a model aromatic sulfonate compound, or with sulfate. Degradation of LAS was observed already at the young plant stage, as in all treatments 10- to 50-fold reductions of the initial (background) LAS concentrations were noted. Quantitative PCR analyses showed no significant effects of treatment on the bacterial abundances, which tended to increase from the young plant to the flowering stages of plant development. The bacterial community structures, determined via PCR-DGGE, were strongly affected by the presence of plants. This rhizosphere effect became more apparent at the flowering stages. Both the bacterial and β-proteobacterial community structures were affected by the presence of LAS, but dose-related effects were not observed. LAS also caused significant changes in the community structures, as compared to those in inorganic sulfate amended soil. Sulfate did not influence the bacterial community structures and only affected the β-proteobacterial ones at the flowering stage. Surprisingly, the presence of LAS did not exert any significant effect on the abundance of the Variovorax asfA gene, although clone libraries revealed a dominance of Variovorax types in the rhizosphere, especially in the high-level LAS treatment. Our results suggest that rhizosphere communities are key players in LAS degradation in soils, and that desulfonator Variovorax spp. plays a minor role in the mineralization of aromatic sulfonates in soil cropped with potato

Soil and Cultivar Type Shape the Bacterial Community in the Potato Rhizosphere

The rhizospheres of five different potato cultivars (including a genetically modified cultivar) obtained from a loamy sand soil and two from a sandy peat soil, next to corresponding bulk soils, were studied with respect to their community structures and potential function. For the former analyses, we performed bacterial 16S ribosomal RNA gene-based PCR denaturing gradient gel electrophoresis (PCR-DGGE) on the basis of soil DNA; for the latter, we extracted microbial communities and subjected these to analyses in phenotype arrays (PM1, PM2, and PM4, Biolog), with a focus on the use of different carbon, sulfur and phosphorus sources. In addition, we performed bacterial PCR-DGGE on selected wells to assess the structures of these substrate-responsive communities. Effects of soil type, the rhizosphere, and cultivar on the microbial community structures were clearly observed. Soil type was the most determinative parameter shaping the functional communities, whereas the rhizosphere and cultivar type also exerted an influence. However, no genetically modified plant effect was observed. The effects were imminent based on general community analysis and also single-compound analysis. Utilization of some of the carbon and sulfur sources was specific per cultivar, and different microbial communities were found as defined by cultivar. Thus, both soil and cultivar type shaped the potato root-associated bacterial communities that were responsive to some of the substrates in phenotype arrays

Spatial and temporal variations of bacterial community in a sewage polluted urban river: the Zenne River (Belgium)

info:eu-repo/semantics/nonPublishe

Effects of Plant Genotype and Growth Stage on the Betaproteobacterial Communities Associated with Different Potato Cultivars in Two Fields▿ †

Bacterial communities in the rhizosphere are dynamic and susceptible to changes in plant conditions. Among the bacteria, the betaproteobacteria play key roles in nutrient cycling and plant growth promotion, and hence the dynamics of their community structures in the rhizosphere should be investigated. Here, the effects of plant cultivar, growth stage, and soil type on the communities associated with potato cultivars Aveka, Aventra, Karnico, Modena, Premiere, and Désirée were assessed for two different fields containing sandy soil with either a high or low organic compound content. Thus, bacterial and betaproteobacterial PCR-denaturing gradient gel electrophoresis analyses were performed to analyze the effects of plant cultivar and growth on the rhizosphere community structure. The analyses showed that in both fields all cultivars had a rhizosphere effect on the total bacterial and betaproteobacterial communities. In addition, the plant growth stage strongly affected the betaproteobacterial communities in both fields. Moreover, the community structures were affected by cultivar, and cultivars differed in physiology, as reflected in their growth rates, root development, and estimated tuber starch contents. Analyses of betaproteobacterial clone libraries constructed for two selected cultivars (one cultivar that produced low-starch-content tubers and one cultivar that produced high-starch-content tubers), as well as bulk soil, revealed that the rhizospheres of the two cultivars selected for specific bacteria, including plant-growth-promoting bacteria, such as Variovorax and Achromobacter spp. In addition, quantitative PCR-based quantification of the Variovorax paradoxus-specific functional gene asfA (involved in desulfonation) indicated that there were clear potato rhizosphere effects on the abundance of this gene. Interestingly, both cultivar type and plant growth stage affected the community under some circumstances

Comparative analysis of bacterial communities in a potato field as determined by pyrosequencing

Background: Plants selectively attract particular soil microorganisms, in particular consumers of root-excreted compounds. It is unclear to what extent cultivar type and/or growth stage affect this process. Methodology/Principal Findings: DNA-based pyrosequencing was used to characterize the structure of bacterial communities in a field cropped with potato. The rhizospheres of six cultivars denoted Aveka, Aventra, Karnico, Modena, Premiere and Desiree, at three growth stages (young, flowering and senescence) were examined, in addition to corresponding bulk soils. Around 350,000 sequences were obtained (5,700 to 38,000 per sample). Across all samples, rank abundance distributions best fitted the power law model, which indicates a community composed of a few highly dominant species next to numerous rare species. Grouping of the sequences showed that members of the Actinobacteria, Alphaproteobacteria, next to as-yet-unclassified bacteria, dominated. Other groups that were consistently found, albeit at lower abundance, were Beta-, Gamma- and Deltaproteobacteria and Acidobacteria. Principal components analyses revealed that rhizosphere samples were significantly different from corresponding bulk soil in each growth stage. Furthermore, cultivar effects were found in the young plant stage, whereas these became insignificant in the flowering and senescence stages. Besides, an effect of time of season was observed for both rhizosphere and bulk soils. The analyzed rhizosphere samples of the potato cultivars were grouped into two groups, in accordance with the allocation of carbon to starch in thei

Seasonal variations and resilience of bacterial communities in a sewage polluted urban river.

The Zenne River in Brussels (Belgium) and effluents of the two wastewater treatment plants (WWTPs) of Brussels were chosen to assess the impact of disturbance on bacterial community composition (BCC) of an urban river. Organic matters, nutrients load and oxygen concentration fluctuated highly along the river and over time because of WWTPs discharge. Tag pyrosequencing of bacterial 16S rRNA genes revealed the significant effect of seasonality on the richness, the bacterial diversity (Shannon index) and BCC. The major grouping: -winter/fall samples versus spring/summer samples- could be associated with fluctuations of in situ bacterial activities (dissolved and particulate organic carbon biodegradation associated with oxygen consumption and N transformation). BCC of the samples collected upstream from the WWTPs discharge were significantly different from BCC of downstream samples and WWTPs effluents, while no significant difference was found between BCC of WWTPs effluents and the downstream samples as revealed by ANOSIM. Analysis per season showed that allochthonous bacteria brought by WWTPs effluents triggered the changes in community composition, eventually followed by rapid post-disturbance return to the original composition as observed in April (resilience), whereas community composition remained altered after the perturbation by WWTPs effluents in the other seasons.Journal ArticleResearch Support, Non-U.S. Gov'tSCOPUS: ar.jinfo:eu-repo/semantics/publishe

Distribution of Bacteria and Archaea in meromictic tropical Lake Kivu (Africa)

Lake Kivu is a meromictic lake in East Africa with enormous amounts of dissolved methane (CH4) and carbon dioxide (CO2) in its deep waters and surprisingly low CH4 in the surface waters. We applied 454 pyrosequencing of 16S rRNA gene fragments to study the bacterial and archaeal community compositions (BCC and ACC, respectively) to provide insight into the ecology of the microbes in Lake Kivu. The vertical distribution of electron donors and acceptors in the chemically stratified water column may be responsible for the stratified distribution of microbial populations, suggesting well-defined functional specialization. The highest microbial richness was detected in the anoxic zone, which hosted high percentages of bacterial sequences related to uncultured and poorly described phyla. This suggests an under-representation of anoxic environments in current databases and the presence of previously undescribed taxa. Microbial diversity is made up of 2 fractions: abundant species (e.g. Galand et al. 2009) and rare species. Abundant species were more stable than rare species over time. The detection of rare candidate divisions (e.g. OP3, WS3, GN02) co-occurring with sulphur-oxidising Epsilonproteobacteria, sulphate- reducing Deltaproteobacteria, hydrogen-oxidising Dehalococcoidetes and methanogens might indicate interactions in the carbon and sulphur cycles in the anoxic waters.SCOPUS: ar.jinfo:eu-repo/semantics/publishe

Pelagic photoferrotrophy and iron cycling in a modern ferruginous basin

8 páginas, 3 figurasIron-rich (ferruginous) ocean chemistry prevailed throughout most of Earth’s early history. Before the evolution and proliferation of oxygenic photosynthesis, biological production in the ferruginous oceans was likely driven by photoferrotrophic bacteria that oxidize ferrous iron {Fe(II)} to harness energy from sunlight, and fix inorganic carbon into biomass. Photoferrotrophs may thus have fuelled Earth’s early biosphere providing energy to drive microbial growth and evolution over billions of years. Yet, photoferrotrophic activity has remained largely elusive on the modern Earth, leaving models for early biological production untested and imperative ecological context for the evolution of life missing. Here, we show that an active community of pelagic photoferrotrophs comprises up to 30% of the total microbial community in illuminated ferruginous waters of Kabuno Bay (KB), East Africa (DR Congo). These photoferrotrophs produce oxidized iron {Fe(III)} and biomass, and support a diverse pelagic microbial community including heterotrophic Fe(III)-reducers, sulfate reducers, fermenters and methanogens. At modest light levels, rates of photoferrotrophy in KB exceed those predicted for early Earth primary production, and are sufficient to generate Earth’s largest sedimentary iron ore deposits. Fe cycling, however, is efficient, and complex microbial community interactions likely regulate Fe(III) and organic matter export from the photic zone.This work was partially supported by Belgian (FNRS 2.4.515.11 and BELSPO SD/AR/02A contracts), Danish (grant no. DNRF53 to DEC), and European (grant no. ERC-StG 240002, for stable isotope measurements) funds. AVB is a senior research associate at the FRS-FNRS. SAC was supported by the Agouron institute.Peer reviewe