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6. Comparison of methane metabolism in the rhizomicrobiomes of wild and related cultivated rice accessions reveals a strong impact of crop domestication

Author

Tian, Lei, Chang, Jingjing, Shi, Shaohua, Ji, Li, Zhang, Jianfeng, Sun, Yu, Li, Xiaojie, Li, Xiujun, Xie, Hongwei, Cai, Yaohui, Chen, Dazhou, Wang, Jilin, van Veen, J.A., Kuramae, Eiko, Phan Tran, Lam-Son, Tian, Chunjie, Tian, Lei, Chang, Jingjing, Shi, Shaohua, Ji, Li, Zhang, Jianfeng, Sun, Yu, Li, Xiaojie, Li, Xiujun, Xie, Hongwei, Cai, Yaohui, Chen, Dazhou, Wang, Jilin, van Veen, J.A., Kuramae, Eiko, Phan Tran, Lam-Son, and Tian, Chunjie

Abstract

Microbial communities from rhizosphere (rhizomicrobiomes) have been significantly impacted by domestication as evidenced by a comparison of the rhizomicrobiomes of wild and related cultivated rice accessions. While there have been many published studies focusing on the structure of the rhizomicrobiome, studies comparing the functional traits of the microbial communities in the rhizospheres of wild rice and cultivated rice accessions are not yet available. In this study, we used metagenomic data from experimental rice plots to analyze the potential functional traits of the microbial communities in the rhizospheres of wild rice accessions originated from Africa and Asia in comparison with their related cultivated rice accessions. The functional potential of rhizosphere microbial communities involved in alanine, aspartate and glutamate metabolism, methane metabolism, carbon fixation pathways, citrate cycle (TCA cycle), pyruvate metabolism and lipopolysaccharide biosynthesis pathways were found to be enriched in the rhizomicrobiomes of wild rice accessions. Notably, methane metabolism in the rhizomicrobiomes of wild and cultivated rice accessions clearly differed. Key enzymes involved in methane production and utilization were overrepresented in the rhizomicrobiome samples obtained from wild rice accessions, suggesting that the rhizomicrobiomes of wild rice maintain a different ecological balance for methane production and utilization compared with those of the related cultivated rice accessions. A novel assessment of the impact of rice domestication on the primary metabolic pathways associated with microbial taxa in the rhizomicrobiomes was performed. Results indicated a strong impact of rice domestication on methane metabolism; a process that represents a critical function of the rhizosphere microbial community of rice. The findings of this study provide important information for future breeding of rice varieties with reduced methane emission during cultivation for su

Published
2022

10. Rice domestication influences the composition and function of the rhizosphere bacterial chemotaxis systems

Author

Sun, Yu, Tian, Lei, Chang, Jingjing, Shi, Shaohua, Zhang, Jianfeng, Xie, Hongwei, Cai, Yaohui, Chen, Dazhou, Kuramae, Eiko, van Veen, J.A., Li, Weiqiang, Tran, Lam-Son Phan, Tian, Chunjie, Sun, Yu, Tian, Lei, Chang, Jingjing, Shi, Shaohua, Zhang, Jianfeng, Xie, Hongwei, Cai, Yaohui, Chen, Dazhou, Kuramae, Eiko, van Veen, J.A., Li, Weiqiang, Tran, Lam-Son Phan, and Tian, Chunjie

Abstract

Aims Specific soil bacteria can sense and respond to the selective rhizosphere recruitment of root exudates using unique systems of chemotaxis that mediate plant-microbe and microbe-microbe interactions. This study investigates how the bacterial chemotaxis systems have been impacted by selection during the domestication of rice (Oryza species). Methods Shotgun metagenomic sequencing and 16S rRNA gene amplicon sequencing were performed to investigate the bacterial chemotaxis systems and chemotactic bacteria in the rhizospheres of wild and cultivated rice. Metabolomics analysis was performed to examine the root metabolites of different accessions of rice. Results The bacterial chemotaxis genes exhibited a higher abundance in the rhizospheres of wild rice than cultivated rice, and that the compositional profile of chemotaxis genes was distinctly different between types of rice. Differential selection of chemotaxis systems was at least partially driven by changes in the metabolite profiles of rice roots that were affected by domestication. A core group of chemotactic bacteria was also identified, and specific chemotactic bacteria were found to function as hub taxa in the rhizosphere bacterial community. Conclusion The present study provides novel insights into the composition and function of the bacterial chemotaxis systems in the rhizospheres of wild and domesticated rice. It also provides a new perspective on the impact of rice domestication on the assembly of rhizomicrobiome.

Published
2021

13. Metabolic activity and population dynamics of rhizobia introduced into unamended and bentonite-amended loamy sand

Author

Heijnen, C.E., Burgers, S.L.G.E., and Van Veen, J.A.

Subjects
Rhizobium -- Research, Soil microbiology -- Research, Microbial metabolism -- Analysis, Biological sciences
Abstract

A comparison of the cumulative amount of carbon dioxide respired by rhizobia in sterile bentonite-amended loamy sand and unamended loamy sand is discussed. Measurements were made over time by using various innoculum densities ranging from 1,000 to 10,000,000,000 per gram of dry soil. Vaiance analysis were performed for each sampling. It was found that the colonization of protective microhabitats were determined by pore shape, waterfilled pre system or by isolated pores.

Published
1993

14. Nitrification inhibitors effectively target N2O-producing Nitrosospira spp. in tropical soil

Author

Cassman, N., Soares, Johnny R., Pijl, A.S., Lourenço, Késia S., van Veen, J.A., Cantarella, Heitor, Kuramae, E.E., Cassman, N., Soares, Johnny R., Pijl, A.S., Lourenço, Késia S., van Veen, J.A., Cantarella, Heitor, and Kuramae, E.E.

Abstract

The nitrification inhibitors (NIs) 3,4‐dimethylpyrazole (DMPP) and dicyandiamide (DCD) can effectively reduce N2O emissions; however, which species are targeted and the effect of these NIs on the microbial nitrifier community is still unclear. Here, we identified the ammonia oxidizing bacteria (AOB) species linked to N2O emissions and evaluated the effects of urea and urea with DCD and DMPP on the nitrifying community in a 258 day field experiment under sugarcane. Using an amoA AOB amplicon sequencing approach and mining a previous dataset of 16S rRNA sequences, we characterized the most likely N2O‐producing AOB as a Nitrosospira spp. and identified Nitrosospira (AOB), Nitrososphaera (archaeal ammonia oxidizer) and Nitrospira (nitrite‐oxidizer) as the most abundant, present nitrifiers. The fertilizer treatments had no effect on the alpha and beta diversities of the AOB communities. Interestingly, we found three clusters of co‐varying variables with nitrifier operational taxonomic units (OTUs): the N2O‐producing AOB Nitrosospira with N2O, NO3−, NH4+, water‐filled pore space (WFPS) and pH; AOA Nitrososphaera with NO3−, NH4+ and pH; and AOA Nitrososphaera and NOB Nitrospira with NH4+, which suggests different drivers. These results support the co‐occurrence of non‐N2O‐producing Nitrososphaera and Nitrospira in the unfertilized soils and the promotion of N2O‐producing Nitrosospira under urea fertilization. Further, we suggest that DMPP is a more effective NI than DCD in tropical soil under sugarcane.

Published
2019

15. Moisture is more important than Temperature for Assembly of Both Potentially Active and Whole Prokaryotic Communities in Subtropical Grassland

Author

Lupatini, M., Suleiman, A.K.A., Jacques, Rodrigo J.S., Pylro, Victor Satler, van Veen, J.A., Kuramae, E.E., Roesch, Luiz F.W., Lupatini, M., Suleiman, A.K.A., Jacques, Rodrigo J.S., Pylro, Victor Satler, van Veen, J.A., Kuramae, E.E., and Roesch, Luiz F.W.

Abstract

Moisture and temperature play important roles in the assembly and functioning of prokaryotic communities in soil. However, how moisture and temperature regulate the function of niche- versus neutral-based processes during the assembly of these communities has not been examined considering both the total microbial community and the sole active portion with potential for growth in native subtropical grassland. We set up a well-controlled microcosm-based experiment to investigate the individual and combined effects of moisture and temperature on soil prokaryotic communities by simulating subtropical seasons in grassland. The prokaryotic populations with potential for growth and the total prokaryotic community were assessed by 16S rRNA transcript and 16S rRNA gene analyses, respectively. Moisture was the major factor influencing community diversity and structure, with a considerable effect of this factor on the total community. The prokaryotic populations with potential for growth and the total communities were influenced by the same assembly rules, with the niche-based mechanism being more influential in communities under dry condition. Our results provide new information regarding moisture and temperature in microbial communities of soil and elucidate how coexisting prokaryotic populations, under different physiological statuses, are shaped in native subtropical grassland soil.

Published
2019

16. Resilience of the resident soil microbiome to organic and inorganic amendment disturbances and to temporary bacterial invasion

Author

Lourenço, Késia S., Suleiman, A.K.A., Pijl, A.S., van Veen, J.A., Cantarella, H., Kuramae, E.E., Lourenço, Késia S., Suleiman, A.K.A., Pijl, A.S., van Veen, J.A., Cantarella, H., and Kuramae, E.E.

Abstract

Background Vinasse, a by-product of sugarcane ethanol production, is recycled by sugarcane plantations as a fertilizer due to its rich nutrient content. However, the impacts of the chemical and microbial composition of vinasse on soil microbiome dynamics are unknown. Here, we evaluate the recovery of the native soil microbiome after multiple disturbances caused by the application of organic vinasse residue, inorganic nitrogen, or a combination of both during the sugarcane crop-growing season (389 days). Additionally, we evaluated the resistance of the resident soil microbial community to the vinasse microbiome. Results Vinasse applied alone or 30 days prior to N resulted in similar changes in the soil microbial community. Furthermore, the impact of the application of vinasse together with N fertilizer on the soil microbial community differed from that of N fertilizer alone. Organic vinasse is a source of microbes, nutrients, and organic matter, and the combination of these factors drove the changes in the resident soil microbial community. However, these changes were restricted to a short period of time due to the capacity of the soil community to recover. The invasive bacteria present in the vinasse microbiome were unable to survive in the soil conditions and disappeared after 31 days, with the exception of the Acetobacteraceae (native in the soil) and Lactobacillaceae families. Conclusion Our analysis showed that the resident soil microbial community was not resistant to vinasse and inorganic N application but was highly resilient.

Published
2018

17. Effect of Burkholderia tropica and Herbaspirillum frisingense strains on sorghum growth is plant genotype dependent

Author

Schlemper, T.R., Dimitrov, M., Silva Gutierrez, Frederico, van Veen, J.A., Silveira, A.P.D., Kuramae, E.E., Schlemper, T.R., Dimitrov, M., Silva Gutierrez, Frederico, van Veen, J.A., Silveira, A.P.D., and Kuramae, E.E.

Abstract

Sorghum is a multipurpose crop that is cultivated worldwide. Plant growth-promoting bacteria (PGPB) have important roles in enhancing sorghum biomass and nutrient uptake and suppressing plant pathogens. The aim of this research was to test the effects of the endophytic bacterial species Kosakonia radicincitans strain IAC/BECa 99, Enterobacter asburiae strain IAC/BECa 128, Pseudomonas fluorescens strain IAC/BECa 141, Burkholderia tropica strain IAC/BECa 135 and Herbaspirillum frisingense strain IAC/BECa 152 on the growth and root architecture of four sorghum cultivars (SRN-39, Shanqui-Red, BRS330, BRS509), with different uses and strigolactone profiles. We hypothesized that the different bacterial species would trigger different growth plant responses in different sorghum cultivars. Burkholderia tropica and H. frisingense significantly increased the plant biomass of cultivars SRN-39 and BRS330. Moreover, cultivar BRS330 inoculated with either strain displayed isolates significant decrease in average root diameter. This study shows that Burkholderia tropica strain IAC/BECa 135 and H. frisingense strain IAC/BECa 152 are promising PGPB strains for use as inocula for sustainable sorghum cultivation.

Published
2018

18. Co-variation of bacterial and fungal communities in different sorghum cultivars and growth stages is soil dependent

Author

Schlemper, T.R., van Veen, J.A., Kuramae, E.E., Schlemper, T.R., van Veen, J.A., and Kuramae, E.E.

Abstract

Rhizosphere microbial community composition can be influenced by different biotic and abiotic factors. We investigated the composition and co-variation of rhizosphere bacterial and fungal communities from two sorghum genotypes (BRS330 and SRN-39) in three different plant growth stages (emergence of the second leaf, (day10), vegetative to reproductive differentiation point (day 35), and at the last visible emerged leaf (day 50)) in two different soil types, Clue field (CF) and Vredepeel (VD). We observed that either bacterial or fungal community had its composition stronger influenced by soil followed by plant growth stage and cultivar. However, the influence of plant growth stage was higher on fungal community composition than on the bacterial community composition. Furthermore, we showed that sorghum rhizosphere bacterial and fungal communities can affect each other’s composition and structure. The decrease in relative abundance of the fungus genus Gibberella over plant growth stages was followed by decrease of the bacterial families Oxalobacteracea and Sphingobacteriacea. Although cultivar effect was not the major responsible for bacterial and fungal community composition, cultivar SRN-39 showed to promote a stronger co-variance between bacterial and fungal communities.

Published
2018

19. Nitrosospira sp. govern nitrous oxide emissions in a tropical soil amended with residues of bioenergy crop

Author

Lourenço, Késia S., Cassman, N., Pijl, A.S., van Veen, J.A., Cantarella, Heitor, Kuramae, E.E., Lourenço, Késia S., Cassman, N., Pijl, A.S., van Veen, J.A., Cantarella, Heitor, and Kuramae, E.E.

Abstract

Organic vinasse, a residue produced during bioethanol production, increases nitrous oxide (N2O) emissions when applied with inorganic nitrogen (N) fertilizer in soil. The present study investigated the role of the ammonia-oxidizing bacteria (AOB) community on the N2O emissions in soils amended with organic vinasse (CV: concentrated and V: non-concentrated) plus inorganic N fertilizer. Soil samples and N2O emissions were evaluated at 11, 19, and 45 days after fertilizer application, and the bacterial and archaea gene (amoA) encoding the ammonia monooxygenase enzyme, bacterial denitrifier (nirK, nirS, and nosZ) genes and total bacteria were quantified by real time PCR. We also employed a deep amoA amplicon sequencing approach to evaluate the effect of treatment on the community structure and diversity of the soil AOB community. Both vinasse types applied with inorganic N application increased the total N2O emissions and the abundance of AOB. Nitrosospira sp. was the dominant AOB in the soil and was correlated with N2O emissions. However, the diversity and the community structure of AOB did not change with vinasse and inorganic N fertilizer amendment. The results highlight the importance of residues and fertilizer management in sustainable agriculture and can be used as a reference and an input tool to determine good management practices for organic fertilization.

Published
2018

20. Dominance of bacterial ammonium oxidizers and fungal denitrifiers in the complex nitrogen cycle pathways related to nitrous oxide emission

Author

Lourenço, Késia S., Dimitrov, M., Pijl, A.S., Soares, Johnny R., do Carmo, J.B., van Veen, J.A., Cantarella, Heitor, Kuramae, E.E., Lourenço, Késia S., Dimitrov, M., Pijl, A.S., Soares, Johnny R., do Carmo, J.B., van Veen, J.A., Cantarella, Heitor, and Kuramae, E.E.

Abstract

Organic compounds and mineral nitrogen (N) usually increase nitrous oxide (N2O) emissions. Vinasse, a by‐product of bio‐ethanol production that is rich in carbon, nitrogen, and potassium, is recycled in sugarcane fields as a bio‐fertilizer. Vinasse can contribute significantly to N2O emissions when applied with N in sugarcane plantations, a common practice. However, the biological processes involved in N2O emissions under this management practice are unknown. This study investigated the roles of nitrification and denitrification in N2O emissions from straw‐covered soils amended with different vinasses (CV: concentrated and V: nonconcentrated) before or at the same time as mineral fertilizers at different time points of the sugarcane cycle in two seasons. N2O emissions were evaluated for 90 days, the period that occurs most of the N2O emission from fertilizers; the microbial genes encoding enzymes involved in N2O production (archaeal and bacterial amoA, fungal and bacterial nirK, and bacterial nirS and nosZ), total bacteria, and total fungi were quantified by real‐time PCR. The application of CV and V in conjunction with mineral N resulted in higher N2O emissions than the application of N fertilizer alone. The strategy of vinasse application 30 days before mineral N reduced N2O emissions by 65% for CV, but not for V. Independent of rainy or dry season, the microbial processes were nitrification by ammonia‐oxidizing bacteria (AOB) and archaea and denitrification by bacteria and fungi. The contributions of each process differed and depended on soil moisture, soil pH, and N sources. We concluded that amoA‐AOB was the most important gene related to N2O emissions, which indicates that nitrification by AOB is the main microbial‐driven process linked to N2O emissions in tropical soil. Interestingly, fungal nirK was also significantly correlated with N2O emissions, suggesting that denitrification by fungi contributes to N2O emission in soils receiving straw and vinasse appli

Published
2018

28. Shifts in rhizosphere fungal community during secondary succession following abandonment from agriculture

Author

Hannula, S.E., Morriën, E., De Hollander, M., van der Putten, W.H., van Veen, J.A., De Boer, W., Hannula, S.E., Morriën, E., De Hollander, M., van der Putten, W.H., van Veen, J.A., and De Boer, W.

Abstract

Activities of rhizosphere microbes are key to the functioning of terrestrial ecosystems. It is commonly believed that bacteria are the major consumers of root exudates and that the role of fungi in the rhizosphere is mostly limited to plant-associated taxa, such as mycorrhizal fungi, pathogens and endophytes, whereas less is known about the role of saprotrophs. In order to test the hypothesis that the role of saprotrophic fungi in rhizosphere processes increases with increased time after abandonment from agriculture, we determined the composition of fungi that are active in the rhizosphere along a chronosequence of ex-arable fields in the Netherlands. Intact soil cores were collected from nine fields that represent three stages of land abandonment and pulse labeled with 13CO2. The fungal contribution to metabolization of plant-derived carbon was evaluated using phospholipid analysis combined with stable isotope probing (SIP), whereas fungal diversity was analyzed using DNA-SIP combined with 454-sequencing. We show that in recently abandoned fields most of the root-derived 13C was taken up by bacteria but that in long-term abandoned fields most of the root-derived 13C was found in fungal biomass. Furthermore, the composition of the active functional fungal community changed from one composed of fast-growing and pathogenic fungal species to one consisting of beneficial and slower-growing fungal species, which may have essential consequences for the carbon flow through the soil food web and consequently nutrient cycling and plant succession.

Published
2017

29. Rhizobacterial community structure differences among sorghum cultivars in different growth stages and soils

Author

Schlemper, T.R., Leite, M.F.A., Reis Lucheta, Adriano, Shimels, M., Bouwmeester, H.J., van Veen, J.A., Kuramae, E.E., Schlemper, T.R., Leite, M.F.A., Reis Lucheta, Adriano, Shimels, M., Bouwmeester, H.J., van Veen, J.A., and Kuramae, E.E.

Abstract

Plant genotype selects the rhizosphere microbiome. The success of plant–microbe interactions is dependent on factors that directly or indirectly influence the plant rhizosphere microbial composition. We investigated the rhizosphere bacterial community composition of seven different sorghum cultivars in two different soil types (abandoned (CF) and agricultural (VD)). The rhizosphere bacterial community was evaluated at four different plant growth stages: emergence of the second (day 10) and third leaves (day 20), the transition between the vegetative and reproductive stages (day 35), and the emergence of the last visible leaf (day 50). At early stages (days 10 and 20), the sorghum rhizosphere bacterial community composition was mainly driven by soil type, whereas at late stages (days 35 and 50), the bacterial community composition was also affected by the sorghum genotype. Although this effect of sorghum genotype was small, different sorghum cultivars assembled significantly different bacterial community compositions. In CF soil, the striga-resistant cultivar had significantly higher relative abundances of Acidobacteria GP1, Burkholderia, Cupriavidus (Burkholderiaceae), Acidovorax and Albidiferax (Comamonadaceae) than the other six cultivars. This study is the first to simultaneously investigate the contributions of plant genotype, plant growth stage and soil type in shaping sorghum rhizosphere bacterial community composition.

Published
2017

30. Methanogens predominate in natural corrosion protective layers on metal sheet piles.

Author

Kip, Nardy, Jansen, S., Leite, M.F.A., De Hollander, M., Afanasyev, M., Kuramae, E.E., van Veen, J.A., Kip, Nardy, Jansen, S., Leite, M.F.A., De Hollander, M., Afanasyev, M., Kuramae, E.E., and van Veen, J.A.

Abstract

Microorganisms are able to cause, but also to inhibit or protect against corrosion. Corrosion inhibition by microbial processes may be due to the formation of mineral deposition layers on metal objects. Such deposition layers have been found in archaeological studies on ancient metal objects, buried in soil, which were hardly corroded. Recent field investigations showed that natural mineral deposition layers can be found on sheet piles in soil. We investigated the microbial communities of these deposition layers and the adjacent soil. Our data, from five different sampling sites, all show striking differences between microbial communities of the deposition layer versus the adjacent soil over the depth profile. Bacterial species dominated in top soil while archaeal sequences increased in abundance with depth. All mineral deposition layers from the steel surface were dominated by Euryarchaeota, of which almost all sequences were phylogenetically related with the Methanobacteria genus. The mineral layer consisted of carbonate precipitates. Based on 16S rDNA gene sequencing data we hypothesize that the methanogens directly extract electrons from the metal surface, thereby, initially inducing mild corrosion, but simultaneously, inducing carbonate precipitation. This, will cause encrustation of the archaea, which drastically slow down their activity and create a natural protective layer against further corrosion.

Published
2017

31. Characterization of novel Acidobacteria exopolysaccharides with potential industrial and ecological applications

Author

Kielak, A.M., Castellane, T.C.L., Campanharo, J.C., Colnago, L.A., Costa, Ohana Y.A., Corradi da Silva, M.L., van Veen, J.A., Lemos, E.G., Kuramae, E.E., Kielak, A.M., Castellane, T.C.L., Campanharo, J.C., Colnago, L.A., Costa, Ohana Y.A., Corradi da Silva, M.L., van Veen, J.A., Lemos, E.G., and Kuramae, E.E.

Abstract

Acidobacteria have been described as one of the most abundant and ubiquitous bacterial phyla in soil. However, factors contributing to this ecological success are not well elucidated mainly due to difficulties in bacterial isolation. Acidobacteria may be able to survive for long periods in soil due to protection provided by secreted extracellular polymeric substances that include exopolysaccharides (EPSs). Here we present the first study to characterize EPSs derived from two strains of Acidobacteria from subdivision 1 belonging to Granulicella sp. EPS are unique heteropolysaccharides containing mannose, glucose, galactose and xylose as major components, and are modified with carboxyl and methoxyl functional groups that we characterized by Fourier transform infrared (FTIR) spectroscopy. Both EPS compounds we identified can efficiently emulsify various oils (sunflower seed, diesel, and liquid paraffin) and hydrocarbons (toluene and hexane). Moreover, the emulsions are more thermostable over time than those of commercialized xanthan. Acidobacterial EPS can now be explored as a source of biopolymers that may be attractive and valuable for industrial applications due to their natural origin, sustainability, biodegradability and low toxicity.

Published
2017

32. Successive DNA extractions improve characterization of soil microbial communities

Author

Dimitrov, M.R., Veraart, A.J., De Hollander, M., Smidt, H., van Veen, J.A., Kuramae, E.E., Dimitrov, M.R., Veraart, A.J., De Hollander, M., Smidt, H., van Veen, J.A., and Kuramae, E.E.

Abstract

Currently, characterization of soil microbial communities relies heavily on the use of molecular approaches. Independently of the approach used, soil DNA extraction is a crucial step, and success of downstream procedures will depend on how well DNA extraction was performed. Often, studies describing and comparing soil microbial communities are based on a single DNA extraction, which may not lead to a representative recovery of DNA from all organisms present in the soil. The use of successive DNA extractions might improve soil microbial characterization, but the benefit of this approach has only been limitedly studied. To determine whether successive DNA extractions of the same soil sample would lead to different observations in terms of microbial abundance and community composition, we performed three successive extractions, with two widely used commercial kits, on a range of clay and sandy soils. Successive extractions increased DNA yield considerably (1–374%), as well as total bacterial and fungal abundances in most of the soil samples. Analysis of the 16S and 18S ribosomal RNA genes using 454-pyrosequencing, revealed that microbial community composition (taxonomic groups) observed in the successive DNA extractions were similar. However, successive DNA extractions did reveal several additional microbial groups. For some soil samples, shifts in microbial community composition were observed, mainly due to shifts in relative abundance of a number of microbial groups. Our results highlight that performing successive DNA extractions optimize DNA yield, and can lead to a better picture of overall community composition.

Published
2017

33. Functional traits dominate the diversity-related selection of bacterial communities in the rhizosphere

Author

Yan, Y., Kuramae, E.E., De Hollander, M., Klinkhamer, P.G.L., van Veen, J.A., Yan, Y., Kuramae, E.E., De Hollander, M., Klinkhamer, P.G.L., and van Veen, J.A.

Abstract

We studied the impact of community diversity on the selection of bacterial communities in the rhizosphere by comparing the composition and the functional traits of these communities in soil and rhizosphere. Differences in diversity were established by inoculating into sterilized soils diluted suspensions of the same soil. We used 16S ribosomal RNA amplicon sequencing to determine the taxonomical structure of the bacterial communities and a shotgun metagenomics approach to investigate the potential functional diversity of the communities. By comparing the bacterial communities in soil and rhizosphere, the selective power of the plant was observed both at the taxonomic and functional level, although the diversity indices of soil and rhizosphere samples showed a highly variable, irregular pattern. Lesser variation, that is, more homogenization, was found for both the taxonomic structure and the functional profile of the rhizosphere communities as compared to the communities of the bulk soil. Network analysis revealed stronger interactions among bacterial operational taxonomic units in the rhizosphere than in the soil. The enrichment processes in the rhizosphere selected microbes with particular functional genes related to transporters, the Embden–Meyerhof–Parnas pathway and hydrogen metabolism. This selection was not random across bacteria with these functional traits, but it was species specific. Overall, this suggests that functional traits are a key to the assembly of bacterial rhizosphere communities.

Published
2017

34. Soil networks become more connected and take up more carbon as nature restoration progresses

Author

Morriën, W.E., Hannula, S.E., Snoek, L.B., Helmsing, N.R., Zweers, Hans, de Hollander, M., Soto, Raquel Luján, Bouffaud, Marie Lara, Buée, M., Dimmers, W.J., Duyts, Henk, Geisen, Stefan, Girlanda, Mariangela, Griffiths, R.I., Jorgensen, H.B., Jensen, J., Plassart, P., Redecker, Dirk, Schmelz, R.M., Schmidt, Olaf, Thomson, Bruce C., Tisserant, Emilie, Uroz, Stephane, Winding, Anne, Bailey, M.J., Bonkowski, M., Faber, J.H., Martin, F., Lemanceau, Philippe, de Boer, W., van Veen, J.A., van der Putten, W.H., Morriën, W.E., Hannula, S.E., Snoek, L.B., Helmsing, N.R., Zweers, Hans, de Hollander, M., Soto, Raquel Luján, Bouffaud, Marie Lara, Buée, M., Dimmers, W.J., Duyts, Henk, Geisen, Stefan, Girlanda, Mariangela, Griffiths, R.I., Jorgensen, H.B., Jensen, J., Plassart, P., Redecker, Dirk, Schmelz, R.M., Schmidt, Olaf, Thomson, Bruce C., Tisserant, Emilie, Uroz, Stephane, Winding, Anne, Bailey, M.J., Bonkowski, M., Faber, J.H., Martin, F., Lemanceau, Philippe, de Boer, W., van Veen, J.A., and van der Putten, W.H.

Abstract

Soil organisms have an important role in aboveground community dynamics and ecosystem functioning in terrestrial ecosystems. However, most studies have considered soil biota as a black box or focussed on specific groups, whereas little is known about entire soil networks. Here we show that during the course of nature restoration on abandoned arable land a compositional shift in soil biota, preceded by tightening of the belowground networks, corresponds with enhanced efficiency of carbon uptake. In mid- and long-term abandoned field soil, carbon uptake by fungi increases without an increase in fungal biomass or shift in bacterial-to-fungal ratio. The implication of our findings is that during nature restoration the efficiency of nutrient cycling and carbon uptake can increase by a shift in fungal composition and/or fungal activity. Therefore, we propose that relationships between soil food web structure and carbon cycling in soils need to be reconsidered.

Published
2017

35. Baiting of bacteria with hyphae of common soil fungi revealed a diverse group of potentially mycophagous secondary consumers in the rhizosphere

Author

Rudnick, M.B., van Veen, J.A., de Boer, W., and Microbial Ecology (ME)

Subjects
Fungal inhibition, fungi, Fungal-bacterial interactions, Fungal suppression, Soil Biology, PE&RC, Root exudates, Mycorrhizosphere, NIOO, Rhizosphere, Trophic interactions, Bodembiologie, Mycophagy
Abstract

Fungi and bacteria are primary consumers of plant-derived organic compounds and therefore considered as basal members of soil food webs. Trophic interactions among these microorganisms could, however, induce shifts in food web energy flows. Given increasing evidence for a prominent role of saprotrophic fungi as primary consumers of root-derived carbon, we propose that fungus-derived carbon may be an important resource for rhizosphere bacteria. To test this assumption, two common saprotrophic, rhizosphere-inhabiting fungi, Trichoderma harzianum and Mucor hiemalis, were confronted in a microcosm system with bacterial communities extracted from the rhizospheres of a grass and sedge species, Carex arenaria and Festuca rubra. This showed a widespread ability of rhizosphere bacteria to attach to and feed on living hyphae of saprotrophic fungi. The identity of the fungi had a strong effect on the composition of these potentially mycophagous bacteria, whereas plant species identity was less important. Based on our results, we suggest that food web models should account for bacterial secondary consumption since this has important consequences for carbon fluxes with more carbon dioxide released by microbes and less microbial carbon available for the soil animal food web.

Published
2015

36. Abundance, richness and structure of soil fungal communities across an European transect

Author

Buee, Marc, Tisserant, Emilie, Hannula, S.E., Fauchery, Laure, Plassart, Pierre, Stone, D., Creamer, R., De Boer, W., van Veen, J.A., Martin, Francis, Interactions Arbres-Microorganismes ( IAM ), Institut National de la Recherche Agronomique ( INRA ) -Université de Lorraine ( UL ), Agroécologie [Dijon], Institut National de la Recherche Agronomique ( INRA ) -Université de Bourgogne ( UB ) -AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement, Royal Netherlands Academy of Arts and Sciences, Irish Agriculture and Food Development Authority, Interactions Arbres-Microorganismes (IAM), Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL), Institut National de la Recherche Agronomique (INRA)-Université de Bourgogne (UB)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement, Royal Netherlands Academy of Arts and Sciences (KNAW), and Université de Lorraine (UL)-Institut National de la Recherche Agronomique (INRA)

Subjects
[ SDV ] Life Sciences [q-bio], soil fungi, biogeography, high-throughput sequencing, ecology, [SDV]Life Sciences [q-bio]
Abstract

EASPEECOLDURGENOSOL; In contrast with plants and animals, biogeographical patterns of fungal assemblages have been little explored. Consequently, the factors driving the diversity and the composition of these communities are poorly understood. The EcoFINDERS project aimed at (i) characterizing the soil fungal diversity according to soil types, land uses and climate, and (ii) determining environmental variables explaining the fungal richness and community structure. Highthroughput sequencing of the ITS2 region was used to explore fungal assemblages in eleven countries along a latitudinal gradient in Europe. Parallel to the sequence based analyses, the fungal abundance was measured from the same DNA samples using qPCR targeting ITS2 region. We showed that the European soil fungal diversity varies in terms of richness, relative abundance and distribution according to land uses (forests, pastures, arable soils), soil and climatic parameters. Remarkably, fungal diversity increases from forest to arable soils and this richness pattern was also positively correlated with pH, CEC, Ca and Clay. These Highthroughput sequencing results have been partially confirmed by qPCR data. Indeed, also the fungal copy numbers in soils were affected by land-use and differed between climatic zones. The highest abundances were measured in (Boreal) forestry sites and the lowest in Mediterranean soils and in arable sites. However, the fungal abundance, unlike richness, was negatively correlated with pH, whereas the soil organic matter content seemed to have no affect on fungal abundance. Interestingly, along this large climatic gradient, we did not find relationship between richness and latitude, which could be a proxy of temperature. The usual ecological pattern between richness and thermic gradient did not appear transferable to soil fungi. Finally, the PCoA analysis revealed that the composition of fungi was largely explained by soil pH and climatic parameters. These results, with additional biogeographical studies, should help to predicting future distribution patterns of soil fungi.

Published
2014

37. Genomic comparison of chitinolytic enzyme systems from terrestrial and aquatic bacteria

Author

Bai, Yani, Eijsink, V.G.H., Kielak, A.M., Van Veen, J.A., De Boer, W., Bai, Yani, Eijsink, V.G.H., Kielak, A.M., Van Veen, J.A., and De Boer, W.

Abstract

Chitin degradation ability is known for many aquatic and terrestrial bacterial species. However, differences in the composition of chitin resources between aquatic (mainly exoskeletons of crustaceans) and terrestrial (mainly fungal cell walls) habitats may have resulted in adaptation of chitinolytic enzyme systems to the prevalent resources. We screened publicly available terrestrial and aquatic chitinase-containing bacterial genomes for possible differences in the composition of their chitinolytic enzyme systems. The results show significant differences between terrestrial and aquatic bacterial genomes in the modular composition of chitinases (i.e. presence of different types of carbohydrate binding modules). Terrestrial Actinobacteria appear to be best adapted to use a wide variety of chitin resources as they have the highest number of chitinase genes, the highest diversity of associated carbohydrate-binding modules and the highest number of CBM33-type lytic polysaccharide monooxygenases. Actinobacteria do also have the highest fraction of genomes containing β-1, 3-glucanases, enzymes that may reinforce the potential for degrading fungal cell walls. The fraction of bacterial chitinase-containing genomes encoding polyketide synthases was much higher for terrestrial bacteria than for aquatic ones supporting the idea that the combined production of antibiotics and cell-wall degrading chitinases can be an important strategy in antagonistic interactions with fungi.

Published
2016

38. The ecology of Acidobacteria: moving beyond genes and genomes

Author

Kielak, A.M., Barreto, C.C., Kowalchuk, G.A., van Veen, J.A., Kuramae, E.E., Kielak, A.M., Barreto, C.C., Kowalchuk, G.A., van Veen, J.A., and Kuramae, E.E.

Abstract

The phylum Acidobacteria is one of the most widespread and abundant on the planet, yet remarkably our knowledge of the role of these diverse organisms in the functioning of terrestrial ecosystems remains surprisingly rudimentary. This blatant knowledge gap stems to a large degree from the difficulties associated with the cultivation of these bacteria by classical means. Given the phylogenetic breadth of the Acidobacteria, which is similar to the metabolically diverse Proteobacteria, it is clear that detailed and functional descriptions of acidobacterial assemblages are necessary. Fortunately, recent advances are providing a glimpse into the ecology of members of the phylum Acidobacteria. These include novel cultivation and enrichment strategies, genomic characterization and analyses of metagenomic DNA from environmental samples. Here, we couple the data from these complementary approaches for a better understanding of their role in the environment, thereby providing some initial insights into the ecology of this important phylum. All cultured acidobacterial type species are heterotrophic, and members of subdivisions 1, 3, and 4 appear to be more versatile in carbohydrate utilization. Genomic and metagenomic data predict a number of ecologically relevant capabilities for some acidobacteria, including the ability to: use of nitrite as N source, respond to soil macro-, micro nutrients and soil acidity, express multiple active transporters, degrade gellan gum and produce exopolysaccharide (EPS). Although these predicted properties allude to a competitive life style in soil, only very few of these prediction shave been confirmed via physiological studies. The increased availability of genomic and physiological information, coupled to distribution data in field surveys and experiments, should direct future progress in unraveling the ecology of this important but still enigmatic phylum.

Published
2016

39. Plant and soil fungal but not soil bacterial communities are linked in long-term fertilized grassland.

Author

Cassman, N., Leite, M.F.A., Pan, Y., De Hollander, M., van Veen, J.A., Kuramae, E.E., Cassman, N., Leite, M.F.A., Pan, Y., De Hollander, M., van Veen, J.A., and Kuramae, E.E.

Abstract

Inorganic fertilization and mowing alter soil factors with subsequent effects–direct and indirect - on above- and below-ground communities. We explored direct and indirect effects of long-term fertilization (N, P, NPK, Liming) and twice yearly mowing on the plant, bacterial and fungal communities and soil factors. We analyzed co-variation using 16S and 18S rRNA genes surveys, and plant frequency and edaphic factors across treatments. The plant and fungal communities were distinct in the NPK and L treatments, while the bacterial communities and soil factors were distinct in the N and L treatments. Plant community diversity and evenness had low diversity in the NPK and high diversity in the liming treatment, while the diversity and evenness of the bacterial and fungal communities did not differ across treatments, except of higher diversity and evenness in the liming treatment for the bacteria. We found significant co-structures between communities based on plant and fungal comparisons but not between plant and bacterial nor bacterial and fungal comparisons. Our results suggested that the plant and fungal communities are more tightly linked than either community with the bacterial community in fertilized soils. We found co-varying plant, bacterial and fungal taxa in different treatments that may indicate ecological interactions.

Published
2016

40. Primer Sets Developed for Functional Genes Reveal Shifts in Functionality of Fungal Community in Soils

Author

Hannula, S.E., van Veen, J.A., Hannula, S.E., and van Veen, J.A.

Abstract

Phylogenetic diversity of soil microbes is a hot topic at the moment. However, the molecular tools for the assessment of functional diversity in the fungal community are less developed than tools based on genes encoding the ribosomal operon. Here 20 sets of primers targeting genes involved mainly in carbon cycling were designed and/or validated and the functioning of soil fungal communities along a chronosequence of land abandonment from agriculture was evaluated using them. We hypothesized that changes in fungal community structure during secondary succession would lead to difference in the types of genes present in soils and that these changes would be directional. We expected an increase in genes involved in degradation of recalcitrant organic matter in time since agriculture. Out of the investigated genes, the richness of the genes related to carbon cycling was significantly higher in fields abandoned for longer time. The composition of six of the genes analyzed revealed significant differences between fields abandoned for shorter and longer time. However, all genes revealed significant variance over the fields studied, and this could be related to other parameters than the time since agriculture such as pH, organic matter, and the amount of available nitrogen. Contrary to our initial hypothesis, the genes significantly different between fields were not related to the decomposition of more recalcitrant matter but rather involved in degradation of cellulose and hemicellulose.

Published
2016

41. Biosynthetic genes and activity spectrum of antifungal polyynes from Collimonas fungivorans Ter331

Author

Fritsche, K., van den Berg, M., de Boer, W., van Beek, T.A., Raaijmakers, J.M., van Veen, J.A., Leveau, J.H.J., and Microbial Ecology (ME)

Subjects
aspergillus-niger, EPS-2, Organic Chemistry, sp nov, national, mycophagy, Organische Chemie, antibiotics, Laboratorium voor Phytopathologie, caryoynencins, Laboratory of Phytopathology, pseudomonas-fluorescens pf-5, identification, bacteria
Abstract

The antifungal activity of bacteria from the genus Collimonas has been well documented, but the chemistry and gene functions that underlie this phenotype are still poorly understood. Screening of a random plasposon insertion library of Collimonas fungivorans Ter331 for loss-of-function mutants revealed the importance of gene cluster K, which is annotated to code for the biosynthesis of a secondary metabolite and which features genes for fatty acid desaturases and polyketide synthases. Mutants in gene cluster K had lost the ability to inhibit hyphal growth of the fungus Aspergillus niger and were no longer able to produce and secrete several metabolites that after extraction and partial purification from wildtype strain Ter331 were shown to share a putative ene-triyne moiety. Some but not all of these metabolites were able to inhibit growth of A.¿niger, indicating functional variation within this group of Collimonas-produced polyyne-like 'collimomycins'. Polymerase chain reaction analysis of isolates representing different Collimonas species indicated that the possession of cluster K genes correlated positively with antifungal ability, further strengthening the notion that this cluster is involved in collimomycin production. We discuss our findings in the context of other bacterially produced polyynes and the potential use of collimomycins for the control of harmful fungi.

Published
2014

42. Studies on the interaction between the biocontrol agent, Serratia plymuthica A30, and blackleg-causing Dickeya sp. (biovar 3) in potato (Solanum tuberosum)

Author

Czajkowski, R.L., de Boer, W.J., van Veen, J.A., van der Wolf, J.M., and Microbial Ecology (ME)

Subjects
biological-control, fungi, national, food and beverages, colonization, endophytic bacteria, erwinia-carotovora, Biometris, PRI BIOINT Ecological Interactions, inoculation, pseudomonas-fluorescens, plant-pathogens, rhizosphere, protein-tagged strain, seed
Abstract

Interactions between Serratia plymuthica A30 and a blackleg-causing biovar 3 Dickeya sp. were examined. In a potato slice assay, S. plymuthica A30 inhibited tissue maceration caused by Dickeya sp. IPO2222 when co-inoculated at a density at least 10 times greater than that of the pathogen. In glasshouse experiments, population dynamics of the antagonist and of the pathogen in planta were studied by dilution plating and confocal laser scanning microscopy (CLSM) using fluorescent protein-tagged strains. Pathogen-free minitubers were vacuum-infiltrated with DsRed-tagged Dickeya sp. IPO2222 and superficially treated during planting with a water suspension containing GFP-tagged S. plymuthica A30. A30 reduced the blackleg incidence from 55% to 0%. Both the pathogen and the antagonist colonized the seed potato tubers internally within 1 day post-inoculation (dpi). Between 1 and 7 dpi, the population of A30 in tubers increased from 101 to c. 103 CFU g-1 and subsequently remained stable until the end of the experiment (28 dpi). Populations of A30 in stems and roots increased from c. 102 to c. 104 CFU g-1 between 7 and 28 dpi. Dilution plating and CLSM studies showed that A30 decreased the density of Dickeya sp. populations in plants. Dilution plating combined with microscopy allowed the enumeration of strain A30 and its visualization in the vascular tissues of stem and roots and in the pith of roots, as well as its adherence to and colonization of the root surface. The implications of these finding for the use of S. plymuthica A30 as a biocontrol agent are discussed.

Published
2012

43. Characterization of bacterial isolates from rotting potato tuber tissue showing antagonism to Dickeya sp. biovar 3 in vitro and in planta

Author

Czajkowski, R.L., De Boer, W.J., Van Veen, J.A., Van der Wolf, J.M., and Microbial Ecology (ME)

Subjects
biological-control, growth, fungi, national, food and beverages, blackleg, colonization, acyl-homoserine-lactone, soft-rot, erwinia-carotovora, Biometris, soilborne, strain, PRI BIOINT Ecological Interactions, rhizosphere
Abstract

Possibilities for biocontrol of biovar 3 Dickeya sp. in potato were investigated, using bacteria from rotting potato tissue isolated by dilution plating on nonselective agar media. In a plate assay, 649 isolates were screened for antibiosis against Dickeya sp. IPO2222 and for the production of siderophores. Forty-one isolates (6·4%) produced antibiotics and 112 isolates (17·3%) produced siderophores. A selection of 41 antibiotic-producing isolates and 41 siderophore-producing isolates were tested in a potato slice assay for control of the Dickeya sp. Isolates able to reduce rotting of potato tuber tissue by at least 50% of the control were selected. Isolates were characterized by 16S rDNA analysis as Bacillus, Pseudomonas, Rhodococcus, Serratia, Obesumbacterium and Lysinibacillus genera. Twenty-three isolates belonging to different species and genera, 13 producing antibiotics and 10 producing siderophores, were further characterized by testing acyl-homoserine lactone (AHL) production, quorum quenching, motility, biosurfactant production, growth at low (4·0) and high (10·0) pH, growth at 10°C under aerobic and anaerobic conditions and auxin production. In replicated greenhouse experiments, four selected antagonists based on the in vitro tests were tested in planta using wounded or intact minitubers of cv. Kondor subsequently inoculated by vacuum infiltration with an antagonist and a GFP (green fluorescent protein)-tagged biovar 3 Dickeya sp. strain. A potato endophyte A30, characterized as S. plymuthica, protected potato plants by reducing blackleg development by 100% and colonization of stems by Dickeya sp. by 97%. The potential use of S. plymuthica A30 for the biocontrol of Dickeya sp. is discussed.

Published
2012

44. Soil and plant factors driving the community of soil-borne microorganisms across chronosequences of secondary succession of chalk grasslands with neutral pH

Author

Kuramae, E.E., Gamper, H.A., Van Veen, J.A., Kowalchuk, G.A., Terrestrial Microbial Ecology (TME), and Microbial Ecology (ME)

Abstract

Although soil pH has been shown to be an important factor driving microbial communities, relatively little is known about the other potentially important factors that shape soil-borne microbial community structure. This study examined plant and microbial communities across a series of neutral pH fields (pH=7.0–7.5) representing a chronosequence of secondary succession after former arable fields were taken out of production. These fields ranged from 17 to >66 years since the time of abandonment, and an adjacent arable field was included as a reference. Hierarchical clustering analysis, nonmetric multidimensional scaling and analysis of similarity of 52 different plant species showed that the plant community composition was significantly different in the different chronosequences, and that plant species richness and diversity increased with time since abandonment. The microbial community structure, as analyzed by phylogenetic microarrays (PhyloChips), was significantly different in arable field and the early succession stage, but no distinct microbial communities were observed for the intermediate and the late succession stages. The most determinant factors in shaping the soil-borne microbial communities were phosphorous and NH4+. Plant community composition and diversity did not have a significant effect on the belowground microbial community structure or diversity.

Published
2011

45. Control of blackleg and tuber soft rot of potato caused by Pectobacterium and Dickeya species: a review

Author

Czajkowski, R.L., Pérombelon, M.C.M., Van Veen, J.A., Van der Wolf, J.M., and Microbial Ecology (ME)

Subjects
bdellovibrio-bacteriovorus, minituber production, somatic hybrids, van hall dye, fluorescent pseudomonads, fungi, food and beverages, PRI BIOINT Ecological Interactions, diploid potato, in-vitro, transgenic potatoes, erwinia-carotovora subsp, acyl-homoserine lactone
Abstract

This paper briefly reviews research on the causative agents of blackleg and soft rot diseases of potato, namely Pectobacterium and Dickeya species, and the disease syndrome, including epidemiological and aetiological aspects. It critically evaluates control methods used in practice based on the avoidance of the contamination of plants, in particular the use of seed testing programmes and the application of hygienic procedures during crop production. It considers the perspective of breeding and genetic modification to introduce resistance. It also evaluates the application of physical and chemical tuber treatments to reduce inoculum load and examines the possibility of biocontrol using antagonistic bacteria and bacteriophages.

Published
2011

46. Exploring the genomic traits of fungus-feeding bacterial genus Collimonas

Author

Song, C., Schmidt, R.L., de Jager, V.C.L., Krzyzanowska, Dorota, Jongedijk, Esmer, Cankar, Katarina, Beekwilder, J., van Veen, Anouk, De Boer, W., van Veen, J.A., Garbeva, P.V., Song, C., Schmidt, R.L., de Jager, V.C.L., Krzyzanowska, Dorota, Jongedijk, Esmer, Cankar, Katarina, Beekwilder, J., van Veen, Anouk, De Boer, W., van Veen, J.A., and Garbeva, P.V.

Abstract

Background Collimonas is a genus belonging to the class of Betaproteobacteria and consists mostly of soil bacteria with the ability to exploit living fungi as food source (mycophagy). Collimonas strains differ in a range of activities, including swimming motility, quorum sensing, extracellular protease activity, siderophore production, and antimicrobial activities. Results In order to reveal ecological traits possibly related to Collimonas lifestyle and secondary metabolites production, we performed a comparative genomics analysis based on whole-genome sequencing of six strains representing 3 recognized species. The analysis revealed that the core genome represents 43.1 to 52.7 % of the genomes of the six individual strains. These include genes coding for extracellular enzymes (chitinase, peptidase, phospholipase), iron acquisition and type II secretion systems. In the variable genome, differences were found in genes coding for secondary metabolites (e.g. tripropeptin A and volatile terpenes), several unknown orphan polyketide synthase-nonribosomal peptide synthetase (PKS-NRPS), nonribosomal peptide synthetase (NRPS) gene clusters, a new lipopeptide and type III and type VI secretion systems. Potential roles of the latter genes in the interaction with other organisms were investigated. Mutation of a gene involved in tripropeptin A biosynthesis strongly reduced the antibacterial activity against Staphylococcus aureus, while disruption of a gene involved in the biosynthesis of the new lipopeptide had a large effect on the antifungal/oomycetal activities. Conclusions Overall our results indicated that Collimonas genomes harbour many genes encoding for novel enzymes and secondary metabolites (including terpenes) important for interactions with other organisms and revealed genomic plasticity, which reflect the behaviour, antimicrobial activity and lifestylesof Collimonas spp.

Published
2015

47. Soil microbiome responses to the short-term effects of Amazonian deforestation

Author

Navarrete, A.A., Tsai, S.M., Mendes, L.W., Faust, K., De Hollander, M., Cassman, N., Raes, Jeroen, Van Veen, J.A., Kuramae, E.E., Navarrete, A.A., Tsai, S.M., Mendes, L.W., Faust, K., De Hollander, M., Cassman, N., Raes, Jeroen, Van Veen, J.A., and Kuramae, E.E.

Abstract

check auteurs http://www.pnas.org, Slash-and-burn clearing of forest typically results in increase in soil nutrient availability.However, the impact of these nutrients on the soil microbiome is not known. Using next generation sequencing of 16S rRNA gene and shotgun metagenomic DNA,we compared the structure and the potential functions of bacterial community in forest soils to deforested soils in the Amazon region and related the differences to soil chemical factors. Deforestation decreased soil organic matter content and factors linked to soil acidity and raised soil pH, base saturation and exchangeable bases. Concomitant to expected changes in soil chemical factors, we observed an increase in the alpha diversity of the bacterial microbiota and relative abundances of putative copiotrophic bacteria such as Actinomycetales and a decrease in the relative abundances of bacterial taxa such as Chlamydiae, Planctomycetes and Verrucomicrobia in the deforested soils. We did not observe an increase in genes related to microbial nutrient metabolism in deforested soils. However, we did observe changes in community functions such as increases in DNA repair, protein processing, modification, degradation and folding functions, and these functions might reflect adaptation to changes in soil characteristics due to forest clear-cutting and burning. In addition, there were changes in the composition of the bacterial groups associated with metabolism-related functions. Co-occurrence microbial network analysis identified distinct phylogenetic patterns for forest and deforested soils and suggested relationships between Planctomycetes and aluminium content, and Actinobacteria and nitrogen sources in Amazon soils. The results support taxonomic and functional adaptations in the soil bacterial community following deforestation. We hypothesize that these microbial adaptations may serve as a buffer to drastic changes in soil fertility after slashand-burning deforestation in the Amazon region.

Published
2015

48. The dual role of microbes in corrosion

Author

Kip, D.J., Van Veen, J.A., Kip, D.J., and Van Veen, J.A.

Abstract

Corrosion is the result of a series of chemical, physical and (micro) biological processes leading to the deterioration of materials such as steel and stone. It is a world-wide problem with great societal and economic consequences. Current corrosion control strategies based on chemically produced products are under increasing pressure of stringent environmental regulations. Furthermore, they are rather inefficient. Therefore, there is an urgent need for environmentally friendly and sustainable corrosion control strategies. The mechanisms of microbially influenced corrosion and microbially influenced corrosion inhibition are not completely understood, because they cannot be linked to a single biochemical reaction or specific microbial species or groups. Corrosion is influenced by the complex processes of different microorganisms performing different electrochemical reactions and secreting proteins and metabolites that can have secondary effects. Information on the identity and role of microbial communities that are related to corrosion and corrosion inhibition in different materials and in different environments is scarce. As some microorganisms are able to both cause and inhibit corrosion, we pay particular interest to their potential role as corrosion-controlling agents. We show interesting interfaces in which scientists from different disciplines such as microbiology, engineering and art conservation can collaborate to find solutions to the problems caused by corrosion.

Published
2015

49. Revisiting the dilution procedure used to manipulate microbial biodiversity in terrestrial systems revisited

Author

Yan, Y., Kuramae, E.E., Klinkhamer, P.G.L., Van Veen, J.A., Yan, Y., Kuramae, E.E., Klinkhamer, P.G.L., and Van Veen, J.A.

Abstract

http://aem.asm.org, It is hard to assess experimentally the importance of microbial diversity in soil for the functioning of terrestrial ecosystems. An approach that is often used to make such assessment is the so-called dilution method. This method is based on the assumption that the biodiversity of the microbial community is reduced after dilution of a soil suspension and that the reduced diversity persists after incubation of more or less diluted inocula in soil. However, little is known about how the communities develop in soil after inoculation. In this study, serial dilutions of a soil suspension were made and reinoculated into the original soil previously sterilized by gamma irradiation. We determined the structure of the microbial communities in the suspensions and in the inoculated soils using 454-pyrosequencing of 16S rRNA genes. Upon dilution, several diversity indices showed that, indeed, the diversity of the bacterial communities in the suspensions decreased dramatically, with Proteobacteria as the dominant phylum of bacteria detected in all dilutions. The structure of the microbial community was changed considerably in soil, with Proteobacteria, Bacteroidetes, and Verrucomicrobia as the dominant groups in most diluted samples, indicating the importance of soil-related mechanisms operating in the assembly of the communities. We found unique operational taxonomic units (OTUs) even in the highest dilution in both the suspensions and the incubated soil samples. We conclude that the dilution approach reduces the diversity of microbial communities in soil samples but that it does not allow accurate predictions of the community assemblage during incubation of (diluted) suspensions in soil.

Published
2015

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