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Unravelling the effects of tropical land use conversion on the soil microbiome

dc.contributor.authorBerkelmann, Dirk
dc.contributor.authorSchneider, Dominik
dc.contributor.authorMeryandini, Anja
dc.contributor.authorDaniel, Rolf
dc.date.accessioned2020-02-09T04:54:06Z
dc.date.available2020-02-09T04:54:06Z
dc.date.issued2020
dc.identifier.urihttp://resolver.sub.uni-goettingen.de/purl?gs-1/17160
dc.description.abstractAbstract Background The consequences of deforestation and agricultural treatments are complex and affect all trophic levels. Changes of microbial community structure and composition associated with rainforest conversion to managed systems such as rubber and oil palm plantations have been shown by 16S rRNA gene analysis previously, but functional profile shifts have been rarely addressed. In this study, we analysed the effects of rainforest conversion to different converted land use systems, including agroforestry (“jungle rubber”) and monoculture plantations comprising rubber and oil palm, on soilborne microbial communities by metagenomic shotgun sequencing in Sumatra, Indonesia. Results The diversity of bacteria and archaea decreased whereas diversity of fungi increased in the converted land use systems. The soil microbiome was dominated by bacteria followed by fungi. We detected negative effects of land use conversion on the abundance of Proteobacteria (especially on Rhizobiales and Burkholderiales) and positive effects on the abundance of Acidobacteria and Actinobacteria. These abundance changes were mainly driven by pH, C:N ratio, and Fe, C and N content. With increasing land use intensity, the functional diversity decreased for bacteria, archaea and fungi. Gene abundances of specific metabolisms such as nitrogen metabolism and carbon fixation were affected by land use management practices. The abundance of genes related to denitrification and nitrogen fixation increased in plantations while abundance of genes involved in nitrification and methane oxidation showed no significant difference. Linking taxonomic and functional assignment per read indicated that nitrogen metabolism-related genes were mostly assigned to members of the Rhizobiales and Burkholderiales. Abundances of carbon fixation genes increased also with increasing land use intensity. Motility- and interaction-related genes, especially genes involved in flagellar assembly and chemotaxis genes, decreased towards managed land use systems. This indicated a shift in mobility and interspecific interactions in bacterial communities within these soils. Conclusions Rainforest conversion to managed land use systems drastically affects structure and functional potential of soil microbial communities. The decrease in motility- and interaction-related functions from rainforest to converted land use systems indicated not only a shift in nutrient cycling but also in community dynamics. Fertilizer application and correspondingly higher availability of nutrients in intensively managed plantations lead to an environment in which interspecific interactions are not favoured compared to rainforest soils. We could directly link effects of land management, microbial community structure and functional potential for several metabolic processes. As our study is the first study of this size and detail on soil microbial communities in tropical systems, we provide a basis for further analyses.
dc.description.sponsorshipOpen-Access-Publikationsfonds 2020
dc.language.isoen
dc.publisherBioMed Central
dc.identifier.bibliographicCitationEnvironmental Microbiome. 2020 Feb 03;15(1):5
dc.rightsopenAccess
dc.rights.urihttps://creativecommons.org/licenses/by/4.0/
dc.titleUnravelling the effects of tropical land use conversion on the soil microbiome
dc.typejournalArticle
dc.identifier.doi10.1186/s40793-020-0353-3
dc.type.versionpublishedVersion
dc.date.updated2020-02-09T04:54:06Z
dc.rights.holderThe Author(s).
dc.bibliographicCitation.volume15
dc.bibliographicCitation.issue1
dc.type.subtypejournalArticle
dc.bibliographicCitation.articlenumber5
dc.bibliographicCitation.journalEnvironmental Microbiome


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