Bacterial Communities in the Rhizosphere of Biofuel Crops Grown on Marginal Lands as Evaluated by 16S rRNA Gene Pyrosequences

Jesus, Ederson da Conceição; Susilawati, Endang; Smith, Stephanie L.; Wang, Qiong; Chai, Benli; Farris, Ryan J.; Rodrigues, Jorge L. M.; Thelen, Kurt D.; Tiedje, James M.

doi:10.1007/s12155-009-9073-7

Cited by 41 publications

(5 citation statements)

References 31 publications

(37 reference statements)

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“…The microbial compositions of Chinese fir plantations of different ages were different. The bacterial dominance of Acidobacteria, Proteobacteria, Actinobacteria, Chloroflexi, and Firmicutes and the fungal dominance of Ascomycota, Basidiomycota and Zygomycota in the present study have been observed in various soils types [45][46][47][48][49], indicating that these microbial phyla play important roles in soil ecosystems. Changes in microbial community composition indicate changes in soil ecological environment and function [50,51].…”

Section: Shift In Soil Enzyme Activities and Composition And Diversity Of Microbial Communitiessupporting

confidence: 53%

Contrasting Effects of Chinese Fir Plantations of Different Stand Ages on Soil Enzyme Activities and Microbial Communities

Wang

Lin

Dong

et al. 2018

Forests

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Soil enzymes and microbial communities are key factors in forest soil ecosystem functions and are affected by stand age. In this study, we studied soil enzyme activities, composition and diversity of bacterial and fungal communities and relevant physicochemical properties at 0–10 cm depth (D1), 10–20 cm depth (D2) and 20–30 cm depth (D3) soil layers in 3-(3a), 6-(6a), 12-(12a), 18-(18a), 25-(25a), 32-(32a) and 49-year-old (49a) Chinese fir plantations to further reveal the effects of stand age on soil biotic properties. Spectrophotometry and high-throughput sequencing was used to assess the soil enzyme activity and microbial community composition and diversity of Chinese fir plantation of different stand ages, respectively. We found that soil catalase activity increased as the stand age of Chinese fir plantations increased, whereas the activities of urease, sucrase and β-glucosidase in 12a, 18a and 25a were lower than those in 6a, 32a and 49a. Shannon and Chao1 indices of bacterial and fungal communities first decreased gradually from 6a to 18a or 25a and then increased gradually from 25a to 49a. Interestingly, the sucrase and β-glucosidase activities and the Shannon and Chao1 indices in 3a were all lower than 6a. We found that the relative abundance of dominant microbial phyla differed among stand ages and soil depths. The proportion of Acidobacteria first increased and then decreased from low forest age to high forest age, and its relative abundance in 12a, 18a and 25a were higher than 3a, 32a and 49a, but the proportion of Proteobacteria was opposite. The proportion of Ascomycota first decreased and then increased from 6a to 49a, and its relative abundance in 12a, 18a and 25a was lower than 3a, 6a, 32a and 49a. Our results indicate that soil enzyme activities and the richness and diversity of the microbial community are limited in the middle stand age (from 12a to 25a), which is important for developing forest management strategies to mitigate the impacts of degradation of soil biological activities.

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Section: Shift In Soil Enzyme Activities and Composition And Diversity Of Microbial Communitiessupporting

confidence: 53%

Contrasting Effects of Chinese Fir Plantations of Different Stand Ages on Soil Enzyme Activities and Microbial Communities

Wang

Lin

Dong

et al. 2018

Forests

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“…In contrasting soils, such as deserts and forests, significantly fewer FP-CAZy core sequences could be identified, suggesting that the soil environment, which can be geographically specific, is important for defining a soil core and its functional potential. This result has been reported previously where soil type was the critical driver of microbial community compositional differences [53,54]. For metagenomic studies, this observation has implications for the genomic or functional level that should be compared between studies.…”

Section: Discussionsupporting

confidence: 82%

Identification of the Core Set of Carbon-Associated Genes in a Bioenergy Grassland Soil

et al. 2016

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Despite the central role of soil microbial communities in global carbon (C) cycling, little is known about soil microbial community structure and even less about their metabolic pathways. Efforts to characterize soil communities often focus on identifying differences in gene content across environmental gradients, but an alternative question is what genes are similar in soils. These genes may indicate critical species or potential functions that are required in all soils. Here we identified the “core” set of C cycling sequences widely present in multiple soil metagenomes from a fertilized prairie (FP). Of 226,887 sequences associated with known enzymes involved in the synthesis, metabolism, and transport of carbohydrates, 843 were identified to be consistently prevalent across four replicate soil metagenomes. This core metagenome was functionally and taxonomically diverse, representing five enzyme classes and 99 enzyme families within the CAZy database. Though it only comprised 0.4% of all CAZy-associated genes identified in FP metagenomes, the core was found to be comprised of functions similar to those within cumulative soils. The FP CAZy-associated core sequences were present in multiple publicly available soil metagenomes and most similar to soils sharing geographic proximity. In soil ecosystems, where high diversity remains a key challenge for metagenomic investigations, these core genes represent a subset of critical functions necessary for carbohydrate metabolism, which can be targeted to evaluate important C fluxes in these and other similar soils.

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“…DNA extraction and SSU rRNA gene amplification methods were described previously (29). The SSU rRNA gene amplicons from the first sample were sequenced by the Joint Genome Institute (JGI) in their standard work flow, which used 454 GS FLX and Titanium platforms and a primer set (926F, AAACTYAAAKGAATTGACGG; 1392R, ACGGGCGG TGTGTRC) that targeted the V6-V8 variable region of bacteria, archaea, and eukaryotes.…”

Section: Methodsmentioning

confidence: 99%

Microbial Community Analysis with Ribosomal Gene Fragments from Shotgun Metagenomes

Guo

Cole

Zhang

et al. 2016

Appl Environ Microbiol

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c Shotgun metagenomic sequencing does not depend on gene-targeted primers or PCR amplification; thus, it is not affected by primer bias or chimeras. However, searching rRNA genes from large shotgun Illumina data sets is computationally expensive, and no approach exists for unsupervised community analysis of small-subunit (SSU) rRNA gene fragments retrieved from shotgun data. We present a pipeline, SSUsearch, to achieve the faster identification of short-subunit rRNA gene fragments and enabled unsupervised community analysis with shotgun data. It also includes classification and copy number correction, and the output can be used by traditional amplicon analysis platforms. Shotgun metagenome data using this pipeline yielded higher diversity estimates than amplicon data but retained the grouping of samples in ordination analyses. We applied this pipeline to soil samples with paired shotgun and amplicon data and confirmed bias against Verrucomicrobia in a commonly used V6-V8 primer set, as well as discovering likely bias against Actinobacteria and for Verrucomicrobia in a commonly used V4 primer set. This pipeline can utilize all variable regions in SSU rRNA and also can be applied to large-subunit (LSU) rRNA genes for confirmation of community structure. The pipeline can scale to handle large amounts of soil metagenomic data (5 Gb memory and 5 central processing unit hours to process 38 Gb [1 lane] of trimmed Illumina HiSeq2500 data) and is freely available at https: //github.com/dib-lab/SSUsearch under a BSD license. Microbial phylogeny, identification, and evolution studies were revolutionized by the introduction of small-subunit (SSU) rRNA analysis 25 years ago (1), and with the advent of PCR and high-throughput sequencing, community structure studies now are commonplace (2-5). The growing sizes of SSU rRNA gene databases provide a rich ecological and phylogenetic context for SSU rRNA gene-based community structure surveys (6, 7). However, the accuracy of PCR-based amplicon approaches is reduced by primer bias and chimeras (8, 9).Unlike gene-targeted amplicon sequencing, shotgun sequencing takes samples from the entire community by sequencing randomly sheared fragments of DNA (10, 11). Hence, while amplicon sequencing can provide far deeper coverage of SSU rRNA genes with the same amount of sequencing, shotgun sequencing may provide a more accurate characterization of microbial diversity, including functional diversity (12). In particular, shotgun sequencing may provide an improved means to detect divergent sequences not recovered by standard SSU rRNA gene primers, such as those of Verrucomicrobia, as well as eukaryotic members of the community (8,(12)(13)(14). Note that both approaches remain prone to sequencing error and bias from environmental DNA extraction (9).The challenges for using shotgun DNA for rRNA analyses are in efficiently searching for these fragments in large sequence data sets and the subsequent analysis of the matching short reads. Several methods have been developed for SSU rRNA retrieval in ...

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Bacterial Communities in the Rhizosphere of Biofuel Crops Grown on Marginal Lands as Evaluated by 16S rRNA Gene Pyrosequences

Cited by 41 publications

References 31 publications

Contrasting Effects of Chinese Fir Plantations of Different Stand Ages on Soil Enzyme Activities and Microbial Communities

Contrasting Effects of Chinese Fir Plantations of Different Stand Ages on Soil Enzyme Activities and Microbial Communities

Identification of the Core Set of Carbon-Associated Genes in a Bioenergy Grassland Soil

Microbial Community Analysis with Ribosomal Gene Fragments from Shotgun Metagenomes

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