Impact of metagenomic DNA extraction procedures on the identifiable endophytic bacterial diversity in Sorghum bicolor (L. Moench)

Maropola, Mapula Kgomotso Annah; Ramond, Jean‐Baptiste; Trindade, Marla

doi:10.1016/j.mimet.2015.03.012

Cited by 71 publications

(43 citation statements)

References 136 publications

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“…The genera Massilia, Pseudomonas , and Limnohabitans were predominant in the three grass species. This is only partly in line with a previous study showing that Pseudomonas, Rhizobium , and Bacillus were the most abundant genera in roots and shoots of sorghum21. Similar results were obtained by Robinson et al 7.…”

Section: Discussionsupporting

confidence: 92%

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Bacterial endophyte communities of three agricultural important grass species differ in their response towards management regimes

Wemheuer

Kaiser

Karlovský

et al. 2017

Sci Rep

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Endophytic bacteria are critical for plant growth and health. However, compositional and functional responses of bacterial endophyte communities towards agricultural practices are still poorly understood. Hence, we analyzed the influence of fertilizer application and mowing frequency on bacterial endophytes in three agriculturally important grass species. For this purpose, we examined bacterial endophytic communities in aerial plant parts of Dactylis glomerata L., Festuca rubra L., and Lolium perenne L. by pyrotag sequencing of bacterial 16S rRNA genes over two consecutive years. Although management regimes influenced endophyte communities, observed responses were grass species-specific. This might be attributed to several bacteria specifically associated with a single grass species. We further predicted functional profiles from obtained 16S rRNA data. These profiles revealed that predicted abundances of genes involved in plant growth promotion or nitrogen metabolism differed between grass species and between management regimes. Moreover, structural and functional community patterns showed no correlation to each other indicating that plant species-specific selection of endophytes is driven by functional rather than phylogenetic traits. The unique combination of 16S rRNA data and functional profiles provided a holistic picture of compositional and functional responses of bacterial endophytes in agricultural relevant grass species towards management practices.

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Section: Discussionsupporting

confidence: 92%

“…In total, 71 samples of the grass species L. perenne, D. glomerata , and F. rubra in two consecutive years were analyzed. Consistent with previous work72021, bacterial endophyte communities were dominated by five phyla. The genera Massilia, Pseudomonas , and Limnohabitans were predominant in the three grass species.…”

Section: Discussionsupporting

confidence: 91%

Bacterial endophyte communities of three agricultural important grass species differ in their response towards management regimes

Wemheuer

Kaiser

Karlovský

et al. 2017

Sci Rep

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“…Extraction requirements and recommendations A range of methods are used to extract DNA from plant tissues, including fungal and bacterial endophytes Maropola et al 2015). Recent extractions of arbuscular mycorrhizal fungal (AMF) DNA from plant roots have used the DNeasy PowerSoil ® kit Padamsee et al 2016), or the DNeasy Plant kit for AMF in the roots of Ammophila arenaria (Johansen et al 2015).…”

Section: Extraction Of Dna From Plant Tissuementioning

confidence: 99%

“…It is possible that the DNeasy PowerSoil ® kit gives superior results in samples of tree roots that are higher in phenolic compounds in comparison to softer tissue like grass roots. DNeasy PowerSoil ® or PowerMax ® kits are routinely used for sample material, including plant tissues, that are high in inhibitory compounds (Dineen et al 2010;Maropola et al 2015), even though relatively low DNA yields are reported for some sample material (Maropola et al 2015). While there is little evidence upon which to base favouring one extraction method over others, standardisation on one method shown to be adequate (or at least not inadequate) will improve the comparability of results obtained from different laboratories.…”

Section: Extraction Of Dna From Plant Tissuementioning

confidence: 99%

Methods for the extraction, storage, amplification and sequencing of DNA from environmental samples

Lear¹,

Dickie²,

Banks³

et al. 2018

105

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Advances in the sequencing of DNA extracted from media such as soil and water offer huge opportunities for biodiversity monitoring and assessment, particularly where the collection or identification of whole organisms is impractical. However, there are myriad methods for the extraction, storage, amplification and sequencing of DNA from environmental samples. To help overcome potential biases that may impede the effective comparison of biodiversity data collected by different researchers, we propose a standardised set of procedures for use on different taxa and sample media, largely based on recent trends in their use. Our recommendations describe important steps for sample pre-processing and include the use of (a) Qiagen DNeasy PowerSoil ® and PowerMax ® kits for extraction of DNA from soil, sediment, faeces and leaf litter; (b) DNeasy PowerSoil ® for extraction of DNA from plant tissue; (c) DNeasy Blood and Tissue kits for extraction of DNA from animal tissue; (d) DNeasy Blood and Tissue kits for extraction of DNA from macroorganisms in water and ice; and (e) DNeasy PowerWater ® kits for extraction of DNA from microorganisms in water and ice. Based on key parameters, including the specificity and inclusivity of the primers for the target sequence, we recommend the use of the following primer pairs to amplify DNA for analysis by Illumina MiSeq DNA sequencing: (a) 515f and 806RB to target bacterial 16S rRNA genes (including regions V3 and V4); (b) #3 and #5RC to target eukaryote 18S rRNA genes (including regions V7 and V8); (c) #3 and #5RC are also recommended for the routine analysis of protist community DNA; (d) ITS6F and ITS7R to target the chromistan ITS1 internal transcribed spacer region; (e) S2F and S3R to target the ITS2 internal transcribed spacer in terrestrial plants; (f) fITS7 or gITS7, and ITS4 to target the fungal ITS2 region; (g) NS31 and AML2 to target glomeromycota 18S rRNA genes; and (h) mICOIintF and jgHCO2198 to target cytochrome c oxidase subunit I (COI) genes in animals. More research is currently required to confirm primers suitable for the selective amplification of DNA from specific vertebrate taxa such as fish. Combined, these recommendations represent a framework for efficient, comprehensive and robust DNA-based investigations of biodiversity, applicable to most taxa and ecosystems. The adoption of standardised protocols for biodiversity assessment and monitoring using DNA extracted from environmental samples will enable more informative comparisons among datasets, generating significant benefits for ecological science and biosecurity applications.

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“…Tsurumaru et al (2015) analyzed a metagenome of the bacterial community associated with the taproot of sugar beet (Beta vulgari L.) The study found that Alphaproteobacteria are dominant, followed by the Actinobacteria and the Betaproteobacteria. Another metagenomic study of the sorghum root and stem microbiome revealed that the two tissues harboured significantly different composition of bacterial communities, but both were dominated by agriculturally important genera such as Microbacterium, Agrobacterium, Sphingobacterium, Herbaspirillum, Erwinia, Pseudomonas and Stenotrophomonas (Maropola et al, 2015).…”

Section: Occurrence and Diversity Of Bacterial Endophytes In Agricultmentioning

confidence: 99%

Bacterial endophytes in agricultural crops and their role in stress tolerance: a review

Miliūtė

Buzaitė

Baniulis

et al. 2015

Zemdirbyste-Agriculture

183

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Bacterial endophytes are a class of endosymbiotic microorganisms widespread among plants that colonize intercellular and intracellular spaces of all plant compartments and do not cause plant disease or significant morphological changes. Plant and endophytic bacteria association includes vast diversity of bacterial taxa and plant hosts and in this review we present an overview of taxonomic composition of endophytes identified in common agricultural crops. Further, during the last decade, new aspects of the microbial diversity have emerged with application of new metagenomic analysis methods in studies of bacterial endophytes. Endophytic bacteria community structure is influenced by plant genotype, abiotic and biotic factors such as environment conditions, microbe -microbe interactions and plant -microbe interactions. Agricultural practices, such as soil tillage, irrigation, use of pesticides and fertilizers have a major effect on function and structure of soil and endophytic microbial populations. Therefore, the use of agricultural practices that maintain natural diversity of plant endophytic bacteria is becoming an important element of sustainable agriculture that could ensure plant productivity and quality of agricultural production. The diverse endophytic microbial communities play integral and unique role in the functioning of agroecosystems. Endophytic bacteria have been shown to have several beneficial effects on their host plant, including growth promoting activity, modulation of plant metabolism and phytohormone signalling that leads to adaptation to environmental abiotic or biotic stress. Use of endophytic bacteria presents a special interest for development of agricultural applications that ensure improved crop performance under cold, draught or contaminated soil stress conditions or enhanced disease resistance.

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Impact of metagenomic DNA extraction procedures on the identifiable endophytic bacterial diversity in Sorghum bicolor (L. Moench)

Cited by 71 publications

References 136 publications

Bacterial endophyte communities of three agricultural important grass species differ in their response towards management regimes

Bacterial endophyte communities of three agricultural important grass species differ in their response towards management regimes

Methods for the extraction, storage, amplification and sequencing of DNA from environmental samples

Bacterial endophytes in agricultural crops and their role in stress tolerance: a review

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