Amplicon –Based Metagenomic Analysis of Mixed Fungal Samples Using Proton Release Amplicon Sequencing

Tonge, Daniel; Pashley, Catherine H.; Gant, Timothy W.

doi:10.1371/journal.pone.0093849

Cited by 57 publications

(34 citation statements)

References 31 publications

(38 reference statements)

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“…However, the database for this gene is highly biased toward metazoans and may thus be limited in the detection of other groups (such as algae and unicellular eukaryotes). Other genes have been targeted for ecological studies (e.g., 18S rDNA, Logares et al, 2014a, 28S rDNA, Hirai et al, 2015, and the ITS region Tonge et al, 2014) and a combination of these genes and COI may give a more comprehensive assessment of diversity. In the future, molecular studies using ARMS may also investigate the functional ability of the assemblage using shotgun metagenomic techniques.…”

Section: Artificial Structures To Monitormentioning

confidence: 99%

Implementing and Innovating Marine Monitoring Approaches for Assessing Marine Environmental Status

et al. 2016

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Marine environmental monitoring has tended to focus on site-specific methods of investigation. These traditional methods have low spatial and temporal resolution and are relatively labor intensive per unit area/time that they cover. To implement the Marine Strategy Framework Directive (MSFD), European Member States are required to improve marine monitoring and design monitoring networks. This can be achieved by developing and testing innovative and cost-effective monitoring systems, as well as indicators of environmental status. Here, we present several recently developed methodologies and technologies to improve marine biodiversity indicators and monitoring methods. The innovative tools are discussed concerning the technologies presently utilized as well as the advantages and disadvantages of their use in routine monitoring. In particular, the present analysis focuses on: (i) molecular approaches, including microarray, Real Time quantitative PCR (qPCR), and metagenetic (metabarcoding) tools; (ii) optical (remote) sensing and acoustic methods; and (iii) in situ monitoring instruments. We also discuss Danovaro et al. Innovative Approaches in Marine Monitoring their applications in marine monitoring within the MSFD through the analysis of case studies in order to evaluate their potential utilization in future routine marine monitoring. We show that these recently-developed technologies can present clear advantages in accuracy, efficiency and cost.

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Section: Artificial Structures To Monitormentioning

confidence: 99%

Implementing and Innovating Marine Monitoring Approaches for Assessing Marine Environmental Status

et al. 2016

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“…This cutoff has not been systematically reviewed or shown to be appropriate for fungal ITS sequencing data. Tonge et al (2014) found that some fungi cannot be amplified by specific “conserved” primer pairs and suggested that a “multi-region approach be taken for other amplicon-based metagenomic studies”. This was not done in our study and may be a limitation.…”

Section: Discussionmentioning

confidence: 99%

Fungal microbiomes associated with green and non-green building materials

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et al. 2017

International Biodeterioration & Biodegradation

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Water-damaged buildings can lead to fungal growth and occupant health problems. Green building materials, derived from renewable sources, are increasingly utilized in construction and renovations. However, the question as to what fungi will grow on these green compared to non-green materials, after they get wet, has not been adequately studied. By determining what fungi grow on each type of material, the potential health risks can be more adequately assessed. In this study, we inoculated green and non-green pieces of ceiling tile, composite board, drywall, and flooring with indoor dust containing a complex mixture of naturally occurring fungi. The materials were saturated with water and incubated for two months in a controlled environment. The resulting fungal microbiomes were evaluated using ITS amplicon sequencing. Overall, the richness and diversity of the mycobiomes on each pair of green and non-green pieces were not significantly different. However, different genera dominated on each type of material. For example, Aspergillus spp. had the highest relative abundance on green and non-green ceiling tiles and green composite boards, but Peniophora spp. dominated the non-green composite board. In contrast, Penicillium spp. dominated green and non-green flooring samples. Green gypsum board was dominated by Phialophora spp. and Stachybotrys spp., but non-green gypsum board by Myrothecium spp. These data suggest that water-damaged green and non-green building materials can result in mycobiomes that are dominated by fungal genera whose member species pose different potentials for health risks.

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“…Accessing the microbial diversity using NGS can be achieved by using two different approaches 1) amplicon sequencing 2) shortgun metagenomics. In first approach the DNA fragments are amplified using a specific primer targeting a single gene like the 16S rDNA for eubacteria [55,56]. In second approach, the large DNA fragments or even complete genomes from organisms in a community can be characterized using shortgun libraries and amplifying them using multiple primer sets.…”

Section: Metagenomicsmentioning

confidence: 99%