Internal Transcribed Spacer and 16S Amplicon Sequencing Identifies Microbial Species Associated with Asbestos in New Zealand

Doyle, Erin L.; Blanchon, Dan; Wells, Sarah; Lange, P. J. de; Lockhart, P. J.; Waipara, Nick; Manefield, Michael; Wallis, Shannon L.; Berry, Terri-Ann

doi:10.3390/genes14030729

Cited by 3 publications

(3 citation statements)

References 49 publications

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“…Asbestos-contaminated soil samples also showed indications of fibril amorphization. Unfortunately, no DNA sequence data were available for these particular samples, but other asbestos-contaminated soil samples from the same areas were sequenced by Doyle et al [38], who identified a range of fungal and bacterial species as being present, including Cladosporium cladosporoides, Epicoccum nigrum, Fusarium oxysporum and Yarrowia lipolytica, all of which have been reported in the literature as being able to produce siderophores in vitro [16,36,39,40]. Previous research by Martino et al [19] found that several soil fungi were able to remove iron from crocidolite fibres in vitro.…”

Section: Discussionmentioning

confidence: 99%

A Preliminary Investigation into the Degradation of Asbestos Fibres in Soils, Rocks and Building Materials Associated with Naturally Occurring Biofilms

Berry,

Wallis,

Doyle

et al. 2024

Minerals

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Bioremediation utilizes living organisms such as plants, microbes and their enzymatic products to reduce toxicity in xenobiotic compounds. Microbial-mediated bioremediation is cost effective and sustainable and in situ application is easily implemented. Either naturally occurring metabolic activity can be utilized during bioremediation for the degradation, transformation or accumulation of substances, or microbial augmentation with non-native species can be exploited. Despite the perceived low potential for the biological degradation of some recalcitrant compounds, successful steps towards bioremediation have been made, including with asbestos minerals, which are prevalent in building stock (created prior to the year 2000) in New Zealand. Evidence of the in situ biodegradation of asbestos fibres was investigated in samples taken from a retired asbestos mine, asbestos-contaminated soils and biofilm or lichen-covered asbestos-containing building materials. Microbial diversity within the biofilms to be associated with the asbestos-containing samples was investigated using internal transcribed spacer and 16S DNA amplicon sequencing, supplemented with isolation and culturing on agar plates. A range of fungal and bacterial species were found, including some known to produce siderophores. Changes to fibre structure and morphology were analysed using Transmission Electron Microscopy and Energy-Dispersive X-ray Spectroscopy. Chrysotile fibrils from asbestos-containing material (ACMs), asbestos-containing soils, and asbestos incorporated into lichen material showed signs of amorphisation and dissolution across their length, which could be related to biological activity.

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Section: Discussionmentioning

confidence: 99%

A Preliminary Investigation into the Degradation of Asbestos Fibres in Soils, Rocks and Building Materials Associated with Naturally Occurring Biofilms

Berry,

Wallis,

Doyle

et al. 2024

Minerals

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“…It has been shown that asbestos fibres can be partially degraded, and the surface reactivity reduced, by the activity of some fungi, bacteria and lichens, and that this is due to removal of metal ions, including iron, by siderophores and similar iron-chelating compounds (Bhattacharya et al 2015;Daghino et al 2006;Daghino et al 2008;Daghino et al 2010;Favero-Longo et al 2005;Favero-Longo et al 2007;Mohanty et al 2018). Several studies have shown that a range of bacteria, cyanobacteria, filamentous fungi, yeast fungi and lichenised fungi are able to colonise asbestos and related mineral deposits (Bhattacharya et al 2016;Daghino et al 2008, Daghino et al 2009Doyle et al 2023).…”

Section: Introductionmentioning

confidence: 99%

“…For microbial bioremediation to be successful, it is necessary to assemble a library of potential siderophore-producing bacteria or fungi that are well suited to the environmental conditions of the local area (Doyle et al 2023). Production of siderophores in candidate isolates can be detected by culturing them on chrome azurol S (CAS)-agar plates.…”

Section: Introductionmentioning

confidence: 99%

Siderophore production in fungi from asbestos biofilms: The first step towards bioremediation of a carcinogenic mineral

Blanchon,

de Lange,

Doyle

et al. 2023

PiBdiv

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Asbestos refers to six types of fibrous, silicate minerals, historically used for a wide range of household, commercial and industrial applications. Asbestos exposure is known to cause diseases such as asbestosis, pleural mesothelioma and lung cancer, and is responsible for around 220 deaths per year in Aotearoa / New Zealand. Asbestos is disposed of using a designated hazardous landfill facility, an expensive and unsustainable practice. As an alternative, research has focused on bioremediation to manage asbestos contamination. Bioremediation research has shown that asbestos fibres can be partially degraded, and surface reactivity decreased, by the activity of iron-chelating siderophores, produced by some fungi and bacteria. This paper presents initial results of siderophore-detecting chrome azurol S (CAS)-agar plate assays on mycobiota collected from biofilms from asbestos-containing building products in Tāmaki Makaurau / Auckland and natural asbestos mineral deposits in Kahurangi National Park, northwest of Whakatū / Nelson.

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Detoxification of Contaminated Soil to Restore Its Health for Sustainable Agriculture

Dahiya,

Behl,

Kumari

et al. 2024

Microorganisms for Sustainability

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Internal Transcribed Spacer and 16S Amplicon Sequencing Identifies Microbial Species Associated with Asbestos in New Zealand

Cited by 3 publications

References 49 publications

A Preliminary Investigation into the Degradation of Asbestos Fibres in Soils, Rocks and Building Materials Associated with Naturally Occurring Biofilms

A Preliminary Investigation into the Degradation of Asbestos Fibres in Soils, Rocks and Building Materials Associated with Naturally Occurring Biofilms

Siderophore production in fungi from asbestos biofilms: The first step towards bioremediation of a carcinogenic mineral

Detoxification of Contaminated Soil to Restore Its Health for Sustainable Agriculture

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