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Diesel−biodegradation and biosurfactant−production by Janthinobacterium lividum AQ5-29 and Pseudomonas fildesensis AQ5-41 isolated from Antarctic soil
| Indexado |
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| DOI | 10.1016/J.IBIOD.2024.105731 | ||||
| Año | 2024 | ||||
| Tipo | artículo de investigación |
Citas Totales
Autores Afiliación Chile
Instituciones Chile
% Participación
Internacional
Autores
Afiliación Extranjera
Instituciones
Extranjeras
Abstract
Given the substantial diesel demand in Antarctic operations, the means of addressing ecological restoration following its inappropriate release are attracting attention from researchers. The Madrid Protocol mandates the use of indigenous microbes in bioremediation. Recent studies have proposed many native isolates with biodegradation temperatures exceeding 20 degrees C, which are impractical for Antarctic contexts. Therefore, harnessing psychrophilic, native degraders with biosurfactant-producing traits presents an advantage for implementation in the harsh Antarctic environment. In this study, effective consortia/isolates demonstrated robust growth and biodegradation rates at 10 degrees C with diesel as the sole carbon source. Two primary bacterial members, Janthinobacterium lividum and Pseudomonas fildesensis, were identified from the most effective consortium SI 20 using 16S rRNA and multilocus-sequence-analysis (MLSA) clustering. The degraders were characterised as being psychrophilic, Gram -negative, rod-shaped, and catalase- and oxidase-positive. Despite the observed antagonistic effects during co-cultivation, strains J. lividum AQ5-29 and P. fildesensis AQ5-41 demonstrated effective diesel removal (2.91 & 4.20 mg mL-1) with biodegradation of C10 to C30 hydrocarbons (40-100%) at 10 degrees C in less than 8 days. Both strains also were identified as biosurfactant producers with varying emulsification activities (32-92%) and cell surface hydrophobicity (52-58%). These findings highlight the potential of both strains for restoring diesel-related substrates, particularly in Antarctica.
| Ord. | Autor | Género | Institución - País |
|---|---|---|---|
| 1 | Yap, How Swen | - |
Univ Putra Malaysia - Malasia
Universiti Putra Malaysia - Malasia |
| 2 | Khalid, Farah Eryssa | Mujer |
Univ Putra Malaysia - Malasia
Universiti Putra Malaysia - Malasia |
| 3 | Wong, Rasidnie Razin | - |
Univ Putra Malaysia - Malasia
Universiti Putra Malaysia - Malasia |
| 4 | Convey, Peter | Hombre |
BRITISH ANTARCTIC SURVEY - Reino Unido
Univ Johannesburg - República de Sudáfrica Millennium Inst Biodivers Antarctic & Subantarct E - Chile University of Johannesburg - República de Sudáfrica Millennium Institute Biodiversity of Antarctic and Subantarctic Ecosystems (BASE) - Chile |
| 5 | Sabri, S. | - |
Univ Putra Malaysia - Malasia
Universiti Putra Malaysia - Malasia |
| 6 | Khalil, K. A. K. | - |
Univ Teknol Mara - Malasia
Universiti Teknologi Mara - Malasia |
| 7 | Zulkharnain, Azham | - |
Shibaura Inst Technol - Japón
Shibaura Institute of Technology - Japón |
| 8 | Merican, Faradina | - |
Univ Sains Malaysia - Malasia
Universiti Sains Malaysia - Malasia |
| 9 | Shaari, Hasrizal | - |
Univ Malaysia Terengganu - Malasia
Universiti Malaysia Terengganu - Malasia |
| 10 | Ahmad, Siti Aqlima | - |
Univ Putra Malaysia - Malasia
Universiti Putra Malaysia - Malasia |
| Fuente |
|---|
| Universiti Putra Malaysia |
| NERC |
| Natural Environment Research Council |
| Jabatan Perkhidmatan Awam Malaysia |
| British Antarctic Survey |
| Yayasan Penyelidikan Antartika Sultan Mizan |
| Universiti Putra Malaysia (UPM) |
| Excellent Students' Program (PPC) scholarship under Malaysian Public Service Department (JPA) |
| Laboratory of Eco-Remediation Technology |
| Malaysian Public Service Department |
| Agradecimiento |
|---|
| This project was financially supported by the research grants attached to S.A. Ahmad (GPM -2019/9678900) disbursed by Universiti Putra Malaysia (UPM) . H.S. Yap is funded by the Excellent Students' Program (PPC) scholarship under Malaysian Public Service Department (JPA) while P. Convey is supported by NERC core funding to the British Antarctic Survey's 'Biodiversity, Evolution and Adaptation' Team. The authors would like to thank Laboratory of Eco-Remediation Technology (EcoRemTech) , Universiti Putra Malaysia, British Antarctic Survey, and Sultan Mizan Antarctic Research Foundation (YPASM) . We also appreciate Nor 'Atiyyah Mohamed for guiding in the gas chromatography analysis. |
| This project was financially supported by the research grants attached to S.A. Ahmad ( GPM-2019/9678900 ) disbursed by Universiti Putra Malaysia (UPM) . H.S. Yap is funded by the Excellent Students' Program (PPC) scholarship under Malaysian Public Service Department (JPA) while P. Convey is supported by NERC core funding to the British Antarctic Survey's ‘Biodiversity, Evolution and Adaptation’ Team. The authors would like to thank Laboratory of Eco-Remediation Technology (EcoRemTech), Universiti Putra Malaysia, British Antarctic Survey, and Sultan Mizan Antarctic Research Foundation (YPASM). We also appreciate Nor ’Atiyyah Mohamed for guiding in the gas chromatography analysis. |
| This project was financially supported by the research grants attached to S.A. Ahmad ( GPM-2019/9678900 ) disbursed by Universiti Putra Malaysia (UPM) . H.S. Yap is funded by the Excellent Students' Program (PPC) scholarship under Malaysian Public Service Department (JPA) while P. Convey is supported by NERC core funding to the British Antarctic Survey's ‘Biodiversity, Evolution and Adaptation’ Team. The authors would like to thank Laboratory of Eco-Remediation Technology (EcoRemTech), Universiti Putra Malaysia, British Antarctic Survey, and Sultan Mizan Antarctic Research Foundation (YPASM). We also appreciate Nor ’Atiyyah Mohamed for guiding in the gas chromatography analysis. |
