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Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater

A multiple metal-resistant Brevibacterium sp. strain CS2, isolated from an industrial wastewater, resisted arsenate and arsenate upto 280 and 40 mM. The order of resistance against multiple metals was Arsenate > Arsenite > Selenium = Cobalt > Lead = Nickel > Cadmium = Chromium = Mercury....

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Autores principales: Sher, Shahid, Tahir Ishaq, Muhammad, Abbas Bukhari, Dilara, Rehman, Abdul
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10480674/
https://www.ncbi.nlm.nih.gov/pubmed/37680980
http://dx.doi.org/10.1016/j.sjbs.2023.103781
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author Sher, Shahid
Tahir Ishaq, Muhammad
Abbas Bukhari, Dilara
Rehman, Abdul
author_facet Sher, Shahid
Tahir Ishaq, Muhammad
Abbas Bukhari, Dilara
Rehman, Abdul
author_sort Sher, Shahid
collection PubMed
description A multiple metal-resistant Brevibacterium sp. strain CS2, isolated from an industrial wastewater, resisted arsenate and arsenate upto 280 and 40 mM. The order of resistance against multiple metals was Arsenate > Arsenite > Selenium = Cobalt > Lead = Nickel > Cadmium = Chromium = Mercury. The bacterium was characterized as per morphological and biochemical characteristics at optimum conditions (37 ℃ and 7 pH). The appearance of brownish color precipitation was due to the interaction of silver nitrate confirming its oxidizing ability against arsenic. The strain showed arsenic processing ability at different temperatures, pH, and initial arsenic concentration which was 37% after 72 h and 48% after 96 h of incubation at optimum conditions with arsenite 250 mM/L (initial arsenic concentration). The maximum arsenic removal ability of strain CS2 was determined for 8 days, which was 32 and 46% in wastewater and distilled water, respectively. The heat-inactivated cells of the isolated strain showed a bioremediation efficiency (E) of 96% after 10 h. Genes cluster (9.6 kb) related to arsenite oxidation was found in Brevibacterium sp. strain CS2 after the genome analysis of isolated bacteria through illumine and nanopore sequencing technology. The arsenite oxidizing gene smaller subunit (aioB) on chromosomal DNA locus (Prokka_01508) was identified which plays a role in arsenite oxidation for energy metabolism. The presence of arsenic oxidizing genes and an efficient arsenic oxidizing potential of Brevibacterium sp. strain CS2 make it a potential candidate for green chemistry to eradicate arsenic from arsenic-contaminated wastewater.
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spelling pubmed-104806742023-09-07 Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater Sher, Shahid Tahir Ishaq, Muhammad Abbas Bukhari, Dilara Rehman, Abdul Saudi J Biol Sci Original Article A multiple metal-resistant Brevibacterium sp. strain CS2, isolated from an industrial wastewater, resisted arsenate and arsenate upto 280 and 40 mM. The order of resistance against multiple metals was Arsenate > Arsenite > Selenium = Cobalt > Lead = Nickel > Cadmium = Chromium = Mercury. The bacterium was characterized as per morphological and biochemical characteristics at optimum conditions (37 ℃ and 7 pH). The appearance of brownish color precipitation was due to the interaction of silver nitrate confirming its oxidizing ability against arsenic. The strain showed arsenic processing ability at different temperatures, pH, and initial arsenic concentration which was 37% after 72 h and 48% after 96 h of incubation at optimum conditions with arsenite 250 mM/L (initial arsenic concentration). The maximum arsenic removal ability of strain CS2 was determined for 8 days, which was 32 and 46% in wastewater and distilled water, respectively. The heat-inactivated cells of the isolated strain showed a bioremediation efficiency (E) of 96% after 10 h. Genes cluster (9.6 kb) related to arsenite oxidation was found in Brevibacterium sp. strain CS2 after the genome analysis of isolated bacteria through illumine and nanopore sequencing technology. The arsenite oxidizing gene smaller subunit (aioB) on chromosomal DNA locus (Prokka_01508) was identified which plays a role in arsenite oxidation for energy metabolism. The presence of arsenic oxidizing genes and an efficient arsenic oxidizing potential of Brevibacterium sp. strain CS2 make it a potential candidate for green chemistry to eradicate arsenic from arsenic-contaminated wastewater. Elsevier 2023-10 2023-08-18 /pmc/articles/PMC10480674/ /pubmed/37680980 http://dx.doi.org/10.1016/j.sjbs.2023.103781 Text en © 2023 The Author(s) https://creativecommons.org/licenses/by-nc-nd/4.0/This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Original Article
Sher, Shahid
Tahir Ishaq, Muhammad
Abbas Bukhari, Dilara
Rehman, Abdul
Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title_full Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title_fullStr Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title_full_unstemmed Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title_short Brevibacterium sp. strain CS2: A potential candidate for arsenic bioremediation from industrial wastewater
title_sort brevibacterium sp. strain cs2: a potential candidate for arsenic bioremediation from industrial wastewater
topic Original Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10480674/
https://www.ncbi.nlm.nih.gov/pubmed/37680980
http://dx.doi.org/10.1016/j.sjbs.2023.103781
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