Induced Mutagenesis and Comparative Genomics of <i>Raoultella</i> sp. 64 for Enhanced Antimony Resistance and Biosorption

Induced Mutagenesis and Comparative Genomics of <i>Raoultella</i> sp. 64 for Enhanced Antimony Resistance and Biosorption

Antimony-resistant bacteria are potential natural resources for the bioremediation of mining soil pollution. A <i>Raoultella</i> sp. 64 strain was isolated from antimony-contaminated soil. To enhance its Sb resistance abilities, this strain was transported into space aboard the Shenzhou...

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Bibliographic Details
Main Authors: Tianhua Huang, Shiran Cao, Xiaohan Li, Chuhan Wang, Xiawei Peng
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Microorganisms
Subjects:
<i>Raoultella ornithinolytica</i>
space breeding
Sb(III)-Oxidizing bacteria
antimony adsorption
differential functional genes
Online Access:https://www.mdpi.com/2076-2607/13/4/880
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Summary:Antimony-resistant bacteria are potential natural resources for the bioremediation of mining soil pollution. A <i>Raoultella</i> sp. 64 strain was isolated from antimony-contaminated soil. To enhance its Sb resistance abilities, this strain was transported into space aboard the Shenzhou spacecraft for space breeding, resulting in a mutant strain, <i>Raoultella</i> sp. D9. The whole genomes of <i>Raoultella</i> sp. 64 and mutant strain <i>Raoultella</i> sp. D9 were sequenced, revealing the genomic information for the bacterium. Comparative genomic analysis was then carried out to identify differential functional genes. The adsorption conditions for Sb(III) were optimized and refined. Further, Fourier transform infrared spectroscopy (FTIR) was used to determine the adsorption of antimony. Results show that strain D9 exhibits a higher tolerance to Sb(III), and Sb resistance genes were identified in both <i>Raoultella</i> sp. 64 and D9. Analysis of the differential functional genes indicated that the increased copy number of <i>pls</i>X may lead to a higher lipid content in the cell membrane, thereby enhancing the cell’s resistance to heavy metals. Mutant strain D9 exhibited better biosorption capacity compared to strain 64. FTIR studies showed that key functional groups, including -OH, C-N, C-H, and C-O, are likely to have participated in Sb(III) biosorption. Further study of the differential functional genes could provide a basis for future research and the subsequent development of technologies for the remediation of Sb-contaminated sites.
ISSN:2076-2607

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