|
|
|
|
|
|
| Spectral Analysis of Extracellular Polymers During Iron Dissimilar
Reduction by Salt-Tolerant Shewanella Aquimarina |
| ZHOU Ao1, 2, YUE Zheng-bo1, 2, LIU A-zuan1, 2, GAO Yi-jun3, WANG Shao-ping3, CHUAI Xin3, DENG Rui1, WANG Jin1, 2* |
1. School of Resources and Environmental Engineering, Hefei University of Technology, Hefei 230009, China
2. Key Laboratory of Nanominerals and Pollution Control of Anhui Higher Education Institutes, Hefei University of Technology, Hefei 230009, China
3. Nanshan Mining Company Ltd., Anhui Maanshan Iron and Steel Mining Resources Group, Ma’anshan 243000, China
|
|
|
|
|
Abstract The growth and metabolism of microorganisms are often affected by salinity, so screening the salt-tolerant strains is of great significance for the biological treatment of saline wastewater. In this paper, Shewanella aquimarina XMS-1, a marine strain with salt tolerant metal reduction function (DMRB), was selected as the research object to explore the effects of salinity on the reduction process of Fe3+ and the changes of extracellular polymers. The Fe3+ reduction ability of XMS-1 and the extracellular polymer (EPS) content under different salinity were investigated. Furthermore, Three dimensional fluorescence excitation-emission (3D-EEM), Raman spectra (Raman), Fourier transform infrared spectroscopy (FTIR), and Two-dimensional correlation spectroscopy (2D-COS) were used to analyze the changes in extracellular polymers during the reduction of Fe3+ by XMS-1. The results show that protein is the main substance in XMS-1 EPS, accounting for more than 80% of EPS content, and polysaccharide content is relatively small. 3% salinity conditions promote EPS production. XMS-1 will secrete more EPS in the high salt environment to protect cells from normal physiological activities. The reduction process of Fe3+ is accelerated at the salinity of 1%~4%, but is inhibited when the salinity is higher than 5%. Too high salinity would inhibit the growth of XMS-1, resulting in the decrease of the Fe3+ reduction rate. The reduction rate of Fe3+ was increased by 2.18 times and reached 44.1% at the salinity of 3%. FTIR and Raman spectra showed that XMS-1 EPS contained metal ion redox functional groups such as carboxyl, hydroxyl, amino and carbonyl. The peaks of protein amides and polysaccharides in EPS were enhanced at 3% salinity, and the representative peaks of protein amides changed significantly. The O- and N- groups were effective redox groups in Fe3+ reduction. In addition, the Three-dimensional fluorescence results showed that after the Fe3+ reduction process, the intensities of the two fluorescent components of tryptophan and tyrosine in EPS decreased. Combined with the analysis of 2D-COS spectral results, it was found that tryptophan-like proteins changed significantly during the reduction of Fe3+, indicating that the two fluorescent components were involved in the reduction process of Fe3+, and tryptophan-like proteins played a stronger role in the reduction process. This study enriched the understanding of the extracellular electron transfer process of EPS in halophilic bacteria, and highlighted the significance of EPS in iron redox transformation in natural environment.
|
|
Received: 2022-02-11
Accepted: 2022-07-05
|
|
|
|
Corresponding Authors:
WANG Jin
E-mail: sophiawj@hfut.edu.cn
|
|
[1] Ji B, Zhang H, Zhou L, et al. Bioresource Technology, 2021, 337: 125363.
[2] Zhang Z B, Cheng Z H, Wu J H, et al. Science of the Total Environment, 2022, 807: 151009.
[3] Graaff D, Loosdrecht M, Pronk M. Water Research, 2020, 172: 115531.
[4] Hu Y Q, Wei W, Gao M, et al. Process Safety and Environmental Protection, 2019, 123: 344.
[5] Fatima T, Arora N K. Microbiological Research, 2021, 244: 126671.
[6] WANG Zi-chao, GAO Meng-chun, WEI Jun-feng, et al(王子超, 高孟春, 魏俊峰, 等). Acta Scientiae Circumstantiae(环境科学学报), 2016, 36(9): 3273.
[7] Chen L, Hu Q, Zhang X, et al. Journal of Environmental Management, 2019, 238: 263.
[8] He Q, Xie Z, Fu Z, et al. Science of the Total Environment, 2021, 752: 141785.
[9] Shi L, Dong H, Reguera G, et al. Nature Reviews Microbiology, 2016, 14(10): 651.
[10] Yan W, Guo W, Wang L, et al. Science of the Total Environment, 2021, 784: 147245.
[11] Gao L, Lu X, Liu H, et al. Frontiers in Microbiology, 2019, 10: 575.
[12] Phélippé M, Gonçalves O, Thouand G, et al. Algal Research, 2019, 38: 101426.
[13] Siddharth T, Sridhar P, Vinila V, et al. Journal of Environmental Management, 2021, 287: 112307.
[14] Azemtsop Matanfack G, Taubert M, Guo S, et al. Analytical Chemistry, 2021, 93(21): 7714.
[15] Huang X, Bai J, Li K R, et al. Marine Pollution Bulletin, 2017, 114(1): 192.
[16] Nguyen P T, Nguyen T T, Vo T N, et al. Scientific Reports, 2021, 11(1): 1301.
[17] VoH N P, Ngo H H, Guo W, et al. Bioresource Technology, 2020, 303: 122877.
[18] Jacquin C, Lesage G, Traber J, et al. Water Research, 2017, 118: 82.
[19] Zhang D, Lee D J, Pan X. Journal of the Taiwan Institute of Chemical Engineers, 2012, 43(3): 450.
[20] Yee E F, Dzikovski B, Crane B R T. Journal of the American Chemical Society, 2019, 141(44): 17571.
[21] Gray H B, Winkler J R. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112(35): 10920.
[22] LÜ Jing-jing, GONG Wei-jin, DOU Yan-yan, et al(吕晶晶, 龚为进, 窦艳艳, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2020, 40(5): 1541.
[23] Hou X, Liu S, Zhang Z. Water Research, 2015, 75: 51.
[24] Kim N K, Mao N, Lin R, et al. Water Research, 2019, 170: 115344.
[25] Yan L, Liu Y, Wen Y, et al. Bioresource Technology, 2015, 179: 460.
[26] Huayhongthong S, Khuntayaporn P, Thirapanmethee K, et al. LWT-Food Science and Technology, 2019, 114: 108419.
[27] Kuhar N, Sil S, Umapathy S. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2021, 258: 119712.
[28] Kengne-Momo R P, Daniel P, Lagarde F, et al. International Journal of Spectroscopy, 2012, 2012: 1.
|
| [1] |
LI Jie, ZHOU Qu*, JIA Lu-fen, CUI Xiao-sen. Comparative Study on Detection Methods of Furfural in Transformer Oil Based on IR and Raman Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 125-133. |
| [2] |
WANG Fang-yuan1, 2, HAN Sen1, 2, YE Song1, 2, YIN Shan1, 2, LI Shu1, 2, WANG Xin-qiang1, 2*. A DFT Method to Study the Structure and Raman Spectra of Lignin
Monomer and Dimer[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 76-81. |
| [3] |
XING Hai-bo1, ZHENG Bo-wen1, LI Xin-yue1, HUANG Bo-tao2, XIANG Xiao2, HU Xiao-jun1*. Colorimetric and SERS Dual-Channel Sensing Detection of Pyrene in
Water[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 95-102. |
| [4] |
WANG Xin-qiang1, 3, CHU Pei-zhu1, 3, XIONG Wei2, 4, YE Song1, 3, GAN Yong-ying1, 3, ZHANG Wen-tao1, 3, LI Shu1, 3, WANG Fang-yuan1, 3*. Study on Monomer Simulation of Cellulose Raman Spectrum[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 164-168. |
| [5] |
GUO Ya-fei1, CAO Qiang1, YE Lei-lei1, ZHANG Cheng-yuan1, KOU Ren-bo1, WANG Jun-mei1, GUO Mei1, 2*. Double Index Sequence Analysis of FTIR and Anti-Inflammatory Spectrum Effect Relationship of Rheum Tanguticum[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 188-196. |
| [6] |
WANG Lan-hua1, 2, CHEN Yi-lin1*, FU Xue-hai1, JIAN Kuo3, YANG Tian-yu1, 2, ZHANG Bo1, 4, HONG Yong1, WANG Wen-feng1. Comparative Study on Maceral Composition and Raman Spectroscopy of Jet From Fushun City, Liaoning Province and Jimsar County, Xinjiang Province[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 292-300. |
| [7] |
LI Wei1, TAN Feng2*, ZHANG Wei1, GAO Lu-si3, LI Jin-shan4. Application of Improved Random Frog Algorithm in Fast Identification of Soybean Varieties[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3763-3769. |
| [8] |
WANG Zhi-qiang1, CHENG Yan-xin1, ZHANG Rui-ting1, MA Lin1, GAO Peng1, LIN Ke1, 2*. Rapid Detection and Analysis of Chinese Liquor Quality by Raman
Spectroscopy Combined With Fluorescence Background[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3770-3774. |
| [9] |
YANG Ke-li1, 2, PENG Jiao-yu1, 2, DONG Ya-ping1, 2*, LIU Xin1, 2, LI Wu1, 3, LIU Hai-ning1, 3. Spectroscopic Characterization of Dissolved Organic Matter Isolated From Solar Pond[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3775-3780. |
| [10] |
LIU Hao-dong1, 2, JIANG Xi-quan1, 2, NIU Hao1, 2, LIU Yu-bo1, LI Hui2, LIU Yuan2, Wei Zhang2, LI Lu-yan1, CHEN Ting1,ZHAO Yan-jie1*,NI Jia-sheng2*. Quantitative Analysis of Ethanol Based on Laser Raman Spectroscopy Normalization Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3820-3825. |
| [11] |
LU Wen-jing, FANG Ya-ping, LIN Tai-feng, WANG Hui-qin, ZHENG Da-wei, ZHANG Ping*. Rapid Identification of the Raman Phenotypes of Breast Cancer Cell
Derived Exosomes and the Relationship With Maternal Cells[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3840-3846. |
| [12] |
LI Qi-chen1, 2, LI Min-zan1, 2*, YANG Wei2, 3, SUN Hong2, 3, ZHANG Yao1, 3. Quantitative Analysis of Water-Soluble Phosphorous Based on Raman
Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3871-3876. |
| [13] |
GUO He-yuanxi1, LI Li-jun1*, FENG Jun1, 2*, LIN Xin1, LI Rui1. A SERS-Aptsensor for Detection of Chloramphenicol Based on DNA Hybridization Indicator and Silver Nanorod Array Chip[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3445-3451. |
| [14] |
ZHU Hua-dong1, 2, 3, ZHANG Si-qi1, 2, 3, TANG Chun-jie1, 2, 3. Research and Application of On-Line Analysis of CO2 and H2S in Natural Gas Feed Gas by Laser Raman Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3551-3558. |
| [15] |
LIU Jia-ru1, SHEN Gui-yun2, HE Jian-bin2, GUO Hong1*. Research on Materials and Technology of Pingyuan Princess Tomb of Liao Dynasty[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3469-3474. |
|
|
|
|
