Soil microbial community in lead smelting area and the role of sulfur-oxidizing bacteria

Chuan Wu; Hong-ren Chen; Yong-ping Lu; Yan-ting Qi; Hai-feng Li; Xing-hua Luo; Yue-ru Chen; Wei Lou; Wei-chun Yang; Wai-chin Li

doi:10.1007/s11771-024-5601-z

Journal of Central South University ›› 2024, Vol. 31 ›› Issue (4) : 1050 -1063. DOI: 10.1007/s11771-024-5601-z

Article

Soil microbial community in lead smelting area and the role of sulfur-oxidizing bacteria

Author information +

History +

PDF

Abstract

The long-term operation of the lead smelter has brought serious heavy metal pollution to the surrounding soil. The microbial community structure and composition of heavy metal contaminated soil is important for the risk assessment and pollution remediation. In this study, a lead smelter operating for more than 60 years was used to investigate the effects of heavy metal pollution on soil microbial community structure and composition in vertical profile. The results showed that the heavy metal content decreases gradually with increasing vertical depth of the soil. The diversity of soil microbial community with moderate pollution was higher than that with low pollution. Regardless of the pollution level, the diversity of soil microbial community was higher in the surface layer than in the bottom layer. The dominant relative abundance genera include Perlucidibaca, Limnobacter, Delftia, Hydrogenophaga, Thiobacillus, Sulfurifustis and Sphingopyxis, showing a higher abundance of sulfur-oxidizing bacteria (SOB). XRD results showed the presence of PbSO₄ in soil, may be due to the enrichment of SOB for the oxidation of sulfur. This sulfur cycle characteristic may be potential for the stabilization and remediation of lead (Pb) into PbSO₄.

Keywords

non-metal smelting / heavy metals / soil contamination / sulfur-oxidizing bacteria / microbial community

Cite this article

Download citation ▾

Chuan Wu, Hong-ren Chen, Yong-ping Lu, Yan-ting Qi, Hai-feng Li, Xing-hua Luo, Yue-ru Chen, Wei Lou, Wei-chun Yang, Wai-chin Li. Soil microbial community in lead smelting area and the role of sulfur-oxidizing bacteria. Journal of Central South University, 2024, 31(4): 1050-1063 DOI:10.1007/s11771-024-5601-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	LiuB, YaoJ, MaB, et al. . Microbial community profiles in soils adjacent to mining and smelting areas: Contrasting potentially toxic metals and co-occurrence patterns. Chemosphere, 2021, 282: 130992 J]

[2]	ShiW, ShaoH, LiH, et al. . Progress in the remediation of hazardous heavy metal-polluted soils by natural zeolite. Journal of Hazardous Materials, 2009, 170(1): 1-6 J]

[3]	WuanaR A, OkieimenF E. Heavy metals in contaminated soils: A review of sources, chemistry, risks and best available strategies for remediation. ISRN Ecology, 2011, 2011402647 J]

[4]	XueS, ShiL, WuC, et al. . Cadmium, lead, and arsenic contamination in paddy soils of a mining area and their exposure effects on human HEPG2 and keratinocyte cell-lines. Environmental Research, 2017, 15623-30 J]

[5]	QianZ, XueS, CuiM, et al. . Arsenic availability and transportation in soil-rice system affected by iron-modified biochar. Journal of Central South University, 2021, 28(6): 1901-1918 J]

[6]	CuiM, WuC, JiangX, et al. . Bibliometric analysis of research on soil arsenic during 2005–2016. Journal of Central South University, 2019, 26(2): 479-488 J]

[7]	ZengJ, LuoX, ChengY, et al. . Spatial distribution of toxic metal(loid)s at an abandoned zinc smelting site, Southern China. Journal of Hazardous Materials, 2022, 425: 127970 J]

[8]	KeW, ZengJ, ZhuF, et al. . Geochemical partitioning and spatial distribution of heavy metals in soils contaminated by lead smelting. Environmental Pollution, 2022, 307119486 J]

[9]	ZhaoX, SunY, HuangJ, et al. . Effects of soil heavy metal pollution on microbial activities and community diversity in different land use types in mining areas. Environmental Science and Pollution Research, 2020, 27(16): 20215-20226 J]

[10]	EilersK G, DebenportS, AndersonS, et al. . Digging deeper to find unique microbial communities: The strong effect of depth on the structure of bacterial and archaeal communities in soil. Soil Biology and Biochemistry, 2012, 5058-65 J]

[11]	Sagova-MareckovaM, ZadorovaT, PenizekV, et al. . The structure of bacterial communities along two vertical profiles of a deep colluvial soil. Soil Biology and Biochemistry, 2016, 101: 65-73 J]

[12]	LiS, ZhaoB, JinM, et al. . A comprehensive survey on the horizontal and vertical distribution of heavy metals and microorganisms in soils of a Pb/Zn smelter. Journal of Hazardous Materials, 2020, 400: 123255 J]

[13]	XueS, JiangX, WuC, et al. . Microbial driven iron reduction affects arsenic transformation and transportation in soil-rice system. Environmental Pollution, 2020, 260114010 J]

[14]	PanX, ZhangS, ZhongQ, et al. . Effects of soil chemical properties and fractions of Pb, Cd, and Zn on bacterial and fungal communities. The Science of the Total Environment, 2020, 715136904 J]

[15]	HuaZ, HanY, ChenL, et al. . Ecological roles of dominant and rare prokaryotes in acid mine drainage revealed by metagenomics and metatranscriptomics. The ISME Journal, 2015, 9(6): 1280-1294 J]

[16]	SunM, XiaoT, NingZ, et al. . Microbial community analysis in rice paddy soils irrigated by acid mine drainage contaminated water. Applied Microbiology and Biotechnology, 2015, 99(6): 2911-2922 J]

[17]	KellyD P, WoodA P. Reclassification of some species of Thiobacillus to the newly designated Genera Acidithiobacillus gen. nov., Halothiobacillus gen. nov. and Thermithiobacillus gen. nov. International Journal of Systematic and Evolutionary Microbiology, 2000, 50511-516 J]

[18]	FanM, LinY, HuoH, et al. . Microbial communities in riparian soils of a settling pond for mine drainage treatment. Water Research, 2016, 96: 198-207 J]

[19]	WatanabeT, MiuraA, ShinoharaA, et al. . Thermithiobacillus plumbiphilus sp. nov., a sulfur-oxidizing bacterium isolated from lead sulfide. International Journal of Systematic and Evolutionary Microbiology, 2016, 66(5): 1986-1989 J]

[20]	MohapatraB R, GouldW D, DinardoO, et al. . An overview of the biochemical and molecular aspects of microbial oxidation of inorganic sulfur compounds. CLEAN - Soil, Air, Water, 2008, 36(10–11): 823-829 J]

[21]	ImhoffJ F, ThielV. Phylogeny and taxonomy of chlorobiaceae. Photosynthesis Research, 2010, 104(2): 123-136 J]

[22]	HuangS, PengB, YangZ, et al. . Spatial distribution of chromium in soils contaminated by chromium-containing slag. Transactions of Nonferrous Metals Society of China, 2009, 19(3): 756-764 J]

[23]	LiF, FanZ, XiaoP, et al. . Contamination, chemical speciation and vertical distribution of heavy metals in soils of an old and large industrial zone in Northeast China. Environmental Geology, 2009, 57(8): 1815-1823 J]

[24]	SunY, ZhouQ, XieX, et al. . Spatial, sources and risk assessment of heavy metal contamination of urban soils in typical regions of Shenyang, China. Journal of Hazardous Materials, 2010, 174(1–3): 455-462 J]

[25]	KimC H, YooD C, KwonY M, et al. . A study on characteristics of atmospheric heavy metals in subway station. Toxicological Research, 2010, 26(2): 157-162 J]

[26]	WuQ, DuY, HuangZ, et al. . Vertical profile of soil/sediment pollution and microbial community change by e-waste recycling operation. The Science of the Total Environment, 2019, 669: 1001-1010 J]

[27]	TangJ, TangH, SimaW, et al. . Physicochemical properties and heavy metal pollution characteristics and correlation analysis of sludge landfill. International Journal of Environmental Analytical Chemistry, 2023, 103(17): 5815-5824 J]

[28]	GillerK E, WitterE, McGrathS P. Heavy metals and soil microbes. Soil Biology and Biochemistry, 2009, 41(10): 2031-2037 J]

[29]	KasemodelM C, SakamotoI K, VarescheM B A, et al. . Potentially toxic metal contamination and microbial community analysis in an abandoned Pb and Zn mining waste deposit. The Science of the Total Environment, 2019, 675: 367-379 J]

[30]	RehmanA, Sohail AnjumM. Cadmium uptake by yeast, candida tropicalis, isolated from industrial effluents and its potential use in wastewater clean-up operations. Water, Air, and Soil Pollution, 2010, 205(1): 149-159 J]

[31]	LiuB, SuG, YangY, et al. . Vertical distribution of microbial communities in chromium-contaminated soil and isolation of Cr(VI)-reducing strains. Ecotoxicology and Environmental Safety, 2019, 180: 242-251 J]

[32]	Piotrowska-SegetZ, CycońM, KozdrójJ. Metal-tolerant bacteria occurring in heavily polluted soil and mine spoil. Applied Soil Ecology, 2005, 28(3): 237-246 J]

[33]	FerisK, RamseyP, FrazarC, et al. . Differences in hyporheic-zone microbial community structure along a heavy-metal contamination gradient. Applied and Environmental Microbiology, 2003, 69(9): 5563-5573 J]

[34]	BouskillN J, Barker-FinkelJ, GallowayT S, et al. . Temporal bacterial diversity associated with metal-contaminated river sediments. Ecotoxicology, 2010, 19(2): 317-328 J]

[35]	YanC, WangF, GengH, et al. . Integrating high-throughput sequencing and metagenome analysis to reveal the characteristic and resistance mechanism of microbial community in metal contaminated sediments. The Science of the Total Environment, 2020, 707: 136116 J]

[36]	JiangC, DiaoX, WangH, et al. . Diverse and abundant antibiotic resistance genes in mangrove area and their relationship with bacterial communities—A study in Hainan Island, China. Environmental Pollution, 2021, 276116704 J]

[37]	LiB, BaoY, XuY, et al. . Vertical distribution of microbial communities in soils contaminated by chromium and perfluoroalkyl substances. The Science of the Total Environment, 2017, 599–600156-164 J]

[38]	TuovinenO H, KellyD P. Studies on the growth of Thiobacillus ferrooxidans. Archiv Für Mikrobiologie, 1973, 88(4): 285-298 J]

[39]	LiJ, SunW, SunX, et al. . Isolation, identification and functional verificaion of sulfur-oxidizing microoganisms in mine tailing. Ecology and Environmental Sciences, 2022, 31(4): 785-792[J]

[40]	ChenY, FengX, HeY, et al. . Genome analysis of a limnobacter sp. identified in an anaerobic methane-consuming cell consortium. Frontiers in Marine Science, 2016, 3257 J]

[41]	González-RosalesC, VergaraE, DopsonM, et al. . Integrative genomics sheds light on evolutionary forces shaping the acidithiobacillia class acidophilic lifestyle. Frontiers in Microbiology, 2022, 12822229 J]

[42]	IssottaF, Moya-BeltránA, MenaC, et al. . Insights into the biology of acidophilic members of the Acidiferrobacteraceae family derived from comparative genomic analyses. Research in Microbiology, 2018, 169(10): 608-617 J]

[43]	ZhaoZ, SunC, LiY, et al. . Driving microbial sulfur cycle for phenol degradation coupled with Cr(VI) reduction via Fe(III)/Fe(II) transformation. Chemical Engineering Journal, 2020, 393124801 J]

[44]	Da SilvaG. Kinetics and mechanism of the bacterial and ferric sulphate oxidation of galena. Hydrometallurgy, 2004, 75(1–4): 99-110 J]

[45]

ZhaoY, DuanF, CuiZ, et al. . Insights into the vertical distribution of the microbiota in steel plant soils with potentially toxic elements and PAHs contamination after 60 years operation: Abundance, structure, co-occurrence network and functionality. The Science of the Total Environment, 2021, 786147338 J]

[46]	LiuJ, YaoJ, ZhuX, et al. . Metagenomic exploration of multi-resistance genes linked to microbial attributes in active nonferrous metal(loid) tailings. Environmental Pollution, 2020, 273115667 J]

[47]	KeC, ZhaoC, RensingC, et al. . Characterization of recombinant E. coli expressing arsR from Rhodopseudomonas palustris CGA009 that displays highly selective arsenic adsorption. Applied Microbiology and Biotechnology, 2018, 102(14): 6247-6255 J]

[48]	WangK, ChenX, YanD, et al. . Petrochemical and municipal wastewater treatment plants activated sludge each own distinct core bacteria driven by their specific incoming wastewater. The Science of the Total Environment, 2022, 826153962 J]

[49]	GuoX, ZhongH, LiP, et al. . Microbial communities responded to tetracyclines and Cu(II) in constructed wetlands microcosms with Myriophyllum aquaticum. Ecotoxicology and Environmental Safety, 2020, 205111362 J]

[50]	GeY, WenZ, HeL, et al. . Metal-immobilizing Pseudomonas taiwanensis WRS8 reduces heavy metal accumulation in Coriandrum sativum by changing the metal immobilization-related bacterial population abundances. Environmental Science and Pollution Research, 2023, 30(31): 76911-76922 J]

[51]	LuoY, ZhangW, LiY, et al. . Sanitary landfill improved CNPS microbial functional gene abundance compared to non-sanitary landfill. Journal of Soils and Sediments, 2020, 20(1): 99-108 J]

[52]	HeH, MiaoY, GanY, et al. . Soil bacterial community response to long-term land use conversion in Yellow River Delta. Applied Soil Ecology, 2020, 156103709 J]

[53]	LiC, QuanQ, GanY, et al. . Effects of heavy metals on microbial communities in sediments and establishment of bioindicators based on microbial taxa and function for environmental monitoring and management. The Science of the Total Environment, 2020, 749141555 J]