Isolation of an acid producing Bacillus sp. EEEL02: Potential for bauxite residue neutralization

Hao Wu; Jia-xin Liao; Feng Zhu; Graeme Millar; Ronan Courtney; Sheng-guo Xue

doi:10.1007/s11771-019-4006-x

Journal of Central South University ›› 2019, Vol. 26 ›› Issue (2) : 343 -352. DOI: 10.1007/s11771-019-4006-x

Article

Isolation of an acid producing Bacillus sp. EEEL02: Potential for bauxite residue neutralization

Author information +

History +

PDF

Abstract

Bauxite residue deposit area (BRDA) is a typical abandoned mining wasteland representing extreme hostile environment with increased alkalinity. Microbially-driven neutralization of bauxite residue, based on the microbial acid producing metabolisms, is a novel strategy for achieving rapid pH neutralization and thus improving its environmental outcomes. The hypothesis was that these extreme conditions promote microbial communities which are capable of novel ecologically relevant functions. Several alkaliphilic acid producing bacteria were isolated in this study. One strain was selected for its superior growth pattern and acid metabolism (termed EEEL02). Based on the phylogenetic analysis, this strain was identified as Bacillus thuringiensis. The optimized fermentation conditions were as follows: pH 10; NaCl concentration 5%; temperature 25 °C; EEEL02 preferred glucose and peptone as carbon and nitrogen sources, respectively. Based on optimal fermentation conditions, EEEL02 induced a significant pH reduction from 10.26 to 5.62 in 5-day incubation test. Acetic acid, propionic acid and CO₂ (g) were the major acid metabolites of fermentation, suggesting that the pH reduction in bauxite residue may be caused by acid neutralization derived from microbial metabolism. This finding provided the basis of a novel strategy for achieving rapid pH neutralization of bauxite residue.

Keywords

bauxite residue / 16S rDNA / Bacillus thuringiensis / acid production / pH neutralization

Cite this article

Download citation ▾

Hao Wu, Jia-xin Liao, Feng Zhu, Graeme Millar, Ronan Courtney, Sheng-guo Xue. Isolation of an acid producing Bacillus sp. EEEL02: Potential for bauxite residue neutralization. Journal of Central South University, 2019, 26(2): 343-352 DOI:10.1007/s11771-019-4006-x

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]	XueS, KongX, ZhuF, HartleyW, LiX, LiYi. Proposal for management and alkalinity transformation of bauxite residue in China [J]. Environmental Science and Pollution Research, 2016, 23(13): 12822-12834

[2]	XueS, WuY, LiY, KongX, ZhuF, HartleyW, LiX, YeYu. Industrial wastes applications for alkalinity regulation in bauxite residue: A comprehensive review [J]. Journal of Central South University, 2019, 26(2): 268-288

[3]	ZhuF, XueS, HartleyW, HuangL, WuC, LiXiao. Novel predictors of soil genesis following natural weathering processes of bauxite residues [J]. Environmental Science and Pollution Research, 2016, 23(3): 2856-2863

[4]	KongX, GuoY, XueS, HartleyW, WuC, YeY, ChengQing. Natural evolution of alkaline characteristics in bauxite residue [J]. Journal of Cleaner Production, 2017, 143: 224-230

[5]	KongX, JiangX, XueS, HuangL, HartleyWILLIAM, WuC, LiXiao. Migration and distribution of saline ions in bauxite residue during water leaching [J]. Transactions of Nonferrous Metals Society of China, 2018, 28(3): 534-541

[6]	ZhuF, ZhouJ, XueS, HartleyW, WuC, GuoYing. Aging of bauxite residue in association of regeneration: A comparison of methods to determine aggregate stability & erosion resistance [J]. Ecological Engineering, 2016, 92(3): 47-54

[7]	XueS, ZhuF, KongX, WuC, HuangL, HuangN, HartleyW. A review of the characterization and revegetation of bauxite residues (Red mud) [J]. Environmental Science and Pollution Research, 2016, 23(2): 1120-1132

[8]	GrafeM, PowerG, KlauberC. Bauxite residue issues: III. Alkalinity and associated chemistry [J]. Hydrometallurgy, 2011, 108(12): 60-79

[9]	LiY, JiangJ, XueS, MillarG, KongX, LiX, LiM, LiChu. Effect of ammonium chloride on leaching behavior of alkaline anion and sodium ion in bauxite residue [J]. Transactions of Nonferrous Metals Society of China, 2018, 28: 2125-2134

[10]	XueS, LiM, JiangJ, GraemeJ M, LiC, KongXiang. Phosphogypsum stabilization of bauxite residue: Conversion of its alkaline characteristics [J]. Journal of Environmental Sciences, 2019, 77: 1-10

[11]	LiX, YeY, XueS, JiangJ, WuC, KongX, HartleyW, LiYi. Leaching optimization and dissolution behavior of alkaline anions in bauxite residue [J]. Transactions of Nonferrous Metals Society of China, 2018, 28: 1248-1255

[12]	ZhuF, HouJ, XueS, WuC, WangQ, HartleyW. Vermicompost and gypsum amendments improve aggregate formation in bauxite residue [J]. Land Degradation and Development, 2017, 28(7): 2109-2120

[13]	WongJ. Use of waste gypsum in the revegetation on red mud deposits: A greenhouse study [J]. Waste Management & Research, 1993, 11(3): 249-256

[14]	JonesB E H, HaynesR J, PhillipsI R. Influence of amendments on acidification and leaching of Na from bauxite processing sand [J]. Ecological Engineering, 2015, 84: 435-442

[15]	KongX, LiM, XueS, HartleyW, ChenC, WuC, LiX, LiYi. Acid transformation of bauxite residue: Conversion of its alkaline characteristics [J]. Journal of Hazardous Materials, 2017

[16]	SantiniT C, KerrJ L, WarrenL A. Microbiallydriven strategies for bioremediation of bauxite residue [J]. Journal of Hazardous Materials, 2015, 293: 131-157

[17]	HamdyM K, WilliamsF S. Bacterial amelioration of bauxite residue waste of industrial alumina plants [J]. Journal of Industrial Microbiology & Biotechnology, 2001, 27(4): 228-233

[18]	SchmalenbergerA, O'sullivanO, GahanJ, CotterP D, CourtneyR. Bacterial communities established in bauxite residues with different restoration histories [J]. Environmental Science & Technology, 2013, 47(13): 7110-7119

[19]	KrishnaP, ReddyM S, PatnaikS K. Aspergillus tubingensis reduces the pH of the bauxite residue (Red mud) amended soils [J]. Water, Air, & Soil Pollution, 2005, 167(1–4): 201-209

[20]	BabuA G, ReddyM S. Aspergillus tubingensis improves the growth and native mycorrhizal colonization of bermudagrass in bauxite residue [J]. Bioremediation Journal, 2011, 15(3): 157-164

[21]	GhommidhC, NavarroJ M, DurandG. Acetic acid production by immobilized acetobacter cells [J]. Biotechnology Letters, 1981, 3(2): 93-98

[22]	RojanP J, NampoothiriK M, NairA S, PandeyA. L (+)-lactic acid production using Lactobacillus casei in solid-state fermentation [J]. Biotechnology Letters, 2005, 27(21): 1685-1688

[23]	SarethyI P, SaxenaY, KapoorA, SharmaM, SharmaS K, GuptaV, GuptaS. Alkaliphilic bacteria: Applications in industrial biotechnology [J]. Journal of Industrial Microbiology & Biotechnology, 2011, 38(7): 769-790

[24]	CalabiaB P, TokiwaY, AibaS. Fermentative production of L:-(+)-lactic acid by an alkaliphilic marine microorganism [J]. Biotechnology Letters, 2011, 33(7): 1429-1433

[25]	ZhilinaT N, KevbrinV V, TurovaT P, LysenkoA M, KostrikinaN A, ZavarzinG A. Clostridium alkalicellum sp. nov., an obligately alkaliphilic cellulolytic bacterium from a soda lake in the Baikal region [J]. Microbiology, 2005, 74(5): 642-653

[26]	WuC, ZhuangL, ZhouS, LiF, HeJian. Corynebacterium humireducens sp. nov., an alkaliphilic, humic acid-reducing bacterium isolated from a microbial fuel cell [J]. International Journal of Systematic and Evolutionary Microbiology, 2011

[27]	NogueiraE W, HayashE A, AlvesE, LimaC A D, AdornoM T, BruchaG. Characterization of alkaliphilic bacteria isolated from bauxite residue in the southern region of minas gerais, Brazil [J]. Brazilian Archives of Biology and Technology, 2017

[28]	PappaA, Sánchez-PorroC, LazouraP, KallimanisA, PerisynakisA, VentosaA, DrainasC, KoukkouA I. Bacillus halochares sp. nov., a halophilic bacterium isolated from a solar saltern [J]. International Journal of Systematic and Evolutionary Microbiology, 2010, 60(6): 1432-1436

[29]	AroraA, KrishnaP, MalikV, ReddyM S. Alkalistable xylanase production by alkalitolerant Paenibacillus montaniterrae RMV1 isolated from red mud [J]. Journal of Basic Microbiology, 2014, 54(10): 1023-1029

[30]	KrishnaP, AroraA, ReddyM S. An alkaliphilic and xylanolytic strain of Actinomycetes Kocuria sp RM1 isolated from extremely alkaline bauxite residue sites [J]. World Journal of Microbiology & Biotechnology, 2008, 24(12): 3079-3085

[31]	SanahujaG, BanakarR, TwymanR M, CapellT, ChristouP. Bacillus thuringiensis: A century of research, development and commercial applications [J]. Plant Biotechnology Journal, 2011, 9(3): 283-300

[32]	SansineneaEBacillus thuringiensis biotechnology [M], 2012

[33]	MengY, XueY, YuB, GaoC, MaYan. Efficient production of L-lactic acid with high optical purity by alkaliphilic Bacillus sp. WL-S20 [J]. Bioresource Technology, 2012, 116(4): 334-339

[34]	LiaoJ, JiangJ, XueS, ChengQ, WuH, RajendranM, HartleyW, HuangLong. A novel acid-producing fungus isolated from bauxite residue: The potential to reduce the alkalinity [J]. Geomicrobiology Journal, 2018, 35(10): 840-847

[35]	KongX, TianT, XueS, HartleyW, HuangL, WuC, LiChu. Development of alkaline electrochemical characteristics demonstrates soil formation in bauxite residue undergoing natural rehabilitation [J]. Land Degradation & Development, 2018, 29(1): 58-67

[36]	KansoS, GreeneA C, PatelB K. Bacillus subterraneus sp. nov., an iron-and manganese-reducing bacterium from a deep subsurface Australian thermal aquifer [J]. International Journal of Systematic and Evolutionary Microbiology, 2002

[37]	TakamiH, TakakiY, UchiyamaI. Genome sequence of Oceanobacillus iheyensis isolated from the Iheya Ridge and its unexpected adaptive capabilities to extreme environments [J]. Nucleic Acids Research, 2002, 30(18): 3927-3935

[38]

IshikawaM, NakajimaK, ItamiyaY, FurukawaS, YamamotoY, YamasatoK. Halolactibacillus halophilus gen. nov., sp. nov. and Halolactibacillus miurensis sp. nov., halophilic and alkaliphilic marine lactic acid bacteria constituting a phylogenetic lineage in Bacillus rRNA group 1 [J]. International Journal of Systematic and Evolutionary Microbiology, 2005

[39]	SarkarP K, HasenackB, NoutM J. Diversity and functionality of Bacillus and related genera isolated from spontaneously fermented soybeans (Indian Kinema) and locust beans (African Soumbala) [J]. International Journal of Food Microbiology, 2002, 77(3): 175-186

[40]	KulshreshthaN M, KumarA, BishtG, PashaS, KumarR. Usefulness of organic acid produced by Exiguobacterium sp. 12/1 on neutralization of alkaline wastewater [J]. The Scientific World Journal, 2012, 2012(4): 345101

[41]	SantiniT C, MalcolmL I, TysonG W, WarrenL A. pH and organic carbon dose rates control microbially driven bioremediation efficacy in alkaline bauxite residue [J]. Environmental Science & Technology, 2016, 502011164-11173