Zinc immobilization and magnetite formation via ferric oxide reduction by Shewanella putrefaciens 200

被引:107
作者
Cooper, DC [1 ]
Picardal, F [1 ]
Rivera, J [1 ]
Talbot, C [1 ]
机构
[1] Indiana Univ, Sch Publ & Environm Affairs, Bloomington, IN 47405 USA
来源
ENVIRONMENTAL SCIENCE & TECHNOLOGY | 2000年 / 34卷 / 01期
关键词
D O I
10.1021/es990510x
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
Long-term batch experiments in an artificial groundwater medium indicated that microbial reduction of synthetic, high-surface-area goethite and lepidocrocite by Shewanella putrefaciens 200 can act to immobilize surface-associated zinc into a new mineral phase that is not soluble in 0.5 M HCl. While Zn was incorporated in siderite grains in experiments with goethite, additional Zn immobilization may result from incorporation into as yet unidentified biogenic minerals or into a more crystalline goethite. Experiments with an oxide mixture primarily composed of lepidocrocite resulted in the production of magnetite, biphasic immobilization of Zn, and an enhanced overall degree of Zn immobilization. When NO3- was present as an alternate electron acceptor, microbial production of Fe(II) was inhibited, and the degree of Zn immobilization was subsequently reduced. These data indicate that (i) biologically induced mineralization can play a key role in the cycling of trace elements in natural systems, (ii) the nature of the oxide surface plays an important role in biologically induced mineralization, and (iii) conditions associated with Fe(II) production are necessary for these processes to immobilize surface-bound Zn within these new mineral phases.
引用
收藏
页码:100 / 106
页数:7
相关论文
共 53 条
[1]   COMPETITION FOR ELECTRON-DONORS AMONG NITRATE REDUCERS, FERRIC IRON REDUCERS, SULFATE REDUCERS, AND METHANOGENS IN ANOXIC PADDY SOIL [J].
ACHTNICH, C ;
BAK, F ;
CONRAD, R .
BIOLOGY AND FERTILITY OF SOILS, 1995, 19 (01) :65-72
[2]   BIOGEOCHEMICAL CONDITIONS FAVORING MAGNETITE FORMATION DURING ANAEROBIC IRON REDUCTION [J].
BELL, PE ;
MILLS, AL ;
HERMAN, JS .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1987, 53 (11) :2610-2616
[3]   MAJOR SITES OF METAL-BINDING IN BACILLUS-LICHENIFORMIS WALLS [J].
BEVERIDGE, TJ ;
FORSBERG, CW ;
DOYLE, RJ .
JOURNAL OF BACTERIOLOGY, 1982, 150 (03) :1438-1448
[4]   BINDING OF METALS TO CELL ENVELOPES OF ESCHERICHIA-COLI-K-12 [J].
BEVERIDGE, TJ ;
KOVAL, SF .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1981, 42 (02) :325-335
[5]   UPTAKE AND RETENTION OF METALS BY CELL-WALLS OF BACILLUS-SUBTILIS [J].
BEVERIDGE, TJ ;
MURRAY, RGE .
JOURNAL OF BACTERIOLOGY, 1976, 127 (03) :1502-1518
[6]   METAL FIXATION BY BACTERIAL-CELL WALLS [J].
BEVERIDGE, TJ ;
FYFE, WS .
CANADIAN JOURNAL OF EARTH SCIENCES, 1985, 22 (12) :1893-1898
[7]   DIAGENESIS OF METALS CHEMICALLY COMPLEXED TO BACTERIA - LABORATORY FORMATION OF METAL PHOSPHATES, SULFIDES, AND ORGANIC CONDENSATES IN ARTIFICIAL SEDIMENTS [J].
BEVERIDGE, TJ ;
MELOCHE, JD ;
FYFE, WS ;
MURRAY, RGE .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1983, 45 (03) :1094-1108
[8]   Arsenic mobilization by the dissimilatory Fe(III)-reducing bacterium Shewanella alga BrY [J].
Cummings, DE ;
Caccavo, F ;
Fendorf, S ;
Rosenzweig, RF .
ENVIRONMENTAL SCIENCE & TECHNOLOGY, 1999, 33 (05) :723-729
[9]   EFFECTS OF NITRATE AND NITRITE ON DISSIMILATORY IRON REDUCTION BY SHEWANELLA-PUTREFACIENS-200 [J].
DICHRISTINA, TJ .
JOURNAL OF BACTERIOLOGY, 1992, 174 (06) :1891-1896
[10]   CHEMICAL BASIS FOR SELECTIVITY OF METAL-IONS BY THE BACILLUS-SUBTILIS CELL-WALL [J].
DOYLE, RJ ;
MATTHEWS, TH ;
STREIPS, UN .
JOURNAL OF BACTERIOLOGY, 1980, 143 (01) :471-480
123456