Low-temperature (9°C) AMD treatment in a sulfidogenic bioreactor dominated by a mesophilic Desulfomicrobium species

Biotechnology and Bioengineering

Volumn 104, Issue 4, 2009, Pages 740-751

  Auvinen, Hannele ^a   Nevatalo, Laura M ^a   Kaksonen, Anna H ^a   Puhakka, Jaakko A ^a  

^a TAMPERE UNIVERSITY OF TECHNOLOGY   (Finland)

Author keywords

AMD treatment; Desulfomicrobium sp.; Low temperature sulfate reduction; Microbial community analysis; Sulfate reducing bioreactor

Indexed keywords

AMD TREATMENT; DESULFOMICROBIUM SP.; LOW-TEMPERATURE SULFATE REDUCTION; MICROBIAL COMMUNITY ANALYSIS; SULFATE REDUCING BIOREACTOR;

BACTERIOLOGY; BIOCONVERSION; BIOLEACHING; BIOLOGICAL WATER TREATMENT; BIOREACTORS; CHEMICALS REMOVAL (WATER TREATMENT); FLUIDIZATION; MINING; NUCLEIC ACIDS; RNA; SEWAGE; SPECTRUM ANALYZERS; WASTEWATER;

WASTEWATER TREATMENT;

CARBON; DNA; FORMIC ACID; IRON; RNA; RNA 16S; SULFATE;

ARTICLE; BIOLEACHING; BIOREACTOR; CARBON SOURCE; DESULFOMICROBIUM; DILUTED BARREN BIOLEACHING SOLUTION; DNA EXTRACTION; ELECTRON; FLUIDIZED BED REACTOR; LOW TEMPERATURE; MESOPHILIC BACTERIUM; MICROBIAL COMMUNITY; NONHUMAN; NUTRIENT; POLYMERASE CHAIN REACTION; RNA EXTRACTION; SULFIDOGENIC BIOREACTOR; WASTE WATER MANAGEMENT;

BIOREACTORS; COLD TEMPERATURE; DELTAPROTEOBACTERIA; DNA FINGERPRINTING; DNA PRIMERS; DNA, BACTERIAL; ELECTROPHORESIS, POLYACRYLAMIDE GEL; FORMIC ACIDS; INDUSTRIAL WASTE; NUCLEIC ACID DENATURATION; OXIDATION-REDUCTION; RNA, BACTERIAL; RNA, RIBOSOMAL, 16S; SULFATES; WATER PURIFICATION;

BACTERIA (MICROORGANISMS); DESULFOMICROBIUM; DESULFOMICROBIUM SP.;

EID: 70350492895     PISSN: 00063592     EISSN: 10970290     Source Type: Journal    
DOI: 10.1002/bit.22434     Document Type: Article

References (40)

1. Bijmans MFM. 2008. Sulfate reduction under acidic conditions for selective metal recovery. PhD Thesis, Wageningen University, Wageningen, (ISBN 978-90-8504-925-8), 156p.
2. Bijmans MFM, Peeters TWT, Lens PNL, Buisman CJN. 2008. High rate sulfate reduction at pH 6 in pH-auxostat submerged membrane bioreactor fed with formate. Water Res 42:2439-2448.
3. Cord-Ruwisch R. 1985. A quick method for the determination of dissolved and precipitated sulfides in cultures of sulfate-reducing bacteria. J Microbiol Methods 4:33-36. (Pubitemid 15055651)
4. Dar SA, Kuenen JG, Muyzer G. 2005. Nested PCR-denaturing gradient gel electrophoresis approach to determine the diversity of sulfate-reducing bacteria in complex microbial communities. Appl Environ Microb 71(5):2325-2330. (Pubitemid 40646973)
5. Finster K, Bak F, Pfenning N. 1994. Desulfuromonas acetexigens sp. nov., a dissimilatory sulfur-reducing eubacterium from anoxic freshwater sediments. Arch Microbiol 161:328-332. (Pubitemid 24133423)
6. Gazea B, Adam K, Kontopoulos A. 1996. A review of passive systems for the treatment of acid mine drainage. Miner Eng 9:23-42. (Pubitemid 126349212)
7. Geets J, Borremans B, Diels L, Springael D, Vangronsveld J, van der Lelie D, Vanbroekhoven K. 2006. DsrB gene-based DGGE for community and diversity surveys of sulfate-reducing bacteria. J Microbiol Methods 66:194-205. (Pubitemid 43922387)
8. 2S. Proceedings of 3rd International Conference on the Abatement of Drainage, Pittsburgh, PA, USA, April 24-29, p 214-222.
9. Huisman JL, Schouten G, Schultz C. 2006. Biologically produced sulphide for purification of process streams, effluent treatment and recovery of metals in the metal and mining industry. Hydrometallurgy 83:106-113. (Pubitemid 44118557)
10. Hulshoff Pol LW, Lens PNL, Stams AJM, Lettinga G. 1998. Anaerobic treatment of sulphate-rich wastewaters. Biodegradation 9:213-224.
11. Isaksen MF, Jørgensen BB. 1996. Adaptation of psychrophilic and psychrotrophic sulfate-reducing bacteria to permanently cold marine environments. Appl Environ Microb 62(2):408-414. (Pubitemid 26047405)
12. Johnson DB. 2000. Biological removal of sulfurous compounds from inorganic wastewaters. In: Lens PNL, Hulshoff Pol LW, editors. Environmental technologies to treat sulfur pollution. London: IWA Publishing, p 175-202.
13. Johnson DB, Hallberg KB. 2005. Acid mine drainage remediation options: A review. Sci Total Environ 228:3-14. (Pubitemid 40174869)
14. Kaksonen AH, Franzmann PD, Puhakka JA. 2003. Performance and ethanol oxidation kinetics of a sulfate-reducing fluidized-bed reactor treating acidic metal-containing waste water. Biodegradation 14:207-217.
15. Kaksonen AH, Franzmann PD, Puhakka JA. 2004. Effects of hydraulic retention time and sulfide toxicity on ethanol and acetate oxidation in sulfate-reducing metal-precipitating fluidized-bed reactor. Biotechnol Bioeng 86:332-343. (Pubitemid 38560361)
16. Karnachuck OV, Pimenov NV, Yusupov SK, Frank YA, Kaksonen AH, Puhakka JA, Ivanov MV, Lindström BE, Tuovinen OH. 2005. Sulfate reduction potential in sediments in the Norilsk mining area, northern Siberia. Geomicrobiol J 22:11-25.
17. Kawazuishi K, Prausniz JM. 1987. Correlation of vapor-liquid equilibria for the system ammonia-carbon dioxide-water. Ind Chem Eng Res 26:1482-1485. (Pubitemid 17620681)
18. Klein M, Friedrich M, Roger AJ, Hugenholtz P, Fishbain S, Abicht H, Blackall LL, Stahl DA, Wagner M. 2001. Multiple lateral transfers of dissimilatory sulfite reductase genes between major lineages of sulfate-reducing prokaryotes. J Bacteriol 183:6028-6035. (Pubitemid 32917422)
19. 2 production and compositions of bacterial communities within a dark fermentation fluidized-bed bioreactor. Biotechnol Bioeng 97:742-758.
20. Lane DJ. 1991. 16S/23S rRNA sequencing. In: Stackebrandt E, Goodfellow M, editors. Nucleic acid techniques in bacterial systematics. Chichester: Wiley Publishing, p 115-175.
21. Lettinga G, Rebac S, Zeeman G. 2001. Challenge of psychrophilic anaerobic wastewater treatment. Trends Biotechnol 19(9):363-369. (Pubitemid 32769891)
22. Lowson RT. 1982. Aqueous oxidation of pyrite by molecular oxygen. Chem Rev 82:461-497.
23. Muyzer G, Hottenträger S, Teske A, Wawer C. 1996. Denaturing gradient gel electrophoresis of PCR-amplified 16S rDNA a new molecular approach to analyze the genetic diversity of mixed microbial communities. In: Akkermans ADL, Van Elsas JD, De Bruijn F, editors. Molecular microbial ecology manual. Dordrecht: Kluwer Academic Publishers, p 1-23.
24. Paulo PL, Kleerebezem R, Lettinga G, Lens PNL. 2005. Cultivation of high rate sulfate reducing sludge by pH-based electron donor dosage. J Biotechnol 118:107-116. (Pubitemid 40814539)
25. Puhakka JA, Salkinoja-Salonen M, Ferguson JF, Benjamin MM. 1990. Effect of molybdate ions on methanation of simulated and natural wastewaters. Appl Microbiol Biotechnol 32:494-498. (Pubitemid 20095308)
26. Sahinkaya E, Ö zkaya S, Kaksonen AH, Puhakka JA. 2006. Sulfidogenic fluidized-bed treatment of metal-containing wastewater at low and high temperatures. Biotechnol Bioeng 96:1064-1071.
27. Sahinkaya E, Ö zkaya S, Kaksonen AH, Puhakka JA. 2007. Sulfidogenic fluidized-bed treatment of metal-containing wastewater at 8 and 65°C is limited by acetate oxidation. Water Res 41:2796-2814.
28. SFS. 1980a. SFS 3044: Metal content of water, sludge and sediment determination by atomic absorption spectroscopy, atomization in flame. General principles and guidelines. Helsinki: Finnish Standard Association SFS, p 8.
29. SFS. 1980b. SFS 3047: Metal content of water, sludge and sediment determination by atomic absorption spectroscopy, atomization in flame. Special guidelines for lead, iron, cadmium, cobalt, copper, nickel and zinc. Helsinki: Finnish Standard Association SFS, p 6.
30. SFS. 1981. SFS 3005: Alkalinity and acidity in water. Helsinki: Finnish Standards Association SFS, p 5.
31. SFS. 1990. SFS 3008: Determination of total residue and total fixed residue in water, sludge and sediment. Helsinki: Finnish Standards Association SFS, p 3.
32. SFS. 1995. SFS-EN ISO 10304-2: Water quality. Determination of dissolved fluoride, chloride, nitrite, orthophosphate, bromide, nitrate and sulfate ions, using liquid chromatography of ions. Helsinki: Finnish Standards Association SFS, p 22.
33. SFS. 1996. SFS-EN ISO 9963-1: Water quality. Determination of alkalinity. Part 1: Determination of total and composite alkalinity. Helsinki: Finnish Standards Association SFS, p 16.
34. Søndergaard J, Elberling B, Asmund G, Gudum C, Iversen KM. 2007. Temporal trends of dissolved weathering products released from a high Arctic coal mine waste rock pile in Svalbard (788N). Appl Geochem 22:1025-1038. (Pubitemid 46679170)
35. Tsukamoto TK, Killion HA, Miller GC. 2004. Column experiments for microbiological treatment of acid mine drainage: Low temperature, low-pH and matrix investigations. Water Res 38:1405-1418.
36. van Houten RT, Hulshoff Pol LW, Lettinga G. 1994. Biological sulphate reduction using gas-lift reactors fed with hydrogen and carbon dioxide as energy and carbon source. Biotechnol Bioeng 44:586-594. (Pubitemid 24254503)
37. van Houten BHGW, Roest K, Tzeneva VA, Dijkman H, Smidt H, Stams AJM. 2006. Occurrence of methanogenesis during start-up of a full-scale synthesis gas-fed reactor treating sulfate and metal-rich wastewater. Water Res 40:553-560. (Pubitemid 43176449)
38. Wagner M, Roger AJ, Flax JL, Brusseau GA, Stahl DA. 1998. Phylogeny of dissimilatory sulfite reductases supports an early origin of sulfate respiration. J Bacteriol 180:2975-2982. (Pubitemid 29122128)
39. Weijma J, Haerkens J-P, Stams AJM, Hulshoff Pol LW, Lettinga G. 2000. Thermophilic sulfate and sulfite reduction with methanol in a high rate anaerobic reactor. Water Sci Technol 42(5):251-258. (Pubitemid 30800621)
40. Widdel F, Bak F. 1991. Gram-negative mesophilic sulfate-reducing bacteria. In: Balows A, Trüper HG, Dworkin M, Harder W, Schleifer K-H, editors. The prokaryotes, Vol.4. 2nd edition. New York: Springer-Verlag, Inc., p 3352-3378.