Dissimilatory nitrate reduction by a strain ofClostridium butyricum isolated from estuarine sediments (original) (raw)
- Baker K (1968) Low cost continuous culture apparatus. Lab Pract 17:817–821
Google Scholar - Brown CM, MacDonald-Brown DS, Stanley SO (1972) Inorganic nitrogen metabolism in marine bacteria: nitrogen assimilation in some marine pseudomonads. J Mar Biol Ass UK 52:793–804
Google Scholar - Caskey WH, Tiedje JM (1980) The reduction of nitrate to ammonium by a_Clostridium_ sp. isolated from soil. J Gen Microbiol 119:217–223
Google Scholar - Chang JP, Morris JG (1962) Studies on the utilization of nitrate by_Micrococcus denitrificans_. J Gen Microbiol 29:301–310
Google Scholar - Cole JA (1978) The rapid accumulation of large quantities of ammonia during nitrite reduction by_Escherichia coli_. FEMS Letters 4:327–329
Google Scholar - Cole JA, Brown CM (1980) Nitrite reduction to ammonia by fermentative bacteria: a short circuit in the biological nitrogen cycle. FEMS Letters 7:65–72
Google Scholar - Cole JA, Coleman KJ, Compton BE, Kavenagh BM, Keevil CW (1974) Nitrite and ammonia assimilation by anaerobic cultures of_Escherichia coli_. J Gen Microbiol 85:11–22
Google Scholar - Cruickshank R (1965) Medical Microbiology, E. S. Livingstone, Edinburgh London, pp 868–869
Google Scholar - Decker K, Jungermann K, Thauer RK (1970) Energy production in anaerobic organisms. Angew Chemie 9:138–158
Google Scholar - Dunn GM, Herbert RA, Brown CM (1978) Physiology of denitrifying bacteria from tidal mudflats in the River Tay. In: DS McLusky, AJ Berry (eds) Physiology and behaviour of marine organisms. Pergamon, Oxford New York, pp 135–140
Google Scholar - Dunn GM, Herbert RA, Brown CM (1979) Influence of oxygen tension on nitrate reduction by a_Klebsiella_ sp. growing in chemostat culture. J Gen Microbiol 112:379–383
Google Scholar - Hadjipetrou LP, Stouthamer AH (1965) Energy production during nitrate respiration by_Aerobacter aerogenes_. J Gen Microbiol 38:29–34
Google Scholar - Harder W, Veldkamp H (1967) A continuous culture study of an obligately psychrophilic_Pseudomonas_ sp. Arch Mikrobiol 59:123–130
Google Scholar - Hasan SM, Hall JB (1975) The physiological function of nitrate reduction in_Clostridium perfringens_. J Gen Microbiol 87:120–128
Google Scholar - Hasan SM, Hall JB (1977) Dissimilatory nitrate reduction in_Clostridium tertium_. Z Allg Mikrobiol 17:501–506
Google Scholar - Inderlied CB, Delwiche EA (1973) Nitrate reduction and growth of_Veillonelia alcalescens_ J Bacteriol 114:1206–1212
Google Scholar - Ishimoto M, Egami F (1959) Meaning of nitrate and sulphate reduction in the process of metabolic evolution. In: F Clark, RLM Synge (eds) Proceedings of the 1st International Symposium on the Origin of Life on Earth. Pergamon, New York, pp 555–561
Google Scholar - Ishimoto M, Umeyama M, Chiba S (1974) Alteration of fermentation products from butyrate to acetate by nitrate reduction in_Clostridium perfringens_. Z Allg Mikrobiol 14:115–121
Google Scholar - Jones JG, Simon BM (1981) Differences in microbial decomposition processes in profundal and littoral lake sediments, with particular reference to the nitrogen cycle. J Gen Microbiol 123:297–312
Google Scholar - Keith SM, Herbert RA (1981) Anaerobic chemostat enrichments of acetate-utilizing sulphate reducing bacteria and saccharolytic clostridia from estuarine and marine sediments. Proc Soc Gen Microbiol 8:276
Google Scholar - Koike I, Hattori A (1978) Denitrification and ammonia formation in anaerobic coastal sediments. Appl Environ Microbiol 35:278–282
Google Scholar - Koyama J (1956) On the nitrate reductase of_Clostridium welchii_. Seikagw 28:74
Google Scholar - Lowry OH, Roseborough NJ, Farr AL, Randall RJ (1951) Protein measurement with the Folin phenol reagent. J Biol Chem 193:265–275
Google Scholar - MacFarlane GT, Herbert RA (1981a) Nitrate dissimilation by_Vibrio_ ssp: isolated from estuarine sediment. J Gen Microbiol (in press)
- Prakash O, Sadana JC (1973) Metabolism of nitrate in_Achromobacter fischeri_. Can J Microbiol 19:15–25
Google Scholar - Rao KK, Gogotov IN, Hall DO (1978) Hydrogen evolution by chloroplast-hydrogenase systems — improvements and additional observations. Biochimie 60:291–296
Google Scholar - Schulp JA, Stouthamer AH (1970) The influence of oxygen, glucose and nitrate upon the formation of nitrate reductase and the respiratory system in_Bacillus licheniformis_. J Gen Microbiol 64:195–205
Google Scholar - Seki-Chiba S, Ishimoto M (1977) Studies on nitrate reductase of_Clostridium perfringens_. J Biochem 82:1663–1671
Google Scholar - Skerman VBD (1967) A guide to the identification of the genera of bacteria. 2nd edn. Williams and Wilkins, Baltimore
Google Scholar - Skinner FA (1960) The isolation of anaerobic cellulose-decomposing bacteria from soil. J Gen Microbiol 22:539–547
Google Scholar - Sørensen J (1978) Capacity for denitrification and reduction of nitrate to ammonia in a coastal marine sediment. Appl Environ Microbiol 35:301–305
Google Scholar - Stanford G, Legg OJ, Dzienia S, Simpson EC (1975) Denitrification and associated nitrogen transformations in soils. Soil Sci 120:147–152
Google Scholar - Woods DD (1938) The reduction of nitrate to ammonia by_Clostridium welchii_. Biochem J 32:2000–2012
Google Scholar