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Aerobic decomposition of Chlorella salina in freshwater and saline conditions
OLR (1985) 32 (9)
E. Biological Oceanography
85:5209
Davey, Allan and W.J. Woelkerling, 1985. Studies on Australian mangrove algae. III. Victorian communities: structure and recolonization in Western Port Bay [Australia]. J. expl mar. Biol. Ecol., 85(2): 177-190. Res. Sch. of Biol. Sci., Australian Natl. Univ., P.O. Box 475, Canberra City, ACT 2601, Australia.
763
8.6-21.5 h in eutrophic waters and 101-313 h in oligotropbic waters; turnover times for leucine were similar or shorter. Utilization rates were similar in surface and eutrophic water, but were higher in the surface film of oligotrophic water. Inst. of Mar. Res., A-018, La Jolla, CA 92093, USA. (mjj) 85:5215
Chan, Kwong-yu, 1985. Aerobic decomposition of Chlorella salina in freshwater and saline conditions. Hydrobiologia, 122(1):35-44. Res. Lab. for Food Protein Prod., Chinese Univ., Shatin, N.T. Hong Kong.
El40. Birds 85:5210
Blokpoel, Hans, R.D. Morris and G.D. Tessier, 1984. Field investigations of the biology of common terns wintering in Trinidad. J. Fld Orn., 55(4):
424-434. Canadian Wildlife Serv., 1725 Woodward Dr., Ottawa, ON K1A 0E7, Canada. 85:5211 Pettit, T.N., H.I. Ellis and G.C. Whittow, 1985. Basal metabolic rate in tropical seabirds. Auk, 102(1): 172-174. Dept. of Physiol., Univ. of Hawaii, Honolulu, HI 96822, USA. 85:5212
Richards, M.H. and R.D. Morris, 1984. An experImental study of nest site selection In common terns. J. Fld Orn., 55(4):457-466. Dept. of Biol. Sci., Brock Univ., St. Catharines, ON L2S 3A1, Canada. 85:5213
Williams, T.C., 1984. How to use marine radar for bird watching. A simple and inexpensive method for using a widely available type of radar. Am. Birds, 38(6):982-983. Dept. of Biol., Swarthmore Coll., Swarthmore, PA 19081, USA.
El50.
Microbiology (communities, proalso bacteria, fungi, yeasts, viruses,
cesses;
etc.) 85:5214
Carlucci, A.F., D.B. Craven and S.M. Henrichs, 1985. Surface-film microheterotrophs: amino acid metabolism and solar radiation effects on their activities. Mar. Biol., 85(1):13-22. Microbial heterotrophy in surface water films off Baja California and southern California was not appreciably inhibited by either visible or ultraviolet radiation, and was sometimes stimulated by solar radiation. Turnover times for glutamic acid were
85:5216
Gabrielson, J.O. and K.S. Hamel, 1985. Decomlmsition of the cyanebaeterlum Nodviarla spumb gena. Botanica mar., 28(1):23-27. Rapid decomposition of the non-refractory dry weight fraction (66%) of N. spumigena occurred at an exponential rate of 16.5%/day for the first 29 days (in the dark, 25°C). At day 70, cellular P and N reached minimum values; N and P were mainly converted to soluble reactive P, ammonia-N and nitrate-nitrite-N. Soil Sci. and Plant Nutrition Gr., Sch. of Agric., Univ. of Western Australia, Nedlands, WA 6009, Australia. (ahm) 85:5217 Jones, R.D. and R.Y. Morita, 1985. Low-temperatare growth and whole--celi kinetics of a marine ammonium oxidizer. Mar. EcoL-Prog. Ser., 21(3):239-243. An ammonium oxidizing bacterium has been isolated from Alaskan waters that is capable of growth at -5°C. Cells grown at 5°C had an optimum growth temperature of 22°C and a maximum of ~29°C. Cells grown at 25°C had an optimum growth temperature of 30°C and a maximum of ~38°C. Whole-ceU kinetic studies indicate that there are physiological differences between cells of this ammonium oxidizer when grown at 5 and 25°C, suggesting that adaptation to higher temperatures should be avoided in autoeeologieal studies. Dept. of Microbiol., Oregon State Univ., Corvallis, OR 97331-3804, USA. 85:5218
Li, W.K.W. and P.M. Dickie, 1985. Metabolic inhibition of size--fractinnated marine plankton radiolabeled with amino adds, g ] ~ , bicarbonate, and phosphate in the light and dark. Microb. Ecol., 11(1):11-24. Time course measurements of radiolabeled substrate uptake were carried out in the presence of various
E. Biological Oceanography
85:5209
Davey, Allan and W.J. Woelkerling, 1985. Studies on Australian mangrove algae. III. Victorian communities: structure and recolonization in Western Port Bay [Australia]. J. expl mar. Biol. Ecol., 85(2): 177-190. Res. Sch. of Biol. Sci., Australian Natl. Univ., P.O. Box 475, Canberra City, ACT 2601, Australia.
763
8.6-21.5 h in eutrophic waters and 101-313 h in oligotropbic waters; turnover times for leucine were similar or shorter. Utilization rates were similar in surface and eutrophic water, but were higher in the surface film of oligotrophic water. Inst. of Mar. Res., A-018, La Jolla, CA 92093, USA. (mjj) 85:5215
Chan, Kwong-yu, 1985. Aerobic decomposition of Chlorella salina in freshwater and saline conditions. Hydrobiologia, 122(1):35-44. Res. Lab. for Food Protein Prod., Chinese Univ., Shatin, N.T. Hong Kong.
El40. Birds 85:5210
Blokpoel, Hans, R.D. Morris and G.D. Tessier, 1984. Field investigations of the biology of common terns wintering in Trinidad. J. Fld Orn., 55(4):
424-434. Canadian Wildlife Serv., 1725 Woodward Dr., Ottawa, ON K1A 0E7, Canada. 85:5211 Pettit, T.N., H.I. Ellis and G.C. Whittow, 1985. Basal metabolic rate in tropical seabirds. Auk, 102(1): 172-174. Dept. of Physiol., Univ. of Hawaii, Honolulu, HI 96822, USA. 85:5212
Richards, M.H. and R.D. Morris, 1984. An experImental study of nest site selection In common terns. J. Fld Orn., 55(4):457-466. Dept. of Biol. Sci., Brock Univ., St. Catharines, ON L2S 3A1, Canada. 85:5213
Williams, T.C., 1984. How to use marine radar for bird watching. A simple and inexpensive method for using a widely available type of radar. Am. Birds, 38(6):982-983. Dept. of Biol., Swarthmore Coll., Swarthmore, PA 19081, USA.
El50.
Microbiology (communities, proalso bacteria, fungi, yeasts, viruses,
cesses;
etc.) 85:5214
Carlucci, A.F., D.B. Craven and S.M. Henrichs, 1985. Surface-film microheterotrophs: amino acid metabolism and solar radiation effects on their activities. Mar. Biol., 85(1):13-22. Microbial heterotrophy in surface water films off Baja California and southern California was not appreciably inhibited by either visible or ultraviolet radiation, and was sometimes stimulated by solar radiation. Turnover times for glutamic acid were
85:5216
Gabrielson, J.O. and K.S. Hamel, 1985. Decomlmsition of the cyanebaeterlum Nodviarla spumb gena. Botanica mar., 28(1):23-27. Rapid decomposition of the non-refractory dry weight fraction (66%) of N. spumigena occurred at an exponential rate of 16.5%/day for the first 29 days (in the dark, 25°C). At day 70, cellular P and N reached minimum values; N and P were mainly converted to soluble reactive P, ammonia-N and nitrate-nitrite-N. Soil Sci. and Plant Nutrition Gr., Sch. of Agric., Univ. of Western Australia, Nedlands, WA 6009, Australia. (ahm) 85:5217 Jones, R.D. and R.Y. Morita, 1985. Low-temperatare growth and whole--celi kinetics of a marine ammonium oxidizer. Mar. EcoL-Prog. Ser., 21(3):239-243. An ammonium oxidizing bacterium has been isolated from Alaskan waters that is capable of growth at -5°C. Cells grown at 5°C had an optimum growth temperature of 22°C and a maximum of ~29°C. Cells grown at 25°C had an optimum growth temperature of 30°C and a maximum of ~38°C. Whole-ceU kinetic studies indicate that there are physiological differences between cells of this ammonium oxidizer when grown at 5 and 25°C, suggesting that adaptation to higher temperatures should be avoided in autoeeologieal studies. Dept. of Microbiol., Oregon State Univ., Corvallis, OR 97331-3804, USA. 85:5218
Li, W.K.W. and P.M. Dickie, 1985. Metabolic inhibition of size--fractinnated marine plankton radiolabeled with amino adds, g ] ~ , bicarbonate, and phosphate in the light and dark. Microb. Ecol., 11(1):11-24. Time course measurements of radiolabeled substrate uptake were carried out in the presence of various