Legendre L, Courties C, Troussellier M. Flow cytometry in oceanography 1989- 1999: environmental challenges and research trends[J]. Cytometry, 2001, 44: 164-172.
[7]
Ram A S P, Nair S, Chandramohan D. Bacterial growth efficiency in the tropical estuarine and coastal waters of Goa, southwest coast of India[J] . Microb Ecol, 2003,45 : 88 - 96.
[8]
Hobbie J E, Daley R J, Jasper S. Use of nuclepore filters for counting bacteria by fluorescence microscopy [ J]. Appl Environ Mierobiol, 1977, 33(5) : 1 225 - 1 228.
[9]
Bj ?rosen P K. Automatic determination of bacterioplankton biomass by image analysis[J]. Appl Environ Microbial,1986, 51(6) : 1 199-1 204.
[10]
Lee S, Fuhrman J A. Relationships between biovolume and biomass of naturally derived marine bacterioplankton[J].Appl Environ Mierobiol, 1987, 53:1 298 - 1 303.
[11]
Kroer N. Relationships between biovolume and carbon and nitrogen content of hacterioplankton[J]. FEMS Microblol Ecol, 1994, 13: 217-224.
[12]
Fagerbakke K M, Heldal M. Content of carbon, nitrogen,oxygen, sulfur and phosphorus in native aquatic and cultured bacteria[J]. Aquat Microb Ecol, 1996, 10: 15-27.
[13]
Trousselier M, Bouvy M, Courties C, et al. Variation of carbon content among bacterial species under starvation condition[J]. Aquat Microb Ecol, 1997, 13:113 -119.
Watson S W, Novitsk T J, Quinby H L, et al. Determination of bacterial number and biomass in the marine environment[J]. Appl Environ Microbial, 1977, 33:940- 946.
[16]
Bratbak G, Dundas I. Bacterial dry matter content and biomass estimations[J]. App Environ Microbiol, 1984,48: 755- 757.
[17]
Bj?rnsen P K, Kuparinen J. Determination of bacterioplankton biomass, net production and growth efficiency in the Southern Ocean[J]. Mar Ecol Prog Ser, 1991, 71:185- 194.
[18]
Bratbak G. Bacterial biovolume and biomass estimation[J]. ADP Environ Microbiol, 1985, 49:1 488- 1 493.
[19]
Kroer, N. Relationships between biovolume and carbon and nitrogen content of bacterioplankton[J]. FEMS Microbial Ecol, 1994, 13:217 - 224.
[20]
Norland S. The relationship between biomass and volume of bacteria[A]. Kemp P F, Sherr B F, Sherr E B, and Cole J J (ed.). Handbook of methods in aquatic microbial ecology[C]. London: Lewis Publishers, 1993. 303-307.
[21]
Norland S, Heldal M, Tumyr O. On the relation between dry matter and volume of bacteria [J ]. Microb Ecol, 1987, 13: 95-101.
[22]
Loferer- Kr?ssbacher M, Klima J, Psenner R. Determination of bacterial cell dry mass by transmission electron microscopy and densitometric image analysis[J]. Appl Environ Microbiol, 1998, 64:668 - 694.
[23]
Posch T, Loferer - Kr??bacher M, Gao G. Precision of bacterioplankton biomass determination: a comparison of two fluorescent dyes, and of allometric and linear volume - to - carbon conversion factors[J]. Aquat Microb Ecol, 2001, 25: 55-63.
[24]
Fuhrman J A. Bactefioplankton secondary production estimates for coastal waters of British Columbia, and California[J]. Appl Environ Microbial, 1980, 39(6) :1085- 1095.
[25]
Cole J J, Findlay S, Pace M L. Bacterial production in fresh and saltwater ecosystems : a cross - system overview[J]. Mar Ecol Prog Set, 1988, 43:1 - 10.
[26]
Azam F, Fenchel J, Field J G, et al. The ecological role of water- column microbes in the sea[J]. Mar Ecol Prog Ser. 1983, 10: 157-163.
[27]
Bianchi A, Wambeke F V, Garcin J. Bacterial utilization of glucose in the water column from eutrophic to oligotrophic pelagic areas in the eastern North Atlantic Ocean[J]. Journal of Marine System, 1998, 14: 45-55.
[28]
Fuhrman J A, Azam F. Thymidine incorporation as a measurement of heteretrophic bactefioplankton production in marine surface waters: evaluation and field results[J]Marine Biology, 1982, 66: 109- 120.
[29]
Ducklow H W, Hill S M. Tritiated thymidine incorporation and the growth of heteretrophic bacteria in warm core rings[J]. Limnol Oceanogr, 1985, 30: 260-272.
[30]
Biddanda B, Opsahl S, Benner R. Plankton respiration and carbon flux through bactefioplankton on the Louisiana shelf[J]. Limnol Oceanogr, 1994, 39(6) : 1 259- 1275.
[31]
Moriarty D J W. Techniques for estimating bacterial growth rates and production of biomass in aquatic environments[A]. Grigorova R, Norris J R. In Methods in Microbiology (22): Techniques in Microbial Ecology [C].San Diego: Academic Press, 1990. 211 - 234.
[32]
Smith E M, Kemp W M. Planktonic and bacterial respiration along an estuarine gradient: responses to carbon and nutrient enrichment[J]. Aquat Microb Ecol, 2003, 30:251 - 261.
[33]
Smith E M, Kemp W M. Size structure and the production/respiration balance in a coastal plankton community[J]. Limnol Oceanogr, 2001, 46(3) : 473 - 485.
[34]
del Giorgio P A, Cole J J, Cimbleris A. Respiration rates in bacteria exceed phytoplankton production in unproductive aquatic systems[J]. Nature, 1997, 385: 148- 151.
[35]
Rivkin R B, Legendre L. Biogenic carbon cycling in the upper ocean: effect of microbial respiration[J]. Science,2001, 291:2 398- 2 400.
[36]
Jahnke R A, Craven D B. Quantifying the rele of heteretrephic bacteria in the carbon cycle : a need for respiration rate measurements[J]. Linmol Oeeanogr, 1995,40(2) : 436- 441.
[37]
del Giorgio P A, Cole J J. Bacterial growth efficiency in natural aquatic systems[J]. Annu Rev Ecol Syst, 1998,29: 503- 541.
[38]
Robinson C, Williams P J L. Plankton net community production and dark respiration in the Arabian Sea during September [J]. Deep- Sea Res Ⅱ, 1999, 46:745 - 765.
[39]
Toolan T. Coulometrie carbon - based respiration rates and estimates of baetefioplankton growth effieieneies in Massaehusetts Bay[J]. Limnol Oceanogr, 2001,46(6) :1 298- 1 308.
[40]
Eiler A, Langenheder S, Bertilsson S, et al. Heterotrophic bacterial growth efilciency and community structure at different natural organic carbon concentrations[J]. Appl Environ Microbial, 2003, 69(7) : 3 701 -3 709.
[41]
Bell U T, Kuparinen J. Assessing Phytoplankton and Bacterioplankton Production During Early Spring in Lake Erken, Sweden[J]. Appl Environ Microblol, 1984, 48(6): 1 221- 1 230.
[42]
Williams P J leB. Micrebial contribution to overall marine plankton metabolism : direct measurements of respiration[J]. Oceanol Acta, 1981, 4: 359-364.
[43]
肖天.海洋细菌在微食物环中的作用[J].海洋科学,2000,24(7):4—6.
[44]
González N, Anad6n R, Viesca L. Carbon flux through the microbial community in a temperature sea during summer: role of bacterial metabolism[J]. Aquat Mierob Eeol, 2003, 33: 117- 126.
[45]
Sherry N D, Boyd P W, Sugimoto K, et al. Seasonal and spatial patterns of heterotrophic bacterial production, respiration, and biomass in the subarctic NE Pacific[J].Deep - Sea Research H, 1999, 46:2 557 - 2 578.
[46]
Fuhrman J A, Sleeter T D, Carlson C A, et al. Dominance of bacterial biomass in the Sargasso sea and its ecological implications[J]. Mar Ecol Frog Set, 1989,57: 207- 217.
[47]
Caron C A, Ducklow H W. Growth of bacterioplankton and consumption of dissolved organic carbon in the Sar gasso Sea[J]. Aquat Mierob Eeol, 1996, 10: 69- 85.
[48]
Shiah F K, Ducklow H W. Temperature and substrate regulation of bacterial abundance, production and specific growth rate in Chesapeake Bay, USA[J]. Mar Ecol FrogSer, 1994, 103: 297-308.
[49]
Shiah F K, Liu K K, Kao SJ, et al. The coupling of bacterial production and hydrography in the southern East China Sea: spatial patterns in spring and fall[J]. Continental Shelf Researela, 2000, 20:459 - 477.
[50]
Azam F, Fenchel T, Field J G, et al. The ecological role of water column microbes in the sea[J]. Mar Ecol Prog Ser, 1983, 10: 257-263.
[51]
Lemée R, Rochelle - Newall E, Wambeke F V, et al.Seasonal variation of bacterial production, respiration and growth efficiency in the open NW Mediterranean Sea[J].Aquat Microb Ecol, 2002, 29:227- 237.
