Abstract
Simulation modeling has been an integral, albeit ad hoc, component of the field of aquatic microbial ecology for the past two decades. One of the most critical steps in simulation modeling is the initial formulation of a clear set of questions and goals. It is doubtful that a single generic model could be constructed to address adequately all questions of interest concerning the microbial loop because of the tremendous range in time scales that define these questions. Progress in the field of aquatic microbial ecology will benefit from an integrated research program including experimental and modeling approaches. A submodel of bacterial utilization of various qualities of organic matter that we have under construction is presented. This submodel will be a component of a larger model to evaluate the effects of quality and quantity of organic matter and inorganic nutrient inputs on estuarine food web structure and efficiency. The overall model will be general enough in its structure that it should be applicable to a wide range of questions concerning the microbial loop, with time scales ranging from hours to days.
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References
Anderson TR (1992) Modelling the influence of food C:N ratio, and respiration on growth and nitrogen excretion in marine zooplankton and bacteria. J Mar Res 14:1645–1671
Bratbak G, Thingstad TF (1985) Phytoplankton-bacteria interactions: an apparent paradox? Analysis of a model system with both competition and commensalism. Mar Ecol Prog Ser 25:23–30
Caron DA, Goldman JC, Bennett MR (1988) Experimental demonstration of the roles of bacteria and bacterivorous protozoa in plankton nutrient cycles. Hydrobiologia 159:27–40
Fasham MJR, Ducklow HW, McKelvie SM (1990) A nitrogen-based model of plankton dynamics in the oceanic mixed layer. J Mar Res 48:591–639
Goldman J, Caron DA, Dennett MR (1987) Regulation of gross growth efficiency and ammonium regeneration in bacteria by substrate C:N ratio. Limnol Oceanogr 32:1239–1252
Kirchman DL, Keil RG, Wheeler PA (1990) Ammonium recycling limits nitrate use in the oceanic subarctic Pacific. Limnol Oceanogr 35:1258–1266
Maloney CL, Field JG (1991) The size-based dynamics of plankton food webs. I. A simulation model of carbon and nitrogen flows. J Plankton Res 13:1003–1038
Pace ML, Glasser JE, Pomeroy LP (1984) A simulation analysis of continental shelf food webs. Mar Biol 82:47–63
Pomeroy LIZ (1974) The ocean's food web, a changing paradigm. BioScience 24:499–504
Steele JH (1974) The structure of marine ecosystems. Harvard University Press, Cambridge
Wetzel RL (1994) Modeling the microbial loop: an estuarine modeler's perspective. Microbial Ecology 28:331–334
Wetzel RL, Christian RR (1984) Simulation model studies on the interactions between carbon substrates, bacteria, and consumers in a salt marsh estuary: Duplin River, Sapelo Island, Georgia, USA. Bull Mar Science 35:601–614
Wright RT (1988) Methods for evaluating the interaction of substrate and grazing as factors controlling planktonic bacteria. Arch Hydrobiol Beih 32:229–242
Wright RT (1988) A model for short-term control of the bacterioplankton by substrate and grazing. Hydrobiologia 159:111–117
Wright RT, Coffin RB (1994) The microbial loop in a saltmarsh estuary: steady state vs. constant change. (Paper presented at Microbial Loop Symposium)
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Hopkinson, C.S., Vallino, J.J. Toward the development of generally applicable models of the microbial loop in aquatic ecosystems. Microb Ecol 28, 321–326 (1994). https://doi.org/10.1007/BF00166823
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DOI: https://doi.org/10.1007/BF00166823