Some general relationships in comparing the feeding physiology of suspension-feeding bivalve molluscs

Abstract

We have studied feeding behaviour in the cockle Cerastoderma edule (L.), the oyster Crassostrea gigas (Thunberg) and the mussel Mytilus edulis (L.) for input to a model predicting the environmental capacity of the bay of Marennes-Oléron, France for shellfish culture. We present a common set of equations that summarize functional interrelations observed between component processes of feeding physiology, whilst allowing predictions of feeding behaviour and net organic absorption rate on the basis of seston abundance and seston organic content alone. Selective processes, and the consequences of those processes, are an important feature of those interrelations. Each species was able selectively to enrich the organic content of ingested matter relative to filtered matter, preferentially rejecting inorganic matter prior to ingestion as pseudofaeces. When feeding upon natural seston, the efficiency of that selection varied positively with both the mass of seston filtered h −1 and the organic content of filtered matter. At the highest food availabilities, when the mass of seston filtered h −1 was greatest, more than 60% of the organic matter ingested h −1 by each species resulted from selective processes. Physiological consequences of that selection were amplified by positive exponential relations between the net absorption efficiency for ingested organics and the organic content of ingested matter. We show that our common set of equations satisfactorily predict net organic absorption rate measured directly in all three species feeding throughout the same natural tidal variations of food. Collective findings therefore establish that similar functional interrelations control feeding responses in each species, and identify key relations affecting selection and absorption for use in the future modelling of growth and environmental relations. By fitting a common set of equations to responses measured directly under the same natural conditions of seston availability, we have standardised the comparison of environmental influences upon rates and efficiencies of feeding behaviour for each species. The mass of seston filtered h −1 increased in similar positive relations with seston abundance in each species. However, there were significant behavioural differences in the processing of filtered particles. Compared with the epifaunal species C. gigas and M. edulis, C. edule is normally infaunal, and demonstrated a lower capacity to selectively ingest organic matter. Alternatively, compared with M. edulis, C. gigas was not as efficient either in the net selection of organic matter or in digesting and/or assimilating ingested organics, resulting in lower rates of net energy gain. These differences are discussed bearing in mind present experimental conditions, as well as the natural habitat and comparative morphology of each studied species.