Plankton succession and assemblage structure in two neighbouring littoral ecosystems in the north-west Mediterranean Sea
J.-L. Jamet A C , N. Jean B , G. Bogé A , S. Richard A and D. Jamet AA Université du Sud Toulon-Var, Equipe de Biologie des Milieux Aquatiques, Laboratoire PROTEE, E. A. 3819. B. P. 20132. F-83957 La Garde cedex, France.
B Institut National des Sciences et Techniques de la Mer, CNAM/INTECHMER Laboratoire d’Etudes et de Recherches Marines, E. A. 3202 B. P. 324. F-50103 Cherbourg cedex, France.
C Corresponding author. Email: jamet@univ-tln.fr
Marine and Freshwater Research 56(1) 69-83 https://doi.org/10.1071/MF04102
Submitted: 17 May 2004 Accepted: 25 November 2004 Published: 4 February 2005
Abstract
We studied seasonal variations in bacterial abundance and succession in phyto- and zooplankton assemblages (particularly small taxa) in two neighbouring shallow bays (near Toulon, Mediterranean Sea, France): Little Bay (polluted, eutrophic), and Niel Bay (less polluted, oligotrophic). In Little Bay, bacteria developed in northern spring and phytoplankton (Dinophyceae > 20 µm) in late northern winter–early spring. Zooplankton levels peaked at the end of northern spring and in autumn; this community was dominated by Oithona nana. In Niel Bay, bacterial levels peaked during northern spring and autumn. Phytoplankton (Dinophyceae, Bacillariophyceae) abundance was low and only peaked in June. Zooplankton levels peaked in northern mid-summer. Little Bay was influenced more by the land and by human activities than by the sea. Seasonal factors (e.g. water temperature) and sudden influences (e.g. rain and, indirectly, Mistral wind) may have modified the succession of the plankton communities in this bay. Successions did not follow Margalef’s model and the classical scheme for zooplankton. Conversely, Niel Bay functioning and plankton assemblages were most influenced by the physical environment of the sea than by the land or by human activities. Successions were closely related to the classical scheme of the Mediterranean Sea.
Extra keywords: bacteria, ecology, marine ecosystem, phytoplankton, pollution, zooplankton.
Acknowledgments
The authors thank the Institut Universitaire de Technologie of the Université du Sud Toulon-Var (Director of the IUT, Prof. B. Rossetto) and the Département de Génie Biologique for technical support (Chief of Department, Prof. M. Camail). The authors are also indebt to Dr C. Le Poupon and J.-M. Ginoux for their scientific advices. They also thank the two anonymous referees for suggestions that improved the manuscript.
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