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Biomasss and microzooplankton seasonal assemblages in the Bahía Blanca Estuary, Argentinean Coast

Published online by Cambridge University Press:  04 March 2011

M.S. Barría de Cao*
Affiliation:
IADO (CONICET–UNS) Florida 4750, 8000-Bahía Blanca, Argentina DBByF–UNS, San Juan 670-Bahía Blanca, Argentina
M.C. Piccolo
Affiliation:
IADO (CONICET–UNS) Florida 4750, 8000-Bahía Blanca, Argentina Departamento de Geografía y Turismo–UNS, 12 de Octubre y San Juan, Bahía Blanca, Argentina
G.M. Perillo
Affiliation:
IADO (CONICET–UNS) Florida 4750, 8000-Bahía Blanca, Argentina Departamento de Geología–UNS, San Juan 670, Bahía Blanca, Argentina
*
Correspondence should be addressed to: M.S. Barría de Cao, IADO (CONICET–UNS) Florida 4750, 8000-Bahía Blanca, Argentina email: [email protected]

Abstract

We investigated the occurrence and seasonal variation of the biomass of rotifers, tintinnids, the heterotrophic dinoflagellate Gyrodinium fusus and copepod nauplii in the Bahía Blanca Estuary (38°42′S61°50 ′W), Argentina, during an annual cycle. The rotifers fauna comprised three species, while the tintinnids were represented by sixteen species. The biomass of the rotifers fluctuated between 0.62 and 8.90 µgC l−1. The biomass of the tintinnids fluctuated between 0.13 and 9.37 µgC l−1, the biomass of the nauplii stages between 1.78 and 7.65 µgC l−1; while the biomass of G. fusus varied from 0.26 and 7.94 µgC l−1, these results are compared to estimates of microzooplankton in other regions. We analysed the presence of the different groups in relation to the environmental variables, based on point-biserial correlation. Salinity fluctuated between 25.14 and 36.64; temperature between 7.5 and 23.2°C, solar radiation between 0.9 and 30.8 MJ m−2d−1 and Secchi distance between 0.25 and 1.43 m. Rotifers were correlated positively with temperature, chlorophyll-a and Secchi depth and negatively with salinity. The tintinnids were positively correlated with salinity. Gyrodinium fusus was positively correlated with Secchi depth, and chlorophyll-a, and negatively with temperature and solar radiation. Nauplii stages were negatively correlated with chlorophyll-a. Based on the occurrence of the microzooplankters in relation to the physico-chemical variables, it was possible to establish two seasonal assemblages: (a) the co-occurrence of the rotifers and the heterotrophic dinoflagellate G. fusus during the winter–spring; and (b) the tintinnids and nauplii larvae during the summer. We conclude that, in this estuary, physico-chemical variables are the forcing factors that directly, or indirectly, influence the seasonal assemblages of the microzooplankton.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 2011

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