RESUMO
El aumento de la salinidad en los ecosistemas de agua dulce genera preocupación sobre los efectos adversos que puede provocar sobre las especies dulceacuícolas y el suelo. Las concentraciones óptimas de iones de sodio y calcio para que las especies del género Hydra tengan condiciones fisiológicas adecuadas son relativamente bajas. Este trabajo se enfocó en comparar la sensibilidad de H. vulgaris e H. viridissima frente al cloruro de sodio (NaCl). Las especies fueron mantenidas bajo condiciones de fotoperiodo, iluminación y temperatura controladas. Se obtuvieron las tasas de crecimiento y en ensayos de toxicidad aguda se calcularon las CE50 (Concentración efectiva media) y CL50 (Concentración letal media) como indicadores de la sensibilidad al NaCl. H. vulgaris fue más sensible al NaCl dado que la CL50-96h fue de 1,0 g/l NaCl (entre 0,8 - 1,2 g/l como intervalo de confianza al 95%), mientras que H. viridissima presentó una CL50-96h promedio de 2,6 g/l (entre 2,0 - 3,3 g/l como intervalo de confianza del 95%). Se considera que esta última fue más tolerante al NaCl, probablemente por la relación simbiótica con la microalga Chlorella vulgaris, ya que podría generar un efecto protector. Se espera que comprender el comportamiento de estos biomodelos respecto al aumento de la salinización permita la evaluación temprana de riesgos ecológicos en ecosistemas acuáticos tropicales.
The increase in salinity in freshwater ecosystems raises concern about the adverse effects that it can cause in freshwater species and the soil. The sodium and calcium ions optimum concentrations required for genus Hydra to have adequate physiological conditions are relatively low. This research compared the H. vulgaris and H. viridissima sodium chloride (NaCl) sensitivity. The species were propagated under photoperiod, lighting and temperature-controlled conditions. The growth rates were obtained and EC50 (mean effective concentration) and LC50 (mean lethal concentration) were calculated by means of acute toxicity tests as indicators of sensitivity to NaCl. For H. vulgaris the LC50-96h was 1.0 g/l of NaCl with a range between 0.8 - 1.2 g/l of NaCl, compared to H. viridissima presented an average LC50-96h of 2.6 g/l of NaCl with a 95% confidence interval between 2.0 - 3.3 g/l of NaCl. The H. viridissima was more tolerant, probably the symbiotic relationship with Chlorella vulgaris, can generate a protective effect. Understanding the behavior of these species with respect to increased salinization can allow an early assessment of ecological risks in tropical aquatic ecosystems.
RESUMO
Hydroids of the Pacific coast of Mexico have been little studied. For the coast of Oaxaca, only five papers provide information on species of the region, with some records included in those publications being questionable. Seven species, Pennaria disticha, Clytia linearis, Clytia cf. gracilis, Obelia dichotoma, Ventromma halecioides, Dynamena crisioides and Tridentata turbinata, were discovered during the study and are reported herein. Of these species, Pennaria disticha and Tridentata turbinata are new records for the Mexican Pacific coast, and Clytia linearis and Ventromma halecioides are new records for Oaxaca. Geographic ranges of other hydroids, recorded in earlier studies, are expanded.
Assuntos
Cnidários , Hidrozoários , Animais , MéxicoRESUMO
Hydroids are broadly reported in epiphytic associations from different localities showing marked seasonal cycles. Studies have shown that the factors behind these seasonal differences in hydroid richness and abundance may vary significantly according to the area of study. Seasonal differences in epiphytic hydroid cover and richness were evaluated in a Sargassum cymosum C. Agardh bed from Lázaro beach, at Ubatuba, Brazil. Significant seasonal differences were found in total hydroid cover, but not in species richness. Hydroid cover increased from March (early fall) to February (summer). Most of this pattern was caused by two of the most abundant species: Aglaophenia latecarinata Allman, 1877 and Orthopyxis sargassicola (Nutting, 1915). Hydroid richness seems to be related to S. cymosum size but not directly to its biomass. The seasonal differences in hydroid richness and algal cover are shown to be similar to other works in the study region and in the Mediterranean. Seasonal recruitment of hydroid species larvae may be responsible for their seasonal differences in algal cover, although other factors such as grazing activity of gammarid amphipods on S. cymosum must be taken into account.
RESUMO
Hydroids are broadly reported in epiphytic associations from different localities showing marked seasonal cycles. Studies have shown that the factors behind these seasonal differences in hydroid richness and abundance may vary significantly according to the area of study. Seasonal differences in epiphytic hydroid cover and richness were evaluated in a Sargassum cymosum C. Agardh bed from Lázaro beach, at Ubatuba, Brazil. Significant seasonal differences were found in total hydroid cover, but not in species richness. Hydroid cover increased from March (early fall) to February (summer). Most of this pattern was caused by two of the most abundant species: Aglaophenia latecarinata Allman, 1877 and Orthopyxis sargassicola (Nutting, 1915). Hydroid richness seems to be related to S. cymosum size but not directly to its biomass. The seasonal differences in hydroid richness and algal cover are shown to be similar to other works in the study region and in the Mediterranean. Seasonal recruitment of hydroid species larvae may be responsible for their seasonal differences in algal cover, although other factors such as grazing activity of gammarid amphipods on S. cymosum must be taken into account.
RESUMO
Hydroids are broadly reported in epiphytic associations from different localities showing marked seasonal cycles. Studies have shown that the factors behind these seasonal differences in hydroid richness and abundance may vary significantly according to the area of study. Seasonal differences in epiphytic hydroid cover and richness were evaluated in a Sargassum cymosum C. Agardh bed from Lázaro beach, at Ubatuba, Brazil. Significant seasonal differences were found in total hydroid cover, but not in species richness. Hydroid cover increased from March (early fall) to February (summer). Most of this pattern was caused by two of the most abundant species: Aglaophenia latecarinata Allman, 1877 and Orthopyxis sargassicola (Nutting, 1915). Hydroid richness seems to be related to S. cymosum size but not directly to its biomass. The seasonal differences in hydroid richness and algal cover are shown to be similar to other works in the study region and in the Mediterranean. Seasonal recruitment of hydroid species larvae may be responsible for their seasonal differences in algal cover, although other factors such as grazing activity of gammarid amphipods on S. cymosum must be taken into account.