Osmoregulatory power influences tissue ionic composition after salinity acclimation in aquatic decapods.

Decapod crustaceans show variable degrees of euryhalinity and osmoregulatory capacity, by responding to salinity changes through anisosmotic extracellular regulation and/or cell volume regulation. Cell volume regulatory mechanisms involve exchange of inorganic ions between extra- and intra-cellular (tissue) compartments. Here, this interplay of inorganic ions between both compartments has been evaluated in four decapod species with distinct habitats and osmoregulatory strategies. The marine/estuarine species Litopenaeus vannamei (Lv) and Callinectes danae (Cd) were submitted to reduced salinity (15‰), after acclimation to 25 and 30‰, respectively. The freshwater Macrobrachium acanthurus (Ma) and Aegla schmitti (As) were submitted to increased salinity (25‰). The four species were salinity-challenged for both 5 and 10 days. Hemolymph osmolality, sodium, chloride, potassium, and magnesium were assayed. The same inorganic ions were quantified in muscle samples. Muscle hydration (MH) and ninhydrin-positive substances (NPS) were also determined. Lv showed slight hemolymph dilution, increased MH and no osmotically-relevant decreases in muscle osmolytes; Cd displayed hemolymph dilution, decreased muscular NaCl and stable MH; Ma showed hypo-regulation and steady MH, with no change in muscle ions; As conformed hemolymph sodium but hypo-regulated chloride, had stable MH and increased muscle NPS and ion levels. Hemolymph and muscle ions (especially chloride) of As were highly correlated (Pearson, +0.83). Significant exchanges between hemolymph and muscle ionic pools were more evident in the two species with comparatively less AER regulatory power, C. danae and A. schmitti. Our findings endorse that the interplay between extracellular and tissue ionic pools is especially detectable in euryhaline species with relatively lower osmoregulatory strength.

Assessment of acute toxicity of carbofuran in Macrobrachium olfersii (Wiegmann, 1836) at different temperature levels.

Carbofuran (2,3-dihydro-2,2-dimethyl-7-benzofuranyl methylcarbamate; C12H15NO3) is one of the most toxic carbamate pesticides. For acute toxicity of carbofuran, juveniles of Macrobrachium olfersii were exposed to different concentrations of carbofuran using the static renewal method at different temperature levels (15, 20 and 25°C) at pH 7.0. The main purpose of the present study was to detect the acute toxicity of carbofuran to M. olfersii and investigate its effects on oxygen consumption and ammonium excretion; these tests have not been carried out in this species before. First, the acute toxicity - median lethal concentration - of carbofuran to M. olfersii for 24, 48, 72 and 96 h was examined, which resulted in the following values: 1.64, 1.22, 0.86 and 0.42 mg L(-1), respectively. Furthermore, we also found that carbofuran caused an inhibition in oxygen consumption of 60.6, 65.3 and 66.2% with respect to the control. In addition, after separate exposures to carbofuran, elevations in ammonium excretion were more than 500% with respect to the control.

Uptake and depuration of PCB-153 in edible shrimp Palaemonetes varians and human health risk assessment.

A medium-term mesocosm exposure study was conducted to elucidate bioaccumulation and depuration of polychlorinated biphenyl congener 153 (PCB-153) in edible shrimp Palaemonetes varians. Over the 15-day exposure period, shrimp under different exposure concentrations exhibited a significant increase in PCB-153 concentration compared with control organisms. Distinct bioaccumulation patterns and uptake rates were observed depending on the exposure concentrations. For low PCB-153 exposure levels (0.25µgL(-1)), accumulation followed a saturation model, reaching an apparent steady state after fifteen days exposure. For intermediate (2.5µgL(-1)) and high PCB-153 levels (25µgL(-1)), accumulation was faster and linear. In addition, the bioaccumulation rate was not proportional to PCB-153 concentration, and the bioaccumulation was higher at intermediate exposure concentrations. Regarding the depuration phase, P. varians lost up to 30% of PCB-153 after 72h and levels continued slowly to decrease until the end of the 30-d experimental period. However, PCB-153 levels in shrimp did not reach background values, and those exposed to moderate and high PCB-153 concentrations presented contamination levels much higher than the regulatory limit for human food consumption (75ngg(-1) ww for Σ6 PCB).

Preliminary risk assessment of the lipid-regulating pharmaceutical clofibric acid, for three estuarine species.

Clofibric acid is the active metabolite of several fibrate drugs prescribed to reduce blood cholesterol levels. It is persistent and widely detected in the environment. Clofibric acid toxicity was assessed using three estuarine organisms: an alga (Dunaliella tertiolecta), a crustacean (Palaemonetes pugio), and a fish (Fundulus heteroclitus). Mortality and sublethal physiological responses (protein, lipid, cholesterol, and cytochrome P450 levels) were examined. Clofibric acid did not significantly affect cell density or growth rate of D. tertiolecta (concentrations 1000 microg/L). Survival of P. pugio and F. heteroclitus were also unaffected at clofibric acid concentrations 1000 microg/L. In addition, no significant changes in the sublethal test endpoints were found. An additional chronic (17-day) exposure of F. heteroclitus to clofibric acid (10 microg/L) was conducted and found no effects on survival or sublethal endpoints. The rabbit polyclonal CYP450 4A antibody did cross react with F. heteroclitus, demonstrating that a CYP4A-like isoform is present in this teleost species and may be used in future induction studies. Clofibric acid, however, did not alter CYP4A levels in F. heteroclitus. Measured concentrations in the environment have not exceeded 10 microg/L. Therefore, the results of this study indicate a low risk of adverse effects from environmental exposure to clofibric acid for the species tested.

Differences in maintenance energy expenditure by two estuarine shrimp (Palaemonetes pugio and P. vulgaris) that may permit partitioning of habitats by salinity.

The estuarine shrimp Palaemonetes pugio and P. vulgaris co-occur across a broad range in salinity. Field surveys and laboratory lethality tests suggest that low salinity conditions favor P. pugio over P. vulgaris. This study compared energetic expenditures across a range in salinity (0.5-35 ppt) to test the hypothesis that P. pugio experiences lower maintenance-energy requirements than P. vulgaris in low-salinity habitats. Standard metabolic rate (SMR) was measured as the minimum oxygen consumption rate at 25 degrees C to estimate daily maintenance-energy expenditure. SMR was greatest at 0.5 and least at 10 ppt (irrespective of species), and greater for P. vulgaris than for P. pugio. At low salinity (1.5-3 ppt), SMR was lower for P. pugio than for P. vulgaris. Energy expenditure did not coincide with the pattern predicted based upon osmoregulatory costs alone; no reduction was observed near the reported hemolymph concentration for P. vulgaris, although a minimum was observed near the hemolymph isoionic concentration for P. pugio. A local minimum in SMR by P. pugio between 1.5 and 3 ppt contrasted with relatively high SMR of P. vulgaris across this range. It appears that low-salinity habitats are energetically more favorable for P. pugio than for P. vulgaris. The results suggest an adaptive mechanism allowing P. pugio to occupy environments that present its competitor, P. vulgaris, with greater energetic challenges. While long-term exposure to very low salinity may be detrimental to both species, energetic traits of P. pugio may confer it with greater success than P. vulgaris in habitats in which salinity periodically fluctuates to low values.