The biocide triclosan as a potential developmental disruptor in Mytilus early larvae.

The broadly utilized biocide triclosan (TCS) is continuously discharged in water compartments worldwide, where it is detected at concentrations of ng-µg/L. Given its lipophilicity and bioaccumulation, TCS is considered potentially harmful to human and environmental health and also as a potential endocrine disruptor (ED) in different species. In aquatic organisms, TCS can induce a variety of effects: however, little information is available on its possible impact on invertebrate development. Early larval stages of the marine bivalve Mytilus galloprovincialis have been shown to be sensitive to environmental concentrations of a number of emerging contaminants, including EDs. In this work, the effects of TCS were first evaluated in the 48 h larval assay in a wide concentration range (0.001-1,000 µg/L). TCS significantly affected normal development of D-veligers (LOEC = 0.1 µg/L; EC50 = 236.1 µg/L). At selected concentrations, the mechanism of action of TCS was investigated. TCS modulated transcription of different genes involved in shell mineralization, endocrine signaling, ceramide metabolism, and biotransformation, depending on larval stage (24 and 48 h post-fertilization-hpf) and concentration (1 and 10 µg/L). At 48 hpf and 10 µg/L TCS, calcein staining revealed alterations in CaCO3 deposition, and polarized light microscopy showed the absence of shell birefringence due to the mineralized phase. Observations by scanning electron microscopy highlighted a variety of defects in shell formation from concentrations as low as 0.1 µg/L. The results indicate that TCS, at environmental exposure levels, can act as a developmental disruptor in early mussel larvae mainly by interfering with the processes of biomineralization.

Thyroid hormone regulation of cell migration and oxidative metabolism in polymorphonuclear leukocytes: clinical evidence in thyroidectomized subjects on thyroxine replacement therapy.

Migration and superoxide anion (O2-) generation were studied in polymorphonuclear leukocytes (PMNs) from 14 athyreotic patients, previously treated by total thyroidectomy and radioiodine therapy for differentiated thyroid carcinoma, and from age- and sex-matched euthyroid healthy controls. Patients were studied twice: in hypothyroidism (visit 1) and after TSH-suppressive L-T4 replacement therapy (visit 2). Random migration and N-formyl-Met-Leu-Phe (fMLP) 0.1-microM induced chemotaxis were similar in cells from patients at both visit 1 and visit 2 and from healthy controls. On the contrary, resting O2- generation in cells from patients was significantly lower than control values, both at visit 1 and 2. At visit 1, fMLP 0.1 muM-induced O2- generation was significantly lower than control values, while phorbol-myristate acetate (PMA) 100-ng/ml induced O2- generation was similar in cells from patients and from controls. At visit 2 both responses increased, resulting in fMLP-induced O2- generation superimposable to control values and PMA-induced O2- generation significantly higher with respect to both visit 1 and cells from controls. In vitro exposure of PMNs from healthy subjects to L-T4 did not affect O2- generation in resting cells, and significantly increased that induced by fMLP or PMA only at high, supra-physiological concentrations. Neither TSH nor T3 had significant effects at any of the concentrations tested. The present results document the existence of a correlation between thyroid status and oxidative metabolism of human PMNs, which is however unlikely to depend upon a direct action of thyroid hormones on these cells.