Living biomass supported on a natural-fiber biofilter for lead removal.

Living biomass biofilters constitute an excellent alternative for heavy metal bioremediation. In situ biomass and exopolysaccharides production involve a crucial advantage over other bioremediation alternatives such as lignocellulosic biomass-based materials. In this study, a biofilm-forming bacterium was isolated from an ambient exposed to heavy metals. Bacterial biomass was inoculated on a biofilter packed with Furcraea andina fibers. The goal was to develop a continuous low-cost biofilter to remove low-to-moderate concentrations of Pb2+. Adsorption equilibrium and kinetics were determined for the fibers and the biofilm developed on the fibers. Biofilm presence had positive effects on the maximum adsorption capacity and the process kinetics. Biofilters packed with 20 g of F. andina fibers, with and without living biomass biofilm, were evaluated under continuous inflow of Pb2+ (325 mg/day) at a concentration of 50 mg/L. The best results were obtained with the biofilm-fiber biofilter where total adsorption on Pb2+ were observed for 72 h. Maximum absorption capacity was 48.75 mg/g at pH = 7.

Study of the ichthyotoxic microalga Heterosigma akashiwo by transcriptional activation of sublethal marker Hsp70b in Transwell co-culture assays.

Despite the advance of knowledge about the factors and potential mechanisms triggering the ichthyotoxicity in microalgae, these remain unclear or are controversial for several species (e.g. Heterosigma). Neither typical toxicity tests carried out with cell extracts nor direct exposure to harmful species were proved suitable to unravel the mechanism of harm. Ichthyotoxic species show a complex harmful effect on fish, which is mediated through various mechanisms depending on the species. In this work, we present a method to study sub-lethal effects triggered by reactive oxygen species of a population of harmful algae in vivo over a fish cell line. To that end, Transwell co-cultures in which causative and target species are separated by a 0.4 µm pore membrane were carried out. This allowed the evaluation of the effect of the released molecules by cells in a rapid and compact test. In our method, the harmful effect was sensed through the transcriptional activation of sub-lethal marker Hsp70b in the CHSE214 salmon cell line. The method was tested with the raphidophyte Heterosigma akashiwo and Dunaliella tertiolecta (as negative control). It was shown that superoxide intracellular content and its release are not linked in these species. The methodology allowed proving that reactive oxygen species produced by H. akashiwo are able to induce the transcriptional activation of sub-lethal marker Hsp70b. However, neither loss of viability nor apoptosis was observed in CHSE214 salmon cell line except when exposed to direct contact with the raphidophyte cells (or their extract). Consequently, ROS was not concluded to be the main cause of ichthyotoxicity in H. akashiwo.

LC-MS/MS Detection of Karlotoxins Reveals New Variants in Strains of the Marine Dinoflagellate Karlodinium veneficum from the Ebro Delta (NW Mediterranean).

A liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was developed for the detection and quantitation of karlotoxins in the selected reaction monitoring (SRM) mode. This novel method was based upon the analysis of purified karlotoxins (KcTx-1, KmTx-2, 44-oxo-KmTx-2, KmTx-5), one amphidinol (AM-18), and unpurified extracts of bulk cultures of the marine dinoflagellate Karlodinium veneficum strain CCMP2936 from Delaware (Eastern USA), which produces KmTx-1 and KmTx-3. The limit of detection of the SRM method for KmTx-2 was determined as 2.5 ng on-column. Collision induced dissociation (CID) spectra of all putative karlotoxins were recorded to present fragmentation patterns of each compound for their unambiguous identification. Bulk cultures of K. veneficum strain K10 isolated from an embayment of the Ebro Delta, NW Mediterranean, yielded five previously unreported putative karlotoxins with molecular masses 1280, 1298, 1332, 1356, and 1400 Da, and similar fragments to KmTx-5. Analysis of several isolates of K. veneficum from the Ebro Delta revealed small-scale diversity in the karlotoxin spectrum in that one isolate from Fangar Bay produced KmTx-5, whereas the five putative novel karlotoxins were found among several isolates from nearby, but hydrographically distinct Alfacs Bay. Application of this LC-MS/MS method represents an incremental advance in the determination of putative karlotoxins, particularly in the absence of a complete spectrum of purified analytical standards of known specific potency.

Cytotoxicity of yessotoxin and okadaic acid in mouse T lymphocyte cell line EL-4.

Yessotoxin (YTX) and okadaic acid (OA), algal toxins accumulated in edible shellfish, were previously shown to induce a specific and reversible T Cell Receptor (TCR) down-regulation in T lymphocyte EL-4 cells, in a time and concentration-dependent manner, via protein kinase C (PKC) and serine/threonine protein phosphatase 2A (PP2A) activities. In this study we have evaluated the development of other signs of toxicity induced by low concentrations of YTX or OA for 3 days of treatment. Concentrations of YTX as low as 1 nM decreased a 35% the concentration of viable cells after 48 h exposure to the toxin, while concentrations as little as 5 nM YTX or OA were sufficient to induce membrane blebbing. The concentration of YTX that produced after 24 h of incubation a 50% reduction in maximum cell viability (EC5024) was approximately 46 nM, whereas with OA over 75% of the cells were still viable after exposure to 100 nM OA. According to our results, the cytoskeleton of EL-4 cells seems to be a cell component particularly sensitive to YTX and OA with disruption of F-actin cytoskeleton in these cells treated with concentrations of YTX or OA as low as 5 nM at 48 h incubation. Toxicity by YTX or OA involved typical hallmarks of apoptosis and an increase of reactive oxygen species (ROS) production. The cytotoxic effects of YTX and OA reported here, and the previously demonstrated potential of these toxins to regulate the activity of EL-4 cells through the regulation of TCR expression, rise reasonable concern about possible risks for human health associated to the chronic exposure to low amounts of YTX or OA itself or enhanced by the presence of other shellfish toxins specially by a population potentially at risk such as immunocompromised patients.