J.J. Gallardo-Rodríguez

Bioactives from microalgal dinoflagellates

Dinoflagellate microalgae are an important source of marine biotoxins. Bioactives from dinoflagellates are attracting increasing attention because of their impact on the safety of seafood and potential uses in biomedical, toxicological and pharmacological research. Here we review the potential applications of dinoflagellate toxins and the methods for producing them. Only sparing quantities of dinoflagellate toxins are generally available and this hinders bioactivity characterization and evaluation in possible applications. Approaches to production of increased quantities of dinoflagellate bioactives are discussed. Although many dinoflagellates are fragile and grow slowly, controlled culture in bioreactors appears to be generally suitable for producing many of the metabolites of interest.

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.

Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum

Benthic marine dioflagellate microalgae belonging to the genus Prorocentrum are a major source of okadaic acid (OA), OA analogues and polyketides. However, dinoflagellates produce these valuable toxins and bioactives in tiny quantities, and they grow slowly compared to other commercially used microalgae. This hinders evaluation in possible large-scale applications. The careful selection of producer species is therefore crucial for success in a hypothetical scale-up of culture, as are appropriate environmental conditions for optimal growth. A clone of the marine toxic dinoflagellate P. belizeanum was studied in vitro to evaluate its capacities to grow and produce OA as an indicator of general polyketide toxin production under the simultaneous influence of temperature (T) and irradiance (I0). Three temperatures and four irradiance levels were tested (18, 25 and 28 °C; 20, 40, 80 and 120 µE·m−2·s−1), and the response variables measured were concentration of cells, maximum photochemical yield of photosystem II (PSII), pigments and OA. Experiments were conducted in T-flasks, since their parallelepipedal geometry proved ideal to ensure optically thin cultures, which are essential for reliable modeling of growth-irradiance curves. The net maximum specific growth rate (µm) was 0.204 day−1 at 25 °C and 40 µE·m−2·s−1. Photo-inhibition was observed at I0 > 40 μEm−2s−1, leading to culture death at 120 µE·m−2·s−1 and 28 °C. Cells at I0 ≥ 80 µE·m−2·s−1 were photoinhibited irrespective of the temperature assayed. A mechanistic model for µm-I0 curves and another empirical model for relating µm-T satisfactorily interpreted the growth kinetics obtained. ANOVA for responses of PSII maximum photochemical yield and pigment profile has demonstrated that P. belizeanum is extremely light sensitive. The pool of photoprotective pigments (diadinoxanthin and dinoxanthin) and peridinin was not able to regulate the excessive light-absorption at high I0-T. OA synthesis in cells was decoupled from optimal growth conditions, as OA overproduction was observed at high temperatures and when both temperature and irradiance were low. T-flask culture observations were consistent with preliminary assays outdoors.

Shear-induced changes in membrane fluidity during culture of a fragile dinoflagellate microalga

The commonly used shear protective agent Pluronic F68 (PF68) was toxic to the marine dinoflagellate microalga Protoceratium reticulatum, but had a shear‐protective effect on it at concentrations of ≤0.5 g L−1. Supplementation of P. reticulatum cultures with PF68 actually increased the fluidity of the cell membrane; therefore, the shear protective effect of PF68 could not be ascribed to reduced membrane fluidity, an explanation that has been commonly used in relation to its shear protective effect on animal cells. Data are reported on the membrane fluidity of P. reticulatum and its response to the presence of PF68 under sublethal and lethal turbulence regimens. The membrane fluidity was found to depend strongly on the level of lipoperoxides in the cells produced under lethal agitation.

Modelling of multi-nutrient interactions in growth of the dinoflagellate microalga Protoceratium reticulatum using artificial neural networks

This study examines the use of artificial neural networks as predictive tools for the growth of the dinoflagellate microalga Protoceratium reticulatum. Feed-forward back-propagation neural networks (FBN), using Levenberg-Marquardt back-propagation or Bayesian regularization as training functions, offered the best results in terms of representing the nonlinear interactions among all nutrients in a culture medium containing 26 different components. A FBN configuration of 26-14-1 layers was selected. The FBN model was trained using more than 500 culture experiments on a shake flask scale. Garsons algorithm provided a valuable means of evaluating the relative importance of nutrients in terms of microalgal growth. Microelements and vitamins had a significant importance (approximately 70%) in relation to macronutrients (nearly 25%), despite their concentrations in the culture medium being various orders of magnitude smaller. The approach presented here may be useful for modelling multi-nutrient interactions in photobioreactors.

New insights into shear-sensitivity in dinoflagellate microalgae

A modification of a flow contraction device was used to subject shear-sensitive microalgae to well-defined hydrodynamic forces. The aim of the study was to elucidate if the inhibition of shear-induced growth commonly observed in dinoflagellate microalgae is in effect due to cell fragility that results in cell breakage even at low levels of turbulence. The microalgae assayed did not show any cell breakage even at energy dissipation rates (EDR) around 10(12)Wm(-3), implausible in culture devices. Conversely, animal cells, tested for comparison purposes, showed high physical cell damage at average EDR levels of 10(7)Wm(-3). Besides, very short exposures to high levels of EDR promoted variations in the membrane fluidity of the microalgae assayed, which might trigger mechanosensory cellular mechanisms. Average EDR values of only about 4·10(5)Wm(-3) increased cell membrane fluidity in microalgae whereas, in animal cells, they did not.

Rapid method for the assessment of cell lysis in microalgae cultures

A solid understanding of the effect of hydrodynamic forces encountered by microalgae in bioprocesses would benefit existing bioprocesses, eventually allowing an increase in their productivity. For this purpose, a sensitive method able to quantify cell lysis is crucial. Most of the available protocols and methods intended for this purpose were developed for animal or insect cells. In the case of microalgae, the commercial kits tested were unable to determine the cell lysis extension. The method proposed here was developed to relate the release of a cytoplasmic component (enzyme lactate dehydrogenase (LDH)) with cell lysis by measuring the NADH (reduced form of nicotinamide cofactor adenine dinucleotide) produced by LDH. Although different commercial kits based on similar processes are available, they are more complicated to use and not applicable to microalgae nor when longer-term tests are to be performed.

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.

Evaluation of Furcraea Andina Fibers as Bacterial Support for Biological Denitrification

ABSTRACT The aim of the study was to determine the performance of Furcraea andina fibers as biofilter support. Furcraea andina fibers could be a candidate to be used as support for bacterial immobilization to be applied, among others, in environmental processes such as bioremediation and biofiltration of wastewaters. Adhesion of Pseudomonas irreversibly occurred in lower times than inert supports such as polyethylene terephthalate demonstrating the advantages of using natural supports. Nitrate consumption rates obtained were comparable to rates reported in bibliography. A first-order kinetics was found for denitrification in the biofilm due to the diffusion of nitrate into the biofilm.