Marine phycotoxins are a multiplicity of bioactive compounds which are produced by microalgae and bioaccumulate in the marine food web. Phycotoxins affect the ecosystem, pose a threat to human health, and have important economic effects on aquaculture and tourism worldwide. However, human health and food safety have been the primary concerns when considering the impacts of phycotoxins. Phycotoxins toxicity information, often used to set regulatory limits for these toxins in shellfish, lacks traceability of toxicity values highlighting the need for predefined toxicological criteria. Toxicity data together with adequate detection methods for monitoring procedures are crucial to protect human health. However, despite technological advances, there are still methodological uncertainties and high demand for universal phycotoxin detectors. This review focuses on these topics, including uncertainties of climate change, providing an overview of the current information as well as future perspectives.
Azaspiracid toxins were first identified at the end of the last century in Irish mussels, and during the last two decades considerable cytotoxic and neurotoxic effects caused by these toxins have been described. Azaspiracids are synthesized by dinoflagellates and accumulate in several species of filter-feeding bivalve mollusks, thereby incorporating into the food chain and causing human intoxications. Among the cellular effects of azaspiracids, inhibition of spikes in neurons and hyperpolarization of the neuronal membrane potential have been reported; however, the underlying processes leading to these effects were never elucidated. In this regard, initial studies reported no activity of the toxin in neuronal voltage-gated sodium channels, and a recent work described no effect of azaspiracid-1 on the inactivation kinetics of voltage-gated sodium channels; however, the relationship between the known alterations of the cytoskeleton caused by these toxins and their effects on ion channels has never been evaluated. In this work, the cytotoxic effect of azaspiracids was evaluated in human cells as well as their activity on voltage-gated sodium channels and in cell morphology in order to unravel the cellular targets involved in the mechanism of action of this group of marine toxins. The data reported here demonstrate, for the first time, that both azaspiracid-1 and azaspiracid-2 caused a rapid concentration-dependent inhibition of the amplitude of voltage-gated sodium currents without affecting their inactivation kinetics, an effect that was increased after long-term treatment of the cells with the toxin. Simultaneously, long-term exposure of the cells to azaspiracids caused a profound alteration of the cell cytoskeleton and decreased the metabolic activity of human cells. Altogether, the data presented here indicate that the partial blockade of voltage-gated sodium channels by these toxins is not related with their effect on the actin cytoskeleton. However, since azaspiracids are common toxins in European waters, their effect on voltage-gated sodium channels, first reported here, should be considered to avoid synergistic toxicity with other marine toxins that are known potent blockers of sodium channels such as the saxitoxins and tetrodotoxins, but further studies are needed in order to elucidate how these compounds alter ion homeostasis.
Ciguatoxins (CTX) cause ciguatera poisoning, which is the most common reported human food poisoning related to natural marine toxins. Pacific ciguatoxins are the most abundant and studied CTX analogues; however, the growing distribution of Caribbean analogues and the limited data available on their biological effects make necessary to re-evaluate their relative potency. For decades, the guidelines established by regulatory agencies have assumed that the potency of the Caribbean CTXs were tenfold lower than the Pacific CTXs. We present here an integrated study involving Neuro-2a cells (the method used worldwide to test ciguatoxins), electrophysiological assays, and in silico simulations that evidence the similar cytotoxicity of Caribbean and Pacific ciguatoxins and their asymmetry binding within sodium channels. The binding mode of the toxins was first explored by molecular docking using the GOLD program and the resulting binary complexes were further studied by Molecular Dynamics simulation studies using the molecular mechanics force field AMBER. The simulation studies explain their distinct impact on the activation potential of the channel as experimentally observed and provide a detailed picture of the effects caused by these toxins on an atomic scale. Graphical Abstract
Azaspiracids (AZAs) are marine toxins produced by dinoflagellates belonging to the genera Azadinium and Amphidoma that caused human intoxications after consumption of contaminated fishery products, such as mussels. However, the exact mechanism for the AZA induced cytotoxic and neurotoxic effects is still unknown. In this study several pharmacological approaches were employed to evaluate the role of anion channels on the AZA effects that demonstrated that cellular anion dysregulation was involved in the toxic effects of these compounds. The results presented here demonstrated that volume regulated anion channels (VRACs) are affected by this group of toxins, and, because there is not any specific activator of VRACs besides the intracellular application of GTPγ-S molecule, this group of natural compounds could represent a powerful tool to analyze the role of these channels in cellular homeostasis. In addition to this, in this work, a detailed pharmacological approach was performed in order to elucidate the anion channels present in human HEK293 cells as well as their regulation by the marine toxins azaspiracids. Altogether, the data presented here demonstrated that the effect of azaspiracids in human cells was completely dependent on ATP-regulated anion channels, whose upregulation by these toxins could lead to regulatory volume decrease and underlie the reported toxicity of these compounds.
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